259 33 30MB
English Pages 836 [840] Year 1985
Molecular Mechanism of Steroid Hormone Action Recent Advances
Molecular Mechanism of Steroid Hormone Action Recent Advances Editor V Κ Moudgil
W DE
G
Walter de Gruyter · Berlin · New York 1985
Editor Virinder Κ. Moudgil, Ph. D. Department of Biological Sciences Oakland University Rochester, Michigan 48063 U.S.A.
Library of Congress Cataloging in Publication Data
Molecular mechanism of steroid hormone action. Includes bibliographies and indexes. 1. Steroid hormones-Receptors. 2. Hormones, Sex-Receptors. 3. Molecular biology. I. Moudgil, Virinder K., 1945QP572.S7M65 1985 599'.0142 85-6787 ISBN 0-89925-032-7 (U.S.)
CIP-Kurztitelaufnahme der Deutschen
Bibliothek
Molecular mechanism of steroid hormone action : recent advances / ed. V K. Moudgil. - Berlin ; New York : de Gruyter, 1985. ISBN 3-11-010118-1 (Berlin) ISBN 0-89925-032-7 (New York) NE: Moudgil, Virinder K. [Hrsg.]
3110101181 Walter de Gruyter • Berlin • New York 0-89925-032-7 Walter de Gruyter, Inc., New York
Copyright © 1985 by Walter de Gruyter & Co., Berlin 30 All rights reserved, including those of translation into foreign languages. No part of this book may be reproduced in any form - by photoprint, microfilm or any other means nor transmitted nortranslated into a machine language without written permission from the publisher. Printing: Gerike GmbH, Berlin. Binding: Dieter Mikolai, Berlin. Printed in Germany.
To dearest Bauji
FOREWORD
During the last two decades, progress in research on steroid hormone receptors has resulted in the development of new approaches for contraception and the diagnosis and treatment of endocrine-related disorders and cancers. Significant advancements also have been recorded in the purification, characterization and immunochemistry of steroid hormone receptors. However, despite such progress, understanding of the precise molecular mechanism of steroid hormone action has remained obscure. It is in the spirit of seeking a better understanding of the mode of action of steroid hormones that the idea of compiling such information was conceived. The chapters in this book represent invited contributions from the leading investigators engaged in research in the general area of steroid hormone receptors. The effort of comprising this volume has brought together the most significant and current work of prominent, world reknowned scientists. Each chapter has been written to provide the reader with an adequate background of the subject while, at the same time, introducing the state of the art and most current contributions of the investigator(s). Although many excellent books, monographs and comprehensive reviews on the subject already exist, limitation of such works has often times rested in the inadequate interpretation and discussion of the information reviewed. This book provides a first-hand interaction with the various approaches and directions adopted by the authors in their quest for knowledge of the molecular mechanism of steroid hormone action. The need for a discussion on this subject cannot be overemphasized since, even after great strides and significant achievements in the molecular aspects of steroid receptors, the native structure of the receptor molecule still alludes investigators. It is hoped that this book will provide a much needed and timely background for the cell, molecular and developmental biologist. Although the book was written with the scientist in mind, it should also provide an invaluable reference source for graduate students in biology and medicine.
VIII I am indebted to Dr. David Toft, Mayo Clinic, for introducing me to this most exciting subject of steroid hormone receptors, and most certainly for his continued guidance and encouragement. I thank Ms. Cynthia Winston for her secretarial assistance and Walter de Gruyter for the rapid publication of this volume.
The effort invested in the organization and preparation of this book is dedicated to the living memory of my father, Pandit Harbhagwan Moudgil.
Rochester, January 1985
The Editor
CONTENTS Structure and Molecular Organization Molecular organization of the estrogen receptor system AKIRA MURAYAMA Structure, properties and subcellular localization of the chick oviduct progesterone receptor JAN MESTER, JEAN-MARIE GASC, THIERRY BUCHOU, JACK-MICHEL RENOIR, IRENE JOAB, CHRISTINE RADANYI, NADINE BINART, MARIA-GRAZIA CATELLI and ETIENNE-EMILE BAULIEU Studies of the subunit composition of the 8.5S rabbit uterine progestin receptor LEE E. FABER, PINE-K., K. TAI, YOSHIAKI MAEDA and JOHN E. MYERS Alterations in mouse glucocorticoid receptor structure: Effects of various hydrolytic enzymes WAYNE V. VEDECKIS, BRANKA KOVACIC-MILIVOJEVIC, MARGOT C. La Pointe and CHERYL E. REKER Affinity labeling steroids as biologically active probes of glucocorticoid receptor structure and function S. STONEY SIMONS, JR The physiological significance of the structure of glucocorticoid and progesterone receptors CORIANNE M. SILVA and JOHN A. CIDLOWSKI Activation/Transformation An allosteric regulatory mechanism for estrogen receptor activation ANGELO C. NOTIDES, SHLOMO SASSON and STEVE CALLISON . Specific e f f e c t s of monovalent cations and of adenine nucleotides on glucocorticoid receptor activation, as studied by aqueous two-phase partitioning P.A. ANDREASEN and K. JUNKER
·
χ Low-molecular-weight and macromolecular translocation modulators affecting the binding of activated receptor-glucocorticoid complex to nuclei, chromatin and DNA FUMIHIDE BOHASHI and Y U K I Y A SAKAMOTO
225
The important role of cytoplasmic modulators in the pathway for steroid receptor to be converted to the biologically active form BUNZO SATO, YASUKO NISHIZAWA, KEIZO NOMA, M A K A T O NAKAO, SUSUMU KISHIMOTO and KEISHI MATSUMOTO
249
Phosphorylation Phosphorylation on tyrosine of the 17B-estradiol receptor FERDINANDO AURICCHIO, ANTIMO MIGLIACCIO, ANDREA ROTONDI and GABRIELLA CASTORIA
279
Phosphorylation of progesterone receptor JOHN J. DOUGHERTY
299
Purification, activation and phosphorylation of the glucocorticoid receptor THOMAS J. SCHMIDT and GERALD LITWACK
309
Interaction of nucleotides with steroid hormone receptors VIRINDER K. MOUDGIL
351
Regulation and Biological Responses Steroid hormone receptor dynamics: The key to tissue responsiveness THOMAS G. MULDOON
377
An endogenous ligand for type II binding sites in normal and neoplastic tissues B A R R Y M. MARKAVERICH and JAMES H. CLARK
399
Regulation of mammary responsiveness to estrogen: An analysis of differences between mammary gland and the uterus GOPALAN SHYAMALA
413
Progesterone regulation of nuclear estrogen receptors: Evidence for a receptor regulatory factor WENDELL W. LEAVITT
437
XI Receptors and biological responses of estrogens, antiestrogens and progesterone in the fetal and newborn uterus CHARLOTTE SUMIDA and JORGE RAUL PASQUALINI
471
Nuclear Components and Gene Expression Steroid receptor-DNA interactions S. A N A N D K U M A R a n d H E R B E R T W. D I C K E R M A N
505
The rat pituitary estrogen receptor: Role of the nuclear receptor in the regulation of transcription of the prolactin gene and the nuclear localization of the unoccupied receptor JAMES D. SHULL, WADE V. WELSHONS, MARA E. LIEBERMAN a n d J A C K GORSKI
539
Characterization of different forms of the androgen receptor and their interaction with constituents of cell nuclei EPPO MULDER and ALBERT 0 . BRINKMAN
563
Differential sensitivity of specific genes in mouse kidney to androgens and antiandrogens JAMES F. CATTERALL, CHERYL S. WATSON, KIMMO K. KONTULA, OLLI A . J A N N E and C. W A Y N E B A R D I N
587
Pharmacology and Clinical Correlations Molecular pharmacology of tamoxifen; an antiestrogen with antitumor properties in animals and man V. C R A I G J O R D A N
603
Studies on glucocorticoid receptors in normal and neoplastic rodent and human leukocytes: Structure, degradation, kinetics of formation and activation NIKKI J. HOLBROOK, JACK E. BODWELL, DIRK B. MENDEL and A L L A N M U N C K
637
Progestin treatment, progesterone receptors, and breast cancer KATHRYN B. HORWITZ, SCOT M. SEDLACEK, CAROYLN D'ARVILLE a n d LISA L. WEI
659
XII
Neurotransmission Steroid hormones, receptors and neurotransmitters GARY DOHANICH, BRUCE NOCK and BRUCE S. McEWEN
. . . . ο ....
.
701
New Systems, Techniques The steroid receptor of Achlya ambisexualis ROBERT M. RIEHL and DAVID 0 . TOFT . . . . . . . . . . . . . . . . .
733
The receptor for 2,3,7,8-tetrachlorodibenzo-p-dioxin: Similarities and dissimilarities with steroid hormone receptors LORENZ POELLINGER, JOHAN LUND, MIKAEL GILLNER and JAN-AKE GUSTAFSSON . . . . . . . . . . . . . . . . . . . . . . .
755
Separation and characterization of isoforms of steroid hormone receptors using high performance liquid chromatography JAMES L. WITTLIFF . . . . . . . . . . . . . . . . . . . . . . . . . . .
791
Author Index
815
Subject Index
. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
817
M O L E C U L A R ORGANIZATION OF THE ESTROGEN RECEPTOR SYSTEM
Akira M u r a y a m a Department of Physiological Chemistry, The Tokyo M e t r o p o l i t a n Institute of Medical Science, Honkomagome, Bunkyoku, Tokyo 113, Japan
Introduction Background Method Results A. Estrogen receptor system of the cytosol of porcine uterus. a) Basic estrogen receptor molecule estrogen receptor molecule
(vero-ER) and the proteolyzed
(secto-ER).
b) "8S" estrogen receptor-forming
factor.
c) Subunit structure of "8S" estrogen receptor-forming d) Purification of basic estrogen receptor molecule estrogen receptor-binding
factor.
(vero-ER) and
factors.
B.
Estrogen receptor system of the nuclei of porcine uterus.
C.
Molecular m e c h a n i s m of the translocation of estrogen receptor
from
the cytoplasm into the nucleus. a) Molecular m e c h a n i s m of "5S" estrogen receptor
formation.
b) M e c h a n i s m of the nuclear translocation of estrogen receptor. D.
Regulation of the reactivity of basic estrogen receptor molecule (vero-ER) w i t h estrogen receptor-binding
factors.
a) Strongly hydrophobic domain of basic estrogen receptor molecule (vero-ER). b) R e g u l a t i o n of association and dissociation of basic receptor molecule
estrogen
(vero-ER) w i t h estrogen receptor-binding
Discussion References
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
factors.
2 Introduction
Steroid hormone receptors are intracellular receptors, which recognize the hormones not on the cellular membranes, but in the inside of the target cells.
Since steroid hormones labeled with tritium of high specific
activity became available in the early 1960s (1,2), intensive studies have been made on steroid hormone receptors leading to many interesting proposals on the mode of action of steroid hormones (see reviews 3-13). However, there are as yet many discrepancies between the proposed molecular models of steroid hormone receptors, and little is known on the reactions of the receptors in the target cells to induce the hormonal responces. Precise information of the molecular organization of the steroid hormone receptor system is an important basis of the study of the action mechanism of the hormones.
We presented recently a new molecular model of the structural constitution of estrogen receptors (14-18) and progesterone receptors (19), which are
Θ
Estradiol
strongly hydrophobic domain 2.9S ER
Kd a 10 "M Kd = 10 Μ IMg 1 mM)
Bs
'5iER-FF (component A)
"5S'ER
^ Kd ^10*8M (Mg2* 1 mMI "6S"ER-FF (component Bl6
* "6S" ER
Sec/o-ER Kd => 10 Μ Kd = 10 Μ (M, 1 mMI
3.6SER
Fig. 1.
(.2SER
'8SER-FF Icomponent B)6 •(component Al
Molecular constitution of the estrogen receptor system
"8S" ER
(171
3 very similar to each other.
We showed that there is one basic estrogen
receptor (ER) molecule (vero-ER) (sedimentation coefficient, 4.5S; Stokes radius, 44 A) in the estrogen target tissues (14,18).
Vero-ER interacted
specifically with the endogenous components designated as ER-binding factors (ERBFs) ["5S" ER-forming factor ("5S" ER-FF), (component A);
"6S" ER-FF,
(component B).; "7S" ER-FF, (component B) ·(component A); "8S" ER-FF, b ζ (component B),•(component A)] to form estrogen receptors ["5S" ER, (verob ER)·("5S" ER-FF);
"6S"ER, (vero-ER)·("6S" ER-FF);
(component B)2·(component A);
"7S" ER, (vero-ER)·
"8S" ER, (vero-ER)•(component B)^·(component
A)] with various molecular constitutions (15-18).
Vero-ER is proteolyzed
by the endogenous proteases (20) to form various receptor fragments [sectoER (sedimentation coefficient, 4.5S; Stokes radius, 35 A); "3.8S" ER;
"4.2S" ER;
"2.9S" ER, etc.], which still bind with estradiol, but no
longer bind with ERBFs (14,18) (Fig. 1).
This chapter reviews the recent studies of our laboratory, and presents new conceptions of the molecular organization of the estrogen receptor system.
Background
Steroid hormone receptors are extracted in the cytosol fractions with the conventional buffers without utilizing detergents, in contrast to the membrane-bound receptors.
In spite of the facile extractability, study of
steroid hormone receptors on the molecular level is extremely troublesome. Two majour obstacles seem to have been disregarded until now in the study of steroid hormone receptors.
First, steroid hormone receptors undergo
complicated association and dissociation with endogenous protein factors, appropriate understanding of which is an important basis of the study of the receptor phenomena.
Second, steroid hormone receptors are extremely
susceptible to the modifications by the proteases coextracted with them. Through the proteolytic modifications, the binding site of the receptors to the hormones are slightly affected, while the capability of the receptors to undergo specific reactions with the endogenous protein factors is lost. The binding site to the hormone is only a part of the whole receptor molecule.
It is important to protect the steroid hormone receptors from the
4 endogenous proteases, and to separate them from the protein factors which associate with them with high affinities.
The following studies on the
molecular organization of the estrogen receptor system were undertaken by taking special care on these respects.
Methods A.
Buffer.
The following buffers were utilized.
TEMA [10 mM Tris, 1.5 mM EDTA, 1.5 iM
2-mercaptoethanol, 0.25 mM antipain (21), pH 8.0] buffer. of antipain) buffer.
TMA (TEMA devoid of EDTA) buffer.
TEM (TEMA devoid
P^EMA (n mM potas-
sium phosphate, 1.5 mM EDTA, 1.5 mM 2-mercaptoethanol, 0.25 mM antipain, pH 6.5) buffer.
Β.
Ρ EM (Ρ EMA devoid of antipain) buffer, η η
Porcine (gilt) uteri (18).
Gilt (female pig before her first conception) uteri weighing less than 80 g/uterus were collected at the local slaughter house immediately after the animals were killed.
The uteri were removed of connective and adipose
tissues, and immediately used for the experiments.
C.
Assay of estrogen receptor-binding factor (ERBF) activity (16). -13
The sample (0.1 ml in TEMA buffer) to be assayed was mixed with 2 χ 10 mol of basic estrogen receptor molecule (vero-ER) labeled with [ H]estradiol (assuming one molecule of vero-ER binds with one molecule of estradiol) in 0.1 ml of TEMA buffer, and then kept for 5 h at 1°C.
The mixture was then
subjected to sucrose gradient (5-20%) centrifugation in TEMA buffer, and ER activity appearing at 8S ("8S" ER), 6.5S ("6S" ER), 5.5S ("5S" ER), or 4.5S (vero-ER) was estimated.
One unit of "8S" ER-forming factor ("8S"
ER-FF), "6S" ER-FF, or "5S" ER-FF activity -13was defined as the amount of the respective factor to complex with 1 χ 10
mol of vero-ER to form "8S" ER,
"6S" ER or "5S" ER under the assay condition. D.
Estimation of the equilibrium dissociation constants (Kd) of the basic
estrogen receptor molecule (vero-ER) for estrogen receptor-binding factors (ERBFs) (22). Aliquots of respective ERBF-preparations (0.5 units in 0.1 ml TEMA buffer)
5 were incubated with preparations of labeled vero-ER ranging from 1 χ 10 Μ to 1 χ 10~ 9 Μ at 1°C for 5 h.
^
The complex, (vero-ER)· (ERBF), was sepa-
rated from vero-ER by sucrose gradient (5-20%) centrifugation.
It was
assumed that the dissociation of the complex, (vero-ER)·(ERBF), into veroER and ERBF during the process of the centrifugation was negligible, since the obtained sedimentation patterns of the estrogen receptors were symmetrical.
The equilibrium binding data obtained were plotted according to
Scatchard (23) assuming that one molecule of estradiol binds to one molecule of vero-ER.
Estimation of the apparent equilibrium dissociation con2+ stants in the presence of Mg was carried out similarly in TMA buffer (24)
Results
A.
Estrogen receptor system of the cytosol of porcine uterus.
a) Basic estrogen receptor molecule (vero-ER) and proteolyzed estrogen receptor molecule (secto-ER) (14,18).
The estrogen receptor (ER) of the
fresh cytosol sedimented at 8S ("8S" ER) in the low salt conditions, and at 4.5S in the presence of 0.4 Μ KCl or 0.4 Μ NaSCN (Fig. 2).
Similar remark-
able variation of the sedimentation pattern of steroid hormone receptors depending on the salt conditions have been widely reported.
The molecular
model of steroid hormone receptors is required to explain consistently the salt-dependent variation of the sedimentation pattern of the receptors. To solve this problem, it is necessary to separate the basic constituents of the receptor system from each other, and to reconstitute the association and dissociation.
When the cytosol was incubated in the presence of NaSCN for 12 h at 4°C and then analyzed, ER sedimented at 2.9S in the presence of 0.4 Μ NaSCN, and at 4.5S in the low salt conditions or in the presence of 0.4 Μ KCl (Fig. 2).
However, when the incubation of the cytosol with NaSCN was
carried out in the presence of antipain (0.25 mM), a protease inhibitor of microbial origin (21), the modification of the sedimentation pattern of ER through the incubation could be prevented (Fig. 2).
These results indicated
that the proteolytic modification of the cytosolic ER took place during the
6
Fig. 2. Sedimentation analysis of native and proteolyzed estrogen receptors (18). Sucrose gradient centrifugation was carried out either in TEMA buffer (A), in TEMA buffer containing 0.4 Μ KCl (D), or in TEMA buffer containing 0.4 Μ NaSCN (C). Labeled cytosol ( — Ο — ) . Labeled cytosol incubated in the presence of 0.4 Μ NaSCN for 12 h at 4°C ( — O " — ) . Labeled cytosol incubated in the presence of 0.4 Μ NaSCN and 0.25 mM antipain for 12 h at 4°C ( — # — ) . Fraction III (Fig. 3B) ( - & — ) . Fraction III + unlabeled cytosol ( — A — ) . Fraction II (Fig. 3A) ( — Q - — ) . Fraction II + unlabeled cytosol ( — • — ) . Fraction IV (Fig. 3B) (—57.—).
incubation with NaSCN in the absence of an appropriate protease inhibitor. We utilized antipain in the following study to prevent the eventual proteolytic modification of ER by the endogenous protease.
When the labeled cytosol prepared in TEMA (see method) buffer was subjected to a two-step gel filtration on a Sephadex G-150 column in TEMA buffer in the presence of 0.4 Μ KCl and in the presence of 0.4 Μ NaSCN, ER with a Stokes radius of 44 A (fraction III, Fig. 3B) and a sedimentation coefficient of 4.5S (Fig. 2) was obtained as a sole ER activity in the eluate. This indicated that there is one basic estrogen receptor molecule in the uterine cytosol.
The basic receptor molecule with a Stokes radius of 44 A
and a sedimentation coefficient of 4.5S was designated as vero-ER (vero, taken from the Latin verus).
Vero-ER by itself did not undergo self-associ-
60
50
AO
STOKES
30
RADIUS (A)
Fig. 3. T w o - s t e p gel f i l t r a t i o n of the labeled cytosol (16). (A) L a b e l e d cytosol w a s s u b j e c t e d to gel f i l t r a t i o n on Sephadex C - 1 5 0 in T E M A b u f f e r c o n t a i n i n g 0.4 Μ KCl ( Ο ), or in TEM b u f f e r c o n t a i n i n g 0.4 Μ KCl ( φ ). (Β) F r a c t i o n I ( Δ ) or f r a c t i o n II ( A ) w a s s u b j e c t e d to gel f i l t r a t i o n 3 on Sephadex G - 1 5 0 in T E M A buffer c o n t a i n i n g 0.4 Μ N a S C N . , [ H]estradio1 content; , a b s o r b a n c e at 280 nm. The a r r o w s i n d i c a t e the p e a k s of e l u t i o n for Blue D e x t r a n (BD), c a t a l a s e (Cat), a l d o l a s e (Aid), BSA, egg a l b u m i n (EA), and m y o g l o b i n (Myo).
ation and - d i s s o c i a t i o n depending o n the salt conditions
(Fig. 2).
When
the fraction of v e r o - E R w a s m i x e d w i t h unlabeled cytosol, ER sediraented a 8S under the low salt conditions suggesting the presence of a component ("8S" ER-forming factor, "8S" ER-FF) which binds w i t h vero-ER to form "8S ER in the cytosol
(Fig. 2).
When gel filtration of the labeled cytosol w a s carried out in TEM
(TEMA
devoid of antipain) buffer in the presence of 0.4 Μ KCl, ER eluted in the fractions
(fraction II, Fig. 3A) w i t h a smaller Stokes radius
compared to vero-ER.
(35 A) as
This indicated that vero-ER was proteolyzed by a
protease during the gel filtration in the absence of antipain. olyzed receptor with a Stokes radius of 35 A and a sedimentation cient of 4.5S w a s designated as secto-ER
The prote coeffi-
(secto, taken from the Latin
8 secare).
Secto-ER no longer possessed the capability to form "8S" ER when
mixed with unlabeled cytosol (Fig. 2). presence of 0.4 Μ NaSCN (Fig. 2).
Secto-ER sedimented at 2.9S in the
When secto-ER was subjected to gel fil-
tration in the presence of 0.4 Μ NaSCN, ER was eluted in the fractions with a Stokes radius of 24 A (fraction IV, Fig. 3B).
The ER of fraction IV
sedimented at 2.9S in the presence of 0.4 Μ NaSCN, and at 4.5S in the absence of NaSCN (Fig. 2).
These results indicated that in the presence of
0.4 Μ NaSCN, secto-ER is dissociated into "2.9S" ER fragment (Stokes radius, 24 A) and a counterpart with a similar molecular size.
b) "8S" estrogen receptor-forming factor ("8S" ER-FF) (15,18).
To analyze
the cytosolic factor ("8S" ER-forming factor, "8S" ER-FF) which binds with vero-ER to form "8S" ER, the unlabeled cytosol was subjected to gel filtration on a Sephadex G-150 column under the low salt (TEMA) conditions, and the eluate was divided into fractions as shown in Fig. 4.
1 BD 3000 -
Τ
I
1
I
Cat Aid Μ
Each fraction
1
BSA
EA
Myo
J
J
J
(A)
-
ο
ΪΪΑ
in
BCDE
F
G
Η
I
1500
radius(A)
(>5B)
50
t58_52)
40 STOKES
(52_50)
30 RADIUS (A)
0.5
i a 9
20
(50-48) (48-46) (46-38) (38-28) (28-19)
u
CE
/ 60
B
UJ
\
ου
1.0
(19>)
Fig. 4. Gel filtration of "BS" ER and "8S" ER-forming factor (15). Gel filtration of the labeled and unlabeled cytosol was carried out on a Sephadex G-150 column (1.6 χ 96 cm) In TEMA buffer. — Ο — , [ H]estradiol content; , absorbance at 280 nm. The arrows Indicate the elution peaks of the standards (see the legend to Fig. 3).
g
was assayed for the activity [ER-binding factor (ERBF) activity] to bind with vero-ER (sedimentation coefficient, 4.5S) to form ER with a higher sedimentation coefficient.
The main peak of "8S" ER-FF was eluted in the
fractions with a Stokes radius of approximately 51 A (fraction C in fig. 4B).
Other ERBF activity was not detected in the eluate.
"8S" ER-FF was
assumed to be a protein, since it was destroyed by trypsin, but not by DNase and RNase.
"8S" ER-FF did not bind with estradiol.
When a mixture
of vero-ER and "8S" ER-FF was subjected to gel filtration under the low salt (TEMA) conditions, ER eluted in the fractions with a Stokes radius of 68 A similar to the cytosolic "8S" ER (Fig. 4A) .
The levels of vero-ER and "8S" ER-FF of the cytosol preparations of various specimens of gilt uteri are shown in Fig. 5. ER was relatively small.
Variation of the level of
The ER-rich tissues contained approximately 2-
fold ER as compared to ER-poor tissues.
In contrast, the content of "8S"
ER-FF varied over 50 times among the tissues.
Positive correlation was
1
S 60
>
(Λ
• ··
5> 50 _ J2
1 §
Ο ι 11 I tr LLI
00
30
-
•
20
•
1 ·· •V* * τ» ·
-
• ·· ·
10
-
_
·
·
• •
•
J
«_
• •
· ·
·
·
·
•
• ·
k
.
1
1
l
Fig. 11. A n a l y s i s of the m o l e c u l a r forms of the c y t o s o l i c e s t r o g e n r e c e p t o r b i n d i n g factors In the p r e s e n c e of 0.4 Μ KCl at lower and h i g h e r t e m p e r a t u r e s (17). Gel f i l t r a t i o n of the u n l a b e l e d cytosol w a s c a r r i e d out on a S e p h a d e x G-150 c o l u m n in TEM buffer c o n t a i n i n g 0.4 Μ KCl at 4 ° C (A), a n d at 25°C (B) .
of the cytosolic estrogen receptor-binding factors (0.4 Μ KCl) conditions at lower
(4°C) and higher
(ERBFs) in the h i g h salt
(25°C)
temperatures.
The unlabeled cytosol w a s subjected to gel filtration in TEM buffer
contain-
ing 0.4 Μ KCl at 4°C and at 25°C respectively, and the eluates were assayed for ERBF activity. ER-forming factor
When the gel filtration w a s carried out at 4°C,
"7S"
("7S" ER-FF) which binds w i t h vero-ER to form ER sediment-
ing at 7S ("7S" ER) under the low salt conditions w a s eluted in the fractions with a Stokes radius of around 49 A (fraction Β in Fig. IIA).
Com-
ponent Β (basic unit of "6S" ER-FF) was further detected in the eluate (fraction H, in Fig. IIA).
"7S" ER-FF was shown to be a 1:2 complex of
component A and component Β (17).
These results showed that "8S" ER-FF
is dissociated into "7S" ER-FF and component Β in the high salt (0.4 Μ KCl) conditions at 4°C.
As expected, w h e n the gel filtration of the cytosol
was carried out at 25°C (condition of activation of the cytosolic
receptor),
"7S" ER-FF disappeared, and component A and component Β were eluted in the
20 respective fractions (fractions E' and H', Fig. IIB). ty was observed in the eluate.
No other ERBF activi-
These results supported strongly the assump-
tion that under the activation conditions, component A is liberated from the binding with component B, and then forms stable complex with vero-ER to form "5S" ER during the subsequent process of cooling the cytosol (Fig. 12).
The sedimentation patterns of of the reconstructed estrogen receptors and the cytosolic estrogen receptors are shown in Fig. 13.
"6S" ER, "7S" ER
and "8S" ER are present only under the low salt conditions, and dissociated into vero-ER and ERBFs in the high salt (0.4 Μ KCl) conditions. stable in the presence of 0.4 Μ KCl.
"5S" ER is
Under the low salt conditions, re-
constructed "5S" ER sedimented at 5.5S, however, the cytosolic "5S" ER migrated to the bottom fractions (Fig. 13A).
When the reconstructed "5S"
ER was mixed with the unlabeled cytosol and then analyzed by sucrose gradient centrifugation, ER migrated to the bottom fractions under the low salt conditions similar to the cytosolic "5S" ER (Fig. 13A).
These results indi-
ο
"8S" ER low salt, Λ "C
Vero-ER
"7S'ER-FF
O.iMKCI,
°
0
"5S*ER-FF
C U M KCl, 25"C
"5S"ER
Fig. 12.
Molecular mechanism of "5S" ER formation.
21
cated the presence of a cytosolic component (component C) which binds with "5S" ER under the low salt conditions.
b) Mechanism of the nuclear translocation of estrogen receptor (33).
It
was expected that difference in the capabilities to translocate into the isolated nuclei might be observed among the various forms of estrogen receptor (ER) reflecting the regulating mechanism of the translocation of ER from the cytoplasm into the nucleus.
Accordingly we compared the capabil-
ities of various forms of ERs to translocate into the uterine nuclei in an in vitro system.
The results are summarized in Table II.
The amount of
ER translocated into the nuclei was estimated by subtracting the amount of ER adsorbed on the nuclear envelopes from that of ER bound to the whole nuclei.
Vero-ER·Ε (vero-ER bound with estradiol) possessed an outstandingly
high capability to translocate into the nuclei as compared to the associated forms with ERBFs.
This suggested strongly that ER is translocated from the
Fig. 13. Sedimentation analysis of cytosolic and reconstructed estrogen receptors (18). Sucrose gradient centrifugation was carried out in TEMA buffer (A), and in TEMA buffer containing 0.4 Μ KCl (Β). Vero-ER ( — # — ) . Reconstructed "8S" ER ( _ Q _ ) . Reconstructed "7S" ER ( — Ο — ) . Reconstructed "6S" ER ( — Q — ) . Reconstructed "5S" ER ( — Δ — ) . Cytosolic "5S" ER ( — ^ ). Reconstructed "5S" ER + unlabeled cytosol ( — ) .
22 cytoplasm into the nucleus as vero-ER-E, and the translocation is suppressed through binding with ERBFs.
Astonishingly, in contrast to the previous
proposal (3,26,27,31), translocation of "5S" ER-Ε into the nuclei was nearly nil.
We mentioned above that "5S" ER in the cytosol is complexed with com-
ponent C under the low salt conditions.
The complex, ("5S" ER·E)·(component
C), possessed relatively high affinity for the nuclear envelopes, but did not translocate into the nuclei.
The adsorption of the complex to the
nuclear envelopes might have been taken as the translocation into the nuclei previously.
The slight nuclear translocation of ER observed when "6S" ER·Ε
and "8S" ER"Ε were incubated with the isolated nuclei is due to the liber2+ ation of vero-ER-E under the incubation condition caused by Mg added to the incubation medium to protect the nuclei (34). 2+ of Mg
The remarkable effect
on the dissociation of vero-ER from ERBFs is mentioned in the fol-
lowing section.
Table II.
The partially proteolyzed ERs (secto-ER-E and "3.8S" ER-E),
Capabilities of various forms of estrogen receptors to translocate into the porcine nuclei in an iri vitro system (33) .
ER· [''HIE
ER-[ H]E bound to the nuclei finol
ER- [ 3 H]E adsorbed to the nuclear envelopes
ER- [•'HIE translocated into the nuclei
flTDl
fmol
Translocation
%
226
35
191
75
65
45
20
8
110
37
73
29
100
40
60
24
133
110
23
9
Secto-ER- [•'hIE
85
68
17
7
"3.8S" ER-(3H]E
74
55
19
Β
Vero-ER- [-^HlE
"5S" ER-[3H]E
"6S" ER*[^H]E
"8S" ER· I^IE ("5S" ER-[3H]E) • (oonponent c)
^ R . [ 3 H]E (250 final) was incubated with the nuclei or nuclear envelopes in 0.32 Μ sucrose - 1 rrM MgCl 2 - 10 πΜ Tris-HCl - 0.25 irM antipain, pH 8.0, for 3 h at 4°C.
^obtained by subtracting the amount of ER adsorbed to the nuclear envelopes from that of ER bound to the nuclei.
23
which no longer interact with ERBFs, did not translocate into the nuclei. These results indicated that the binding site of vero-ER to ERBFs play important roles in the regulation of the translocation of ER from the cytoplasm into the nucleus.
It was assumed that the cytosolic protease might
reduce the hormone-sensitivity of the target cell through diminishing the amount of ER capable to translocate into the nucleus.
D.
Regulation of the reactivity of basic estrogen receptor molecule
(vero-ER) with estrogen receptor-binding factors.
a) Strongly hydrophobic domain of basic estrogen receptor molecule (vero-ER) (35)•
Vero-ER was shown to possess an extremely strong hydrophobic domain,
which is concealed through binding with estrogen receptor-binding factors (ERBFs).
Vero-ER freed from ERBFs was bound to a phenyl-Sepharose column
under the low salt (TEMA) conditions, and could not be eluted even with TEMA buffer containing 50% ethylene glycol (Fig, 14A).
Most of the strongly
hydrophobic proteins of the cytosol are eluted from the column with the low salt buffer in the presence of 50% ethylene glycol.
To elute vero-ER
from the column, it was necessary to utilize ethanol as a polarity-reducing agent.
Vero-ER could be eluted quantitatively from the column with TEMA
buffer containing 30% ethanol (Fig. 14A).
Dissociation of [ H]estradiol
from the receptor was negligible during the process of the elution from phenyl-Sepharose.
In contrast, reconstructed "5S" ER, "6S" ER and "8S" ER passed straight through the phenyl-Sepharose column in TEMA buffer (Fig. 14B).
This showed
that the strongly hydrophobic domain of vero-ER is concealed in the complexes of vero-ER with ERBFs.
The association and dissociation of vero-ER
with ERBFs is regulated mainly by ionic forces.
As mentioned above,
vero-ER is dissociated from ERBFs under the high salt (0.4 Μ KCl) conditions favorable for the hydrophobic interactions.
Accordingly, it is assumed
that the strong hydrophobic domain and the binding sites with ERBFs occupy different positions on vero-ER molecule.
Both secto-ER and "3.8S" ER passed straight through the column under the
24
FRACTION
NUMBER
Fig. 14. A n a l y s i s of h y d r o p h o b i g i t y of e s t r o g e n r e c e p t o r s w i t h a p h e n y l Sepharose c o l u m n (35). 1.6 χ 10 c p m of e s t r o g e n r e c e p t o r s in 1 m l of T E M A b u f f e r w e r e a p p l i e d (beginning a t the f i r s t a r r o w ) to 0.2 m l c o l u m n s equilibrated with TEMA buffer. The c o l u m n s w e r e w a s h e d 5 - t i m e s w i t h 1 m l T E M A b u f f e r c o n t a i n i n g 50% e t h y l e n e g l y c o l (the s e c o n d a r r o w ) . The c o l u m n s w e r e finally w a s h e d 5 - t i m e s w i t h 1 m l of T E M A b u f f e r c o n t a i n i n g 30% e t h a n o l (the third a r r o w ) . (A) V e r o - E R ( — O — ) . (B) R e c o n s t r u c t e d " 5 S " E R ( — β — ) ; r e c o n s t r u c t e d " 6 S " ER ( — * — ) ; r e c o n s t r u c t e d " 8 S " ER ( — # — ) . (C) S e c t o - E R (—Δ—); " 3 . 8 S " ER ( - - Ο - ) .
low salt conditions
(Flg. 14C), indicating that the strong hydrophobic
m a i n of vero-ER w a s totally destroyed by the endogenous protease.
do-
The c o n -
comitant removal of the strong hydrophobic domain and the binding sites w i t h ERBFs suggested that they occupy each other close positions o n vero-ER molecule.
b) Regulation of association and dissociation of basic estrogen receptor molecule
(vero-ER) w i t h estrogen receptor-binding factors
(22,24).
The
affinity of vero-ER w i t h ERBFs as estimated from the apparent dissociation constant 2.6 χ Ι Ο
(Kd) v a l u e s [2.5 χ 1 0 ~ 9 Μ ("8S" ER-FF); 3.0 χ 1 0 ~ 9 Μ ("6S" ER-FF); -10
Μ ("5S" ER-FF)] is very h i g h in TEMA buffer
(Fig. 15).
The a f -
finity of "5S" ER-FF for v e r o - E R is one order higher than the affinity of
25 "6S" ER-FF or "8S" ER-FF.
The stronger affinity of "5S" ER-FF to vero-ER
is an important basis of "5S" ER formation from "8S" ER as mentioned in the previous section. 2+ Astonishingly, Mg
at very low concentrations influenced significantly the
interaction of vero-ER with ERBFs.
The apparent Kd values of vero-ER for
9 ERBFs [3.5 χ 10~ 8 Μ ("8S" ER-FF); 6.0 χ ΙΟ" 8 Μ ("6S" 2+ ER-FF); 2.7 χ 10~ Μ ("5S" ER-FF)] observed in the presence of 1 mM Mg were all increased over 2+ 10 times as compared with in the absence of Mg (Fig. 15).
In Fig. 16 is shown the effect of Mg into the isolated nuclei.
2+
on the translocation of vero-ER
In the absence of ERBFs, vero-ER was translocated
into the nuclei almost quantitatively independent of the concentration of 2+ Mg . This indicated that the translocation of vero-ER dissociated from 2+ ERBFs is not influenced by Mg . As mentioned above, ERBFs inhibited the nuclear translocation of vero-ER under the conventional assay conditions 2+ (containing 1 mM Mg
for the protection of the nuclei).
The inhibitory
effects of ERBFs on the nuclear translocation of vero-ER were reduced dras-
Fig. 15. Scatchard analysis of the affinity of vero-ER with estrogen receptor-binding factors in the absence or presence of 1 mM MgCl (24).
26
•ο Ol
σ
.Ω 3
υ c
Ο NO "Ui *
MgCI2 (mM) 2+ Fig. 16. Effect of Mg on the nuclear translocation of vero-ER-E in the absence and presence of estrogen receptor-binding factors (24). Vero-ER-E (200 fmol) ( — O — ) ; vero-ER-E (200 fmol) + "5S" ER-forming factor (3 units) (—·—); vero-ER-E (200 fmol) + "6S" ER-forming factor (3 units) ( — * — ) ; vero-ER-E (200 fmol) + "8S" ER-forming factor (3 units) ( — · — ) ; labeled cytosol ( — α — ) .
tically by increasing the concentration of Mg In the presence of 5 mM Mg
in the incubation medium.
, the inhibitory effects of "8S" ER-FF and
"6S" ER-FF on the translocation of vero-ER into the nuclei were nearly nil. The inhibitory effect of "5S" ER-FF on the nuclear translocation of vero-ER 2+ disappeared completely in the presence of 10 mM Mg . These results showed 2+ that Mg
promoted the dissociation of YSXA-ER from ERBFs and restore the
capability to translocate into the nuclei.
As mentioned above, vero-ER
in the uterine cytosol is complexed with "8S" ER-FF in the low salt condi2+ 2+ tions when Mg is absent. In the presence of Mg (10 mM), however, the cytosolic receptor sedimented not at 8S, but migrated to the bottom frac2+ tions (24). Purified vero-ER sedimented at 4.5S in the presence of Mg (10 mM) (24). Accordingly it was assumed that, in 2+ the cytosol, vero-ER dissociated from "8S" ER-FF in the presence of Mg is bound to other macromolecule under the low salt conditions. In accord with the assumption, 2+ the promoting effect of Mg on the translocation of the cytosolic receptor 2+ into the nuclei was not evident (Fig. 16).
Anyhow, Mg
play important roles in the action mechanism of estrogen.
is expected to
27 Discussion
In this chapter, we presented new aspects on the molecular organization of the estrogen receptor system.
In the early 1970s, Mueller et^ a^l. proposed
presciently that "8S" ER is a complex of basic "4S" ER, which is common to different aggregates, and a subunit which does not bind estradiol
(4,36-38).
By incubating the labeled cytosol at higher temperatures they observed not "5S" ER formation, but formation of modified "4S" ER which no longer gives "8S" ER (4, 36-38).
They considered that the basic "4S" ER interacts with
a cytosolic factor which is dialyzable and ether soluble to form modified "4S" ER (4,37,38).
The possibility of the interaction of lipophilic lower
molecular components with the receptor remains, but the more frequently encountered modification of the basic "4S" ER into modified "4S" ER is caused by the endogenous protease.
Puca et al. reported for the first time the proteolytic modification of
2+ estrogen receptor by the endogenous Ca
-requiring protease (39).
They
further carried out detailed analysis of the estrogen receptor system by utilizing NaSCN to inhibit aggregation and dissociation of receptor
(40).
They proposed that "2.8S" ER is the basic subunit of estrogen receptor, and that "4S" ER (dimer), "5S" ER (tetramer), and "8S" ER (octamer) are formed through the self-association of the basic subunit (40). Modification
2+ of receptor by Ca
-not requiring protease takes place, however, in the
presence of NaSCN.
The disappearance of the property of the cytosolic
receptor to aggregate and dissociate through the NaSCN-treatment (40) is attributed to the proteolytic destruction of the binding site of the native receptor with receptor-binding factors.
The "2.8S" ER which they
observed in the presence of NaSCN, and proposed to be the basic subunit of estrogen receptor (40) is obtained from the proteolyzed receptor through dissociating at the nick by the chaotropic salt. Sherman e_t al. utilized antipain (21) for the first time to protect steroid hormone receptors from the endogenous proteases (41-43).
They reported
detailed analysis of the proteolyzed receptor (mero-receptor, "2-3S" receptor) and the relation to the native receptor (41-43).
The concentration
(50 mM) of the protease inhibitor utilized in their studies, however, might
28 be too high to be applied widely for the analysis of the receptor system.
Molecular organization of steroid hormone receptor systems might be similar to each other (44).
We showed that the oviduct progesterone receptor system
is similar to the uterine estrogen receptor system (19).
Colvard & Wilson
reported "8S" androgen receptor-promoting factor which binds with "4S" receptor to form "8S" receptor (45).
Joab et_ al^. reported that "8S" proges-
terone receptor contains a non hormone binding protein component which is common to "8S" receptors for other steroid hormones (46).
Receptor-binding
factors might be common for the receptors of different steroid hormones. It was proposed in various reports from O'Malley's laboratory that "6S" progesterone receptor is a complex of two different basic "4S" receptors (receptor A and receptor B) (7, 47, 48). It might be possible that receptor A and receptor Β suffered proteolytic modifications during the process of the purification.
Reconstruction of "6S" progesterone receptor from recep-
tors A and Β has not yet been accomplished.
The results presented in this chapter suggested strongly that vero-ER with the free binding sites to ER-binding factors and open hydrophobic domain is the activated receptor which translocates from the cytoplasm into the nucleus.
The temperature-dependent process for the activation of the recep-
tor (3,26,27,31) is assumed to be necessary to dissociate vero-ER from ER-binding factors.
King & Greene reported the exclusive localization of
estrogen receptor by utilizing monoclonal antibodies generated against estrogen receptor (49). for
It appeares that they utilized proteolyzed receptor
the production of the antibodies.
The possibility remains that
their antibodies recognized proteolyzed receptors, but failed to recognize native receptor. Proteolyzed receptor is easily detected in nuclei (25), but not in the fresh cytosol (14,18,41).
the uterine
Further detailed
study would be needed to solve the problem.
References
1.
Glascock, R.F., Hoekstra, W.G.: Biochem. J. 72^, 673-682 (1959).
2.
Jensen, E.V., Jacobson, Η.I.: In: Biological Activities of Steroids in
29 Relation to Cancer. 161-178 Press, New York 1960.
(G. Pincus & E.P. Vollmer Eds.), Academic
3.
Jensen, E.V., DeSombre, E.R.:
4.
Mueller, G.C., Vonderhaar, Β., Kim, U.H., Mahieu, L.M.: Ree. Prog. Horm. Res. 28, 1-49 (1972).
Ann. Rev. Biochem. 41, 203-230
(1972).
5.
Gorski, J., Gannon, F.: Annu. Rev. Physiol. 38, 425-450
6.
Yamamoto, K.R., Alberts, Β.Μ. : Annu. Rev. Biochem. 4_5, 721-746
(1976).
7.
Schräder, W.T., O'Malley, B.W.: In: Receptors and Hormone Action. 1 8 9 224 (B.W. O'Malley & L. Birnbaumer Eds.), Academic Press, New York 1978.
8.
Bualieu, E.E.: Klin. Wschr. 56, 683-695
9.
Clark, J.H., Peck, Jr.E.J.: Female Sex Steroids, Receptors and Function. Springer Verlag, Berlin 1979.
(1976).
(1978).
10. Baxter, J.D., Rousseau, G.G.: In: Glucocorticoid Hormone Action. 1-24 (J.D. Baxter & G.G. Rousseau Eds.), Springer Verlag, Berlin 1979. 11. Katzenellenbogen, B.S.: Ann. Rev. Physiol. 42, 17-35
(1980).
12. Kanazir, D.T.: In: Hormonally Active Brain Peptides. 181-214 (McKerns & Pantic Eds.), Plenum Publishing Corporation, New York 1982. 13. Moudgil, V.K.: In: Principles in Recepterology. Ed.), Walter de Gruyter, Berlin 1983.
273-379
(M.K. Agarwal
14. Murayama, Α., Fukai, F., Hazato, T., Yamamoto, T.: J. Biochem. 88, 955-961 (1980). 15. Murayama, Α., Fukai, F., Hazato, T., Yamamoto, T.: J. Biochem. 88^, 963-968 (1980). 16. Murayama, Α., Fukai, F., Yamamoto, T.: J. Biochem. 88^, 969-976
(1980).
17. Murayama, Α., Fukai, F., Yamamoto, T.: J. Biochem. 88, 1457-1466 18. Murayama, Α., Fukai, F.: J. Biochem. 89, 1829-1837
(1980).
(1981).
19. Murayama, Α., Fukai, F., Yamamoto, T.: J. Biochem.
1305-1315
20. Murayama, Α., Fukai, F., Murachi, T. : J. Biochem. 95_, 1697-1704
(1980). (1984).
21. Suda, H., Aoyagi, T., Hamada, M., Takeuchi, T., Umezawa, H.: J. Antibiotics 25, 263-266 (1972). 22. Murayama, Α., Fukai, F.: J. Biochem. 92, 2039-2042 23. Scatchard, G.: Ann. N.Y. Acad. Sei. 5^, 660-672
(1949).
24. Fukai, F., Murayama, Α.: J. Biochem. 95, 1227-1230 25. Murayama, Α., Fukai, F.: J. Biochem. 90, 823-832
(1982).
(1984).
(1981).
26. Jensen, E.V., Suzuki, T., Kawashima, T. Stumpf, W.E., Jungblut, P.W., DeSombre, E.R.: Proc. Natl. Acad. Sei. U.S. 59_, 632-638 (1968). 27. Gorski, J., Toft, D., Shamala, G., Smith, D., Notides, Α.: Ree. Prog. Horm. Res. 7A_, 45-80 (1968). 28. Giannopoulos, G., Gorski, J.: J. Biol. Chem. 246, 2530-2536
(1971).
29. Stancel, G.M., Leung, K.M.T., Gorski, J.: Biochemistry 12^, 2137-2141 (1973).
30 30. Rochefort, Η., Baulieu, Ε.Ε: Endocrinology 84, 108-116 (1969). 31. Jensen, E.V., DeSombre, E.R.: Science 182, 126-134 (1973). 32. Puca, G.A., Bresciani, F.: Nature 218, 967-969 (1968). 33. Murayama, Α., Fukai, F.: J. Biochem. 94, 511-519 (1983). 34. Tata, J.R.: In: Methods in Enzymology Vol. 31, 253-262 (S. Fleisher & L. Packer Eds.), Academic Press, New York 1974. 35. Murayama, Α., Fukai, F.: FEBS Letters 158, 255-258 (1983). 36. Vonderhaar, B.K., Kim, U.H., Mueller, G.C.: Biochim. Biophys. Acta 208, 517-527 (1970). 37. Vonderhaar, B.K., Kim, U.H., Mueller, G.C.: Biochim. Biophys. Acta 215, 125-133 (1970). 38. Mueller, G.C., Cowan, R.A.: Adv. Biosciences 1^, 55-76 (1974). 39. Puca, G.A., Nola, E., Sica, V., Bresciani, F.: J. Biol. Chem. 252, 1358-1366 (1977). 40. Sica, V., Nola, E., Puca, G.A., Bresciani, F.: Biochemistry 15_, 19151923 (1976). 41. Sherman, M.R., Pickerling, L.A., Rollwagen, F.Μ., Miller, L.K.: Fed. Proc. Fed. Am. Soc. Exp. Biol. 37_, 167-173 (1978). 42. Sherman, M.R., Berzilai, D., Pine, P.R., Tuazon, Fe.Β.: In: Steroid Hormone Receptor Systems. 357-375 (W.W. Leavitt & J.Η. Clark Eds.), Plenum Publishing Corporation, New York 1979. 43. Sherman, M.R., Tuazon, F.B., Miller, L.K.: Endocrinology 1Ό6, 17151727 (1980). 44. Hazato, T., Murayama, Α.: Biochem. Biophys. Res. Commun. 98, 488-493 (1981). 45. Colvard, D.S., Wilson, E.M.: Endocrinology 109, 496-504 (1981). 46. Joab, I., Radanyi, C., Renoir, M., Buchou, T., Catelli, M.G., Binart, N., Mester, J., Baulieu, E.E.: Nature 308, 850-853 (1984). 47. Schräder, W.T., Kuhn, R.W., O'Malley, B.W.: J. Biol. Chem. 252, 299307 (1977). 48. Coty, W.A., Schräder, W.T., O'Malley, B.W.: J. Steroid Biochem. 1Ό, 1-12 (1979). 49. King, W.J., Greene, G.L.: Nature 307, 745-747 (1984).
Acknowledgements This review is dedicated to the memory of the late Prof. Tadashi Yamamoto (1917-1981) who inspired me with his profound insights. I thank Dr. F. Fukai for his help in the preparation of this manusctipt.
STRUCTURE,
PROPERTIES
AND
SUBCELLULAR LOCALIZATION
OF T H E CHICK
OVIDUCT
P R O G E S T E R O N E RECEPTOR.
J a n Mester,
Jean-Marie
Gasc, Thierry
Buchou,
Jack-Michel
Renoir,
Joab, Christine Radanyi, N a d i n e Binart, M a r i a - G r a z i a Catelli,
Irene
Etienne-Emile
Baulieu INSERM U 33, Lab. Hormones, 94270 Bicetre, France
I.
Introduction
Although a considerable effort has been invested hormone now
receptors since their discovery
that
data
concerning
their
primary
in the study of
in the early sixties, structure
as w e l l
steroid
it is only
as
subunit
composition are becoming available. This breakthrough is to be thanked for mainly
to
the
progress
that
has
been
achieved
in
the
techniques
of
purification of these proteins w h i c h are not only relatively unstable, but also present at low concentrations in target tissues and h a v i n g a tendency to
aggregate
under
a
non-activated
receptor
problem
by
posed
variety forms
tendency
of
by
to
conditions.
molybdate
form
has
aggregates,
Stabilisation helped and
to
design
of
affinity derivatives makes it possible to obtain high purity of
several
purified
kinds receptor
immunohistological
of
steroid hormone preparations
studies.
receptors.
have
In this
been
Antibodies
raised
chapter, we
results concerning the chick oviduct progesterone
and
of
the
surmount
the
suitable preparations
against used
such
in
shall review our
recent
receptor.
II. Background
1)
Chick oviduct as a target tissue for progesterone. The term "progesterone" is in fact a m i s n o m e r insofar as the chicken
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
is
concerned
as
there
is
no
gestation
to
maintain.
However,
progesterone is secreted during the egg-laying cycle of the h e n and is apparently
important
in its regulation. Their effects in the oviduct
fall roughly into two categories. First progesterone is an inducer of synthesis
of
(immature)
chick has
several
leads to development
of
the
egg
white
proteins.
to be first exposed of the tubular
the oviduct. After w i t h d r a w a l
For
this,
the
to estrogen priming
which
glands in the m a g n u m p o r t i o n of
of estrogen,
the
tubular
gland
cells
respond to progesterone by synthesis of large quantities of egg white proteins,
mainly
ovalbumin,
conalbumin,
ovomucoid
and
lysozyme.
A
secondary treatment of estrogen-primed, w i t h d r a w n chick w i t h e s t r o g e n has a similar effect on the synthesis of these proteins in the tubular glands,
and
induces,
progesterone least
partly
antagonizes
in
addition,
tissue
growth.
The
effects
and estrogen on the egg white p r o t e i n synthesis additive certain
of
(see
reviews
the
estrogen
1,
2).
Second,
effects,
for
growth and d i f f e r e n t i a t i o n of the immature oviduct
of
are at
progesterone
instance
tissue
(3, 4), as w e l l as
growth of the "withdrawn" oviduct tissue induced by estrogen
treatment
(5-7). In terms of specific p r o t e i n synthesis, progesterone has often a transient "antiestrogen" effect instance,
it retards
conalbumin synthesis estrogen + (6).
the
: during a short period of time, for
estrogen-induced
increase
in the rate
(6, 8). Similar observations hold also
progesterone-induced
Induction of ornithine
changes
in DNA-polymerase
decarboxylase,
an enzyme
for
of the
activity
implicated
in
polyamine synthesis and known to be active in growing tissues
(9) is
another
These
estrogen effect
observations
(10)
inhibited
by progesterone
(11).
are correlated with, and perhaps a consequence of,
decrease in the nuclear (and total cellular) estrogen receptor
the
content
of the oviduct cells after treatment w i t h estrogen and progesterone as compared
to estrogen alone. For more
progesterone
information on the effects
in the chicken oviduct, see the reviews cited above
2) and references
therein.
of (1,
33 Early studies on the chick oviduct progesterone receptor. Since the first report of Sherman et al. (12) it is known that the high
affinity progesterone-binding
recovered
in the high-speed
protein of the chick oviduct
supernatant
of
the tissue
is
homogenate.
Consequently, it has been assumed that, as the other steroid hormone receptors, also this one is a cytoplasmic protein. (This assumption is at present questioned Already
: see section V).
in the immature chick oviduct, progesterone 3
levels of
the order
hormone binding molecule.
of
10
molecules
per
cell
receptor is at
as determined
by
(13), assuming one progesterone binding site/protein
Estrogen priming
leads to tissue differentiation
so that
eventually some 90 % of the cells become 4organized in tubular glands ; at
this
stage,
there
are
some
5-7.10
progesterone
binding
sites/cell. Estrogen withdrawal is followed by a progressive but not rapid loss of the progesterone receptor : while the tissue regresses from 1-2 g to about 100 mg after 2 weeks and remains without further change,
the
progesterone
receptor
concentration
is
approximately
halved at 2 weeks of estrogen withdrawal and again after the following 2-3 weeks
(13). Secondary
estrogen administration
induces again an'·
augmentation of the progesterone receptor level, probably by the novo synthesis, after an
6 h lag (14).
Treatment in vivo with progesterone "translocates" only a relatively small fraction of the total cellular
progesterone
receptor
to the
nucleus. While this "translocation" may not imply a shift from the cytoplasm to the nuclear compartment in the anatomical sense, the data reflect the fact that a portion of the total receptor population has become
associated
with
the nucleus
sufficiently
tightly
to
resist
solubilisation by the (low-salt) homogenization buffer. The proportion of
the
"nuclear"
receptor
decreases
during
the
hours
following
progesterone administration and by 6 h it differs little from that in untreated controls) . Gel filtration studies suggested heterogeneitey of the chick oviduct progesterone receptor : as many as five species differing by their
34 Stokes radii order
were identified and numbered I - V, in decreasing
(15). The largest
(non-activated The
two
(form I) is probably a mixture of a "native"
; see further) receptor and heterogeneous
following
progestin-binding
species, proteins
on
the
other
in monomeric
hand,
are
aggregates.
authentic
state. They can be
easier
resolved by ion-exchange chromatography and are now currently referred to a "subunit A" identification
(= form
was
III) and
subsequently
"subunit
made
B"
possible
(= form II). Their by
the
use
of
a
photolabile progestin R 5020, which can be covalently attached to the binding proteins by exposure to UV light (16). Their molecular weights were found analysis
to be
108K (B) and
79K
(A), respectively, by
SDS-PAGE
(see 17, 18 for review). Finally, the forms IV and V turned
out to be fragments formed from the A and/or Β subunits by action of an endogenous, Ca
2+
-activated protease (19, 20).
II. Definition of "native" and "activated" ("transformed") receptors. 3 The
H-progesterone-receptor
complexes formed
in the soluble fraction of
the homogenate of chick oviduct tissue, at low ionic strength and at low temperature, display the characteristics of what has been termed "native", i.e. non-activated
form. This means
nuclei or to their components
that they do not bind
to
isolated
(chromatin, DNA), nor to certain synthetic
polyanions (phosphocellulose ; ATP-agarose). Within < 1 h at incubation at > 20°C or at high ionic strength acquire
the capacity
to bind
(> 0.3) the receptor-hormone
to the above-mentioned
structures, although the binding is frequently change of properties has been initially
solid
incomplete
complexes
supports
or
(21, 22). This
termed "activation" since it is
presumed that binding to the nuclear components implies that the receptor is active in mediating hormonal effects on gene expression. Until present, no
in vitro
test
of
receptor
"activity"
is available
and
therefore
"activation" remains a concept based on hypothesis rather than facts. It is also to be printed out that the binding of receptors to the cell nucleus does
not
always
lead
to hormonal
effects
(for
ex.
in
the
case
of
antiestrogen-estrogen receptor complexes of the chick oviduct, 23, 24).
35 As
a
result
of
"activation",
physico-chemical
progesterone receptor are altered
properties
of
the
: the hormone receptor complexes become
smaller as reflected by a change of their sedimentation coefficient 8S to 4S) and R is tightened, Acquisition
s
leading
of
(from
(from 7.7 nm to 5.2 nm) and the binding of the hormone to a longer half-time
affinity
for nuclei,
of dissociation
chromatin, DNA and
(25, 27).
the change of
physico-chemical properties of the chick oviduct progesterone receptor have always
been
observed
to
occur
simultaneously.
"transformation", is preferred by some authors
An
alternative
term,
(19) to cover the ensemble
of the changes on receptor characteristics (see also section IV.4).
III. Methods
All methods are described in detail in the articles cited. The procedure we have developed for purification of the different forms of the progesterone receptor are schematically represented by a flowchart
(Fig.
1). Affinity
chromatography was performed by loading the high-speed supernatant of the homogenate of estrogen-stimulated of NADAC-Sepharose
(immature) chick oviducts onto a column
(28) ; the gel was washed
containing KCl and urea and eluted eluates
were
then
subjected
elution was carried
to
with 2 μΜ
fractionation
out by applying
sequentially with 3 H-progestin
(29, 31). The
on DEAE-cellulose
a continuous
buffers
where
or discontinuous
KCl
gradient. The choice of buffers throughout purification was dictated by the forms of receptor desired to obtain. The non-activated
form had to be protected by
including 20 mM Na2MoO^ ; in addition, the concentration of urea had
to
be kept < 2.5 Μ during the affinity gel washing procedure since above this limit, a significant proportion of the receptor becomes transformed (32). To purify
the "activated"
receptor, KCl
(0.3 Μ) was added
to 4S
to the
cytosol > 1 h prior to loading onto the affinity native (26, 30). When the receptor was to be crosslinked with glutaraldehyde, phosphate buffers were used instead of Tris. Antibodies
raised
against
the progesterone
receptor
IgG-RB and monoclonal BF4) are characterized 33, 35.
(polyclonal
in Table I and
IgG-G,
references
36 Fig. 1 : Progesterone receptor purification flow-chart (refs. 28, 31). Chick oviduct tissue
Homogenization in 3 vols, of buffer Ultracentrifugation
High speed supernatant
Alternative procedures
+ Na.MoO, (20 mM) 2 4
+ KCl (0.3 Μ ) > 1 h at 0°C
Chromatography on NADAC-Sepharose / \ (ref. 28)
Eluate
Eluate
\
/
Chromatography on DEAE-Celluose (elution with KCl gradient)
\ Purified non-transformed (8S) receptor
Two forms of the purified transformed receptor eluted at 0.08 Μ (subunit A) and > 0.2 Μ KCl (subunit Β)
Iimnunohistological experiments were performed with paraffin sections of the tissue which had been fixed by one of the following procedures (36) : -
Bouin's
fluid
for 60 to 80 min, followed
by several washes
in 70 %
ethanol. - Carnoy's fluid for 60 to 80 min, followed by several washed in absolute ethanol.
37 - Glutaraldehyde
(0,5 %) in 0,1 Μ Soerensen buffer pH 7.4 for 90 min,
followed by several washed in either Soerensen buffer or PBS. - Absolute ethanol + 17, acetic acid for 60 to 80 min, followed by several washed in absolute ethanol. Dehydration was made in graded ethanol when needed, and terminated in 1-butanol before embedding
in paraffin.
For antibody
reactions,
the
sections were deparaffinized, rehydrated and rinsed with PBS. They were then incubated first in 3 % non-immune serum of the animal species in which the second antibody was raised. The excess of serum was removed and the sections were incubated with the first antibody (90 to 120 min). After washing in PBS, sections received the second biotinylated antibody (dilution 1:400 ; 30 min). The second antibody was removed by washing with PBS and complexed with avidin-biotin-peroxidase the
peroxidase
activity
tetrahydrochloride
was
revealed
by
(30 min). After washing, 3-3'-diaminobenzidin
(DAB) (0.5 mg/ml) in presence of 0.01 %
·*"η
^
7.6 Tris buffer. Sections were then rinsed, dehydrated and mounted.
TABLE I : Antibodies against the chick oviduct progesterone receptor (PR)
Antibody
Raised Non-den 90% labeling efficiency of the receptors by removing low molecular weight thiols and by adjusting the time 3 and temperature of the reaction, the concentration of receptor and [ H]Dex-Mes, and most importantly the pH of the reaction solution (31) . We had previously determined that a-keto mesylates preferentially reacted with thiols and that virtually no reaction occurred unless the thiol group was ionized (14).
Accordingly,
when the pH of 3 the reaction solution at 0°C was varied from 6.7 to 8.6, the yield of [ H]Dex-Mes—labeled
98K receptors increased from M 8 %
to
•^92% of the available receptors in ( N H ^ ^ S O ^ precipitated rat liver cytosol (as determined by [^H]dexamethasone binding at the same pH) (31; see also Section IIB).
It could be calculated from these data that, if a
single amino acid was being labeled by Dex-Mes, that amino acid had a pK^ of "W.4. While this appears low for the pK a of a cysteine, the pKa of the 3 -SH group in bovine serum albumin is 7, 3 8 1 - 3 8 8 ( 1982) .
B.C.,
Litwack,
G.:
Endocrinology
83. G r i p p o , J.F. , T i e n r u n g r o j . W., D a h m e r , M . K . , H o u s l e y , P.R., Pratt, W . Β . : J . iol. Chem. 2J58, 1 3658-1 3664 ( 1983) . R . Η . S. :
84. D u b o s , R.J., T h o m p s o n 5 0 1 - 5 1 0 (1938). Liao,
S.:
85.
Liang, Τ. ( 1974).
86 .
B a r r a c k , E.R., Coffey 7 2 6 5 - 7 2 7 5 (1980).
J. Biol. Chem.
J. Biol. Chem.
87 . F e l d m a n , Μ., K a l l o s , J. 256, 1 1 4 5 - 1 1 4 8 (1981).
D.S. :
2_49,
J. B i o l .
Hollander,
4671-4678
Chem.
V.P.:
124,
255,
J. Biol.
Chem
349 88. L i a ο , S., Sraythe, S., Tyraoczko, J . L . , R o s s i n i , G . P . , C h e n , C., H i i p a k k a , R.A.: J. B i o l . C h e m . 255 , 5 5 4 5 5551 (1980). 89. T y m o c z k o , J . L . , S h a p i r o , J., S i m e n s t a d , D . J . , Nish, J. S t e r o i d B i o c h e m . J_6, 5 9 5 - 5 9 8 (1982). 90. C h o n g , M . T . , L i p p m a n , M . E . : 3002 (1982).
J. B i o l . C h e m . 2_57,
91. R o s s i n i , G . P . , B a r b i r o l i , B.: C o m m u n . U 3 , 8 7 6 - 8 8 2 ( 1983).
Biochem.
Biophys.
A.D.:
2996Res.
92. H u t c h e n s , T . W . , M a r k l a n d , F . S . , H a w k i n s , Ε . F . : Proc e e d i n g s of the 64th Annual M e e t i n g of the E n d o c r i n e S o c i e t y , a b s t . 568, (1982). 93. H u t c h e n s , T . W . , M a r k l a n d , F . S . , H a w k i n s , Ε.F.: B i o p h y s . Res. C o m m u n . 105, 20-27 ( 1 9 8 2 ) . 94. T y m o c z k o , J . L . , P h i l l i p s , M . M . : 142-149 (1983).
Endocrinology
Biochem. 112,
95. S i n g h , V., E e s s a l u , T., G h a g , S., M o u d g i l , V.: Excerpta M e d i c a , A b s t r a c t s of the 7th I n t e r n a t i o n a l C o n g r e s s of E n d o c r i n o l o g y , a b s t . 2095, E l s e v i e r S c i e n c e P u b l i s h e r s Co . , Inc . , New York ( 1984) . 96. H o u s l e y ,
P.R.,
P r a t t , W . B . : Fed. Proc . 43, a b s t . 908( 1984)
97. M i l l e r , A . S . , S c h m i d t , T . J . , L i t w a c k , G.: Excerpta Medica, A b s t r a c t s of the 7th I n t e r n a t i o n a l C o n g r e s s of E n d o c r i n o l o g y , a b s t . 1056, E l s e v i e r S c i e n c e P u b l i s h e r s Co., Inc . New York ( 1984) . 98. Van B e l l e , H.:
Cell C a l c i u m
99. A r any i , P., N a r a y , Α.: 272 (1980). 100. Van B o h e m e n , C . G . , P h y s i o l . 4. 9 5 - 1 1 0
2, 4 8 3 - 4 9 4
J. S t e r o i d
E l i a r d , P.H., (1983).
102. Z o l l e r , M . J . , T a y l o r , 8368 ( 1 9 7 9 ) .
S.S.:
(1981).
Biochem.
VZ,
267-
Rousseau, G.G.:
Mol.
J. B i o l . C h e m . 254,
8363-
103. H a t h a w a y , G . M . , Z o l l e r , M . J . , T r a u g h , J . Α . : C h e m . 2_5_6, 1 1442-1 1446 ( 1981 ).
J.
104. H o p p e , J., F r i e s t , W.: ( 1979) .
141-146
Eur. J. B i o c h e m .
105. S c h m i d t , T . J . , M i l l e r - D i e n e r , C h e m . 219, 9 5 3 6 - 9 5 4 3 (1984).
93,
Α., L i t w a c k , G.:
Biol.
J.
Biol.
INTERACTION
OF
V i r i η der
Mo u d g i 1
Κ.
NUCLEOTIDES
WITH
STEROID
HORMONE
RECEPTORS
Biochemical E n d o c r i n o l o g y L a b . , Department of Biological Sciences, Oakland U n i v e r s i t y , Rochester, Michigan 48063
Introduction
Under to
physiological
enter
tor
their
proteins
receptor
its
to
sites
chromatin sponse
is
called
interaction
atin
form
complex
alteration
conditions,
target
(2,3).
regulation
to
The
be
of
gene
expression
receptors
seem
to
and
in
triggering
have
chemical data
techniques
which
aided
in
the
ported plasm.
resulted
the
teraction in
of
to
be
Upon are
physiologic
Recently, and
from
by
a
with
predominantly
to
that
rat
the
in
into
and
the
recepbio-
ligands. such
The
approaches
for
(4).
the
binding
hormone
mechanism
the
re-
hormonal
established,
hormonal
hormones,
nuclear
hormone
employed
receptors
localized
relocate
in
Steroid
uterus
steroid
of
in
to chrom-
hormonal
histochemical
two-step
the
prior
a
been
both
response.
steroid-
nuclear
with
events
yet
radiolabeled
of
availability
not role
studies
hormones,
believed
has key
recep-
The
eliciting of
believed
temperature-dependent
receptors
for
studied
using
estradiol of
a
hormonal been
formulation
absence
complexes
trogen
a
generally
play
a
undefined,
sequence
but
tors
of
essential
complete
are
specific
'transformation' yet
interaction
to
The
as
with
complexes.
undergo or
certain,
hormones
interact
hormone-receptor
'activation'
appears
steroid
and
thought
with
(1).
cells
the
in-
Accordingly,
have
been
target-cell
recyto-
receptor-hormone nucleus
under
conditions.
nuclear
localization
progesterone
has
of
been
unoccupied demonstrated
receptors in
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
the
for target
es-
352 cells The
by
use
receptor
of
may,
therefore,
with
the
a
the a
sites.
process
In
be
complexed not
bind
capacity at
can
elevated
tion
of
(see
review
by
the
such
clei,
with to
been
temperature
in gel
by
1).
The
and
now
nonactivated
an
agent
which
have
A
been
number
lieved no
to
factor
of
recently
appeared
factors the
to
be
target
nuclear
high of and
on
conditions,
hormone,
by
by
treatments
other
complexes for
and
have
are
on
dilu-
activated
isolated
resins
unstable
can
of
receptors
the
be
against and
results
This
maintained
sodium
capacity)
pro-
activation
preparations.
presence
(2,
in
procedures
receptor
nu-
altered
ion-exchange
receptors
and
binding
ionic
affinity
preliminary
progesterone-
cellular
influence
The
receptor
the
the
that
binding
Thus,
from
purification
steroid
steroid
(19).
purified
reported
of
of
in
as
complexes
studies
and
of
nonactivated
complexes
crude
form
stabilizes
(loss
activation
tivation
in
correct,
thought
can
increased
overcome,
be
to the
receptors
presence
lengthy
to
be
lead with
steroid
phosphocellulose,
the
only
the
under
mobility
associated may
event(s).
filtration
previous
been
prove
(5-8).
homogenate
complex
could
steroid-receptor
and
and
(1),
their
their
vitro
steroid-receptor
form
hormone
(9,10).
the
develop
kinetics
loosely
extraction
form
a
is
receptors
to
of
the
postulations
nuclei in
approaches
steroid-receptor
their
cytosol, ref.
that
temperature,
hormones
in
inactivation
upon
other
fraction
with
intranuclear
low
performed has
binding the
acquired
activation
problem
receptor
these
isolated
be
Since
nonactivated
had
at
cytosol
steroid
systems,
DMA-cellulose
dissociation
mote
the
treatments
10-18).
of
Should of
cytosols
do
the
its
representing
cell-free
tissue
and
association
activation
in
represent
nucleus,
tighter
nuclear
i m m u n o h i stochern i c a 1 a n d
recovered
molybdate, thermal blocks
on
heat
ac-
glucocorticoid
receptors
reported
are
(20,21).
have
process
of
necessary
been
receptor for
which
activation.
heat-activation
beWhile
of
353 purified
chicken
cellulose purified
have
been
which
reported
forms
produce
the
(24).
tentiates' (25-27).
5S
activated 8S
to An
4.5S form
influence
with
of
trix
i_n_ vi t r ο .
have
been
form
of
under
and
be
to
mutant
the
an
CEM-7
(31).
process
of
also
has
been role
step
activation
of
A
in
in
the
rat
in
the
the
nonactinuclear
ma-
activation
activation intact
of
cells
of
normal
resistant
activation
factors,
receptors
'po-
vitro
response
be
to
uterine
Zn++
glucocorticoid to
re-
converts
receptor
cellular
steroid
in
towards
shown
reported of
to
a
receptor
that
that
conditions,
been
(28-30).
exact
on
steroid
nuclei
receptor
in
factors
protein,
reported
affinity
cell-free
of
reported to
0Ν A the
cellular
estrogen
factor
studies
obligatory
cells The
a
androgen
has
glucocorticoids
of
fective
to
been
receptor
reduced most
of
a
on
complexes
many
activator
have
identified
Although
receptors
appears
has
(20),
conferred
activation
form
Wilson
the
glucocorticoid
cells
form,
shows
performed
4S
androgen
also
the
receptor
the
and
have
which
be
Furthermore,
estrogen
activated
binding
receptor
only
glucocorticoid-receptor
Colvard
They
could
(21).
a complex
cytosol
vated
system
(22,23).
progesterone
capacity
nonactivated
reconstituted
ceptors
oviduct
binding
if
de-
any,
remains
to
in be
established.
Mechanism
A
number
chanism
of of
tivation the
4S
is
Nielsen been the
activation
hypotheses activation
has
to
monomers This
of
5S or
been
of
steroid
have of
been
steroid
explained
by
transformation
of
the
addition
of
consistent
with
(36)
showed
which
suggested
that
sedimentation
the a
a
proposed
to
receptors
explain
rat
uterine
second and
the
steroid
model
estrogen binding
studies order
the
me-
(1,13,32-34).
dimerization
kinetic
of
receptors
the
non-steroid
activation
properties
hormone
of
Not ides
reaction.
receptors
on
receptor
subunit
It
accompanying
Ac-
based
(35).
and has
changes
are
two
in
dif-
354 ferent shown
processes that
(37,38).
estrogen
monomeric
receptor
and
quent
and
separate
event.
units
(7-9S
receptor
to
3.4S)
that
and
(43,44)
postulated
the
are
receptor,
receptors
may
difficult
to
thesis
be
been that
that
and
requires
only
transformation
of
steroid
be
described
steric ation
mechanism of
Measurement The
extent
measuring
of
nuclei
Toft
(46)
be
binding
Weichman
activation
and
or
John
comparable, can
be
have
H]estradiol
from
exponential
process.
the
dissociation the
netics
[
of
slow
ATP
is
the
by
steroid It
one
is
hypo-
steroid
(34).
reported
The
from
favour in
a 1..
with
of
studied
result
et
steroid
process.
an
the
of
generally
this allo-
dissoci-
[
determined
complexes
to
phosphocellulose.
(47) of
have All
three
using
H]estradiol from
the
dissociation,
and
another determining
methods
appear
portion
of
ATP-Sepharose.
receptor fast
by
a greater
demonstrated
The
by
target
Miller
introduced
activation
although
estrogen
component
Hjestradiol
Sherman
form
to
of
progesterone-
hormone
appears
detected
(15)
[
receptor;
of
sub-
associated
the
steroid-receptor
measurement
Notides
for
proteolysis
of
subse-
a consequence
activation
by
a
(1,41,43-45).
component from
of
receptor a3 n d
later)
ATP-Sepharose.
qualitatively
activated
tion
to
of some
presence
DNA-cellulose
involves
and
as
the
activation
of
Moudgil
RNA
recently
in
receptor
(42).
native
may c o n s e q u e n t l y
receptor binding
as
activation
receptors
subunits
receptor
and
and
that
receptor to
of
the
cell
method
which
receptor
their
the
the
or
of
accepted
contain
process of
laboratory
(to
in
have
change
follows
receptors
may
in
the
activation
systems
with,
widely
dissociation
involved
explain
since
receptor
and
(39)
dissociation
glucocorticoid
oligomers
Gorski
dimerization The
has
(5,20,40,41) have
and
a conformational
concurrently
activation,
receptors
Sakai
induces
that
the
follows
component
from
the
activated therefore,
dissociaa
two-
results
nonactivated one.
The
provide
ki a
355 sensitive
criterion
ceptor
general
The
in
monitoring
of
has
receptor
complexes
glycerol
or
upon
earlier. more
widely
used.
with
criterion
two
states
it
one
molecular
is
by
of
re-
molecules
are
transforming
form
to
observe receptor
salt-free to
agents
receptor
of
steroid-
in
converted
measuring
possible
sedimentation
nonactivated
7-9S and
the of
and
The
as
gradients
treatment
from
the
transformation
sediment
sucrose
direct
change
been
This
distinguishing
receptor
analysis
eties
for
(48,49).
a
3-5S
described
activation
gradual, to
moi-
is
complete
another
following
activation.
Influence
of
nucleotides
Munck
and
Brink-Johnsen
cific
binding
of
Subsequently,
in
forms,
steroid was
binding
receptor version In
and
suggested was to
other
loss
of
that
form
that
incompetent
during ATP
it
was
an
(52).
partially
restored
phosphatase
steroid
to
established
is
be
its
release
from
at
mouse
by
an
of
from
and
the
the
be
that
slowed
and
its
ATP-Mg
Moudgil
and
that
the
(L-cells) by
the
the
John
cytosol
nucleotides
in
generating
receptor
binding
systems.
can
presence
(44)
in
of
ad-
of
binding
(capable
con-
thymocytes in
the
process.
capacity
rat
It
nucleus,
ATP-dependent
binding
with
exists
percursor.
the
fibroblast
can
L-cells
(52,53).
other
generate
spepro-
receptor
demonstrated
mouse
25 °C
glucocorticoid
for
to
that
dependent
that
steroid, was
incubation
A role
energy
(51)
subsequently
receptors
reported
required
rebind
binding
by
an
receptors
non-steroid-binding
to
from
ATP.
of
be
a
inhibitors
increased with
initially
Additionally,
be
forms
may
incubation
of
incubated
had
hormone
proposed
binding
cytosol
an
ATP
from
heat-treated
ported
was
following
steroid
studies,
of
(50)
it
glucocorticoid
cytosol dition
a
steroid
glucocorticoids
cess. two
on
re-
aliquots active
hormone)
remains
Although
it
is
356 apparent latory roid
that
either
component(s)
binding,
steroid ceptor
occurs
Preliminary
observations
Toft,
ATP
with
steroid
made
unpublished)
cytosol
from
cow
uterus
observations
led
to
enhancement ATP
could
or
to
Sepharose
yield from
an hen
be
its 4B
affinity oviduct an
were
adsorbed
buffers
This
interaction have
phosphates, tion
are
is
a
regu-
direct
ste-
evidence
that
of
re-
cAMP
and
reported
systems general
the
to
AMP.
for
phenomenon
binding.
whether
effect
this
of
the
linked
ribose
via
a
spacer
6-carbon
progesterone-receptor
salt be ATP
with
a majority resin
or
the
and
free
reversible, over
main
other
complexes
(NH^J^SO^ of
the
could
of
this
eluted
(54,55).
in
nature,
nucleoside
features
and
com-
be
ligand ionic
to
triinterac-
I.
avian
interaction
indicating
to
to
covalently
The
Table
as
(Moud-
ATP
was
column,
for
of
progesterone
fractionated
to
laboratory
addition
a direct
affinity
high
found
in
Toft's
that
ATP
When were
preference
cleotide-receptor other
was
summarized
Originally
by
containing
a
its
ATP-Sep harose
with
Dr.
enhanced
attributed
resin.
over
in
metabolism.
cytosol
plexes
to
some
phosphorylation
investigations
through
passed
and
of
or
facilitate
receptors
showed
These
with
provides
a result
crude
added
itself to
lacking.
of
and
protein
phosphorylated that
as
Interaction
gil
receptor be
information
binding is
the may
that (Table
progesterone
receptor,
has
now
observed
ATP
binding
II).
been
by
steroid
the in
ηu-
many
receptors
357 T a b l e I. Properties ftΤP-Seρharοse and 1.
Ionic
2.
Ligand
3.
Binding
4.
Selective
5.
Nature Specificity
Steroid-Receptor Rema ins Intact
Reproduced
II.
with
Interaction
Receptor Progesterone
Estrogen
Glucocorticοi d
Androgen Vi tami η- DJ
Steroid
permission
Receptor
studies were and
discovered
Chick, Rat Chick
(54,55),
the
chick the
1
with
ftTP-Sepharose
Reference Moudgil & Toft (54,55) L e a v i tt e t a l . ( 5 6 ) Moudgil et al. (47) M i l l e r & T o f t (46) Moudgil & Eessalu (58) K a t z e n e l l e n b o g e n et al. (59) Moudgil & Weekes (60) Moudgil & John (47) M c B l a i n e t al . ( 6 1 )
hen
M o u d g i l et al. (62) M u l d e r et al. (63) H a u s s l e r & Pike (64)
reference
Activation
utilized
that
from
reference
Receptors
Hen Rat Mouse
In
ATP-Sepharose
of
from
Oviduct Liver Mammary Gland Oviduct Prostate Intestine
of
previous
permission
Animal C h i c k , hen Hamster Rat Ra t
with
preparations
Complex
Tissue Oviduct Uterus Brain Uterus
Requirement
soon
Specificity
Reversible
7.
Reproduced
H i g h s a l t d i s r u p t s the interaction A T P is a n e c e s s a r y constituent ftTP is p r e f e r r e d o v e r other nucleotides Y i e l d s p u r i f i c a t i o n of 100 X - f o l d or h i g h e r
Divalent Cations Not Required
6.
Table
of the I n t e r a c t i o n Between Steroid-Hormone Receptors
for
1
ATP-Sepharose
(NH^^SO^-precipitated
to
study
the
progesterone
receptor
in
the
interaction receptor. freshly
Binding
receptor between It
was
prepared
cy-
358 tosol
had
1 i111e
activation could
occur
hormone shown that 0°C
step
had
the been
no
The
rat
retention
at
2 3°C
binding
the
for
eluted tion,
with the
1Μ
maximum
FRACTION
on
of
ATP
(Fig.
to
receptor
for
method
Cytosol
acetonide
binding
at
subsequent
enhanced
of
an
receptor-
(47).
However,
The
that
subsequently
receptor
ATP-Sepharose this
5
was
periods 1).
and
ATP-Sepharose
H]triamcinolone
time
resin
to
activation
ATP-Sepharose.
Employing
extent
NUMBER
[
various
adsorbed
KCl.
of
immobilized
with
affinity
quantitatively
ATP-Sepharose binding
glucocorticoid 3
incubated
no
to
to
liver
showed
for
before
requirement
binding
incubation
was
affinity
required
(46).
complex
for
or is
receptor
activated
receptor
and
be
could
receptor to
activa-
ATP-Sepharose
10
F I G . 1. E f f e c t of h e a t - a c t i ν a t i ο η on the b i n d i n g of glucocort i c o i d - r e c e ρ t o r , c o m ρ 1 e χ to A T P - S e p h a r o s e . Rat liver cytosol was incubated [ H ] t r i a m c i n o l o n e acetonide for 4 h at 0 ° C . Al i quots (0.5ml) containing [3H]triamcinolone acetonide-receptor c o m p l e x w e r e i n c u b a t e d a t 2 30 C f o r t i m e s s h o w n , c o o l e d o n ice and c h r o m a t o g r a p h e d on i d e n t i c a l 2- m 1 c o l u m n s of ATP-Sepharose. The c o l u m n s were w a s h e d with lOmM Tris-HCl b u f f e r , 2 0% g l y c e r o l , l O m M K C l , pH 8 a n d the a d s o r b e d c o m p l e x e s w e r e rec o v e r e d w i t h the s a m e b u f f e r c o n t a i n i n g IM K C l . Taken with permission from ref. 47.
359 ranged
between
binding heat the
of
50-70?
of
the
receptor-hormone
treatment)
ATP-Sepharose
uptake
cytosol
has
of
the
receptor
therefore,
has
application
activation
of
steroid
conveniently
used
hormone in
shown
(46).
assays
by
The salt
to
or
parallel
ATP-Sepharose
in
the
receptors.
batch
receptor.
(activated been
atography,
be
nuclear
to
total
complexes
The
for
chrom-
measurement resin
multiple
of
can
also
sample
mea-
surements .
Inhibitors
The
of
ATP
functional
tablished
with
chapter.
The
step to
in
the
provide
tion,
the
pounds
mechanism
have
and
sodium
of
famycin to
to
latter
known
binding
later an
the
have
with
action.
been
do
nuclei,
an
effort
interac-
These
with com-
AF/013
5'-phosphate
not the
this
Several
rifamycin
block
in
interfere
pyridoxal
agents but
isolated
to
(1,65,66).
(ATA),
These
In
sought.
appear
es-
important
receptor-ATP
(o-phe.),
process,
action
of
is
with
have
an the
also
o-phenanthroline,
receptors
antibiotic
inhibitory that
may
been
of
DNA
demonstrated acid
effects
also
be
interfere cell-free
in-
DNA-cellulose
and
blocks
a metal
on
is the
a
that
and to
be
has
RNA
been
of
Rishown
polymerases;
meta1 - contaiηiηg
triphenylmethane
activities
binding
chelator,
meta11 ο proteiηs .
derivative
activities
Aurintricarboxylic
transferases,
discussed
ATP-Sepharose
molybdate.
been
represent
which
acid
not
be
to
process
identified
has
may
hormone
definition
steroids
AF/013
enzymes. with
steroid
binding
(19,65-70).
that
interfere
the
of
receptor
inhibitory
suggests
will
o-phenanthroline
steroid
teraction
ATP
binding
aurintricarboxylic
the
of
and
this
binding
ATP-Sepharose
The
of
been
include
(Rif.), (PLP)
certainty nucleotide
additional
receptor
with
significance
inhibitors
compounds
binding
of
steroid
dye,
nucleotidyl receptors
to
360 ATP-Sepharose to
block
tween cule
ATP
the
inhibitor
which
receptor these
(58,60,71,72). binding
may
be
due and
to
for
Although
are
not
characterization
and
identification
the
steroid
of
these
inhibitors
roid-receptor liver
receptors are
systems
glucocorticoid
should are
the
of
a Schiff
appears base
the
receptor
DNA
binding
modes
present,
prove
applicable
and
and exact
inhibitors
on
at
of
l y s i n e of
ATP the
clear
5'-phosphate
formation
a critical
necessary
(65,69,70).
Pyridoxal the
of
their
in
various
acceptor
valuable.
The
generally
summarized
in
to
moleof
action use
III
the
of the sites
effects
different
Table
be-
for
sterat
receptor.
Table I I I . E f f e c t s o f V a r i o u s I n h i b i t o r s on t h e B i n d i n g o f [ ^H ] d e x a m e t h a s o n e - R e c e p t o r C o m p l e x t o D N A - C e l 1 u l o s e a n d ATP-Sepharose C o n c e n t r a t i o n Ί S p e c i f i c LJH J de x a m e t h a s o n e b i n d i n g Compo und Used DNA-Cel1ulose ATP - S e p h a r o s e Control (no inhibitor)
—
100
100
NaV03
lOmM
75
74
Na2W04
lOmM
3
0
Na2Mo04
1 OmM
0
0
5mM
17
60
14
34
0
0
0
7
0
0
PL Ρ ATA Heparin o-Phe . Ri f .
O.OlmM 30 0u g/m1 3m Μ 1 75ug/ml
F r e s h l y e x c i s e d l i v e r s from b i l a t e r a l l y a d r e n a l e c t o m i z e d adult m a l e r a t s w e r e h o m o g e n i z e d a t 0°C i n 2 v o l u m e s ( V / w ) o f T r i s b u f f e r ( 2 0 m Μ T r i s - H C l , 12mM t h i o g l y c e r o l , 10 - g l y c e r o l and 0.3mM ρ h e n y 1 m e t h y 1 s u 1 f o n y 1 f l u o r i d e , pH 7 . 5 ) . The h o m o g e n a t e was c l e a r e d by c e n t r i f u g a t i o n a t 1 5 0 , 0 0 0 x g f o r 60 m i n . The r e s u l t i n g c y t o s o l was c o m p l e x e d w i t h 2 0 η Μ [ J H ] d e x a m e t h a s o n e f o r 2 h at 0°C. The e x c e s s s t e r o i d was r e m o v e d by t r e a t m e n t w i t h a c h a r c o a l s u s p e n s i o n and a l i q u o t s o f c y t o s o l w e r e i n c u b a t e d w i t h t h e c o m p o u n d s l i s t e d i n t h e t a b l e and w e r e h e a t activated (23°C, 1 h). P o r t i o n s ( 0 . 5 m l ) were u s e d to m e a s u r e D N A - c e l l u l o s e and A T P - S e p h a r o s e b i n d i n g . Taken w i t h p e r m i s s i o n from r e f e r e n c e 66.
361 Effects
While
of
the
obscure, of
ATP
on
the
functional it
is
activated
clear
steroid
activation
significance that
receptors.
of
steroid
hormone
when
is
free
solution
mobilized
form
and
to
the
effect
solic
gain
in
of
insight
the
It
than
into
nucleotide
on
tissue
cytosols
containing complexes
for
the
quired
the
at
0-4°C,
properties
of
Sepharose
( 41 , 4 3 - 4 5 , 7 3 ) ( F i g .
ATP-dependent nuclear
tions
in
and
in
the
its
of
effects ATP
of
steroid
modifier sive
is
shown
method
vitro.
ventional activation and
is
imize
the
receptor
is
Figure
used
out
for
at
structural
components.
5.
studying
4).
cyto-
with
prepared
as
shown
and
lOmM
complexes
ATP
ac-
by
their
and
receptor
ATP-
found of
more
may
reported
conditions
for
be
additive
a
biological
A
comprehen-
ATP
com-
offers activation
over
the
activation. less
liver
of
conΑΤ Ρ-
cumbersome
(0-4°C)
metabolism rat
3) the
receptor
by
advantages
receptor
and
be
receptor
quantitative,
assay
(Fig.
to
to
altera-
heat-transforma-
steroid
of
forms
by
Furthermore,
activation. of
several
alterations
Initially
were
process
achieving
mild
ATP,
progesterone-
Transformation
the
has
the
of
freshly
DEAE-Sephacel
nucleotide
activation
convenient,
carried the
in
procedure
modes
on
(Fig.
receptors,
of
The
receptor
of
of
When
im-
assumption
accompanied
ATP
studying
above
function(s)
cytosol was
process
process
another
of
the
for
the
DNA-cellulose
and
the
an
receptor
heat
of
in
present
incubated
accelerates
scheme
plexes
in
of
ATP
is
2).
sedimentation
(43).
Since
of
different by
estrogen-,
counterparts
mobility
rate
property
that
activation
nuclei,
transformation
binding
transforming
tion
isolated
remained
a
influenced
on
were
activated
binding
their
it
has is
possible
are
steroid-receptor
increased
The
to
binding
investigated.
glucocorticoid-receptor
receptors
binding
presumed
the
was
min
is
Based
the
receptor
40-60
ATP
when
steroid
target
of
receptors
(ATP-Sepharose).
more
steroid
ATP-Sepharose
aspects it
of
which the
min-
cytosol
glucocorticoid
362
ATP
(mM)at
0°C
FIG. 2 . A c t i v a t i o n of s t e r o i d - r e c e p t o r c o m p l e x e s by A T P . A s e r i e s of a l i q u o t s c o n t a i n i n g steroid-receptor complexes were i n c u b a t e d at 0°C for 4 0 - 6 0 min w i t h lOmM T r i s - H C l buffer containing different concentrations of ATP (pH 8 ) . The samples were subsequently charcoal-treated and i n c u b a t e d w i t h isolated nuclei from rat liver (GR), chick o v i d u c t (PR), and rat uterus (ER). The n u c l e a r s u s p e n s i o n s were w a s h e d with 1ow-saltbuffer and the n u c l e a r - b o u n d c o m p l e x e s were e x t r a c t e d w i t h high-salt Tris-HCl b u f f e r ( 1 Μ K C l ) , pH 7 . 4 . G R , g l u c o c o r t i c o i d receptor; PR, progesterone receptor; ER, estradiol receptor.
F I G . 3. E f f e c t of A T P - t r e a t m e η t on the r e s o l u t i o n of c y t o s o l glucocortic o i d - re c e ρ to r c o m p l e x e s on OEAE-Sephacel. Rat liver cytosol containing [3H]triamcinolone acetonide-receptor complexes was incubated f o r 1 h a t 0° C w i t h 1 O m K A T P (pH 8) or w i t h 5mM Na2W04. Samples (0.5ml) were chromatographed over identical 5m 1 D Ε A Ε Sephacel columns pre-equilibrated with buffer containing lOmM Tris-HCl, 12mM t h i o g l y c e r o l , 20':· g l y c e r o l , l O m M KCl, pH 7 . The r e s i n - b o u n d r e c e p t o r was e l u t e d by a s t e p - w i s e increase in ionic strength. T w e n t y 1-ml fractions were collected each with above buffer containing 0 . 1 5 M or 0 . 5 K KCl. Small aliquots (0.5ml) were used for the m e a s u r e m e n t of radioactivity.
363
5 - 2 0 Ά sucrose y.control
gradients »—t'ATP
υ ι ο δ >ϊ 0:
20 FRACTION
40 NUMBER
FIG. 4. E f f e c t o f A T P - t r e a t m e η t on t h e r a t e o f s e d i m e n t a t i o n of s t e r o i d - r e c e p t o r c o m p l e x e s from t a r g e t tissue cytosols. The s t e r o i d - r e c e p t o r c o m p l e x e s p r e p a r e d from hen o v i d u c t (PR), rat u t e r u s (ER) and r a t l i v e r (GR) c y t o s o l s w e r e i n c u b a t e d at 0 ° C f o r 4 0 - 60 m i n w i t h l O m M T r i s - H C l b u f f e r , pH 8 (0 0) or T r i s - b u f f e r c o n t a i n i n g l O m H A T P (I 1). P o r t i o n s ( 0 . 2 m l ) of the a b o v e p r e p a r a t i o n s were l a y e r e d over 5-20' l i n e a r sucrose gradients. The g r a d i e n t s were c e n t r i f u g e d at 1 5 0 , 0 0 0 x g (SW r o t o r ) f o r 16 h ( P R , E R ) o r a t 2 7 0 , 0 0 0 x g ( v e r t i c a l r o t o r ) f o r 2 h (GR). F r a c t i o n s w e r e c o l l e c t e d by p i e r c i n g the b o t t o m o f the g r a d i e n t tubes and a l i q u o t s w e r e used for radioactivity mea s u r e m e n ts.
receptor,
activation
demonstrated
in
many
of
steroid
receptor
receptors
systems
by
(Table
ATP IV).
has
now
been
364
Increased
binding
to:
ATP-Sepharose DNA-Cellulose Phosphocellulose
Η
- R — * H R — » H R *
•
Isolated
nuclei
Slow •
Temperature
4 pH • Ionic
strength
Cytosol
Change
in sedimentation
Change
in
Altered
dilution
Gel
dissociation
mobility
ion-exchange
rate
size on resms
filtration
Phosphatase Phosphorylated ATP.
compounds
4°C
FIG. 5. A c t i v a t i o n o f s t e r o i d - r e c e p t o r c o m p l e x e s i_n v i t r o . A c o m p r e h e n s i v e scheme f o r s t u d y i n g a c t i v a t i o n o f steroid-recept o r c o m p l e x e s in c e l l - f r e e s y s t e m s . H, s t e r o i d hormone; R, r e c e p t o r ; HR, h o r m o n e - r e c e p t o r complex (no η a c t i ν a ted ) ; H R * , s t e r ο i d - h o r m ο η e - r e c e ρ t ο r complex (activated).
Table
Progesterone
A c t i v a t i o n o f S t e r o i d R e c e p t o r s by A T P C o n d i t i o n of S y s tem Activation References Rat liver 5 - 1 0 mM ATP » John & M o u d g i l (43) , 4 ° C , 4 0 min M o u d g i l & John ( 4 4 ) 2 - 4 mM A T P , Rat liver A n d r e a s e n (74 ) 0 . 1 Μ KCl , 0° C 1 0 mM A T P , Rat liver B a r n e t t e t al . ( 7 5 ) 1 5 ° C , 3 0 miη M C F - 7 e e l 1 s 10 mM A T P , 1 h C h o n g & L i ppman ( 7 6 ) 10 mM A T P , 0 ° C H o l b r o o k et al . ( 7 7 ) Rat thymus cells Rat u t e r u s 10 mM A T P , 4 ° c , M o u d g i 1 & E e s s a l u 4 0 min (45) M C F - 7 e e l 1 s 10 mM A T P , Nawata et a l . ( 7 8 , 0°C , 1 h 79) Moudgil et a l . (41) Hen o v i d u c t 10 mM ATP , 4 ° C , 40 min
Reproduced
with
Receptor Glucocort icοid
Estrogen
IV.
permission
from
reference
1
365 A number which sol
of
receptor
Sepharose) are
compounds
interfere
to an
pounds,
which
Table
have the
been
state.
in T a b l e is n o t
identified
ability
acceptor
binding
summarized
discussed
with
of A T P
(nuclei, Effects
V.
fully
The
to
over
the
DNA-cel1ulose
of
mode
some of
understood
of
the
and
these
action
at
years
transform
of
ATP-
inhibitors
these
present,
cytο-
has
com-
been
earlier.
V.
C h e m i c a l i n h i b i t o r s of the p r o c e s s r e c e p t o r a c t i v a t i o n by A T P .
Control PLP o - P h e n a n t h r o l i ne Sodium levamisole Sodium tungstate Sodium molybdate Rifamycin AF/013 Heparin ATA
progesterone-
[ 3 H ] R 5 0 2 0 - receptor complex b o u n d to A T P - S e p h a r o s e
Concentration mM (ug/ml )
Inhibitor
of
c!
100 84 83 84 59 1 9 11 0 0
- -
5 3 10 10 10 (175) ( 300 ) 0.02
F r e s h l y p r e p a r e d hen o v i d u c t c y t o s o l w a s c o m p l e x e d w i t h TD n~M [ 3 H ] R 5 0 2 0 for 2 h at 4 ° C . A s e r i e s of t u b e s w a s s e t up (in d u p l i c a t e ) in a final v o l u m e of 0.5 ml a n d c o n t a i n e d 0 . 1 5 ml of r e c e p t o r c o m p l e x , 20% g l y c e r o l , 10 m Μ A T P and d i f f e r e n t inh i b i t o r s at c o n c e n t r a t i o n s s h o w n in the t a b l e . The c o n t e n t s of t u b e s w e r e m i x e d a n d i n c u b a t e d for 1 h at 4°C . Following t h i s , 0.5ml D e x t r a n - c o a t e d c h a r c o a l s u s p e n s i o n w a s a d d e d to e a c h t u b e to r e m o v e f r e e n u c l e o t i d e s and i n h i b i t o r s . After c e n t r i f u g a t i o n at l O O O x g f o r 5 m i n , p o r t i o n s ( 0 . 7 m l ) of s u p e r n a t a n t w e r e u s e d to m e a s u r e the e x t e n t of r e c e p t o r a c t i v a t i o n by u s i n g A T P - S e p h a r o s e b a t c h a s s a y s . Taken with permission from r e f e r e n c e 41.
Significance receptors
Several receptor creases tor
of
lines
the
of
evidence
function. the
(44,80).
extent The
interaction
suggest
Addition of
between
steroid
of
a role
ATP
to
binding
sterοid-receρtοr
ATP
and
for
target
ATP
steroid
in
cell
steroid cytosol
by g l u c o c o r t i c o i d
complexes
are
in-
recep-
activated
366 upon can of
incubation also
ATP,
effects
be
tween
on
involve
the
receptors
have
demonstrated
dialdehyde, receptor.
Based
been
are
mediated
ceptors
via
is
not
by
which
activated
receptor
is
in
activated ATP
forms.
of
out
in
the
the
receptor
influence
on
the
latter
if
ATP
(Table
supbe-
II).
Addi-
site
on
McBlain
Toft
(81)
and
to
all,
of
of
site(s)
stewho
21 - 31 -
ATP,
avian
available
binding
is
ATP-binding
linked
not
view
progesterone
information, the on
may
process
interaction
derivative
other
Although
of
The
from of
8S
presence
both
favour
of
oviduct other
of
receptor.
the
knowledge
for
of
ATP the
it
effects steroid
re-
an
activated
receptor
'native'
metastable
structure,
easily
ceptor
disrupt
8S
is
steps
disrupted.
oligomeric
a
and
form
that (and
(5,82).
the
then
activa-
perhaps
of
consequence with-
The
nonac-
vitro
may
structure
the
readily.
molecule,
behaves ATP
which
more
direct
native
molecule
mean
receptor
hypothesis
hormones)
an
shift
receptor
oligomeric
into would
nonactivated
the
the
cytosol
receptor
favours
enzyme-catalyzed
the
This
ATP-Sepharose
progesterone
the
transforms ATP.
com-
ATP-Sep harose
and
oligomeric
and
and
nonactivated
to
resins
steroid of
s t e r o i d - r e c e ρ tor
However,
and
free
activated a
the
Binding
nonactivated
to
dissociation
transforms
understood.
bind
involvement
tivated
ATP
form
polyanion
chick
receptor of
may
present
tion
in
influences ATP
to
the
state
equilbrium
The
and
some,
completely
an
binds
of
aldehyde
nucleotide
requires
that
studies
(41).
analog
capacity
immobilized an
activation
(1,41,43-47,54,55,73).
mechanism
plex
this
that
This
demonstrating
irreversibly
on
proposed
its
of
an
8).
n o n - h y d r o 1iζ a b l e
triphosphate
direct.
and
from
that
be
be
reports
existence
come
can
has
to
receptors to
(pH a
binding
metabolism,
numerous
steroid clues
its
hormone
appears
the
ATP
1
5 -[@ , γ - i m i d o ]
ATP
roid
The
lOmM
substituting
the
by
tional
with
by
adenosine
activation
ported
0°C
of
possibly of
at
achieved
bind
as
with
(perhaps
by
a re-
367 competing ganized
In
in
recent
have of
for the
shown
steroid
forms
to
receptors,
as
well by
Auricchio
of
enzyme
effects
lated,
is
the
hormone
is
role
as
is
becoming
(86)
and
sults that
of
Fig. ATP.
of
of
7).
mouse
of
To
with
prepare
cytosol.
[
uterine
or
the A in
particular
receptor
steroid The
for
studies
40
has
from
to
be
the
are model for
the phos-
unrerepresteroid on
the
cytosol
been
this
and
good
(84,85),
laboratory
a
the
sub-
significance
is of
a
estrogen
tissue
[ ^H ] d e χ a m e t h a s o n e
have
Reshown
phosphoprotein
glucocorticoid
liver
treated
of
Phos-
demonstrated.
receptor
tissue,
was
are
established.
phosphorylation
hepatic
nM
receptors
progesterone
(87,88)
Pjorthophosphate
with
to
emphasis
physiologic
remains
glucocorticoid
The
es-
receptors
that
perform
cell
the
Whether
processes
are (75,
purification
related
target
steroid
receptors
restore
hypothetical a
the
processes
cytosol.
are
two
to
re-
binding
partial
ATP
molybdate
cytosol
that
steroid
reported
chapter
6 with
steroid
the i n t a c t 32
complexed
of
suggested
utilizes
this
receptors
liver
or-
inactivation
ATP-Sepharose
been
events
in
evident
cubated
0°C .
or
present.
of
preliminary
in
transformation
have
phosphorylation.
rat
(88)(Fig.
and
at
glucocorticoid
the
receptor
of in
for
of
phosphorylation phorylation
sodium
transformation
receptor
clear
shown
for
like
apparently
sequence
Phosphorylation
It
inhibitors
also
a 1 . (84)
the
subunits
temperature-dependent block
has
the
et
speculated
strates
It
ability
of
not
senting
and
discussed
phorylation
the
DNA-cellulose
which
trogen-binding ATP
keep
ρ hosρhory1 atiοn-deρ hosρhory1 ation
83). an
to
structure)(82).
inhibit
nuclear,
influenced
required
phosphatase to
(19,65,75).
binding
bonds
native
years,
been
ceptor
certain
with
mince was 40:'
mesylate
was
iη-
used
to
( ΝΗ^ ) ^S04 for
3
h
at
368
FIG. 6. A hypothetical model o f g l u c o c o r t i c o i d a c t i o n in a t a r g e t cell showing possible i n v o l v e m e n t of ATP. G , glucoc o r t i c o i d ; R, r e c e p t o r ; G R c , g l u c o c o r t i c o i d - r e c e p t o r complex. T a k e n w i t h p e r m i s s i o n f r o m r e f . 7 5.
The
glucocorticoid-receptor
graphy mi de tor
over
gel
revealed
which
DEAE-Sephacel
{7%)
the on
presence the
Many
questions
about
roid
receptors
remain
tors,
metabolism
under
and
other
of
of
the
of
specific
may
circumstances
added of
Whereas,
result the
by
in
chromato-
SDS-po1yacryla purified
P-containing
of
function
unanswered. ATP
purified
partially 32
several
availability a
was
DNA-cel1ulose.
electrophoresis
depended
ditions,
complex
ΜgC1^ ATP
binding
effects
nucleotide
bands
(Fig.
under
recep-
7 ). by
certain on
may
the be
stecon-
recep-
meta-
369 1 0 % SOS-PAGE of Photphorylottd
GRc
FIG. 7. P h o s p h o r y l a t i o n of rat l i v e r g l u c o c o r t i c o i d receptor by i n c u b a t i o n o f [ 3 2 p ] _ 0 r t h o p h o s p h a t e w i t h l i v e r t i s s u e mince. The l i v e r m i n c e was s u s p e n d e d in a p h o s p h a t e - f r e e J o k l i k medium p l u s ΜgC12 and i n c u b a t e d f o r 3 - 4 h a t 3 7 ° C . The m i n c e was w a s h e d w i t h c o l d h o m o g e n i z a t i o n b u f f e r c o n t a i n i n g 2 5mM N a F a n d homogenized. The c y t o s o l was f r a c t i o n a t e d w i t h s a t u r a t e d ammonium s u l f a t e , d e s a l t e d on S e p h a d e x G - 7 5 c o l u m n and was incub a t e d w i t h 5 0 n M u n l a b e l e d d e χ a m e t h a s ο ηe m e s y l a t e f o r 3 h . Under i d e n t i c a l c o n d i t i o n s , l i v e r mince was i n c u b a t e d w i t h unl a b e l e d p h o s p h a t e and the r e c e p t o r was f r a c t i o n a t e d and d e s a l t e d as a b o v e b u t i n c u b a t e d w i t h 50nM [ ^ H j d e x a m e t h a s o n e mesy l a t e for 3 h at 0°C. The p r e p a r a t i o n s were t h e n s u b j e c t e d to SDS-electrophoresis a n a l y s i s on 10'. a c r y l a m i d e g e l s . Gels w e r e s l i c e d i n t o 2 - 3mm p i e c e s , d i g e s t e d w i t h p r o t o s o l and were mixed with s c i n t i l l a t i o n c o c k t a i l (67:3:30; toluene:protosol: T r i t o n X - 10 0 ) c o n t a i n i n g 0 . 5 g O m n i f l u o r . Phosphorylation performed i n p r e s e n c e (0 0) and a b s e n c e ( I ·) of MgCl?.
bolized formed tial
of
by or
the
receptor.
reported
steroid
Although
suggesting
receptors
has
these been
no
studied
views, explored
have
the
been
enzymic
recently.
perpoten-
370
116 Κ
97 Κ
67 Κ
43 Κ
29 Κ
2
3
Ια
2α
3α
FIG. 8. P h o s p h o r y l a t i o n o f c a l f thymus hi s t o n e s u s i n g purif i e d GR a s a p r o t e i n k i n a s e . P u r i f i e d GR w a s d i a l y z e d a n d i n c u b a t e d w i t h h i s t o n e s , Μ g 2 + a n d / o r C a 2 + and [ γ - 3 2 Ρ ] Α Τ Ρ . After c o m p l e t i o n o f t h e r e a c t i o n , t h e TCA p r e c i p i t a t e d s a m p l e s w e r e a p p l i e d t o 10:« P o l y a c r y l a m i d e s l a b g e l s a n d electrophoresis was p e r f o r m e d as d e t a i l e d i n r e f . 9 0 . Far l e f t , m o l . wt. mark e r s ; l a n e 1 , h i s t o n e s w i t h 5mM Μ g C 1 2 ; l a n e 2 , h i s t o n e s with 5mM C a C 1 2 ; l a n e 3 , h i s t o n e s a n d 5m Μ Μ g C 1 2 + 5 0 n M u n l a b e l e d T A . L a n e s l a - 3 a a r e an a u t o r a d i o g r a p h o f l a n e s 1 - 3 . Arrows indic a t e the p o s i t i o n s of r e c e p t o r and p h o s p h o r y l a t e d histones. Taken w i t h p e r m i s s i o n from r e f . 90.
371 Protei η kinase The
postulation
tein
kinase
chick
nase
oviduct
near
rat
in
ions.
The
porated
c h a i n 2 k+ i n a s e the
and
reaction
tein (H3,
H4)
by
Our
of
Miller
of
histones
The
mixture purified
results et
by
steroid an
tance gene
receptors
expression
phorylation
of
teration
the
in
processes
which
ceptor
of
and be
or
who
by
by
be
20893.
the
of
acknowledged.
peptides kinon-
purified
also
the
to
is
may
proteins
other
work
all
be
of
of
thymus
is
to
pro-
hi s t o n e s
shown
in
Figure
observations
phosphorylation
kinase of
activity
at
this
critical
the
well be
by
presence ligand
extent
assessed
in
which
of
(89).
steroid
have
been
phos-
the
al-
Other
phosphorylation
include
time,
recognized,
genes
of
impor-
regulation
involved
specific
influenced
the
light
receptor.
Since
hormones of
in
calf
reported
may
myosin
steroid
the
of
protein
action. proteins
of
preliminary
accurately
receptor, and
proThese
protein
gizzard
receptor
the
receptors
related
This
Reading
be
of
Acknowledgements : fully
increase
of
transcription
ATP
to
with
steroid
might
was
kinase
addition
glucocorticoid
chromatin
of
muscle
The
have
hormone
other
activation affected
well
cannot
steroid
dalton
exhibited
turkey
glucocorticoid
role
(89).
molybdate-stabilized
Phosphorylation
significance
enzymatic for
skeletal
purified
possess
al.
90,000
receptor
hi s t o n e s ,
appeared
(91)
itself et
with d i f f e r e n t protein sub32 [γP]ATP and d i v a l e n t c a t 32 from [ γ P ] A T P was i n c o r -
50 μ Η
(90).
agree
al.
and
receptor
phosphate
thymus
ions
may
Garcia
incubated of
and 2+ rabbit
biological
but
was
phosphorylation.
8.
110,000
laboratory,
presence
Ca
by
glucocorticoid
and
calf
receptors
receptor
provided
that
radioactive
into
Mg
a steroid
this
liver
the
steroid
progesterone In
homogeneity
strates
of
was
reported
activity.
activated
of
that
activity
investigators of
activity
of
re-
binding shown
to
nucleotides.
was
manuscript
supported by
Dr.
Ν.
by
N.I.H.
Eliezer
Grant is
AM-
thank-
372 References
1.
Moudgil, V.K.: In: Principles of Recepterology, 273-379 (M.K. Agarwal, Ed.) Walter de Gruyter, Berlin 1983.
2.
Speisberg, T.C., Steggles, A.W., O'Malley, B.W.: J. Biol. Chem. 246, 4188-4197 (1971).
3.
Steggles, A.W., Speisberg, T.C., Glasser, S.R., O'Malley, B.W.: Proc. Natl. Acad. Sei., U.S.A. 58, 1479-1482 (1971).
4.
Jensen, E.V., Suzuki, T., Kawashima, T., Stumpf, W.E., Jungblut, P.W., DeSombre, E.R.: Proc. Natl. Acad. Sei., U.S.A. 59, 632-638 (1968).
5.
Baulieu, E-E., Binart, Ν., Buchou, T., Catelli, M.G., Garcia, T., Gase, J.M., Groyer, Α., Joab, I., Moncharraont, B., Radanyi, C., Renoir, M.J., Tuohimaa, P., Mester, J. In: Steroid Hormone Receptors: Structure and function, 45-72 (H. Ericksson and J-A., Gustafsson, Eds.) Elsevier Science Publishers, Amsterdam 1983.
6.
King, W.J., Greene, G.L.: Nature (London) 307, 745-747 (1984).
7.
Welshons, W.V., Lieberman, M.E., Gorski, J.: Nature (London) 307 , 747-749 (1984).
8.
Gase, J.M., Renoir, J.M., Radanyi, C., Joab, I., Tuohimaa, P., Baulieu, E-E.: J. Cell Biol. 99, 1193-1201 (1984).
9.
Munck, Α., Wira, C., Young, D.A., Mosher, K.M., Hallahan, C., Bell, P.A.: J. Steroid Biochem. 3, 567-578 (1972).
10.
Buller, R.E., Toft, D.O., Schräder, W.T., O'Malley, B.W.: J. Biol. Chem. 250, 801-808 (1975).
11.
Schräder, W.T., Toft, D.O., O'Malley, B.W.: J. Biol. Chem 2 « , 24012407 (1972).
12.
Baxter, J.D., Rousseau, G.G., Benson, M.C., Garcea, R.L., Ito, J., Tomkins, G.M.: Proc. Natl. Acad. Sei., U . S . A . 69, 1892-1896 (1972).
13.
Milgrom, E., Atger, Μ., Baulieu, E-E.: Biochemistry 12^, 5198-5205 (1973).
14.
Goidl, J.Α., Cake, M.H., Dolan, K.P., Parchman, L.G., Litwack, G.: Biochemistry 16_, 2125-2130 (1977 ).
15.
Atger, M., Milgrom, E.: Biochemistry 15^, 4298-4304
16.
Weichman, B.M., Notides, A.C.: Biochemistry 18, 220-225 (1979).
17.
Sakaue, Y., Thompson, E.B.: Biochem. Biophys. Res. Commun. 7_7, 533-541 (1977).
18.
Parchman, L.G., Litwack, G.: Arch. Biochem. Biophys. 183, 374-382 (1977).
19.
Nishigori, H., Toft, D.O.: Biochemistry 19^, 77-83 (1980).
20.
Yang, C.R., Renoir, J-M., Mester, J., Baulieu, E-E.: Proc. Meet. Endo. Soc. Abstract 251 (1982).
(1976).
373 21.
G r a n d i c s , P . , M i l l e r , Α . , Schmidt, T . J . , Mittman, D . , L i t w a c k , G . : J. B i o l . Chem. 259, 3173-3180 ( 1 9 8 4 ) .
22.
S a t o , B . , Huseby, R . A . , Samuels, L . T . : E n d o c r i n o l o g y 102, 545-555 (1978).
23.
Okamoto, K . , I s o h a s h i , F . , H o r i u c h i , M., Sakamoto, Y . : Biochem. B i o p h y s . Res. Commun. 121_, 940-945 ( 1 9 8 4 ) .
24.
Thampan, T . N . R . V . , C l a r k , J . H . : Nature
(London) 2 9 0 , 152-154
(1981).
25.
C o l v a r d , D . S . , W i l s o n , E.M.: E n d o c r i n o l o g y 109, 496-504
(1981).
26.
C o l v a r d , D . S . , W i l s o n , E.M.: B i o c h e m i s t r y 23, 3471-3478
(1984).
27.
C o l v a r d , D . S . , W i l s o n , E.M.: B i o c h e m i s t r y 23, 3479-3486
(1984).
28.
Munck, Α . , F o l e y , R . : Nature (London) 278, 752-754
29.
M a r k o v i c , R . D . , L i t w a c k , G.: A r c h . Biochem. B i o p h y s . 2 0 2 , 374-379 (1980).
(1979).
30.
H o l b r o o k , N . J . , B o d w e l l , J . E . , J e f f r i e s , M., Munck, Α . : J . Chem. 258, 6477-6485 ( 1 9 8 3 ) .
31.
Schmidt, T . J . , Harmon, J . M . , Thompson, E . B . : Nature (London) 507-510 ( 1 9 8 0 ) .
32.
M i l g r o m , E . : I n : Biochemical A c t i o n s o f Hormones (G. L i t w a c k , Academic P r e s s , New Y o r k , 13, 465-492 ( 1 9 8 1 ) .
33.
Schmidt, T . J . , L i t w a c k , G.: P h y s i o l . Rev. 62_, 1131-1192
34.
Grody, W.W., S c h r ä d e r , W.T. , 0 ' M a l l e y , B.W.: Endocrine Rev. 3, 141163 ( 1 9 8 2 ) .
Biol. 286, Ed.)
(1982).
35.
N o t i d e s , A . C . , N i e l s e n , S . : J. B i o l . Chem. 249, 1866-1873
36.
N o t i d e s , A . C . , N i e l s e n , S . : J . S t e r o i d Biochem. 6 , 483-486
(1974).
37.
B a i l l y , Α . , L e F e v r e , B . , S a v o u r e t , J . F . , M i l g r o m , E . : J. B i o l . Chem. 255, 2729-2734 ( 1 9 8 0 ) .
38.
M ü l l e r , R . E . , T r a i s h , A . M . , W o t i z , H.H.: J . B i o l . Chem. 258, 92279236 ( 1 9 8 3 ) .
(1975).
39.
S a k a i , D. , G o r s k i , J . : B i o c h e m i s t r y 23, 3541-3547
40.
S c h r ä d e r , W.T. , Heuer, S . S . , 0 ' M a l l e y , B.W.: B i o l . Reproduction 134-142 ( 1 9 7 5 ) .
(1984).
41.
Moudgil, V.K., Kruczak, V.H., Eessalu, T . E . , Paulose, C . S . , M.G., Hansen, J . C . : Eur. J. Biochem. Π 8 , 547-555 ( 1 9 8 1 ) .
12,.
Taylor,
42.
V e d e c k i s , W.V.: B i o c h e m i s t r y 22, 1983-1989
43.
John, J . K . , M o u d g i l , V . K . : Biochem. B i o p h y s . Res. Commun. 90, 12421248 ( 1 9 7 9 ) .
(1983).
44.
M o u d g i l , V . K . , John, J . K . : Biochem. J . 190, 799-808
45.
Moudgil, V.K., Eessalu, T.E.:
46.
M i l l e r , J . B . , T o f t , D.O.: B i o c h e m i s t r y 17_, 173-177
(1980).
FEBS L e t t . 122, 189-192
(1980).
(1978).
374 47.
M o u d g i l , V . K . , John, J . K . : Biochem. J . 190, 809-818
(1980).
48.
W o l f s o n , Α . , M e s t e r , J . , Yang, C . R . , B a u l i e u , E - E . : Biochem. Res. Commun. 95, 1577-1584 ( 1 9 8 0 ) .
49.
M c B l a i n , W.A., T o f t , D . O . , Shyamala, G.: B i o c h e m i s t r y 20, 6790-5798 — (1981).
50.
Munck, Α . , Johnsen, T . B . : J . B i o l . Chem. 243, 5555-5565
51.
Munck, Α . , W i r a , C . , Young, D . A . , Mosher, K.M., H a l l a h a n , C . , P . A . : J . S t e r o i d Biochem. 3, 567-578 ( 1 9 7 2 ) .
52.
Sando, J . J . , L a F o r e s t , A . C . , P r a t t , W.B.: J. B i o l . Chem. 254, 47724778 ( 1 9 7 9 ) .
53.
Sando, J . J . , Hammond, N . D . , S t r a t f o r d , C . A . , P r a t t , W.B.: J. Chem. 254, 4779-4789 ( 1 9 7 9 ) .
54.
M o u d g i l , V . K . , T o f t , D.O.: Proc. N a t l . Acad. S e i . U . S . A . 72, 901-905 (1975).
55.
M o u d g i l , V . K . , T o f t , D.O.: Biochim. B i o p h y s . Acta 4 9 0 , 477-488
56.
L e a v i t t , W.W., Chen, T . J . , E v a n s , R.W.: I n : S t e r o i d Hormone Receptor System (W.W. L e a v i t t , J.Η. C l a r k , E d s . ) Plenum P r e s s , New York 1979.
57.
M o u d g i l , V . K . , P r a s s , W.A., K r u c z a k , V . H . : L i f e S e i . 2 5 , (1979).
58.
M o u d g i l , V . K . , E e s s a l u , T . E . : L i f e S e i . 2 7 , 1159-1167
59.
K a t z e n e l l e n b o g e n , B . S . , P a v l i k , E . J . , R o b e r t s o n , D.W., bogen, J . Α . : J. B i o l . Chem. 256, 2908-2915 ( 1 9 8 1 ) .
Biophys.
(1968). Bell,
Biol.
(1977).
1335-1342
(1980). Katzeneln-
60.
M o u d g i l , V . K . , Weekes, G . A . : FEBS L e t t . 94, 324-326
61.
M c B l a i n , W.A., T o f t , D . O . , Shyamala, G.: B i o c h e m i s t r y 2 0 , 6790-6798 (1981).
(1978).
62.
M o u d g i l , V . K . , H e a l y , S . P . , S h a f f e r , T . L . , S z o c i k , J . F . : Biochem. J . 198, 91-99 ( 1 9 8 1 ) .
63.
M u l d e r , E . , V r i j , L . , Foekens, J . Α . : S t e r o i d s
64.
H a u s s l e r , M . R . , P i k e , J.W.: Proc. 5th Workshop on V i t . D. 1982, W i l l i a m s b u r g , V a . , p. 36.
65.
M o u d g i l , V . K . , N i s h i g o r i , H . , E e s s a l u , T . E . , T o f t , D.O.: I n : Gene R e g u l a t i o n by S t e r o i d Hormones ( A . K . Roy, J.H. C l a r k , E d s . ) 1 0 6 - 1 1 9 , S p r i n g e r - V e r l a g , I n c . , New York 1980.
66.
M o u d g i l , V . K . , Murakami, N . , E e s s a l u , T . E . , Caradonna, V . M . , S i n g h , V . B . , H e a l y , S . P . , Q u a t t r o c i o c c h i , T . : I n : Adrenal S t e r o i d Antagonism (M.K. A g a r w a l , Ed.) 1 3 1 - 1 6 8 , Walter de G r u y t e r , B e r l i n , New York 1984.
67.
Lohmar, P . Η . , T o f t , D.O.: Biochem. B i o p h y s . Res. Commun. 6_7, 8 - 1 5 (1975).
68.
T o f t , D. , Lohmar, P . , M i l l e r , J . , M o u d g i l , V . : J . S t e r o i d Biochem. 1053-1059 ( 1 9 7 6 ) .
69.
N i s h i g o r i , H . , M o u d g i l , V . K . , T o f t , D.O.: Biochem. B i o p h y s . Commun. 8 0 , 112-118 ( 1 9 7 8 ) .
36, 633-645
(1980). Feb.
Res.
14-19,
7,
375 70.
T o f t , D.O., Roberts, P . E . , N i s h i g o r i , Η., Moudgil, V.K.: In: Steroid Hormone Receptor Systems (W.W. L e a v i t t , J . Η . , C l a r k , E d s . ) 329-342 Plenum P r e s s , New York 1979.
71.
M o u d g i l , V . K . , E e s s a l u , T . E . : Biochim. B i o p h y s . Acta 6 2 7 , (1980).
72.
M o u d g i l , V . K . , E e s s a l u , T . E . : A r c h . Biochem. B i o p h y s . 2 1 3 , 98-108 (1982).
73.
M o u d g i l , V . K . , John, J . K . , E e s s a l u , T . E . , F i s h e r , V . K . , Murakami, N . , Healy, S . P . , Quattrociocchi , T.M., Singh, V.B., E l i e z e r , N.: In: M i n e r a l o - and G l u c o - C o r t i c o i d Receptors (M.K. A g a r w a l , C.E. S e k e r i s , E d s . ) Acta Medica, Rome ( i n p r e s s ) 1985.
74.
Andreasen, P . A . : Biochim. B i o p h y s . Acta 575, 205-212
75.
B a r n e t t , C . A . , S c h m i d t , T . J . , L i t w a c k , G.: B i o c h e m i s t r y 19, 54465455 ( 1 9 8 0 ) .
76.
Chong,
77.
H o l b r o o k , N . J . , B o d w e l l , J . E . , Munck, Α . : J . B i o l . Chem. 258, 1488514894 ( 1 9 8 3 ) .
78.
Nawata, H . , B r o n z e r t , D . , Lippman, M.E. : J . B i o l . Chem. 256, 50165021 ( 1 9 8 1 ) .
79.
Nawata, H . , Chong, M . T . , B r o n z e r t , D . , Lippman, M . E . : J. B i o l . 256, 6895-6902 ( 1 9 8 1 ) .
80.
B a r n e t t , C . A . , Palmour, R . M . , L i t w a c k , G . , S e e g m i l l e r , J . Ε . : c r i n o l o g y m , 2059-2068 ( 1 9 8 3 ) .
81.
M c B l a i n , W.A., T o f t , D.O.: B i o c h e m i s t r y 22_, 2262-2270
82.
M o u d g i l , V . K . , E e s s a l u , T . E . , Buchou, T . , R e n o i r , J - M . , M e s t e r , Baulieu, E-E.: Endocrinology (submitted).
83.
Leach, K . L . , Dahmer, M . K . , Hammond, N . D . , Sando, J . J . , P r a t t , W.B.: J. B i o l . Chem. 254, 11884-11890 ( 1 9 7 9 ) .
84.
Wei gel , N . L . , T a s h , J . S . , Means, A . R . , S c h r ä d e r , W.T., 0 ' M a l l e y , B.W.: Biochem. B i o p h y s . Res. Commun. 102, 513-519 ( 1 9 8 1 ) .
85.
D o u g h e r t y , J . J . , P u r i , R . K . , T o f t , D.O.: J . B i o l . Chem. 257 , 1422614230 ( 1 9 8 2 ) .
86.
M i g l i a c c i o , Α . , L a s t o r i a , S . , Moncharmont, B . , Rotondi , Α . , F . : Biochem. B i o p h y s . Res. Commun. 109, 1002-1010 ( 1 9 8 2 ) .
301-312
(1981).
M . T . , Lippman, M . E . : J . B i o l . Chem. 25]_, 2996-3002
(1982).
Chem.
Endo-
(1983). J.,
Auricchio,
87.
H o u s l e y , P . R . , P r a t t , W.B.: J. B i o l . Chem 258, 4630-4635
88.
S i n g h , V . B . , E e s s a l u , T . E . , Ghag, S . , M o u d g i l , V . K . : Proc. I n t e r n a t ! . Cong. E n d o c r i n o l , A b s t r a c t 2095 ( 1 9 8 4 ) .
(1983).
89.
G a r c i a , T . , Tuohimaa, P . , M e s t e r , J . , Buchou, T . , R e n o i r , J - M . , B a u l i e u , E - E . : Biochem. B i o p h y s . Res. Commun. Π 3 , 960-966 ( 1 9 8 3 ) .
90.
S i n g h , V . B . , M o u d g i l , V . K . : Biochem. B i o p h y s . Res. Commun. ( i n
91.
M i l l e r , A . S . , Schmidt, T . J . , L i t w a c k , G. (1984) Cong. Endo., A b s t r a c t 1056 ( 1 9 8 4 ) .
Proc. V I I
VII
press).
Internatl.
STEROID HORMONE RECEPTOR DYNAMICS:
THE KEY TO TISSUE RESPONSIVENESS
Thomas G. Muldoon Department of Endocrinology Medical College of Georgia Augusta, Georgia 30912
Introduction By d e f i n i t i o n , s t e r o i d hormone receptors are the s u b c e l l u l a r components which, to the best of our current knowledge, single-handedly dictate q u a l i t a t i v e responsiveness of the cell to the respective hormone.
Tissue s p e c i -
f i c i t y of receptor l o c a l i z a t i o n to responsive c e l l s was e s t a b l i s h e d in the pioneering studies from Jensen's laboratory (1,2) and confirmed by an extensive s e r i e s of autoradiographic analyses (3).
Impetus into
investiga-
tions of receptor nature and function was afforded by c r i t i c a l
demonstra-
tions of the biochemistry of these molecules by a number of groups
(4-7),
defining t h e i r proteinaceous nature and various physicochemical means of detecting and quantifying them.
This early work set the stage for extra-
polation from the q u a l i t a t i v e role of receptors as effectors of i n t r a c e l l u l a r retention to q u a n t i t a t i v e assessment of t h e i r function as determinants of s p e c i f i c hormonal responsiveness.
A number of the chapters in t h i s
book are devoted to various aspects of such s t u d i e s ; the aim of t h i s presentation i s to focus on several areas of receptor regulation and l o c a l i z a tion which have represented a central thrust of the research in our laboratory within recent y e a r s .
In terms of i n t r a c e l l u l a r receptor d i s t r i b u t i o n ,
our studies of the s i g n i f i c a n c e of microsomal components w i l l be presented. Receptor level and f u n c t i o n a l i t y in r e l a t i o n to d i f f e r e n t i a l
gene expres-
sion w i l l be addressed by summarizing our studies on androgen receptors of the rat ventral prostate.
Regulation of a s p e c i f i c sub-population of s t e -
roid hormone receptors within a responsive t i s s u e w i l l be exemplified by addressing our observations in the estrogen-LHRH-LH response system.
Fi-
n a l l y , the complex regulation of the estrogen and progesterone receptors
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
378 by both steroidal
and proteinaceous hormones in mammary tissue will be pre-
sented as representative of the diverse and divers ways in which
respon-
siveness is subservient to regulators of steroid hormone receptor
Intracellular Receptor
activity.
Distribution
The steroid receptor literature is replete with measurements of specific binding activity in cytoplasmic and nuclear compartments of hormonallyresponsive cells.
This approach has been useful
toward understanding
tions and interactions of assorted natural and synthetic hormonal and for elucidating the gross features of the steroid-receptor
complex
association with chromatinic components of the nucleus, generally dered to be a critical
element of the mechanism whereby genetic
is altered by the hormone. several
laboratories
consi-
expression
Of recent vintage are a series of studies
(8-11) which present a strong case for
from
intranuclear
localization of most, if not all, steroid hormone receptors within cells.
ac-
agents,
intact
These findings indicate that receptors designated as cytoplasmic
are actually those which are not strongly bound to chromatin and are leached out into the cytosolic fraction under homogenization and ultracentrifugational
conditions.
manner of visualizing
It is important to note that this change in our
intracellular receptor distribution does not compro-
mise the validity of the multitude of studies performed to determine tionships between receptor binding and functional
rela-
response.
In an analysis of subcellular distribution of estradiol
in castrate rat
uterine cells at intervals after administration of radiolabeled estradiol (12), we observed that nuclear estrogen receptor content diminished
sharply
between 3-5 hours without a concomitant rise in cytoplasmic receptor content (Figure 1); this was the first demonstration in a normal
tissue of a
phenomenon subsequently to be referred to as receptor "processing"
(13).
Strikingly, we were able to show that the complexes lost from the nucleus at this time became associated with the microsomal
fraction of the cell.
Between 5-10 hours after estradiol
microsome-associated
complexes re-entered the nucleus
exposure, these
(Figure 1), leading to a second nuclear
379 peak which was also observed later in mouse uterus (14,15).
The
transient
residence of the nuclear receptors on the microsomes was unexpected and suggested a role for the vacuolar membrane system as a conduit, shuttling steroid-receptor complexes to and from nuclear sites; this phenomenon is clearly distinct from the microsomal-associated receptor forms described by Jungblut and his co-workers
(16-18), which appear to be biosynthetically
developing species of the mature receptor molecule.
FIGURE 1. Subcellular distribution of estradiol in uteri of 2 - w e e k s 1 - o v a riectomized rats following estradiol injection. Animals were administered 0.25 uCi (1.25 pg) of estradiol at time zero and killed in groups at the specified intervals. The designated fractions were separated by differential centrifugation of the uterine homogenate. The data represent compartmental binding as a function of total specifically-bound estradiol recovered at each time point.
In a separate series of experiments, we obtained further evidence for a functional
role of the microsomes in receptor-mediated events.
of 4-mercuriestradiol
Assessment
as an affinity-labeling agent for the estrogen re-
ceptor revealed that this compound was possessed of robust inherent estrogenicity, but no detectable interaction with or effects upon the nuclear genetic material
of the cell
(19,20).
This seemed to defy classical
con-
cepts of the mechanism of steroid hormone action, but in fact only strengthened a growing body of evidence that extranuclear sites of action, particularly those areas associated with translational
processes
involved in the response of the cell to Steroid hormones. tigated the subcellular distribution of radiolabeled
(21-26), are
When we
inves-
4-mercuriestradiol
following administration in vivo (20), we observed a rapid, elevated and prolonged association of this compound with the microsomes, relative to
380
the i n t e r a c t i o n of e s t r a d i o l with t h i s f r a c t i o n (Figure 2; compare with the estradiol data of Figure 1).
The slow and gradual accumulation of small
amounts of the mercury d e r i v a t i v e within nuclei i s a l s o in contrast to the pattern of e s t r a d i o l uptake by nuclei and r e f l e c t s the lack of s p e c i f i c teractions in t h i s
in-
organelle.
FIGURE 2. S u b c e l l u l a r d i s t r i b u t i o n of 4-mercuriestradiol in uteri of 2weeks' ovariectomized rats following 4-mercuriestradiol i n j e c t i o n . Animals received 1.0 uCi of [ 3 H ] 4 - m e r c u r i e s t r a d i o l i n t r a l u m i n a l l y at time zero. Groups were k i l l e d at the i n t e r v a l s shown and the s u b c e l l u l a r d i s t r i b u t i o n of s p e c i f i c a l l y - b o u n d s t e r o i d in each f r a c t i o n was determined. Results are expressed as the percentage of total recovery in each f r a c t i o n . At longer i n t e r v a l s after introduction of the mercury d e r i v a t i v e , we have found that nuclear l e v e l s decline concomitantly with a second increase in microsomal content.
Schematically, the i n t e r a c t i o n s are described in
Figure 3. In recent i n v e s t i g a t i o n s , we have quantified a population of microsomal estrogen receptors which are d i s t i n c t from the cytosol receptors and can be s o l u b i l i z e d in hypotonic buffer.
This l a t t e r property d i s t i n g u i s h e s
these binders from c a l f uterine microsomal receptors described by Parikh et al_. (27), which are not r e a d i l y s o l u b i l i z e d .
The concentration of these
binding s i t e s fluctuates in response to estrogen treatment and at various i n t e r v a l s of the estrous cycle in much the same fashion as do cytosol ceptors.
re-
A s a l i e n t difference from the cytosol form of the receptor i s the
i n a b i l i t y of the microsomal receptor complexes to transform upon heating to a moiety which i s capable of t r a n s l o c a t i n g into i s o l a t e d n u c l e i .
As
shown in Figure 4, conditions which are conducive to transformation of ÖS
381 cytosol receptors to the 5S nuclear form simply lead to d i s s o c i a t i o n of the more l a b i l e microsomal e s t r a d i o l - r e c e p t o r complexes.
FIGURE 3. A mechanism of action c o n s i s t e n t with the a c t i v i t y of 4-mercurie s t r a d i o l (HgE). I n i t i a l i n t e r a c t i o n with the estrogen receptor causes transformation to a 5S complex (HgER 1 ) which accumulates r a p i d l y and extens i v e l y in the microsomes. Small amounts slowly enter the nucleus, but do not interact with chromatin in a s p e c i f i c manner. These complexes are subsequently found in a s s o c i a t i o n with the microsomes.
FIGURE 4. Failure of microsomal estrogen receptors to undergo transformation to a nuclear form. Extracted microsomal receptors were incubated with [ 3 H ] e s t r a d i o l for 2 hrs at 4°C in the presence ( — ) or absence ( · - · ; o-o) of excess unlabeled e s t r a d i o l . One sample (o-o) was further incubated for 30 min at 24°C, and a sample of uterine cytosol (Δ-Δ) was treated i d e n t i c a l l y . Sucrose gradient c e n t r i f u g a t i o n a l a n a l y s i s (15.5 h r s , 350,000 χ g) was performed with l l x C-labeled BSA as an external marker (4.4S, arrow). Note difference in scale between c y t o s o l i c and microsomal samples. An i n t r i g u i n g feature of the microsomal receptor system i s that detachment of the receptors from the membranes by s o l u b i l i z a t i o n imparts to the receptor-exhausted microsomes a newly-acquired acceptor c a p a b i l i t y for cytosol
382 estradiol-receptor complexes.
As shown in Table 1, the capacity of this
acceptor activity parallels rather closely the level of depleted microsomal receptors.
TABLE 1. Acceptor capability of microsomes for cytosol removal of microsomal estrophiles
Group
receptors
following
Concentration of specific binding sites (fmoles/mg protein)
KA (lO^ir1)
Experiment I Control Exhausted Reconstituted
1.31 4.12 1.01
126.7 16.9 156.8
2.04 2.01 2.04
111.5 37.3 87.4
3.10 2.16 3.14
114.7 63.8 132.9
Experiment II Control Exhausted Reconstituted Experiment III Control Exhausted Reconsti tuted
Uterine microsomes were prepared and suspended in buffer. One-third was taken to measure the Control binding level by saturation analysis. The remainder was extracted into steroid-free buffer and the pellet, representing Exhausted microsomes, was re-isolated by centrifugation. Half of these resuspended pellets were submitted to saturation analyses, and the other half was mixed with either an equivalent volume (Experiment I), 3 volumes (Experiment II) or 4 volumes (Experiment III) of original cytosol; these samples represented the Reconstituted microsomal preparations. Following mixing, the cytosol-microsome samples were submitted to saturation binding analysis, using the pelleted, resuspended material as source.
The perinuclear situation of microsomal
components suggests that they may
be included in the newly-described intact cell the vast majority of cellular receptors.
"nuclear" localization of
Our findings indicate a function-
al role for these very active protein-synthesizing organelles as both primary sites of steroid hormone action (through receptor interactions) and as regulators of access of hormone-receptor complexes to functional sites (through their role as acceptors for these complexes).
nuclear
383 Receptors and Differential
Gene
Expression
Repercussions of the eruption of molecular genetics in recent years been felt in the area of steroid hormone action. transcriptional
have
Regulation of specific
events in the chick oviduct by estrogen and
progesterone
(28-30) was exploited as a working system for investigation of hormonal control of gene expression, and progress in this area was swift and revealing.
Work has advanced to the stage where hormonal
loci of action are be-
ginning to be mapped to specific DNA sequences in the vicinity of genes (for recent work, see 31), but the mechanism whereby the
inducible
interaction
between steroid-receptor complexes and chromatin components alters transcription is still not
specific
understood.
In recent studies performed in collaboration with Professor W.I.P. Mainwaring, we have undertaken an analysis of changes in androgen receptors of the castrate male rat ventral
prostate during the course of constant expo-
sure to testosterone by silastic implant.
Our observations have been com-
pared w i t h patterns of androgen-induced protein synthesis during this period.
We have presented our data in preliminary form (32).
tion in this model
Enzyme
system occurs in a distinct biphasic manner.
zymes involved in cell growth and normal
functioning
(including
glucose-6-phosphate dehydrogenase, acid phosphatase and alkaline
induc-
Those enaldolase, phospha-
tase) are maximally stimulated within 1.5 days of androgen exposure, and their levels are dramatically reduced by 2 days. replication
Enzymes involved in DNA
(thymidine kinase, thymidylate synthetase, DNA polymerase a
and DNA unwinding protein), on the other hand, are present in very small amounts at 2 days, but the levels rise synchronously to a peak at 3 days and then slowly recede. criptional
level.
Our studies indicate that control
The mechanism whereby nuclear acceptor activity
over the course of this constant hormonal differential
is at the trans-
stimulation, allowing
changes
temporally
expression of specific genes, will be the focus of our con-
tinuing investigations
into this
phenomenon.
In attempting to define a molecular basis for the observed effects on selective genetic triggering, we have studied ventral tor dynamics during an identical
prostate androgen recep-
testosterone-replacement regimen.
The
384
r e s u l t s (Figure 5) revealed two d i s t i n c t peaks of nuclear androgen receptor binding a c t i v i t y , mirroring the respective patterns of the two sets of enzymes induced. the t r a d i t i o n a l
The i n i t i a l
nuclear retention phase appeared to involve
s t e r o i d - s t i m u l a t e d a s s o c i a t i o n with s p e c i f i c nuclear chro-
matinic components, since i t was o p e r a t i o n a l l y concomitant with cytosol ceptor depletion.
re-
Extensive processing of these receptors followed t h e i r
nuclear accumulation.
At 2.5-3 days into testosterone treatment, the nu-
clear l e v e l s again began to r i s e , but, in t h i s case, the increase was not at the expense of cytosol receptors, which showed only moderate and gradual decreases in l e v e l s during t h i s period.
FIGURE 5. Fluctuations in ventral prostate androgen receptor l e v e l s lowing testosterone implantation into 7-day castrate r a t s . C y t o s o l i c and nuclear ( — ) receptor concentrations were measured as a function days (%-6) after implantation of a testosterone p e l l e t . The castrate vels (-T group) are presented for comparison.
fol( —) of le-
In a previous study (33), we found differences in the androgen-binding properties of the two i n t e r c o n v e r t i b l e forms of cytosol ventral prostate androgen receptors observed by Wilson and French (34,35) and not a t t r i b u t a b l e to endogenous protease a c t i v i t y .
The larger (8S on glycerol gradients) of
the two forms has a 10-fold higher a s s o c i a t i o n rate constant for 5a-dihydrotestosterone than does the smaller 4S form.
Thus, the r e c e p t i v i t y and
the responsiveness of the c e l l to androgen can be expected to be high when the 8S:4S r a t i o i s high.
Glycerol gradient analyses of the receptor forms
at selected i n t e r v a l s of androgen exposure in our model system are shown in Figure 6.
In the absence of androgen replacement, the cytosol
androgen
receptors of the castrate rat t i s s u e are predominantly 8S in nature,
indi-
cating that the c e l l s are h i g h l y responsive to androgen, as judged by t h e i r
385 receptiveness.
The distribution shifts during the first phase of nuclear
binding, such that the 4S form of cytosol processing wave of this event.
receptor is prevalent during the
Between days 2 and 3 of androgen
stimula-
tion (the interval during which the second nuclear surge is occurring), the form of the cytosol
receptor reverts back to the 8S and remains thus for
the duration of this second stage of response.
These findings have been
substantiated by measurements of association rate kinetics for the interaction between androgen and the cytosol
receptors from tissue at the selec-
ted intervals of stimulation.
AxUU Μ FIGURE 6. Glycerol gradient centrifugation of rat prostate cytosol from castrate animals subjected to testosterone replacement for various intervals (in days). Samples containing 6 mg protein/ml were incubated with [3H]mibolerone. Sedimentation patterns were developed in 10-35;, glycerol gradients at 365,000 χ g for 75 min in a vertical rotor. The top of the gradient is to the right of each figure. Bovine γ-globulin (6.6S) sedimented at fraction #14 and BSA (4.4S) at fraction #21 under these conditions .
The second wave of androgen-induced transcription of DNA-replicating
en-
zymes occurs as the .cells pass into the replicative phase of their cycles; this does not, however, begin to explain the mechanism whereby these genes are selectively activated at this time, as opposed to earlier intervals of identical
androgen stimulation
(particularly those times during which the
first wave of protein synthesis is occurring). between the two stages of this overall
The harmonious
synchrony
response and the changes in nature
and amount of androgen receptor activity suggest a functional
correlation
which should become clearer with our projected refinements of the experimental
protocol.
386 Direct Regulation of Nuclear
Receptors
In most instances where steroid hormone receptor regulation has been studied the regulator has been shown to initially alter the subcellular
distribu-
tion of the receptors, which is probably largely a reflection of a change in the affinity or extent of interaction of the receptor with genetic material
in the nucleus (for review, see 36).
Occasionally, however, a curious
situation is encountered wherein levels of nuclear receptor are altered in the absence of any accompanying effect on cytosol
receptor content.
An in-
teresting example is the action of progesterone on estrogen receptors of the hamster uterus.
In this system, progesterone selectively
depresses
nuclear estrogen receptor binding (37) by a mechanism which requires transcriptional
and translational
ted by acid phosphatase (39).
intact
circuitry (38), and appears to be media-
We have reported a similar effect in the rat
anterior pituitary, and have shown tissue specificity, since
progesterone
has no effect on the hypothalamic estrogen receptors of the same animals (40).
The mechanism appears to be different from that of the hamster
uter-
us since nuclear localization of the progesterone is not required even though cytosol
progesterone receptor does seem to be involved.
Along these lines, our curiosity was piqued by our observation that LHRH administration in vivo caused nuclear estrogen receptors of the rat anterior pituitary to increase w i t h o u t any concomitant decrease in cytosol receptor level.
estrogen
In contrast to the progesterone studies mentioned above,
this study involved the action of a peptide hormone known to interact with cell membrane receptors on a species of protein localized within the nucleus.
Conditions were established for investigating this phenomenon in
vitro, using incubation of dispersed anterior pituitary cells in the presence of LHRH (41), and we were able to show the effect on whole cells (Figure 7).
The highly active LHRH analog, (D-Ala 6 ,
des-Gly10)LHRH-N-
ethylamide (designated LHRH-A), had a greater intrinsic activity in elevating nuclear estrogen receptor than did LHRH, and was maximally at a 10-fold lower concentration
(Figure 8).
effective
TRH, on the other hand, was
totally devoid of such activity over a wide concentration range (Figure 9) (42).
387
FIGURE 7. Estrogen receptor l e v e l s following incubation of i n t a c t c e l l s with LHRH for 30 min. Whole a n t e r i o r p i t u i t a r y c e l l s were incubated with 1,5 or 10 ng of LHRH per p i t u i t a r y f o r 30 min at 37°C, and estrogen receptor binding was estimated in the nuclear and extranuclear compartments of the c e l l s . The receptor level observed in control groups of c e l l s was a r b i t r a r i l y assigned a value of zero, and the p o s i t i v e or negative differences in the l e v e l s observed in treated c e l l s was plotted at each dose l e v e l . Values represent t r i p l i c a t e determinations of the number of experiments shown in parentheses. A s t e r i s k : Ρ < 0.05. [Reprinted, with permission, from Singh and Muldoon ( 4 1 ) ] .
0 1
1 0
10
100
1000
Peplicle Hormone Level (p m o l e s ' p i l u i l a r y t
FIGURE 8. Response of e s t r a d i o l receptor to LHRH and LHRH-A in i n t a c t p i t u i t a r y c e l l s . Enzymatically dispersed p i t u i t a r y c e l l s from castrated, lowdose estrogen primed rats were incubated with increasing concentrations of either LHRH or LHRH-A for 30 min at 37°C, followed by estimation of cytosol (A), nuclear (B) and the sum total (C) receptors. Values represent 10-24 observations in 6-18 separate experiments. A s t e r i s k : Ρ < 0.05, compared with c o n t r o l . [Reprinted, with permission, from Singh and Muldoon ( 4 2 ) ] .
388
T R H (ρ moles/pituitary)
FIGURE 9. E f f e c t s of TRH on estrogen receptor populations in intact p i t u itary cells. Increase (+) or decrease ( - ) in femtomoles of c y t o s o l , nuc l e a r and total estrogen receptors per 10 p i t u i t a r y equivalents i s compared to control values (assigned value of z e r o ) , r e s u l t i n g from incubation of p i t u i t a r y c e l l s from castrated, low-dose estrogen primed rats with TRH f o r 30 min at 37°C. Each value i s a mean ± SEM of 3 separate experiments. A s t e r i s k : Ρ < 0.05, as compared with c o n t r o l . [Reprinted, with permission, from Singh and Muldoon ( 4 2 ) ] . Of s i g n i f i c a n t mechanistic importance was the observation that LHRH was capable of a l t e r i n g nuclear estrogen receptor when incubated with i s o l a t e d nuclei (Figure 10).
In attempting to explain t h i s unexpected f i n d i n g , we
are forced to entertain the p o s s i b i l i t y that i n t e r n a l i z a t i o n of LHRH precedes an i n t r a c e l l u l a r mechanism of d i r e c t action of t h i s hormone.
FIGURE 10. E f f e c t of LHRH on estrogen receptors of i s o l a t e d anterior p i t u i t a r y cytosol or n u c l e i . Cytosol and nuclei were prepared and incubated separately with 1-1000 ng of LHRH per p i t u i t a r y for 30 min at 37°C. E s t r o gen receptor a c t i v i t y was then determined in each f r a c t i o n . Values are means + SEM of (n) experiments. A s t e r i s k : Ρ < 0.05, compared with c o n t r o l s incubated in the absence of LHRH. [Reprinted, with permission, from Singh and Muldoon ( 4 1 ) ] .
389 The concept that i n t e r n a l i z a t i o n of peptide hormones represents e x c l u s i v e l y the c e l l u l a r mechanism for degradative elimination of the hormone (43,44) has been questioned (45) on the b a s i s of a number of studies in which i n tranuclear l o c a l i z a t i o n of protein hormones has been observed at e x t r a lysosomal l o c i .
A p o s s i b l e d i r e c t action of LHRH on cell nuclei i s brought
into the realm of f e a s i b i l i t y by the report of s p e c i f i c r e c e p t o r - l i k e binding s i t e s for LHRH on nuclear membranes (46). In considering the mechanism whereby LHRH enhances nuclear estrogen receptor a c t i v i t y , i t therefore becomes important to determine whether cAMP functions as a mediator of t h i s a c t i o n , under the presumption that such mediation should not be required i f the action of the hormone i s indeed directly intracellular.
Of great s i g n i f i c a n c e to such studies i s the ob-
servation that cAMP i s not involved in the mechanism by which LHRH induces LH release from the a n t e r i o r p i t u i t a r y (47-50), in s p i t e of the fact that LHRH does cause increased i n t r a c e l l u l a r cAMP accumulation (51).
In Figure
11 i s presented evidence that LHRH i s capable, at 100 pmoles/pituitary, of s i g n i f i c a n t l y elevating cAMP l e v e l s in a n t e r i o r p i t u i t a r y c e l l s .
The level
of LHRH required was an order of magnitude higher than that which causes maximal nuclear estrogen receptor s t i m u l a t i o n .
The action of the above-
mentioned hyperactive analog of LHRH was l e s s pronounced than that of LHRH, in contrast to the opposite pattern in stimulating nuclear estrogen receptor (see Figure 8).
RELEASING HORMONE CONCENTRATION (PMOLE5 PITUITARY;
FIGURE 11. The influence of LHRH and LHRH-A on c y c l i c AMP production in anterior p i t u i t a r y c e l l s in suspension. C e l l s were incubated for 30 min at 37°C with the indicated l e v e l s of LHRH or LHRH-A. Concentrations of cAMP in the c e l l s and released into the medium were measured by radioimmunoassay. Numbers in parentheses are separate experiments at each dosage.
390 When we attempted to reproduce with dibutyryl cAMP the effects of LHRH on nuclear estrogen receptors, we were unable to do so, using either intact cells (Table 2) or isolated nuclei (Table 3), and amounts of cAMP orders of magnitude greater than the maximally-LHRH-stimulated level.
TABLE 2. Effects of LHRH or DBcAMP on cytosol and nuclear estrogen receptor levels in whole cells under suspension or culture conditions % of control Agent
nuclear ER suspension
cytosol ER culture
suspension
culture
LHRH (pmoles per pituitary) 0 .3
112 ± 1 .6
76
+
3..4
70 ± 1.8
10
166 ± 5 .3
256 ± 8..5
62
+
2..1
50 ± 6.5
100
192 ± 6 .1
256
5,.9
56
+
3,,2
82 ± 0.7
104 ± 0..5
66
+
2.,6
80 ± 1.5
-
34
+
2..0
1.0
102
+•
+
DBcAMP (nM) 0.1 10
95
+
1 .1 .
98 ± 4.,0
-
100
116
+
1 .7 ,
168
+
3,.3
20
+
2.,8
9 ± 4.1
1000
97
+
6.,4
95
+
7..7
30
+
5..4
20 ± 10.1
112
+
2.,2
88
+
3..0
26
+
2.,6
23 ± 8.8
10,000
Fresh anterior pituitary cells in suspension or from 3-day culture were incubated at 37°C for 30 min in the absence (control) or presence of the indicated levels of LHRH or DBcAMP. Cells were collected and subfractionated into cytosol and nuclear fractions for determination of estrogen receptor content. Each value is the mean ± SEM of triplicate determinations, using groups of 20 animals per experiment.
We conclude from these studies that LHRH has a direct specific stimulatory effect on nuclear anterior pituitary estrogen receptors, independent of involvement of cAMP.
This action of LHRH enhances the sensitivity of the
cells to estrogen, precipitating the documented estrogen enhancement of responsiveness to LHRH (52,53) and providing an explanation for the phenomenon of LHRH self-priming, whereby one exposure to LHRH sensitizes cells to a second LHRH stimulus (54,55).
391 TABLE 3. Effect of varying l e v e l s of DBcAMP or LHRH on estrogen receptor binding in i s o l a t e d cytosol and nuclear f r a c t i o n s from anterior p i t u i t a r y homogenates % of control cytosol
nuclei
LHRH (pmoles per pituitary) 112,.0 ± 1.5
(4)
10
121..1 ± 4.0
(4)*
221
± 18
(4)*
100
110,.5 ± 7.2
(4)
385
± 36
(4)
1000
95,.2 ± 3.1
(4)
590
ζ 70
(4)*
1.0
92..2 i 3. 5
(4)
DBcAMP (nM) 0.1
92,,4
± 5.9
(4)
6 .0
(4)
1.0
95,,6
±11 .8
(8)
136,.1 ± 23 .0
89,.0 ±
(8)
10
77,,5
± 4.2
(8)*
83,.6 ± 15 .3
(8)
100
73.,9
± 2.5 ( 1 2 ) *
79,.7 ± 10 .7
(8)
1000
62.,5
± 5.2 (12)*
139.,4 ± 21 .8
(8)
5000
67,.7
i l l .0
(6)*
83.,6 ± 20 .9
(4)
10,000
33.,0
ι
(2)*
87..3 ±
(2)
3.7
8 .6
Cytosol and nuclei were prepared and incubated for 30 min at 37°C with the level of effector indicated. The samples were then cooled to 4°C and the nuclei were washed with b u f f e r . Estrogen receptor content was assessed in each f r a c t i o n and expressed as the percentage of that present in samples incubated without added agent. A s t e r i s k : Ρ < 0.05, as compared with cont r o l s . Values are mean ± SEM for the number of experiments shown in parentheses . D i v e r s i t y of Receptor Regulation Numerous examples appear in the l i t e r a t u r e for regulation of s t e r o i d hormone receptor nature, level and f u n c t i o n a l i t y as a function of a wide array of e f f e c t o r s , hormonal and otherwise.
As a representative of the complex-
i t y which can be involved, we w i l l o u t l i n e some of our observations on normal mouse mammary gland estrogen receptor c o n t r o l .
392 Estrogen receptors of the mouse uterus are maintained and regulated by estrogen in much the same manner as in the rat uterus (12,56). no effect on these receptors of the uterus.
Prolactin has
In marked contrast,
prolactin
is the most potent factor y e t detected for controlling the level of estrogen receptors in mouse mammary tissue (57,58).
Administration of prolactin
to virgin mice results in dramatic stimulation of cytosol estrogen activity (Figure 12).
The receptor in the stimulated state exists as a
more highly-aggregated form than in the virgin animal greater physiological estradiol.
receptor
and, of probably
importance, has a diminished rate of interaction with
We have recently described an analogous situation for androgen
receptors of the rat ventral
prostate (33); in this system, we also find
two molecular forms of the receptor which differ with respect to their avidity for androgens.
In Figure 12 is also presented a pattern of respon-
siveness of the mouse mammary estrogen receptors to prolactin in the thyroidectomized animal.
We have previously observed an involvement of thy-
roid hormones in regulation of estrogen receptors in another tissue, the rat anterior pituitary (59).
Comparison of the two panels of Figure 12
demonstrates that thyroidectomy enhances the sensitivity of the mammary estrogen receptor response to prolactin, since it has been shown that removal of the thyroid does not result in increased prolactin secretion Moreover, it has been reported that endogenous thyroid hormones
(60).
inhibit
the mammotropic actions of prolactin.
FIGURE 12. Effect of prolactin (PRL) on mouse mammary gland estrogen receptor level and nature. Intact (left panel) or thyroidectomized (right panel) virgin mice were injected with prolactin and killed 18 hours later (o), or injected daily with prolactin for 3 days and killed 1 hour after the final injection ( A ) . Equivalent amounts of cytosol protein were incubated with [ 3 H]estradiol and applied to sucrose gradients prepared in low ionic strength buffer. The arrow represents bovine serum albumin at a value of 4.4S.
393 The effect of p r o l a c t i n on mammary t i s s u e estrogen receptors i s seen when the animals are treated with estradiol
(Table 4).
I t was o r i g i n a l l y
that the estradiol d i r e c t l y regulated i t s receptor l e v e l s in t h i s
thought
tissue
as i t does in the uterus; however, the data of Table 4, in which bromocryptine suppression of p r o l a c t i n eradicates the p o s s i b i l i t y of estradiol hancing estrogen receptor a c t i v i t y , demonstrate that the estradiol
en-
action
i s i n d i r e c t and mediated through stimulation of p r o l a c t i n secretion. TABLE 4.
Influence of p r o l a c t i n on mouse mammary gland estrogen receptors Estrogen receptor l e v e l s as % of control
Treatment
Cytosolic
Nuclear
100 ± 9
100 ± 7
Estradiol, 0.5 yg/day χ 30, sc in o i l
61 ± 5
500 ± 43
CB-154*, 100 yg/day χ 30, ip in sal i ne
87 - 8
111 i 17
E s t r a d i o l + CB-154
59 ί 5
133 ± 8
386 ± 38
273 ± 26
Control a
Rat p r o l a c t i n , 50 yg/day, twice d a i l y χ 5, sc in o i l a
Untreated, 58-day old v i r g i n mice *CB-154 = bromocryptine I t can also be seen from Table 4 that prolactin-induced estrogen receptor i s heavily concentrated in the c y t o s o l .
When estradiol
i s subsequently
administered, nuclear t r a n s l o c a t i o n occurs and progesterone receptor i s induced (58). sue i s bimodal.
Thus, the primary control of estrogen receptors in t h i s
tis-
P r o l a c t i n regulates the level of estrogen receptors and
e s t r a d i o l regulates t h e i r f u n c t i o n a l i t y .
Neither hormone, in the absence
of the other, i s capable of e l i c i t i n g maximal estrogenic response.
This
i s o l a t e d instance of multifaceted regulation of a s i n g l e receptor system in a t i s s u e - s p e c i f i c manner exemplifies the complexity with which multiple
394 homeostatic hormonal environments are regulated and maintained. Concluding Remarks In t h i s presentation, work from my laboratory has been d i s c u s s e d , dealing with several s p e c i f i c studies chosen to exemplify d i f f e r e n t aspects of the ways in which regulation of s t e r o i d hormone receptor turnover occurs and i s related to hormonal responsiveness.
To adequately portray the paradox-
ical features of both uniqueness and universal commonness of s t e r o i d a l receptor systems, I have d e l i b e r a t e l y selected four d i f f e r e n t t i s s u e s y s tems, i . e . , uterus, prostate, hypothalamus-adenohypophysis, and mammary gland.
While the q u a n t i t a t i v e features of control and function are v a r i -
able, the basic denominator remains constant.
For instance, the estrogen
receptors of the uterus and mammary gland are p r i n c i p a l l y regulated by estradiol
and p r o l a c t i n , r e s p e c t i v e l y , whereas the fundamental
processes
of control of receptor dynamics and concentration appear to be common to both t i s s u e s .
The overall process of receptor r e g u l a t i o n , j u s t as the
mechanism of s t e r o i d hormone a c t i o n , appears to be a highly-conserved evolutionary t r a i t .
However, the development of t i s s u e and c e l l u l a r
dif-
f e r e n t i a t i o n which has evolved with time has given r i s e to both subtle and profound changes in the control of responsiveness to a given hormone or group of hormones.
This chapter i s designed as a mere introduction to t h i s
subject, d i r e c t i n g the attention of the reader to an area of active current research in our quest for a better understanding of the molecular b a s i s of reproductive physiology and pathology. References 1.
Jensen, E . V . , Jacobson, H . I . : Ree. Progr. Horm. Res. 18, 387-414 (1962).
2.
Jensen, E.V., DeSombre, E.R.: Annu. Rev. Biochem. 41_, 203-230 (1972).
3.
Stumpf, W.E., S a r , M.: In: Receptors and Mechanism of Action of S t e r oid Hormones, Part 1. P a s q u a l i n i , J.R. ( E d . ) , Marcel Dekker, New York, 1977, p. 41.
4.
Gorski, J . , T o f t , D.O., Shyamala, G., Smith, D., Notides, A.C.: Ree. Progr. Horm. Res. 24, 45-80 (1968).
5.
L i a o , S . : I n t l . Rev. Cytology 4T_, 87-172 (1975).
6.
0 1 Mai l e y , B.W., Schräder, W.T.: J. S t e r o i d Biochem. 3, 617-629 (1972).
395 7.
Rousseau, G.G., B a x t e r , J . D . , Tomkins, G.M.: J . Mol. B i o l . 67, 99-115 (1972).
8.
L i n k i e , D.M., S i i t e r i ,
9.
S h e r i d a n , P . J . , Buchanan, J . M . , Anselmo, V . C . : Nature 282, 579-582 (1979).
P . K . : J . S t e r o i d Biochem. 9, 1071-1078
(1978).
10.
K i n g , W . J . , Greene, G . L . : Nature 307, 745-747
11.
Welshons, W.V., Lieberman, M . E . , G o r s k i , J . : Nature 307, 747-749
(1984). (1984)
12.
C i d l o w s k i , J . A . , Muldoon, T . G . : B i o l . Reprod. 18, 234-246
13.
H o r w i t z , K . B . , McGuire, W.L.: J . B i o l . Chem. 253, 8185-8191
(1978).
14.
Korach, K . S . , F o r d , E . B . : Biochem. B i o p h y s . Res. Commun. 8^3, 327-333 (1978).
15.
Korach, K . S . : E n d o c r i n o l o g y 104, 1324-1332
16.
L i t t l e , Μ . , R o s e n f e l d , G . C . , J u n g b l u t , P.W.: Ζ. P h y s i o l . Chem. 353, 231-242 ( 1 9 7 2 ) .
17.
L i t t l e , Μ . , S z e n d r o , P . , T e r a n , C . , Hughes, Α . , J u n g b l u t , P.W.: J . S t e r o i d Biochem. 6 , 493-500 ( 1 9 7 5 ) .
18.
S z e n d r o , P . I . , S i e r r a l t a , W.D., J u n g b l u t , P.W.: Ζ. P h y s i o l . Chem. 364, 1337-1344 ( 1 9 8 3 ) .
(1978).
(1979).
19.
Muldoon, T . G . : B i o c h e m i s t r y 10, 3780-3784
20.
Muldoon, T . G . : J . B i o l . Chem. 255, 1358-1366
(1971).
21.
T a l w a r , G . P . , M o d i , S . , Rao, K . N . : S c i e n c e 150, 1315-1316
(1965).
22.
B e r g , Α . , G u s t a f s s o n , J - A . : J . B i o l . Chem. 248, 6559-6567
(1973).
23.
S u n s h i n e , G.H., W i l l i a m s , D . J . , R a b i n , B . R . : Nature (New B i o l o g y ) 133-136 (1971 ) .
24.
B l y t h , C.A. , Cooper, M . B . , Roobel, Α . , R a b i n , B . R . : Eur. J. 29, 293-300 ( 1 9 7 2 ) .
(1980).
230,
Biochem.
25.
L i a n g , T . , L i a o , S . : J. B i o l . Chem. 249, 4671-4678
26.
L i a n g , T . , Castaneda, E . , L i a o , S . : J . B i o l . Chem. 252, (1977).
(1974).
27.
P a r i k h , I . , A n d e r s o n , W.L., Neame, P . : J . B i o l . Chem. 255, 1026610270 ( 1 9 8 0 ) .
5692-5700
28.
M c K n i g h t , G . S . , P a l m i t e r , R . D . : J . B i o l . Chem. 254, 9050-9058
29.
0 ' M a l l e y , B.W., Woo, S . L . , T s a i , M . J . : C u r r . T o p i c s C e l l . R e g u l . 1 8 , 437-453 ( 1 9 8 1 ) .
(1979).
30.
B r e a t h n a c h , R . , Chambon, P . : Annu. Rev. Biochem. 50, 349-383
31.
0 ' M a i l e y , B.W. ( E d . ) : Gene R e g u l a t i o n .
(1981).
32.
Muldoon, T . G . , M a i n w a r i n g , W . I . P . : 7th I n t l . Congr. of E n d o c r i n o l o g y , Quebec C i t y , 1984. Excerpta Medica, Amsterdam, p. 1061.
33.
F e i t , E . I . , Muldoon, T . G . : E n d o c r i n o l o g y 1J_2, 592-600
Academic P r e s s , New Y o r k , 1982.
(1983).
396 34.
Wilson, Ε.Μ., French, F.S.: J. Biol. Chem. 251, 5620-5629 (1976).
35.
Wilson, E.M., French, F.S.: J. Biol. Chem. 254, 6310-6319 (1979).
36.
Muldoon, T.G.: Endocrine Rev.
37.
Evans, R.W., Chen, T.J., Hendry, W.J., Leavitt, W.W.: Endocrinology 107, 383-390 (1980).
38.
Evans, R.W., Leavitt, W.W.: Proc. Natl. Acad. Sei. (USA) 77, 58565860 (1980).
39.
MacDonald, R.G., Okulicz, W.C., Leavitt, W.W.: Biochem. Biophys. Res. Commun. 104, 570-576 (1982).
40.
Smanik, E.J., Young, H.K., Muldoon, T.G., Mahesh, V.B.: Endocrinology 113, 15-22 (1983).
339-364 (1980).
41.
Singh, P., Muldoon, T.G.: J. Steroid Biochem. 16, 31-37 (1982).
42.
Singh, P., Muldoon, T.G.: Neuroendocrinology 37, 98-105 (1983).
43.
Amsterdam, Α., Berkowitz, Α., Nimrod, Α., Kohen, F.: Proc. Natl. Acad. Sei. (USA) 77, 3440-3444 (1980).
44.
Hizuka, N., Görden, P., Lesniak, M.A., Van Obberghen, E., Carpentier, J-L., Orci, L.: J. Biol. Chem. 256, 4591-4597 (1981).
45.
Posner, B.I., Bergeron, J.J.M., Josefsberg, Z., Khan, M.N., Khan, R.J., Patel , B.A., Sikstrora, R.A. , Verma, A.K.: Ree. Progr. Horm. Res. 37, 539-582 (1983).
46.
Millar, R.P., Rosen, Η. , Badminton, Μ., Pasqualini, C., Kerdelhue, B.: FEBS Letters lj>3, 382-386 (1983).
47.
Naor, Z., Koch, Y., Chobsieng, P., Zor, U.: FEBS Letters 58, 318-321 (1975).
48.
Tang, L.K.L., Spies, H.G.: Endocrinology 94, 1016-1021
49.
Clayton, R.N., Shakespear, R.A., Marshall, J.C.: Mol. Cell. Endocrinol. 11, 63-78 (1978).
50.
Conn, P.M., Morrell, D.V., Dufau, M.L., Catt, K.J.: Endocrinology 104, 448-453 (1979).
51.
Deery, D.J., Howell, S.L.: Biochim. Biophys. Acta 329, 17-22 (1973).
52.
Drouin, J., Lagace, L., Labrie, F.: Endocrinology 99, 1477-1481
53.
Speight, Α., Popkin, R., Watts, A.G., Fink, G.: J. Endocrinol. 88, 301-308 (1981).
54.
Aiyer, M.S., Chiappa, S.A., Fink, G.: J. Endocrinol. 62, 573-588 (1974)
(1974).
(1976).
55.
Castro-Vasquez, Α., McCann, S.M.: Endocrinology
56.
Cidlowski, J.Α., Muldoon, T.G.: Endocrinology 95, 1621-1629 (1974).
13-19 (1975).
57.
Muldoon, T.G.: In: Ontogeny of Receptors and Reproductive Hormone Action. Hamilton, T.H., Clark, J.H., Sadler, W.A. (Eds.), Raven Press, New York, 1979, p. 225.
58.
Muldoon, T.G.: Endocrinology 109, 1339-1346 (1981).
397 59.
Cidlowski, J.Α., Muldoon, T.G.: Endocrinology 97, 59-67 (1975).
60.
Peake, G.I., Birge, C.A., Daughaday, W.H.: Endocrinology 92, 487-493 (1973).
61.
Mittra, I.: Nature 248, 525-526 (1974).
AN ENDOGENOUS LIGAND FOR TYPE II BINDING SITES IN NORMAL AND NEOPLASTIC TISSUES Barry M. Markaverich and James H. Clark
Department of Cell Biology Baylor College of Medicine Houston, Texas 77030
Abstract
The rat uterus contains two classes of specific nuclear estrogen binding sites which may be involved in estrogen action. the classical estrogen receptor are stimulated uterine gen
in the nucleus by estrogen
hyperplasia.
treated
rats
3
[ H]-estradiol measurable
to
exchange
quantities
nuclear
result
dilution
from
estradiol
the
under
represent
(Kd
10-20nM)
conditions which
cause
Dilution of uterine nuclear fractions from estro-
prior
quantitation
results
of
the
occur
dilution
in
type
are not affected by dilution. ing
Type I sites
(Kd InM) and type II sites
of
an
estrogen
increase
II site.
binding
(3-4
Estimates
sites
fold)
in
independently a
specific
binding to these sites.
of
protein
the
of type I sites
These increases in type II sites
of
follow-
concentration
endogenous
by
inhibitor
The inhibitor activity
of
and [3 Η ] —
is present in
cytosol preparations from rat uterus, spleen, diaphragm, skeletal muscle and
serum.
Sephadex
Preliminary
characterization
G-25 chromatography
in molecular weight ( 300). on
LH-20
chromatography
retained on this
These components
since
inhibitor
component
gas-liquid
chromatography-mass
tive
inhibitor
very
similar
304).
activity
high
is not
phenanthrene-like
Analysis
the
lipophilic resin. by
of
cytosol
of
the
inhibitor
activity
shows two distinct peaks which are
ß-peak
by
similar
(a and β) can be separated
component
is
preferentially
Partial purification of the LH-20-8
performance
liquid
chromatography
spectrometric analysis steroidal molecules
preparations
in nature
and consists of two
(molecular on LH-20
and
suggest the p u t a -
weights
302
chromatography
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
and shows
400 that
non-neoplastic
contain
both
mammary
tumors
peak
α
tissues
and
contain
inhibitor
(uterus,
β inhibitor very
liver,
components
low
to
lactating
whereas
mammary
gland)
estrogen-induced
non-measurable
quantities
of
rat
the
6-
activity.
INTRODUCTION
Estrogen
administration
in m o t i o n a n u m b e r of
true
uterine
estrogen
nuclear sites
growth.
receptor
complexes
to
I
nucleus
II
immature
sites
in e s t r o g e n
sites),
The
antagonism
of
uterotropic
responses
inhibition
of
the
type
antagonists ethylene In
this
we
II
cytoplasmic purified liquid
We will
sites
and
or
our
does
not
procedures,
Detection
and M e a s u r e m e n t
presence
II s i t e s w a s II
sites
and
ref
specific
of
an
first
increased 6.
These
and
of
of a p p r o x i m a t e l y
Inhibitory for
the
uterine
[3H]-estradiol
show binding
nuclear that
the
steroid
(5). demonstrates
the
to
nuclear
for
nuclear
binding
material
has
to been
analyzed
by
gas-
the
basis
of
two
is p h e n a n t h r e n e - l i k e
in
300.
Activity
binding
considered w h e n we observed
data
with
and
On
activity
II
that
triphenyl-
binding
This
of
type
for
[^H ] - e s t r a d i o l
chromatography
the
or
and
is s p e c i f i c
receptors.
feel
case
(4)
[^Hj-estradiol
with
I
associated the
(6) w h i c h
inhibitor
the
activation
demonstrated
clomiphene
spectrometry. we
inhibitor
as
is
to
receptor-estrogen
type
is
This
sets
stimulation
binding
or
of
estrogen
work
of
liquid
nature with a molecular weight
The
role
progesterone
this
estrogen
chromatography-mass
derivatization
to
interfere
performance
of
rats
the
hormone
H o w e v e r , we h a v e
recent
that
with
stimulation
precise
and
inhibitor
show
nuclear
by h i g h
the
s u c h as n a f o x i d i n e
summarize
include
sites.
dexamethasone
of an e n d o g e n o u s
II s i t e s .
type
as
derivatives paper
presence type
such
II
ovariectomized
associated
translocation
and
is u n k n o w n .
nuclear
mature
events
(1,2),
(3-5).
action
or
events
These
(type
the
type
to
of b i o c h e m i c a l
of
fractions
with
[^H]-estradiol
that
were
dilution,
to n u c l e a r
type
the q u a n t i t y diluted
(40
II s i t e s
to
type
of
type
(Figure
mg/ml-10
1
mg/ml)
increases
even
401
Specific Binding Ό 3 Ο
CO D
30-
• 10mg/ml ο 20mg/ml • 40mg/ml
-t-1
Ο
3
TJ (0 (0
φ
I
TO
10
20
30
40
3
[ H ] - E s t r a d i o l nM
Fig.
1.
E f f e c t of d i l u t i o n on [ ^ H J - e s t r a d i o l b i n d i n g in u t e r i n e n u c l e a r f r a c t i o n s f r o m a d u l t o v a r i e c t o m i z e d rats i m p l a n t e d w i t h a n e s t r a d i o l p e l l e t for 4 d a y s .
402 though
the quantity
to 4-fold. that
the
of nuclei
Expression quantities
nuclear
of
of
in the
nuclear
concentrations
incubation
(10
type
and
20
II
sites
to
show
increased not
the
that
type
concurrently case.
I sites
with
These
is decreased
the
3-
to
4-fold
Although these binding
curves
are
we will
increases
at
least
lower
ntn [ 3 H]-estradiol) are
(0.4-8.0
dilution,
apparent
measured
2
demonstrates at
mg/ml)
greater than levels measured at 40 mg/ml. appear
mixture
the data on a per uterine basis
show
later
in receptor
that
also
this
estimates
is
are
due
only to an increasing influence of the type II site on the assay of type I sites as we have described previously These
results
measured specific
inhibitor
sites.
To
cytosol nuclei type
examine
the
increased
nuclear
fractions
binding
of
this
of
The
possibility
results
increasing
decreases
II sites
concentration expected.
specific
The
which
decreased
concentration
suggest
uterine
binding
to
competitive
nuclear
II
or nuclear receptor
nuclear
large
cytosol
of
linearly
in
of
dilutions
of
type
related
dilution
sites.
The
of the binding of
inhibitor
[^HJ-estradiol
which
we
to
protein
would
be
identical did
These
to not
results
[ 3 H]-estradiol
of
appears
to
to type
be
a
II sites
[ 3 H]-estradiol to either the
cytosol
(6).
boiled-acid
precipitated
cytosol
from
ACTIVITY adult
tomized rat uteri on Sephadex G-25 revealed two major peaks of activity
nuclear nuclear
yg/ml)
II sites.
of the
to
as
were
(200
uterine
that
the
G E L FILTRATION CHROMATOGRAPHY OF UTERINE CYTOSOL INHIBITOR Chromatography
II
quantities
to
BSA which
cytosol
sites
type
[ 3 H]-estradiol
with
of
to nuclear
yet does not inhibit the binding of
II
demonstrate
contains a specific inhibitor
type
inhibitor
contain
of
binding
measured
[ 3 H]-estradiol binding
type
various
experiments
concentrations
inhibit
cytosol
to
inhibition was not directly
In addition,
protein
which
these
concentrations
the
(6).
further,
of
from dilution of a
of BSA were incubated with
rats
of
quantities may result
[ 3 H]-estradiol
concentrations
from estradiol-implanted
II sites.
suspension
the
that
of
or equivalent
addition
type
suggest
in more dilute
(7).
designated
a and
g
(Figure
2).
This
ovariecinhibitor
activity
was
403
A.
B. L H - 2 0
G-25
(
(p)
• ίΜ, '
Τ
J
l.J/'s»«!«»^, C. G - 2 5 ~
Ο
Fig.
2.
Λ
'
:
LiX^^V^™, , D. G - 2 5 0
'Λ ' h'
10
20
30 40 10 Fraction Number
20
30
40
Chromatography of rat uterine cytosol inhibitor preparations on Sephadex G-25 (A,C, and D) or LH-20 columns (B).
60 c o
I 40 c
20
0 Fig.
3.
10
20
30
40
Fraction Number
50
Comparison of LH-20 elution profiles from acidprecipitated-boiled cytosol preparations (100 mg fresh tissue equivalents/ml) from rat uterus (o) or an estrogeninduced rat mammary tumor (·).
404 measured in the column fractions by their ability to inhibit the binding [ 3 H]-estradiol seen
in
the
to
nuclear
void
volume
type of
II.
the
A minor
column, which
with protein since there was a significant tions.
In
addition,
peak
incubation
of
the
of activity was
is apparently rea
OD28O cytosol
ding
also
associated these
inhibitor
frac-
preparation
with 0.4 Μ KCL for 60 minutes at 4° prior to chromatography on Sephadex G-25
(TE buffer containing 0.4 Μ KCL) dissociated the inhibitor
from the void volume fractions On
the
basis
of
sizing
(raw 507.2) as markers, we and
β inhibitor
chromatography
(data not
experiments
is
of an aliquot
in
of
shown).
using
estimated
components
tryptophan
that
the
(mw 204.2) and
ATP
the molecular weight of the α
range
this
activity
same
of
300-400.
cytosol
Surprisingly,
preparation
on
LH-20
(Figure 2B) shows that the two components are more clearly resolved. determine
if
the
chromatography collected
order
was
the
D).
The
correspond
elution
individual
rechromatographed and
of
analagous
to
a
of
the
their
and
α
and
behavior
β
peak
β
on
peaks
on
Sephadex
fraction
from
LH-20
G-25, LH-20
the of
demonstrate elution
cytosol
of
that
the
this
β peaks
material
preparations
on
from on
larger
LH-20
we and
these fractions on the Sephadex G-25 column (Figure
results
Chromatography
to
To
2C
columns
Sephadex
G-25.
preparative
LH-20
columns facilitates complete separation of the α and β peak fraction due to the selective retention of the β material and has greatly purification of this inhibitor activity
COMPARISON UTERUS, MAMMARY
Since
OF
LH-20
NORMAL
ELUTION
LACTATING
PROFILES
RAT
MAMMARY
facilitated
(see below).
OF
CYTOSOL
GLAND
AND
FROM
RAT
ESTROGEN-INDUCED
OBTAINED
RAT
TUMORS
nuclear
estrogens
type
cause
II sites may
cell
play
growth
a role
be involved
(3,
4)
we
inhibitor
may
this were
the case, then rapidly proliferating
respond
to estrogen might
examine
this
possibility
in modulating
in the mechanisms by which
reasoned
show we
these
deficiencies
prepared
that
cellular
perhaps responses.
neoplastic tissues
in inhibitor
boiled-acid
this
activity.
precipitated
If
which To
cytosol
405 from rat uterus, normal lactating rat mammary gland and estrogen-induced rat
mammary
LH-20.
tumors,
and
chromatographed
aliquots
of
these
cytosols
Individual fractions were assayed for inhibitor activity.
data show that
the
larger LH-20 column (1.0 χ 50 cm: 75 ml bed
on
These volume)
used for these experiments clearly separated the a and β inhibitor peaks (Figure tumor peak
3) in rat
cytosol
uterine
contained
material,
the
cytosol.
Furthermore,
approximately
tumors
contained
although
equivalent
little
of
rat
quantities
mammary
of
the
the 3 component
and
α in
some cases the ß-inhibitor component was nonmeasurable. This
observation
has
also
human breast cancer (15).
been
extended
to
mouse
mammary
tumors
20 chromatography showed that mouse mammary gland contained inhibitor
activity
than
mammary
tumors
in the
This difference in activity appears to result in the ß-inhibitor peak material (Fig. 4, ref completed
a
series
preparations
from
chromatography. ß-inhibitor following
of
uterus
component
molecule
experiments
and
tumor
same
inhibitor
in
in uterine
15).
In addition, we have
where
were
cytosol
cytosol
mixed
was
(as compared
(since
they
readily
are
of
very
inhibitor
the
peak
28-38
(Figure
in tumors which (fractions
ß-peak
However,
biological preparations
prior
to
material
in
3)
quantitatively
recovered
to uterus) is not
in
crude
rat
due
to
At present we do not
relationship similar
between ο and β
molecular weight) and
Certainly the inhibitor activity
suggests
there
is not observed
tumors
experiments
activity. from
LH-20
that the
is
an
altered
in the uterus.
form
Whether
28-38) represents an altered or metabolized
preliminary
material
inhibitor
form the ß-material, or if perhaps the tumors
metabolize this ß-inhibitor component.
activity
cytosol
These results suggest that the tumor cytosol
there is a precursor-product
peaks
fractions
animals.
deficiency
in the ß-inhibitor component, and the low levels of
tumor
the tumor cannot
in
of
from a primary
some intrinsic degradation during the preparation. know whether
20-fold more
strain
The results of these experiments demonstrated
is indeed deficient this
mixing
chromatography.
and
Detailed studies by dilution analysis and LH-
(Figure
3)
indicate
inhibitor
remains
that
preparations
Acid-Precipitated-Boiled uterus
of
liver
to
be
the presence
(containing
is
a
and
this
form of
resolved. of
associated
cytosol
of
the
ß-
with
inhibitor β
inhibitor
406
Fig. 4.
LH-20 chromatography of mouse mammary gland (A) and mouse mammary tumor (B) cytosol. Aliquots (1 ml) of the cytosol preparations (80 mg fresh tissue equivalents/ml) were loaded on an LH-20 column and the columns eluted with TE (10 mM Tris; 1.5 mM EDTA) buffer. Fractions (0.5 ml) were collected and assayed for inhibitor activity as described in methods. Results are plotted as [ 3 H ] - e s t r a d i o l binding to nuclear type II sites (% inhibition) were buffer controls (0% inhibition) contained approximately 45,000 cpm bound. The results were obtained from a single experiment. However, we have analyzed 15-20 separate tumor cytosol preparations and very similar results were obtained.
407 components) inhibit approximately
the growth of rat mammary tumor cells in culture by
80-90%
in
4-7 days.
Conversely,
preparations
from
rat
mammary tumors (containing a, but lacking the ß-inhibitor component) had no significant effect on cell growth in identical experiments for
3-4
weeks.
inhibitor
peak
These
results
material
in
suggest
tumors
that
is
the
absence
correlated
continued of
with
the
rapid
ß-
cell
proliferation in these populations.
PURIFICATION AND PARTIAL CHARACTERIZATION OF INHIBITOR ACTIVITY
As
stated
activity HPLC
of the
inhibitor
(LH-20 6-peak component) remains to be established.
earlier,
However,
analysis
showed
from the silica times
on
elutes very
5-6 minutes
broad
of
with to
injection. a single
procedures
conditions;
to
and
of
the activity
consistently
of uv absorbance
at
254 nM
The peak is somewhat
suggesting
multiple
inhibitor
To date we have tried a number of
these
peak
can be eluted
The samples at this point are
peak
shoulders,
separate
reinjection
activity
has been repeated a number of
the inhibitor activity.
have
components which are not separated. HPLC
inhibitor
liver preparations
observe
appears
peak
identification
This experiment
following
since we
is coincident and
structural
a major
column.
3-4 separate
clean
which
positive
components
fractions)
and
(various we
elution
cannot
further
separate these components on a straight phase column. This heterogeneity of putative inhibitor molecules was supported by GCMS analysis.
The GC-MS analysis of the pooled
minutes) positively
HPLC fractions
identified a number of fatty
nents in the sample inhibitor preparations.
(5.4-5.8
acids as major
compo-
However, these are unlikely
candidates for the inhibitor since the authentic compounds did not inhibit
[ 3 H]-estradiol binding to type II sites over a wide range of concen-
trations
(0.001 nM -
100 pM).
The putative
inhibitor activity appears
to be associated with two remaining components in the sample which have a
molecular
weight
of
302 and
304.
Comparison
of
sample
spectra
to
those of known compounds in the NIH bureau of standards library suggests the inhibitor is very similar to phenanthrene-like
molecules.
408 DISCUSSION AND CONCLUSIONS
These
experiments
demonstrate
that
the adult
ovariectomized
rat
uterus
and a variety of rat tissues contain an inhibitor which interferes with [ 3 H]-estradiol inhibitor with
binding
is specific
estrogen
binding
Consequently,
if
to
type
II
for nuclear
sites
type
to cytoplasmic
this
inhibitor
in
uterine
II sites and
nuclei.
does not
or nuclear estrogen
is
involved
in
receptor
the
(6).
modulation
estrogenic response in target tissues, its effects are expressed an interaction with nuclear type II sites.
This
interfere
of
through
We currently feel that this
molecule represents an endogenous ligand for type II sites (6). Preliminary
characterization
demonstrates
of
this
inhibitor
this molecule(s) is stable to heat
in
rat
uterine
HCL, and therefore it is unlikely to be protein in nature. trypsin and
and proteinase
the
(Figure 350.
inhibitor 2) as We
appears
two
have
major
identical
to
and
the
that
HPLC
with 2
an
peak
seen
and
phenanthrene-like
its activity
chromatographs
peaks
purified
identical
chromatography
Κ do not destroy
activity
it
on
estimated
the
appears
compounds
basis of mass spectrometry of 302 and 304. the
inhibitor
molecules
identification equivalent
and
since
the
(free
fatty
derivatives
only
also is
for
compete not
At
weight
not
thin
layer
of
two
nearly
weights
to homogeneity, "identified"
present
compounds
inhibit
of
(which
on
the
Proof that these are in fact
the the
LH-20
liver
by
consist
shown),
or
time
structural
material we
feel
are good candidates for the inhibitor
measureable
acids) did
type II sites. competes
other
that
activity.
rat
molecular
purification
demonstration
biological
phenanthrene
awaits
G-25
molecular
from
uterus)
to
with
In addition,
(data not
Sephadex
material
in
cytosol
(100° χ 60'), and 0.1 Ν
in
the
sample
has these
activity
preparation
[ 3 H]-estradiol binding
to
nuclear
Although one could argue that if the putative inhibitor
[ 3 H]-estradiol binding to nuclear for
necessarily
triphenylethylene
type
II sites
[ 3 H]-estradiol binding to the estrogen the
case.
derivatives
Nuclear
type
(anti-estrogens)
compounds bind to the estrogen receptor
(7).
II even
it should
receptor, this do
not
though
bind these
Likewise, nuclear type II
sites also appear to bind this inhibitor with amazing specifity, whereas
409 we have been unable receptor
(6).
estrogen binding type
receptor (Figure
I sites
possible
to show this inhibitor
Certainly,
the
if
direct
direct
we
observed
demonstrate
with that
have
to
of
associated
with
the
effect
on
[ 3 H]-estradiol binding
to
a dilution
experiments
obtain
(6).
milligram
It
is
amounts
also
of
the
[ 3 H]-estradiol binding to type I sites would
pharmacological at
were
observed
inhibition
able
interacts with the estrogen
inhibitor
competition
were
inhibitor, competition for be
the
in vivo we would 1) or
in
that
if
concentrations
physiological
(mM).
concentrations
this
Our
data
interaction
is
unlikely · Since
we
have
inhibitor
not
been
activity
describe
any
experiments positive
able
in vivo
direct await
role
it is very
experiments,
however, are very
should
to
normal
4).
mammary
tumors
We
uterus
have
which
liver
which
inhibition cell
(Figure
were
an
this early
time to
action.
These
inhibitor. of its
Once
a
biological
Preliminary
It appears
this
that
in vitro
there is a
and
lactating
mammary
inhibitor
preparations
in
peak
the
g
and myometrial
gland
from
rat
did
not
material
cells, or rat
mammary
In contrast, inhibitor preparations from uterus
contain
cell
or
the
of
in rat mammary tumor cytosol as
3),
that
deficient
the
80% following
of
death,
at
effects
in estrogen of
promising.
growth of uterine stromal
approximately
the
straightfoward.
observed
tumor cells in culture. or
be
in the ß-inhibitor component
(Figure
inhibit
difficult
compound
identification
in vivo
compared
assess
has been made, determination
significance
deficiency
directly
for this
chemical
identification
to
growth
6
material
reduced
4-7 days of treatment. in
inhibition
culture of
cell
results
from
division
or
cell
numbers
by
Whether or not this an
acceleration
both
remains
to
of be
resolved. Although
the physiological
significance of this inhibitor remains to be
resolved, we speculate at this time that the inhibitor may act to modify or
regulate
uterotropic
responses
to
estrogen
or
perhaps
"protective" capacity in cases of hyperestrogenization.
act
in
a
Such hypothesis
are consistent with our current knowledge concerning a possible role for nuclear
type
secondary
II sites
nuclear
in
estrogen
estrogen
action.
binding
sites
We
have
are
shown
only
that
these
activated
or
410 stimulated
in
the
nucleus
hypertrophy,
hyperplasia
dexamethasone
and
under
and
conditions
DNA
progesterone
which
synthesis
antagonism
cause
(3-5).
of uterine
uterine
Furthermore,
growth
in the
rat
is associated with an inhibition of estrogen stimulation of nuclear XI sites the
(4) and these antagonists do not affect the normal functions of
estrogen
On
the
basis
of
that
nuclear
type
II
sites
may
action.
Since
nuclear
type
II
localized
on
suggested
estrogen
receptor.
the
replication
nuclear
(9), we
induced
feel
DNA
estrogen
matrix this
DNA
the
failure
synthesis)
hypothalmus
in
inhibitor
synthesis
of
by
estrogen
estrogen
to
stimulate
mammary
tumors
levels
(~ 15-20 a
fold)
Likewise, ovarian
in
human
tissues
type
II
variety
we of
nuclear
cell
growth as
block of
(hyperplasia;
the
pituitary
and
have
are
basal do
14)
estrogen
which
appear
of
type
respond
this inhibitor may be a component
as are nuclear
type
II sites.
and
in
endocrine
II
sites
in
deficiency.
estrogen
(6).
in a via
tissues
Therefore
of all
tissues
In tissues which do not normally
respond
manner, type
consequently
Conversely,
mammary
(diaphragm, spleen, liver) and these
is that
this
permanently
II sites
to
activity
lower
correlated
the
type
our hypothesis
inhibitor
be
inhibitor
of nuclear
normally
to
quantities of inhibitor
to estrogen in a proliferative
target
with
(12) mouse
nuclear
this
is
consistent
regardless of
with
levels
not
is
independent
levels
correlated
which
activity
II sites
(13,
these
(15) contain significantly
(11) or
higher
measured
tissues
in
the
the failure of
do contain significant
this
or
be DNA
stimulation
Certainly,
component
type
cancer
hypertrophy and hyperplasia
expressed.
to in
Our findings that rat and mouse
inhibitor
3-peak
dependent
these
tissues
Likewise,
appear
may modulate
such
sites
cancer
this
the
breast
Therefore
malignant
of
in
activated and
have
estrogen
implicated
estrogen
to stimulate
and human breast
deficiency
status.
sites
been
we
in
sites.
in these tissues.
nuclear
hypothesis.
tumors
has
activity
organs makes this a tenable hypothesis.
with
involved
binding
inhibiting
target
experiments
be
(10) is related to the inability of estrogen to modulate
activity of this inhibitor estrogen
these
(8) which
these secondary nuclear estrogen binding Perhaps
type
the
tissues
II sites are complexed with
functions which
do
of
these
respond
are
not
to estrogens,
sites
the
411 association of the receptor-estrogen result
in a dissociation
Under
these
observed.
conditions
Consistent
observed
following nuclei
the
this
(Figure
dilution.
from
complex with target cell nuclei may
inhibitor
cellular
with
estrogen treated nuclei
uterine
of
from
hypertrophy
hypothesis
estrogen
Since
ovariectomized
dependent.
is
1) additional this animals
feel that this dissociation of the inhibitor is
nuclear
Obviously,
the
and
our
sites.
hyperplasia
is
that
in
type
II sites
not
observed
in
shown),
we
is
(controls;
not
from nuclear lower
II
observation
nuclear
effect
type
levels
type of
are
II sites inhibitor
activity in neoplastic tissues is consistent with the elevated levels of type
II
sites
measured
these cell populations.
in
tumors
and
the
Although only
rapid
proliferation
tentative at this point
we feel that this is a reasonable model for potential proliferation by type II binding
rate
in
in time,
regulation of cell
inhibitor.
ACKNOWLEDGEMENTS
The authors would technical
like to thank Rebbecca Roberts and M.A. Alejandro
assistance,
Georgietta
Brown
David Scarff for the illustrations.
for
typing
the
manuscript,
Supported by NIH grants
for and
HD-08436.
REFERENCES
1.
Jensen, E.V., Numata, M., Brecher, P.I., DeSombre, Biochemistry of Steroid Hormone Action (Smellie, Academic Press, London 133-159 (1971)
E.R.: In The R.M.S., ed.)
2.
Shyamala, G. Gorski, J.: J. Biol. Chem. 244,
(1967).
1097-1103
3.
Markaverich, B.M., Clark, J.H.: Endocrinology
4.
Markaverich, Β.Μ., Upchurch, 14, 125-132 (1981).
5.
Markaverich, B.M., Upchurch, S., McCormack, Clark, J.H.: Biol. Reprod. 24, 171-181 (1981).
6.
Markaverich, Β.Μ., Roberts, R.R., Finney, R.W. Clark, J.Η.: J. Biol. Chem. 258,11663-11671 (1983).
S.,
Clark,
105, 1458-1462
J.H.:
J. Steroid S.,
(1979). Biochem.
Glasser,
S.R.,
412 7. Markaverich, Β.Μ., Williams, Endocrinology 62-69 (1981).
Μ.,
Upchurch,
S.,
Clark
J.Η.:
8. Clark, J.H. Markaverich, Β.Μ.: In The Nuclear Envelope and Nuclear Matrix, A l a n R. Liss, Inc., New York 260-269 (1982). 9. Pardoll, D.M., Vogelstein, Β. Coffey: Cell 19, 527-536
(1980).
10. Keiner, Κ.L.Peck, E.J., Jr.: J. Receptor Res. 2, 47-62
(1981).
11. Watson, C.S. Clark, J.H.: J. Receptor Res. 1, 91-111
(1980).
12. Watson, (1980).
107,
C.S., Medina,
D.
Clark, J.H.: Endocrinology
13. Syne, J.S., Markaverich, Β.Μ., Research 42, 4443-4448 (1982). 14. Syne, J.S., Markaverich, Β.Μ., Research 42, 4449-4454 (1982).
Clark, Clark,
the
1432-1437
J.H.,
Panko,
W.B.:
Cancer
J.H.
Panko,
W.B.:
Cancer
15. Markaverich, Β.Μ., Roberts R.R., Alejandro, Μ.A. Clark, J.H.: Res. 44, 1575-1579 (1984).
Cancer
REGULATION OF MAMMARY RESPONSIVENESS TO ESTROGEN: AN ANALYSIS OF DIFFERENCES BETWEEN MAMMARY GLAND AND THE UTERUS
Gopalan Shyamala Lady Davis Institute for Medical Research, Sir Mortimer B. Davis - Jewish General Hospital and Department of Medicine, McGill University, Montreal, Quebec, Canada
I) Introduction The mammary gland is a compound tubuloalveolar gland composed of adipose, connective and epithelial tissue elements.
At
birth the gland is still rudimentary which remains in a quiescent state until puberty at which time there is a limited development.
In the adult female during each menstrual cycle,
cyclic proliferative changes and active growth of the ductal tissue occurs but the full development and differentiation of the gland occurs only during pregnancy and lactation.
Almost
all aspects of mammary development and differentiation are under complex hormonal control and there are some apparent differences among various species with regard to hormonal regulation of mammary development and differentiation.
Most of
the classic studies on the developmental biology of the gland have been done with rodents and the conclusions derived from these experiments have been frequently applied to many species including humans. Estrogens have been reported to have a variety of effects on various cell types of mammary glands and are believed to be important for both mammary development and differentiation
(1)
However, as yet the mechanism(s) underlying the actions of estrogens in mammary tissues is poorly understood.
In fact
there are even some doubts as to whether estrogens exert their effects on mammary glands directly
(2), despite the wide docu-
mentation of the presence of estrogen receptors in this tissue
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
414
A detailed discussion of various estrogenic responses occurring in mammary glands, their relationship to estrogen receptors, and their relative importance in the overall biology of the tissues is beyond the scope of this article.
Therefore
this chapter will focus only on certain selected aspects of estrogenic influences occurring during mammary development and differentiation and the possible mechanisms underlying these estrogenic responses in this tissue.
The data used to illus-
trate various aspects of estrogen action are from our own laboratory using mouse as the experimental animal. At present, the major body of literature pertaining to the mechanism of estrogen action has been obtained with rodent uterus.
It is conceivable that estrogens may have different
effects on different target tissues of the same animal both from a qualitative and a quantitative aspect, and these differences may bear a relationship to certain unique functions characteristic to a particular target tissue.
As shown in
this article in the same animal under identical physiological conditions there are differences in responsiveness to estrogen by mammary glands and uterus.
Therefore an attempt has also
been made to discuss certain aspects of mammary responsiveness to estrogens which appear to differ from those observed in the uterus.
It is hoped that such a discussion will prove useful
in the ultimate resolution of the mechanism of estrogen action in mammary gland.
II) Estrogenic Responses in Mammary Glands A. Characterization of early and late responses A characteristic feature of all hormones including estrogens is their ability to elicit a variety of biochemical responses in their target tissues, which may be roughly catalogued into early and late responses.
The three well known responses to
estrogens in most target tissues for estrogen are changes in
415
glucose metabolism, progesterone receptor synthesis and DNA synthesis and these responses to estrogen also manifest in the mammary glands.
Based on the relative time required to
elicit each of these responses, the first wave of increase in glucose oxidation occurring between 1-2 hours after estradiol administration
(Fig. 1) and progesterone receptor synthesis
(Fig. 2) may be termed as early responses while the increase in DNA synthesis
(Fig. 3) and the second wave of increase in
glucose oxidation occurring between 18-21 hours after estradiol administration
(Fig. 1) are classified as late responses.
It
3001-
TIME (hours) Fig. 1. Effect of estradiol on glucose oxidation in mammary glands of castrated mice. A single injection of either saline ( • ) or estradiol (S3) was given to castrated virgin mice prior to killing at indicated times. The ability of the tissues to oxidize glucose was estimated according to procedures previously described (3). The data represent mean ± SEM of three experiments with duplicate determinations in each. The 100% value corresponding to saline treated animals was 44.4 ± 4.4 1 '*COj/mg mammary tissue. is, however, to be noted that while the overall pattern and time scales for initiation of the three estrogenic responses in mammary glands are similar to that previously observed in the uterus tissues.
(6), there are some differences between the two In the case of uterus, both the early and late waves
of glucose oxidation are also associated with increases in the phosphorylation of glucose as measured by the conversion of 2-deoxyglucose to 2-deoxyglucose phosphate
(7).
However, as
416 400 ι-
JL £ ο
1
JL JL,
6
14
18
24
48
72
TIME ( h o u n |
Fig. 2. Temporal relationship between estradiol administration and increase in cytoplasmic mammary progesterone receptor level. Castrated virgin mice were given a single injection of 1 pg of estradiol prior to sacrifice at times indicated. The progesterone receptor levels were assayed by measuring the specific binding of ( 3 H)R5020 in cytoplasmic extracts. Each bar represents the mean ± SEM of three to five experiments. Control values for saline injected animals were: 467 fmoles/mg DNA. [From Shyamala, 1984 (4)] shown in Table 1, in mammary glands estradiol does not cause an increase in the metabolic conversion of 2-deoxyglucose to 2deoxyglucose phosphate.
Thus the conversion of 2-deoxyglucose
to 2-deoxyglucose phosphate, an easy parameter used for detecting the estrogenicity of a compound in the uterus
(7) cannot
be used for assessing estrogenic responsiveness in mammary glands.
Another striking difference between the mammary glands
and the uterus is the temporal relationship between estrogen administration and estrogen mediated increase in DNA synthesis as shown in Fig. 3.
Although in both tissues the increase in
DNA synthesis due to estrogen becomes apparent at approximately 12 hr, in the uterus the maximal increase is observed around 24 hr which returns to control value by 48 hr; however, in the
417
MAMMARY
I
500
ο
£
Ε
200
Ε
100
JL
\
α
Τ
100 12
16
18
24
48
72
96
12
16
18
24
48
72
96
TIME (hours)
Fig. 3. Effect of estradiol on the in vitro incorporation of ( 3 H)thymidine into DNA in the mammary glands and uteri of castrated mice. A single injection of saline (control) or 1 pg E2 was given to castrated virgin mice before killing at the indicated times. The data represent mean ± SEM for three to five experiments. The control values represent the data obtained at 2 4 hours after injection and were: mammary glands, 2989 ± 558 cpm/mg DNA; uterus, 3834 t 403 cpm/mg DNA. [From Shyamala and Ferenczy, 1984 (5)] case of mammary glands the maximal increase in DNA synthesis occurs at approximately 48 hr after estrogen administration returning to control values only at about 96 hr.
Thus the
duration in DNA synthesis due to a single administration of estradiol is greater in mammary gland than in the uterus. However, the magnitude of response to estradiol with respect to DNA synthesis is larger in the case of uterus when compared to the mammary glands.
These relative differences in the
degree of mammary and uterine responsiveness to estradiol is most likely related to the differences in the estrogen receptor content of these tissues
(as shown later) since it mani-
fests regardless of the dose of estradiol administered to the tissue
(Table II).
The possible importance of this difference
in the pattern of DNA synthesis due to estrogen in mammary glands and uterus is discussed later in this article.
418
TABLE I. Effect of estradiol on 2-deoxyglucose metabolism in mammary glands and uterus of castrated mice. Treatment
Dose yg
Saline
mammary glands 14 . 0
-
Estradiol
1
Estradiol
2-deoxyglucose phosphate
3
14., 9 16 . 4
+ +
+
(cpm) uterus
0 ., 45
1875
2.. 3
3233
1 .9 ,
4438
+ + +
274 311 344
Three groups of ovariectomized virgin mice were given a single injection of either saline or indicated dose of estradiol for two hours prior to sacrifice. The conversion of 2-deoxyglucose to 2-deoxyglucose phosphate by the tissues was assayed exactly according to the procedure described by Gorski and Raker (8). The data represent mean ± SEM of three experiments with duplicate determinations in each experiment. TABLE II. Effect of estradiol on the in vitro incorporation of ( 3 H)thymidine into mammary and uterine DNA in castrated mice. Dose of estradiol yg
cpm/mg DNA mammary glands
0.. 25
279
1.. 0
292
3., 0
395
+ + +
36
(% of control) uterus 912
49
921
107
656
+
120
+ +
79 61
Three groups of castrated mice were injected with indicated doses of estradiol for 24 hours prior to killing. The tissues were processed for the in vitro incorporation of ( 3 Η)thymidine into DNA according to procedures previously described (5). The data represent mean ± SEM of three to five experiments.
B. Effect of prolactin on mammary responsiveness to estrogen It is known that the influence of estrogen on mammary development may be modified by virtue of its interplay with other hormones
(1).
More importantly, similar to estradiol prolactin
is also required for mammary development and differentiation (1).
Therefore, any precise understanding of the role of es-
trogens in mammary biology have to take into consideration the
419
C
ο υ S
1
ζβ Ο Ζ 100
I
L
i
Χ
Fig. 4. Effect of prolactin on the estrogenic responses in castrated virgin mice. A single injection of either saline (C) or 1 mg of ovine prolactin (PRL) was administered prior to processing the mammary tissues at indicated times. (A) Glucose oxidation at 1 hr. (B) Progesterone receptor level at 24 hr. (C) Rate of DNA synthesis as measured by in vitro incorporation of labelled thymidine into DNA at 24 hr. [Adapted from Shyamala, 1984 (4)] influence of prolactin on estrogenic responses. In castrated virgin mice, exogenous prolactin has no effect on either mammary glucose oxidation
(Pig. 4A) or progesterone re-
ceptor level (Fig. 4B) or DNA synthesis
(Fig. 4C).
If estra-
diol and prolactin are administered together, there is an increase in mammary response to estradiol as measured by all the three criteria but this increase is not significantly greater than that seem with estradiol alone
(data not shown).
Thus these data reveal that by the three criteria chosen for mammary responsiveness to estrogen, prolactin has no influence on estrogen action in mammary glands.
However, since the
animals used in these studies had not been hypophysectomized, the possibility that prolactin might be necessary for the expression of mammary estrogenic responses could not be ruled out.
For instance it has been reported that the augmentation
of both casein synthesis and lactose synthetase activity by estradiol in explants from pregnant mice depends on the presence of both prolactin and thyroid hormone
(9).
It has also
been reported that prolactin may increase the level of mammary estrogen receptors in mice
(10).
Therefore it is possible
420 that at least some of the estrogenic responses in the mammary glands is influenced indirectly by prolactin. C. Loss of estrogenic sensitivity during lactation in mammary glands Extensive studies from several laboratories have revealed that the sensitivity of normal mammary tissue to both protein and steroid hormonal stimuli may be profoundly altered in relationship to the ontogeny of mammary epithelium, i.e. the mammary glands can modulate their sensitivity to hormones as a function of various physiological states
(1).
This also appears to be
true for estrogenic sensitivity of mammary glands since while the glands from castrated virgin mice are responsive to estradiol as shown previously, by the same criteria for responsiveness to estrogen the mammary glands of castrated lactating mice are nonresponsive to estradiol
(Fig. 5).
It is, however, to be
noted that while estradiol does not stimulate glucose oxidation in mammary glands of lactating mice, the glucose oxidation in the mammary gland of saline-treated, ovariectomized, lactating mice is, in fact, approximately 8-fold higher than that seen in the mammary gland of saline-treated, ovariectomized, virgin mice.
Thus, it appears that while estradiol can stimulate
mammary glucose oxidation, this tissue is not necessarily dependent on this hormone to accelerate its metabolism of glucose. This is not surprising since it has been well established that pituitary
(13), adrenal
(14), and thyroid
(15) hormones can
influence several enzymatic reactions associated with glucose metabolism in the lactating mammary gland.
As with the mammary
gland, estradiol also did not stimulate significantly uterine glucose oxidation in lactating mice
(Fig. 5A) although it was
capable of stimulating the rate of glucose phosphorylation in the same tissue
(Table III).
Estradiol was also effective in
increasing the level of progesterone receptor DNA synthesis in uteri of lactating mice
(11).
(12) and rate of Thus, these
data indicate that while estradiol can accelerate several biosynthetic pathways in its target tissues, the mechanisms by
421
which these individual effects are mediated may be different.
200 1h 1h
Si.
Ε Ε α
500
24h
100 0
Ε r
m
.
Fig. 5. Mammary and uterine responsiveness to estradiol in castrated lactating mice. Mice were castrated on day 2 of lactation, a single injection of saline (C) or 3 ug of estradiol (E) was given on day 9-10 of lactation for the times indicated prior to processing the mammary glands ( • ) and uterus (0). (A) Glucose oxidation [From Shyamala and Ferenczy, 1982 (11)] (B) Progesterone receptor level [From Haslam and Shyamala, 1979 (12)] (C) In vitro incorporation of thymidine into DNA (11).
422
TABLE III. Effect of estradiol on 2-deoxyglucose phosphorylation in uteri of castrated lactating mice Treatment
2-deoxyglucose phosphate
Saline
6501
Estradiol
(1 hr)
9065
Estradiol
(2 hr)
12772
+ + +
(cpm)
1900 980 1289
Three groups of lactating mice between days 7 and 10 of lactation were given a single injection of either saline or 3 yg estradiol for the indicated times prior to killing. [Adapted from Shyamala and Ferenczy, 1982 (11)]
III. Mammary Estrogen Receptors A. Modulation of receptor levels during development It has been widely documented that estrogen receptors are present in normal rodent mammary glands.
Moreover, it has also
been documented that levels of cytoplasmic estrogen receptor in mammary glands are modulated in relation to development such that they are present at the highest level during lactation (16,17,18,19) as illustrated in Fig. 6.
The higher level of
estrogen receptor present during lactation also appears to correlate with the secretory state of the tissue
(Fig. 6).
In contrast to the mammary glands, the uterine estrogen receptor level did not increase during lactation; while the level of estrogen receptor in the uteri from virgin mice was 3297 ± 223 fmoles/uterus, it was 2563 ± 314 fmoles/uterus in lactating mice.
Thus the increase in estrogen receptor levels
during lactation in mammary gland appear to be tissue specific and related to the secretory state of the gland. B. Molecular properties of mammary estrogen receptor Although there is extensive documentation on the mammary estrogen receptors, only limited information is available on the molecular properties of these receptors.
In part this is due
423
Fig. 6. Modulation of mammary cytoplasmic estrogen receptor as a function of lactation.
to the fact that most of the earlier studies had been done prior to the introduction of effective receptor stabilizing agents such as sodium molybdate in the receptor assays and as such were susceptible to degradation and proteolysis during assay.
This in turn led to identification of various forms of
«native» or «non-transformed» mammary estrogen receptor and this led to the conclusion that mammary estrogen receptor exhibits molecular heterogeneity as a function of development (20).
In the presence of sodium molybdate, as shown in Fig. 7
and 8, mammary estrogen receptor from both virgin and lactating mice sediment as 9S species on sucrose gradients.
How-
ever there are differences in the susceptibility of mammary estrogen receptors from different strains of mice to undergo artifactual degradation and such phenomenon is also facilitated by types of buffers used.
As shown in Fig. 9, in con-
trast to the mammary gland from Balb/c mice (Fig. 7), the gland from C 3 H mice have a greater tendency to dissociate into smaller molecular weight components which, however, can be minimized with the use of sodium molybdate.
The molecular
properties of mammary estrogen receptor estimated in the pre-
424
1
1
1
I
-Γ—
Β rfb
20
CM
pdJ -
-
ι Ο
Jf 0·
χ Ε
α
ft
1 / 7 ' /
•
10
t11
° ·/ 1
1 ° 1
Ο
α < 0£ I—
V) LLI
e
ηΧ
I1
I l: #
8
II
\
®
*ο σ ^ ν
G 10
20
30
40
50
10
, 20
S
1, i , 30 40
, 50
FRACTION NUMBER Fig. 7. Effect of sodium molybdate on sedimentation profiles of mammary estrogen receptor from virgin mice. The arrows represent the position of standards: G = gammaglobulin, 6.6S; S = bovine serum albumin, 4.4S. Β and Τ refer to the bottom and top of the gradient, respectively. (A) Cytosol from ovariectomized virgin mice either as is ( · , Δ ) or exposed to 10 mM molybdate ( O ) was incubated with 10 nM ( 3 H)estradiol alone ( Ο , · ) or also with a 100-fold excess of unlabelled estradiol ( Δ ) prior to layering on gradients in phosphate buffer. (B) Cytosol from ovariectomized virgin mice either as is ( · ) or exposed to 10 mM molybdate ( O ) was incubated with 10 nM of (3 Η)estradiol prior to layering on gradients in phosphate buffer containing 10 mM molybdate. [From Gaubert et al, 1982 (21)] sence of sodium molybdate as the receptor stabilizing agent are shown in Table IV and as may be seen there are essentially no differences in the properties of estrogen receptor from virgin and lactating mice. The ability of estrogen receptor to undergo dissociation due
425
Ο χ Ε
α
KJ
_J
Ο α < at
t— (Λ LU ι Χ
FRACTION NUMBER Cytosol from lactating mice either as is ( · , Δ ) or Fig. exposed to 10 mM molybdate ( Ο , • ) was incubated with 10 nM of (3 Η)estradiol either alone ( Ο , Π , · ) or also with a 100-fold excess of unlabelled estradiol ( Δ ) prior to layering on gradients in phosphate buffer only ( Ο , Δ ) or on gradients also containing 10 mM molybdate ( · , • ) . [From Gaubert et al, 1982 (21) ]
to high ionic strength does vary between the mammary tissues of virgin and lactating mice.
The estrogen receptor from lacta-
ting mammary glands are relatively less susceptible to dissociation and this in turn is reflected in their relative inability to undergo in vitro activation due to salt. Although these findings are consistent with the nonresponsiveness of lactating mammary glands to estradiol, it is to be noted that if estradiol is administered to lactating mice, estrogen receptor is found associated with the nuclear fraction
(22). The
precise relationship between estrogen receptor status and mammary responsiveness is therefore not clear at present.
It is
426
Ε
α Ο
Ξ
> ο ο pH ο ο tn + (Ν
α os α S3
E. c o l i rRNA > p o l y
>_ p o l y U > p o l y A : U > p o l y A >
p o l y C as d e t e r m i n e d by c o m p e t i t i o n b e t w e e n the f o r m a t i o n of complexes with synthetic polynucleotides cellulose. Hollander poly
Using
and binding
(10) s h o w e d t h a t the c o p o l y m e r s , p o l y
(dG-dC), were better competitors
h o m o p o l y m e r s or h o m o p o l y m e r d u p l e x e s . e s t r o g e n r e c e p t o r to D N A c e l l u l o s e . i n d i c a t e d that
r e c e p t o r b o u n d m o r e to p o l y d(G-C) A l t h o u g h these studies
(dA-dT)
than single
and
stranded
In this a s s a y ,
d ( A - T ) w a s the m o s t e f f e c t i v e c o m p e t i t o r androgen receptors
to D N A
the s a m e c o m p e t i t i o n a s s a y , K a l l o s &
for b i n d i n g
poly of
Similar studies
with
dihydrotestosterone t h a n p o l y d(A-T)
(38).
indicated that steroid receptors
p r e f e r e n c e s for b i n d i n g
to s y n t h e t i c p o l y m e r s , t h e i r
have
ability
to r e c o g n i z e n u c l e o t i d e b a s e s t r u c t u r e s c o u l d not be inferred.
The p o l y n u c l e o t i d e s e m p l o y e d w e r e
w i t h r e s p e c t to t h e i r s i z e and s e c o n d a r y for a n a l y z i n g
(dT) c e l l u l o s e
receptor complexes
While estradiol
receptor
(dT) c e l l u l o s e , n e i t h e r the h i g h
high capacity serum albumin
(11) d i d , i n d i c a t i n g
istic p r o p e r t y of the s t e r o i d r e c e p t o r s . tide celluloses offer several advantages
01igodeoxynucleoaffinity
in l e n g t h a n d
t h r o u g h t h e i r 5' t e r m i n i , g i v i n g
oligonucleotides a directional polarity. attachment
affinity-
a character-
for use a s
They are r e l a t i v e l y h o m o g e n e o u s
a t t a c h e d to c e l l u l o s e
inter-
could
affinity-low
c a p a c i t y e s t r o g e n b i n d i n g α - f e t o p r o t e i n nor the low
matrixes.
bound
in a m a n n e r a n a l o g o u s to t h e i r
action with DNA-cellulose. b i n d to o l i g o
steroid
(11) b a s e d o n a r e p o r t by T h r o w e r et^
(39) w h o s h o w e d t h a t e s t r a d i o l
to o l i g o
A method
the b a s e r e c o g n i t i o n c h a r a c t e r i s t i c s of
receptors was developed al.
heterogeneous
structure.
The
are
the
covalent
to c e l l u l o s e o v e r c o m e s the p r o b l e m of
dissociation
511
of ligand from the cellulose under experimental conditions. The interference of secondary structure differences is minimal because of the short length of oligonucleotides and their attachment to cellulose.
Effect of Salt Concentration on Steroid Receptor Binding to Oligonucleotide Celluloses Binding of steroid receptors to oligodeoxynucleotide celluloses showed a typical bell-shaped dependence on salt concentration.
The salt dependency of binding varied significantly
among the steroid receptors.
While estradiol receptors bound
optimally in a broad range of monovalent cation concentrations (0.05 to 0.15 Μ KCl), the activated dexamethasone receptors showed a sharp optimum at 0.1 Μ KCl and with testosterone receptors, binding was maximal at low concentrations (< 0.05 M) of KCl. (10,14).
However, the binding of
all steroid receptors to oligonucleotide celluloses decreased at salt concentrations higher than 0.2 M.
Salt-dependence is
a characteristic property of protein : DNA interactions including the cAMP receptor protein (40), lac repressor and other gene regulatory proteins (41).
The salt dependence is
indicative of large electrostatic interactions between the binding domains of DNA and protein.
The binding is presumed
to be entropically driven by the counterion diffusion potential.
The binding of estrogen receptor to the oligodeoxy-
nucleotide celluloses was sensitive to the type of monovalent anions.
Anions which promoted the order structure of water
were favorable for binding while those which disrupted this structure were unfavorable.
Significant differences were
observed in the binding of estradiol receptor to oligo (dT)and oligo (dG)- celluloses in the presence of various anions. The binding of estradiol receptor to oligo (dG) cellulose was
512 less s e n s i t i v e to I , C I O , ' cellulose. anions
-
4
-
,.
and SCN
t h a n to o l i g o
The s e n s i t i v i t y of lac r e p r e s s o r to
(dT)
chaotropic
for b i n d i n g to D N A is b e l i e v e d to be due to
conforma-
t i o n a l c h a n g e s in the DNA b i n d i n g d o m a i n of the
repressor
protein.
estradiol
The differences
in the s e n s i t i v i t y of
r e c e p t o r to c h a o t r o p i c a n i o n s for b i n d i n g oligo
(dG)
to o l i g o
(dT)
c e l l u l o s e s m a y r e p r e s e n t the v a r i a t i o n s
conformational
changes
i n d u c e d by the a n i o n s
the D N A b i n d i n g d o m a i n of the s t e r o i d
and
in the
in s u b s i t e s of
receptors.
P r e f e r e n c e s of S t e r o i d R e c e p t o r s for B i n d i n g
to
01igonucleotides A c o m p a r i s o n of e s t r a d i o l r e c e p t o r b i n d i n g oligodeoxynucleotides
to
homologous
of equal a v e r a g e l e n g t h a t t a c h e d
to
c e l l u l o s e , s h o w e d that the o r d e r of a f f i n i t y w a s o l i g o oligo
(dT)
(Fig. 1).
> oligo
(dC)
>> o l i g o
(dA) > o l i g o
Androgen and glucocorticoid
(dl)
quantitative differences
(14).
corticoid receptor binding
B i n d i n g of t e s t o s t e r o n e
significant
(dT) c e l l u l o s e
(dC), w h i l e
(dT) a n d
r e c e p t o r s to o l i g o
(dA)
lose w a s r e l a t i v e l y b e t t e r than t h a t of e s t r a d i o l o r methasone
receptor
(14).
A s s o c i a t i o n c o n s t a n t s for
receptor-oligodeoxynucleotide
cellulose complexes
d e t e r m i n e d by the t e c h n i q u e d e s c r i b e d (43).
the c y t o s o l e s t r a d i o l eluted
(1 ml)
cellu-
dexaestradiol
were oligodeoxy-
to w h i c h w a s a p p l i e d a s a m p l e
receptor complexes.
The p r o t e i n
from the c o l u m n b y p a s s a g e of a b u f f e r of
salt concentration
oligo
by d e H a s e t h et. a l .
The m e t h o d e m p l o y e d a small c o l u m n of the
nucleotide cellulose
gluco-
was
testosterone
r e c e p t o r s s h o w e d no d i f f e r e n c e s b e t w e e n o l i g o (dC).
showed
Temperature-activated
to o l i g o
m a r k e d l y g r e a t e r t h a n to o l i g o
(13,42)
receptors also
similar binding preferences although there were
(dG) >
(0.15 Μ N a C l ) .
of
was
constant
Association constants
were
Figure 1. Binding of Steroid receptors to oligonucleotide celluloses: (Top left), mouse uterine estrogen receptor (46); (Top right), mouse kidney estrogen receptor (14); (Bottom left), activated dexamethosone receptor (14); (Bottom right) mouse kidney testosterone receptor (14).
514
calculated
from the e l u t i o n d a t a by using
= Vf/j^0)- w h e r e V f
the e q u a t i o n
is the v o l u m e of the f r a c t i o n and
total m o l a r a m o u n t of n u c l e o t i d e s o n the c o l u m n . obtained
Ο
K_D bsd is the
k was
from the s l o p e of the s e m i l o g a r i t h m i c p l o t of
the
r e c e p t o r p r o t e i n r e m a i n i n g o n the c o l u m n a f t e r f r a c t i o n i (Pc^)
v e r s u s the f r a c t i o n n u m b e r .
The association
r e f l e c t the r e l a t i v e a f f i n i t i e s of e s t r a d i o l the o l i g o n u c l e o t i d e
celluloses
(Table 1).
constants
receptors
The
for
observed
Table 1 A p p a r e n t a s s o c i a t i o n c o n s t a n t s for m o u s e estradiol
receptor
. oligodeoxynucleotide
NaCl
oligo(dG)
3.7 χ
104M-1
oligo(dT)
1.75 χ
104M-1
oligo(dC)
1.49 χ
104M_1
v a l u e s are c o m p a r a b l e binding
complexes
RD A p p a r e n t K Q ^^
Oligodeoxynucleotide
and Alberts
uterine
to the c o n s t a n t d e t e r m i n e d by
(4) for e s t r a d i o l
receptor binding
Yamamoto
to D N A .
p a t t e r n of e s t r o g e n r e c e p t o r p r o t e i n l a b e l e d
s t e r o i d or n o n s t e r o i d e s t r o g e n s o r a n t i e s t r o g e n s , the s a m e s e l e c t i v i t y
with
also
showed
(42).
T h e s u b s i t e s of the p o l y n u c l e o t i d e b i n d i n g d o m a i n of receptors were further characterized. h o l o r e c e p t o r to e l e v a t e d t e m p e r a t u r e s c a u s e d a r a p i d loss of b i n d i n g (dC)-, w i t h o u t a f f e c t i n g (13).
The
E x p o s u r e of
estrogen
(37° for 10-30
to o l i g o
the b i n d i n g
(dT)- and
to o l i g o
min.)
oligo
(dG)-
D i s s o c i a t i o n of the b o u n d e s t r o g e n r e c e p t o r
estrogen
cellulose from
515 oligodeoxynucleotide
c e l l u l o s e s , by i n c r e a s i n g
concentrations
of K C l , o r by c i b a c r o n b l u e F3GA s h o w e d that o l i g o
(dG)
bound
e s t r o g e n r e c e p t o r w a s m o r e s t a b l e t h a n the r e c e p t o r b o u n d oligo
(dC)- and ( d T ) - c e l l u l o s e s .
The f o r m a t i o n of the
deoxynucleotide cellulose - estrogen receptor complexes i n h i b i t e d by c i b a c r o n b l u e F 3 G A , p y r i d o x a l p h o s p h a t e , diethyl pyrocarbonate.
T h e s e s t u d i e s s h o w e d that
was
and
higher
c o n c e n t r a t i o n s of the c o m p o u n d s w e r e n e c e s s a r y to i n h i b i t f o r m a t i o n of r e c e p t o r - o l i g o
(dG) c e l l u l o s e c o m p l e x e s ,
for c o m p l e x e s w i t h o t h e r o l i g o d e o x y n u c l e o t i d e (44,45). oligo
Competition
for r e c e p t o r b i n d i n g
insoluble was
if the s o l u b l e o l i g o m e r c o n t a i n e d 8 or m o r e
n u c l e o t i d e s and w a s m o r e p r o n o u n c e d w i t h the h o m o l o g o u s (dT) t h a n w i t h the h e t e r o l o g o u s o l i g o
(dG).
These
d o m a i n of e s t r o g e n r e c e p t o r subsites: nucleotides
binding
is c o m p o s e d of two c l a s s e s
s t a b l e s i t e s w h i c h b i n d to d e o x y g u a n y l a t e
and relatively (N sites)
labile sites which
oligo
observa-
t i o n s led to the s u g g e s t i o n that the p o l y n u c l e o t i d e
sites)
of
(G
interact w i t h
other
(19,46).
A c t i v a t i o n of S t e r o i d R e c e p t o r s to B i n d
Oligodeoxynucleotide
Celluloses It is g e n e r a l l y b e l i e v e d t h a t c y t o s o l
steroid
receptors
undergo a temperature or high salt-mediated change
in c o n -
f o r m a t i o n w h i c h f a c i l i t a t e s t h e i r m i g r a t i o n to the
nucleus
a n d b i n d i n g to the n u c l e a r a c c e p t o r s i t e s . zation
the
than
celluloses
to the
(dT) c e l l u l o s e m a t r i x by the s o l u b l e o l i g o m e r
efficient
to
oligo-
is not a p p l i c a b l e
binding properties.
to DNA and
This
W h i l e the g l u c o c o r t i c o i d
receptors
r e q u i r e a c t i v a t i o n to b i n d j_n v i t r o to D N A , o t h e r r e c e p t o r s d o not
(4).
Studies on
generali-
oligodeoxynucleotide steroid
oligodeoxynucleotide
c e l l u l o s e b i n d i n g p r o p e r t i e s of s t e r o i d r e c e p t o r s
clearly
516 showed due
that no s i g n i f i c a n t
to p r e i n c u b a t i o n
of
tors at t e m p e r a t u r e s tions.
Exposure 30 m i n
controls
receptors process
was
to n u c l e a r
such an a c t i v a t i o n
bind
salt
with
step
for o t h e r or
activation
celluloses.
UTERINE E 2 R
at 2 2 °
for
unacti-
glucocorticoid an
activation
of these
steroid
recep-
concentra-
sites or to D N A .
receptors The
receptors
absence to
oligodeoxynucleotides
by a n u m b e r of l a b o r a t o r i e s
LIVER dexR
of
following
the a c t i v a t i o n
acceptor
observed
i n c r e a s e o v e r the
The b i n d i n g
e i t h e r DNA or p o l y n u c l e o t i d e s reported
high
for 30 m i n or p r e i n c u b a t i o n
(Fig. 2).
is c o n s i s t e n t
was
testosterone
to o l i g o d e o x y n u c l e o t i d e
in a 6 to 12 fold (14)
and
receptors without
to o l i g o d e o x y n u c l e o t i d e s
for b i n d i n g of
bound
to 0.5 Μ KCl
resulted
in binding
18-37°C or w i t h
However glucocorticoid
were minimally
vated
increase
the e s t r o g e n
KIDNEY E 2 R
(4,39,42,47).
KIDNEY TESTOSTERONE
RECEPTOR 1200 -
g 1000 800-
Z) ο
600-
Ρ •c O Ο
Figure 2. Activation requirements of steroid receptors for binding to oligodeoxynucleotide celluloses (14).
517 B i n d i n g of S t e r o i d R e c e p t o r s to
Polyribonucleotides
Although steroid receptors bind preferentially nificant binding strated.
King
to D N A ,
to R N A and p o l y r i b o n u c l e o t i d e s c a n be
(48) s h o w e d that u t e r i n e e s t r o g e n
(rG) >> p o l y
(rC) > p o l y
(rA) > p o l y
demon-
receptor
b o u n d to p o l y n u c l e o t i d e s w i t h an o r d e r of p r e f e r e n c e poly
sig-
where
(rl). L i a o e t
al.
(12) d e t e r m i n e d the r e l a t i v e a f f i n i t i e s of s t e r o i d
receptors
for the p o l y r i b o n u c l e o t i d e s
in
releasing
by t h e i r e f f e c t i v e n e s s
the s t e r o i d r e c e p t o r s b o u n d to D N A - c e l l u l o s e .
(rG) w a s the m o s t e f f e c t i v e p o l y n u c l e o t i d e
in this a s s a y
androgen, estrogen, glucocorticoid and progesterone tors.
Poly
(rC) and p o l y
recently
F e l d m a n e_t a_l. (49) c o n f i r m e d t h e s e s t u d i e s
(rA) w e r e a l m o s t
d e m o n s t r a t e d that in i n h i b i t i n g (rU) >> p o l y
(rA) = p o l y
(rG),
ineffective.
the b i n d i n g of
r e c e p t o r to DNA the o r d e r of a f f i n i t y w a s , p o l y
More and
estrogen (rG) > p o l y
(rC).
It is, t h u s , e v i d e n t that s t e r o i d r e c e p t o r s r e c o g n i z e ferent nucleotide base structures. h a v e the h i g h e s t a f f i n i t y and
All steroid
for
dif-
receptors
for g u a n i n e , the l o w e s t for
intermediate affinities
R o l e of A c c e s s o r y
for
recep-
(rU) w a s a b o u t half as e f f e c t i v e as p o l y
but poly
Poly
adenine
pyrimidines.
Proteins
A l t h o u g h m a n y l i n e s of e v i d e n c e h a v e c l e a r l y
demonstrated
t h a t s t e r o i d r e c e p t o r s b i n d to s p e c i f i c s i t e s o n the D N A , a v a i l a b l e e v i d e n c e h a s not e s t a b l i s h e d solely responsible specific genes.
is
for the r e g u l a t i o n of e x p r e s s i o n of
T h e k i n e t i c s of b i n d i n g
w i t h the p r o p o s e d r e g u l a t o r y r o l e . supporting
that this b i n d i n g
the
is not
consistent
T h e r e are s e v e r a l
the c o n c e p t that f u n c t i o n a l
b i n d i n g of
reports
steroid
518 r e c e p t o r s to g e n o m i c D N A r e q u i r e s a d d i t i o n a l [see r e v i e w by S p e l s b e r g ejt £ 1 . ( 5 0 ) ] .
nuclear
proteins
Complete removal
of
h i s t o n e s and the bulk of n o n h i s t o n e p r o t e i n s from c h i c k oviduct chromatin resulted tightly bound proteins. DNA
for P - R b i n d i n g (51)
receptor
the s p e c i f i c i t y
(P-R) b i n d i n g
following
r e m o v a l of p r o t e i n s from c h r o m a t i n r e v e a l e d
yielded a fraction
(CP-3) c o n t a i n i n g
nucleoacidic
that
which
proteins
t i g h t l y b o u n d to D N A w i t h e n h a n c e d P - R b i n d i n g .
Similar
findings were also reported
prostate chromatin
for a n d r o g e n
receptor-rat
(52) and for e s t r o g e n r e c e p t o r s
calf-uterine chromatin
(53).
In n o n - t a r g e t
in the
t i s s u e s s u c h as
the s p l e e n and the e r y t h r o c y t e w h i c h show little P - R r e m o v a l of h i s t o n e s a n d the bulk of n o n h i s t o n e increased binding acceptor sites
indicating
in m a s k i n g
T h e p r o t e i n s of H o w e v e r , the
s t i t u t e d c o m p l e x of C P - 3 p r o t e i n s w i t h D N A s h o w e d b i n d i n g of P - R ( 5 0 , 5 4 , 5 5 ) .
Further
in two
Monoclonal
pro-
(13-18 k
antibodies
r a i s e d a g a i n s t these p r o t e i n s b l o c k e d p r o g e s t e r o n e to c h r o m a t i n or to the N A P - D N A c o m p l e x
guanidine
These
t e i n s w e r e c h a r a c t e r i z e d as small m o l e c u l a r w e i g h t
binding
CP-3
fractions
w h i c h p r o m o t e d e n h a n c e d b i n d i n g of P - R to D N A . (50).
recon-
f r a c t i o n a t i o n of the
h y d r o c h l o r i d e b u f f e r e d at pH 6, r e s u l t e d
in n a t u r e
CP-3
marked
p r o t e i n s by m o l e c u l a r s i e v e c h r o m a t o g r a p h y using 6M
and hydrophobic
binding,
proteins,
t h a t m a y be i n v o l v e d
in n o n - t a r g e t t i s s u e s .
f r a c t i o n did not b i n d to P - R d i r e c t l y .
Da)
of
tissues.
r e m o v a l of h i s t o n e s a n d bulk of n o n h i s t o n e p r o t e i n s , (NAP)
chroma-
binding
from t a r g e t a n d n o n t a r g e t
E x a m i n a t i o n of p r o g e s t e r o n e sequential
few
than native
in that r e c e p t o r
f o l l o w e d s a t u r a t i o n k i n e t i c s and r e f l e c t e d o r i g i n of the c h r o m a t i n
a
This structure designated NAP was a
more physiologic template tin o r d e p r o t e i n i z e d
in a f r a c t i o n c o n t a i n i n g
receptor
(56).
DNA
s e q u e n c e s w h i c h are t i g h t l y b o u n d to the C P - 3 p r o t e i n s are a c l a s s of
intermediate
communication).
repetitive DNA
(Spelsberg,
personal
The s i g n i f i c a n c e of t h e s e s i t e s in the
p r o d u c t i v e b i n d i n g of P - R r e m a i n s to be
elucidated.
519 In a d d i t i o n to the n u c l e a r p r o t e i n s , w h i c h u p o n b i n d i n g specific sites on genomic DNA enhance ing to s u c h s i t e s , t h e r e are c y t o s o l stimulate steroid binding nucleotide polymers.
steroid receptor proteins which
to i m m o b i l i z e d D N A o r
T h r o w e r et a l .
also
synthetic
(39) s h o w e d t h a t
t i o n of u t e r i n e c y t o s o l to S e p h a d e x g e l
filtered
addi-
uterine
c y t o s o l i c e s t r o g e n r e c e p t o r s s t i m u l a t e d b i n d i n g of the t o r s to o l i g o
(dT) c e l l u l o s e .
n e e d for c y t o s o l eluted oligo
from o l i g o
It a p p e a r e d t h a t d u r i n g
a n d d e s o r p t i o n of e s t r o g e n r e c e p t o r ( s ) affinity matrix.
fresh
the
from o l i g o
adsorption (dT)
cellu-
f a c t o r or f a c t o r s r e m a i n e d b o u n d to O n e f a c t o r was s h o w n to be
the
heat-stable,
n o n d i a l y z a b l e , s e n s i t i v e to p r o n a s e , p r o t e i n a s e κ, p e p s i n S t a p h . a u r e u s p r o t e a s e V , b u t r e s i s t a n t to t r y p s i n o r trpysin.
Such factors were present
a
receptor
(dT) c e l l u l o s e c o l u m n , to r e b i n d
l o s e , an a c c e s s o r y
recep-
T h a n k i et a_l. (57) d e t e c t e d
f a c t o r s for m o u s e k i d n e y e s t r o g e n
(dT) c e l l u l o s e .
to bind-
in c y t o s o l s
and
chymo-
from
kidney
u t e r u s and lung b u t n o t in b r a i n and s k e l e t a l m u s c l e
cyto-
sols.
oligo-
The h e a t - s t a b l e
nucleotide celluloses
f a c t o r w a s e f f e c t i v e w i t h all as b i n d i n g m a t r i c e s .
Prior
incubation
w i t h the m a t r i c e s a l s o s t i m u l a t e d r e c e p t o r b i n d i n g
and
there
w a s no i n d i c a t i o n t h a t the factors d i r e c t l y r e a c t e d w i t h holoreceptor. to DNA
The r o l e of s u c h f a c t o r s
is u n k n o w n a t this
in s p e c i f i c
time.
D u r i n g o u r s t u d i e s o n the a c c e s s o r y p r o t e i n s for the of e s t r o g e n r e c e p t o r to o l i g o d e o x y n u c l e o t i d e
i n c r e a s e d the r e b i n d i n g of p a r t i a l l y
h o l o r e c e p t o r to o l i g o ( d T )
cellulose.
Fox et. al. (58)
f o u n d that e s t r o g e n a n d a n d r o g e n r e c e p t o r s b o u n d m o r e ly to DNA c e l l u l o s e al.
in the p r e s e n c e of l y s o z y m e s .
(57) d e m o n s t r a t e d
it
calf purified also strong-
Thanki
that H 2 A , H 2 B a n d H3 w e r e m o s t
t i v e w h i l e the l y s i n e - r i c h HI w a s i n a c t i v e .
binding
celluloses,
w a s o b s e r v e d that b a s i c p r o t e i n s s u c h as l y s o z y m e and thymus histones
the
binding
£t
effec-
Polylysine
and
520 γ-globulin were ineffective.
Addition of individual
histones
to a 200-fold purified mouse kidney estrogen receptor complex resulted in the stabilization of the steroid bound to the receptor.
H2A and H2B were most effective, HI and H3 were
less effective while lysozyme and γ-globulin were ineffective.
Histone H2B was cleaved by cyanogen bromide into a
N-terminal half containing 32% of the residues as basic amino acids and the C-terminal half which contained 20% of its residues as basic amino acids.
Both N-terminal and
C-terminal half molecules were tested for their ability to stimulate the oligo (dT)-cellulose binding of estrogen holoreceptor.
The N-terminal half was more active than the
C-terminal half, while the mixture of N- and C-terminal half produced an intermediate effect (Fig. 3).
_
60
ο*
Μ lormlnnl
α
Ζ m
20 ο
10
20
H2b HALF-MOLECULE ADDED tyiq)
Figure 3. Effect of N- and C-terminal half molecules of H2B on oligo (dT) cellulose binding of estradiol receptor (57).
521 The N - t e r m i n a l half of H2B s t a b i l i z e d
the 4S s p e c i e s of
h o l o r e c e p t o r w h i l e a d d i t i o n of the C - t e r m i n a l half m a r k e d a g g r e g a t i o n of r e c e p t o r p r o t e i n al.
(Fig. 4).
(59) o b s e r v e d that r a b b i t u t e r i n e c y t o s o l
the
led to Kallos
receptors
the et
bound
to the i m m o b i l i z e d h i s t o n e s w i t h the a f f i n i t y o r d e r ; H2B > H2A >> H4 M O
>>> H i .
F o r m a t i o n of a c o m p l e x b e t w e e n
estro-
g e n r e c e p t o r s and h i s t o n e s w a s s h o w n b y a s h i f t in the e l e c t r i c p o i n t to h i g h e r pH v a l u e s . tinct binding site, separate
iso-
The p r e s e n c e of a d i s -
from e s t r o g e n and
polynucleotide
b i n d i n g d o m a i n s , w a s d e t e c t e d by l i m i t e d p r o t e o l y s i s . p a r t i a l l y d i g e s t e d e s t r o g e n r e c e p t o r D N A b i n d i n g of r e c e p t o r was m a r k e d l y r e d u c e d w h i l e s t e r o i d and b i n d i n g w e r e u n a f f e c t e d . T h u s , it a p p e a r s that receptors have a site(s)
histone estrogen
for s e l e c t i v e b i n d i n g of
h i s t o n e s or s i m i l a r c a t i o n i c p r o t e i n s . containing
In the
the
nucleosomal
D i g e s t i o n of
nuclei
radio-labeled estrogen receptors, followed
density gradient centrifugation
i n d i c a t e d that the
a c t i v i t y w a s p r i m a r i l y a s s o c i a t e d w i t h the
by
radio-
mononucleosomal
f r a c t i o n s w h i c h c o n t a i n e d H2A, H 2 B , H3 a n d H4 h i s t o n e s not HI
(60,61).
These observations may
r o l e for the h i s t o n e s receptor
molecules.
indicate a
in the n u c l e a r p o s i t i o n i n g
of
but
specific the
522
(·) No addition (o)+ H2b ES
Γ
(ο) + Ν terminal halfmolecule (·)+ C terminol balf-molecute 4.6 S i
4 6 5
Φι '
A^
\r r 'Ρ \\ ΐ DE
i
; Ά φ
-
9
j\
Ν
r
eexes
Ο
I
/
I I I 10 20 Ο FRACTION
10
20
Figure 4. Stabilization of estrogen holoreceptor by the island C-terminal half molecules of H2B (57).
The effect of histone H2B on oligodeoxynucleotide properties of estrogen receptors also indicated interesting feature.
binding
another
When uterine cytosolic estrogen recep-
tor complexes were bound to the immobilized
oligodeoxynucleo-
tides and subsequently eluted with 0.5 Μ KCl, the receptor complexes obtained were incapable of binding to oligo (dT), oligo (dC) and oligo (dA), while retaining the binding to oligo (dG) at reduced levels.
Addition of H2B to this
preparation fully restored the binding to all the oligo-
523 nucleotide celluloses in the order seen with crude estrogen receptors (Table 2).
This property may reflect the ability
of histones or histone-like cationic proteins to modulate the recognition capabilities of the DNA-binding domain of steriod receptors in general, and estrogen receptors in particular.
Table 2 Rebinding of E 2 R eluted from oligo(dT)- and oligo(dG)cellulose complexes to oligodeoxynucleotide-celluloses
% bound of input E_R
E2R
off
E 2 R off
oligo(dT)-•eellulose
oligo(dG)-•cellulose
Cellulose
-H2B
+ H2B
-H2B
+ H2B
Oligot dG)
18
33
21
32
01 igo(dA)
0
6
0
6
Oligo(dC)
0
12
0
14
Oligo(dT)
0
22
1
23
E 2 R oligo(dG)- or oligo(dT)-cellulose complexes were formed under standard binding assay conditions. E 2 R was achieved by using 0.5 Μ KCl.
Elution of Bound
Samples (0.2 ml) of the
eluates were used in the rebinding assay with fresh oligodeoxynucleotide-celluloses
in a total volume of 0.6 ml so
that the final concentration of KCl was 0.15 Μ.
H2B was
added to the rebinding assay at 50 pg where indicated.
524 S t e r o i d R e c e p t o r R e c o g n i t i o n of S p e c i f i c DNA The d e m o n s t r a t i o n
that steroid hormone
criminate between nucleotide bases
Sequences
receptors could
i n d i c a t e d that
DNA base sequence
r e c o g n i t i o n w a s a p o s s i b l e step in
action.
it r e m a i n e d
However,
for the t u m u l t u o u s
tumor virus
(MMTV) t r a n s c r i p t i o n b e f o r e a d e t a i l e d
interaction was forthcoming.
a d d i t i o n of g l u c o c o r t i c o i d
Studies
to p r o v i r a l c o n t a i n i n g
(62).
analysis
taining cells
(63).
cells short
into g l u c o c o r t i c o i d
con-
E x o g e n o u s M M T V D N A not i n t e g r a t e d
These experiments
into to the
i n d i c a t e d that the v i r a l D N A
s u f f i c i e n t for h o r m o n e r e s p o n s i v e n e s s and that h o s t D N A not i n v o l v e d These
f i n d i n g s set the s t a g e for a d e t a i l e d s e a r c h for
t i o n e n d o n u c l e a s e s a n d r e c o v e r e d a 1.45 kb s e g m e n t the long t e r m i n a l r e p e a t r e g i o n They transfected
plasmid containing dine kinase recipient
(tk)
(LTR)
and a small
restric-
containing coding
this c l o n e d p r o d u c t along w i t h a
the h e r p e s s i m p l e x v i r u s g e n e for
into m o u s e L c e l l s w h i c h w e r e tk
transformants were tk+ when grown
of g l u c o c o r t i c o i d s .
A n Jji v i v o a s s a y
.
in the
thymiThe
presence
is now a v a i l a b l e
d e t e r m i n i n g w h a t p a r t of the M M T V g e n o m e c o n t a i n e d the mone responsive
the
proviral
Fasel et aJL. (65) c l e a v e d the M M T V g e n o m e w i t h
region.
was was
(65,66).
g l u c o c o r t i c o i d r e c e p t o r e f f e c t o r r e g i o n w i t h i n the DNA.
of
hormone
receptor
the h o s t c e l l c h r o m o s o m e a l s o w a s c a p a b l e of r e s p o n s e hormone.
that
Furthermore, specific fractions
M M T V D N A w e r e e n o u g h to m e d i a t e a g l u c o c o r t i c o i d response when transformed
mammary
indicated
i n c r e a s e d the rate of M M T V D N A t r a n s c r i p t i o n a f t e r p e r i o d s of e x p o s u r e
hormone
developments
in the role of g l u c o c o r t i c o i d s a s i n d u c e r s of m o u s e of t h i s
dis-
specific
for hor-
region.
H y n e s a n d her c o w o r k e r s
(66) c o n s t r u c t e d c h i m e r a of the
L T R a n d a HSV tk c o d i n g
segment.
T h e y w e r e a b l e to
MMTV
produce
525 n u c l e o t i d e d e l e t i o n s at d e f i n e d d i s t a n c e s synthesis
i n i t i a t i o n or CAP site
at w h i c h m e t h y l g u a n o s i n e
residue
is a t t a c h e d ) .
f o r m e d c e l l s , RNA s y n t h e s i s w a s c o r r e c t l y LTR promoter termination Among
the d e l e t i o n s ,
-202 were responsive
5' to the
RNA
( p e n u l t i m a t e 5" e n d of m R N A In the
initiated
in the r i g h t w a r d tk c o d i n g
sequence was sufficient
for r e s p o n s e .
B u e t t i and D i g g e l m a n n ( 6 7 )
indicated
- 1 0 5 to - 2 0 4 w a s n e c e s s a r y
for the h o r m o n e
by
from
response. these
found t h a t s e q u e n c e s b e t w e e n - 2 0 4 to - 6 0 0 multiple
w e a k e r s i t e s of c o n t r o l , u p s t r e a m of the p r i m a r y W h e n the - 1 0 5 m u t a n t w a s u s e d level of c o r r e c t l y
response
in the t r a n s f e c t i o n ,
the
initiated transcripts was nearly
the
s a m e as that seen w i t h the e n t i r e M M T V D N A .
The
c o i d r e c e p t o r e f f e c t o r r e g i o n of D N A w a s c l e a r l y from t h o s e n u c l e o t i d e s c o m p r i s i n g promoter.
LTR
Similar experiments
i n c r e a s e d the a m p l i t u d e of r e s p o n s e s u g g e s t i n g site.
LTR
site
that the s e q u e n c e
A l t h o u g h the c o r r e c t t r u n c a t e d L T R w a s s u f f i c i e n t ,
basal
to
to g l u c o c o r t i c o i d s w h i l e t h o s e w h o s e
T h i s i n d i c a t e d that a l i m i t e d r e g i o n of the
investigators
the
region.
t h o s e w i t h the s e q u e n c e s from - 1 3 7
s e g m e n t s e n d e d a t - 5 0 or - 3 7 r e l a t i v e to the LTR C A P were not.
trans-
from
the L T R
glucocortiseparate
transcriptional
F u r t h e r a l t e r a t i o n s of the c h i m e r i c c l o n e
(68)
i n c l u d i n g a d d i t i o n of 4 e x o g e n o u s b a s e p a i r s o r d e l e t i o n 20 b a s e p a i r s at p o s i t i o n - 1 0 7 o r s u b s t i t u t i o n of the
of
rat
s a r c o m a v i r u s L T R for that of MMTV at p o s i t i o n - 5 9 to + 1 0 0 h a d no e f f e c t o n g l u c o c o r t o c o i d A n a l y s i s of the a b o v e s t u d i e s
responsiveness.
indicated that a limited
s e q u e n c e w i t h i n the M M T V L T R w a s n e c e s s a r y
for
glucocorticoid
r e s p o n s i v e n e s s b u t the p o s i t i o n of t h i s s e g m e n t had no
fixed
spatial distance
the
from the t r a n s c r i p t i o n a l p r o m o t e r a n d
r e s p o n s e r e g i o n c o u l d be d i s s o c i a t e d
f r o m a weak b u t
tional promotor, suggesting
that a s p e c i f i c
c o n t a c t w i t h RNA p o l y m e r a s e
II w a s not a n e s s e n t i a l
e n t for the r e c e p t o r e f f e c t .
func-
protein-protein ingredi-
The i m m e d i a t e c o n s e q u e n c e
of
526 receptor
i n t e r a c t i o n w a s p r o p o s e d to be a local c h a n g e
chromatin configuration
a n d / o r p r o d u c t i o n of a f a c i l e
s i t e for R N A p o l y m e r a s e
II o r a c c e s s o r y
in entry
transcriptional
factors. A complementary
l i n e of r e s e a r c h w a s
of P a y v a r and his c o w o r k e r s
(15).
i n i t i a t e d by the
They
found
b i n4 d i n g of rat l i v e r g l u c o c o r t i c o i d h o l o r e c e p t o r , 10
finding
selective purified
f o l d , to be r e s t r i c t e d to s e l e c t e d r e g i o n s of the
pro-
v i r a l D N A , s o m e w i t h i n the L T R r e g i o n a n d some in c o d i n g r e g i o n s of the v i r a l g e n o m e .
S c h e i d e r e i t et^ a_l. (70)
using
the d e f i n e d L T R d e l e t i o n c o n s t r u c t s of the L T R -v HSV Tk chimera
i n t r o d u c e d by H y n e s £ t a ^ .
of 2 s p e c i e s of rat g l u c o c o r t i c o i d 40 Κ m o l e c u l e . binding
(66) s t u d i e d the
h o l o r e c e p t o r , a 90 Κ and a
Both species were alike
to Μ M T V D N A .
binding
in t h e i r
preferential
If the c h i m e r i c D N A c o n t a i n e d
segments
including
nucleotide -202 relative
sequences
5' u p s t r e a m
binding.
If t h e y i n c l u d e d s e q u e n c e s - 5 0 o r l e s s , t h e r e
no b i n d i n g .
to the CAP site o r m o r e
from that p o s i t i o n , there w a s
C o m p l e x e s of the 90 Κ r e c e p t o r :
selective was
DNA w e r e
r e c o v e r e d by i m m u n o p r e c i p i t a t ion u s i n g m o n o c l o n a l
antibodies
d i r e c t e d a g a i n s t the n o n - D N A b i n d i n g p o r t i o n s of the
receptor
a n d it d i d not m a t t e r w h e t h e r p u r i f i e d r e c e p t o r o r a c r u d e cytosol preparation was
used.
These data suggested that non-receptor cytosol w e r e not e s s e n t i a l
components
for s e l e c t i v e r e c e p t o r b i n d i n g b u t
v a t i o n of the g l u c o c o r t i c o i d r e c e p t o r w a s n e c e s s a r y , NaMoC> 4 p r e v e n t e d the i n t e r a c t i o n . w a s the d e t e r m i n a t i o n
Of p a r a m o u n t
actias
importance
t h a t a r e g i o n of the M M T V L T R f r o m - 5 0
to - 2 0 2 w a s the b i n d i n g
site w h i c h w a s the same a r e a
as the h o r m o n e r e s p o n s e r e g i o n in t r a n s f o r m a t i o n
defined
experiments.
H a v i n g e s t a b l i s h e d a s e g m e n t of the L T R D N A as a p r e f e r e n t i a l binding
t a r g e t for g l u c o c o r t i c o i d
holoreceptor,
it
remained
527 for S c h e i d e r e i t a n d B e a t o
(70) to p i n p o i n t
for the r e c e p t o r w i t h i n this s e g m e n t .
the c o n t a c t
c h e m i c a l and e n z y m a t i c p r o b e s , t h e y e s t a b l i s h e d t h a t were
four b i n d i n g s i t e s in a s e q u e n c e
o t i d e s 5' to the C A P s i t e . a)
In the r e c e p t o r :
points
Using a combination from - 7 2 to - 1 9 2
A t t h e s e s i t e s they
of
there nucle-
found:
DNA c o m p l e x , s e v e r a l g u a n i n e
residues
w e r e p r o t e c t e d a g a i n s t m e t h y l a t i o n by d i m e t h y l
sulfate.
At the 4 s i t e s , the p r o t e c t e d r e s i d u e s w e r e f o u n d in a common
sequence: 5 ' T G T
Τ C Τ 3'
3' A C A
A G A 51
T h e p r o t e c t i o n at the 4 s i t e s i n c r e a s e d w i t h r i s i n g concentrations. w i t h i n the
receptor
H y p e r m e t h y l a t i o n of o t h e r b a s e s a l s o
occured
complex.
b)
Binding
to the s i t e s o c c u r e d
c)
M e t h y l a t i o n of a l i m i t e d n u m b e r of g u a n i n e
tive amplification was
independently but
coopera-
possible.
abolished glucocorticoid
residues
holoreceptor binding.
In the
s e n s e s t r a n d the g u a n i n e r e s i d u e at - 1 7 4 and in the a n t i s e n s e s t r a n d t h o s e at - 1 7 1 a n d - 1 8 0 w e r e the most protected against methylation
bases
in the r e c e p t o r :
DNA
complex. d)
No c l e a r cut e f f e c t s of p r o t e c t i o n o r i n h i b i t i o n observed
e)
Among
in a d e n i n e
were
residues.
the four s i t e s , that at the m o s t u p s t r e a m
position
d e m o n s t r a t e d g r e a t e r a v i d i t y for the h o l o r e c e p t o r the o t h e r s .
B u t at the l o w e s t r e c e p t o r
all s i t e s b o u n d f)
concentrations,
receptor.
The p r o t e c t e d g u a n i n e r e s i d u e s w i t h i n the c o m p l e x separated Since
than
from e a c h o t h e r by 10 + 1 n u c l e o t i d e
it is the N7 p o s i t i o n of g u a n i n e w h i c h
l a t e d and it is e x p o s e d of the h e l i x , the
pairs.
is m e t h y -
in G : C p a i r s of the m a j o r
investigators concluded
were
groove
that p o i n t s
of
m a x i m a l c o n t a c t of the r e c e p t o r w e r e o n the s a m e face of
528 the h e l i x at two g u a n i n e r e s i d u e s s e p a r a t e d by 2 full c o n s e c u t i v e A c o m p a r i s o n of o t h e r g l u c o c o r t i c o i d flanking sequence
in the m a j o r
groove
turns. regulated genes
indicated either similar binding
city or sequence homologies.
5'
specifi-
In the c l o n e d g e n e of
h
m e t a l l o t h i o n e i n II u n d e r r e g u l a t i o n b y the h o r m o n e as w e l l c a d m i u m , t h e r e w a s one strong b i n d i n g to - 2 6 5 from the C A P s i t e .
s i t e ; l o c a t e d at - 2 4 5
S e q u e n c e a n a l y s i s of
those
r e g i o n s p r o t e c t e d a g a i n s t D N a s e I d i g e s t i o n by b o u n d corticoid holoreceptor containing
(footprinting)
yielded a
gluco-
sequence
5' T G T T C T 3' c o m m o n in d i g e s t i o n p a t t e r n s of
the
p r o t e c t e d M M T V L T R r e g i o n at two s t r o n g b i n d i n g
sites.
5' f l a n k i n g
tyrosine
r e g i o n s of t r y p t o p h a n o x y g e n a s e and
transaminase
(73,74)
The
h a v e also b e e n s e q u e n c e d y i e l d i n g
the
h o m o l o g o u s a r e a s at p o s i t i o n s r e l a t i v e l y e q u i v a l e n t to
the
transcriptional near
i n i t i a t i o n of M M T V
identical sequence
i.e. 5' T X A G T T C T 3'.
in four g l u c o c o r t i c o i d
b i n d i n g of the h o l o r e c e p t o r .
Yet differences
i n d u c t i o n , m u l t i p l i c i t y of s i t e s , e t c .
tional
f a c t o r s m a y be i m p o r t a n t
in e a c h
in the
interaction with control
the
kinetics addi-
case.
r e g i o n s of d e f i n e d
s e q u e n c e s are those of the c h i c k o v i d u c t egg w h i t e C o m p t o n and h i s c o w o r k e r s
for
indicate that
O t h e r s t e r o i d r e g u l a t e d g e n e s s t u d i e d at the level of receptor
The
regulated
genes strongly suggest a primary recognition template of
as
(74) f o u n d p u r i f i e d
holoDNA
proteins.
progesterone
r e c e p t o r s u b u n i t A , d e r i v e d from m a t u r e h e n o v i d u c t s ,
pref-
e r e n t i a l l y b o u n d to c l o n e d
gene.
f r a g m e n t s of the o v a l b u m i n
T h e y u s e d the r e t e n t i o n of r e c e p t o r b o u n d DNA o n ulose
nitrocell-
f i l t e r s as a m e a s u r e of b i n d i n g w i t h s u b s e q u e n t
elution
and e l e c t r o p h o r e s i s a s a m e a n s of i d e n t i f i c a t i o n of the
DNA
fragment.
the
An interesting
d e t a i l of t h e i r work was t h a t
r e c e p t o r did not d i s t i n g u i s h b e t w e e n s p e c i f i c and
nonspecific
529 DNA at low temperatures; following
incubation at 37°C, the A
subunit bound selectively to a small fragment of the ovalbumin gene compared to a larger plasmid fragment or a 6 molar excess of chicken α globin gene sequences.
The ovalbumin
fragment used was OV 1.7 which contained 1,338 nucleotides of the 5' flanking region and 589 nucleotides of coding tions.
sec-
These authors estimated that there was a 10 fold
difference in affinity of binding to specific as opposed to nonspecific
sequences.
Using an alternative means of assay, Mulvihill and her coworkers (75) found selective binding of progesterone receptor to several cloned segments of the egg white proteins including ovalbumin, conalbumin, ovomucoid, the X and Y pseudogenes.
These workers measured the displacement of
holoreceptor from nonspecific calf thymus DNA cellulose by effective gene segment competitors.
Crude or partially
purified progesterone receptor, subunit A, were about the same in their binding descrimination with maximal occuring at 0.05 - 0.08 Μ KCl or NaCl.
interaction
At lower ionic
strengths, the receptors aggregated and at higher ionic strengths, they dis sociated from the DNA.
The DNA cellulose
assay is a measure of equillibrium binding while the nitrocellulose filter assay the holoreceptor to DNA.
determines the rate of association of Deletion mutants were constructed
from a 1.7 kb cloned segment including the 5' flanking
region
of the ovalbumin gene by successive digestions with exonuclease III and SI nuclease or Bal 31 exonuclease.
These dele-
tions demonstrated 3 binding regions existing with a 40 fold increase in relative binding affinity.
When a computer
analysis, set at a cut off of 60% homology, was made of the 14 kb known sequences of egg white proteins a consensus 19 base pair sequence was identified 42 times in the overall group of genes.
The sequence is:
A T C £ £ A T T £ T C T G £ T T G T A
530 Of the s e g m e n t s c o n t a i n i n g were selective binding tive binding sequence
the h o m o l o g o u s s e q u e n c e , 41 of
t e m p l a tes.
T h e f i d e l i t y of the
is h o w e v e r a m a t t e r of
42
puta-
current
research. In a n o t h e r s t u d y (77) the p u r i f i e d A s u b u n i t of progesterone
oviduct
r e c e p t o r w a s found p r e f e r e n t i a l l y c o m p l e x e d to a
s e g m e n t of the 5' f l a n k i n g r e g i o n of the o v a l b u m i n g e n e - 1 3 5 to - 2 4 7 r e l a t i v e to the t r a n s c r i p t i o n a l
initiation site.
e l u c i d a t i o n of s t e r o i d c o n t r o l of o v a l b u m i n e x p r e s s i o n
suf-
f e r e d b e c a u s e a lack of an jji v i v o t r a n s f e c t i o n a s s a y
of
biological responsiveness
tk
chimeric transformants (78,79)
s i m i l a r to the M M T V L T R - H S V
in tk - L c e l l s .
l i n k e d the 5' f l a n k i n g
including
the t r a n s c r i p t i o n a l
ß - g l o b i n g e n e and a n SV40 (pSV-OG).
Recently, Dean et al.
r e g i o n of the
ovalbumin
s t a r t s i t e to a s e g m e n t of
early g e n e u n d e r
its o w n
r e g i o n - 9 5 to - 2 2 1 w a s n e e d e d
s t e r o i d e n h a n c e m e n t b u t not for b a s a l
l e v e l s of
the
control
In t r a n s f e c t e d p r i m a r y o v i d u c t c e l l s , they
t h a t the 5' f l a n k i n g
The
found
for
synthesis.
A g a i n d e l e t i o n m u t a n t s of the c o n s t r u c t w e r e used to d e f i n e the e f f e c t o r r e g i o n . tive
in i n c r e a s i n g
E s t r o g e n and p r o g e s t e r o n e w e r e
t r a n s c r i p t i o n of t h e s e c h i m e r a s .
c o n c l u d e d o n the b a s i s of
individual
They
hormone effects on a
s e r i e s of d e l e t i o n s t h a t p r o g e s t e r o n e l a p p i n g e f f e c t o r s i t e s o r they w e r e
effec-
and estrogen had
in c l o s e
proximity.
H o w e v e r , this m a y b e m o r e c o m p l e x as the a u t h o r s s t a t e p r e l i m i n a r y note t h a t w h e n the 5' f l a n k i n g r e g i o n of b u m i n is s p l i c e d to a h e t e r o l o g o u s p r o m o t e r and the is t r a n s f e c t e d , insensitive.
over-
it is p r o g e s t e r o n e s e n s i t i v e and
in a
ovalchimera
estrogen
531 F i n a l l y , o t h e r g e n o m i c s e g m e n t s h a v e b e e n used to
transform
recipient cells and have maintained hormonal response these
include
lysozyme gene
«j μ globulin
(80), g r o w t h h o r m o n e
(83), t r y p t o p h a n o x y g e n a s e
s t e r o i d b i n d i n g p r o t e i n (85) s e g m e n t s .
—
(81,82),
(84) and
prostatic
The structural
deter-
m i n a n t s of r e c e p t o r b i n d i n g and h o r m o n e r e s p o n s e s h o u l d forthcoming
in the n e a r
be
future.
Conclusion T h i s c h a p t e r has r e c o u n t e d regarding
the s h i f t of the
steroid hormone receptors
From a questionable
pendulum
interaction with
n o n s a t u r a b l e c h a r a c t e r of the b i n d i n g that receptor binding
to the
and hormone response
the
in the 5'
r e g i o n of n u m e r o u s s t e r i o d r e g u l a t e d g e n e s .
Our
f o c u s h a s b e e n o n the role of s t e r o i d h o r m o n e r e c e p t o r s
as
DNA nucleotide sequence recognition proteins, analogous
to
the m y r i a d of p r o k a r y o t i c g e n o m i c r e g u l a t o r y p r o t e i n s lac r e p r e s s o r , C A M P b i n d i n g p r o t e i n . p o u n d e d b y the e v i d e n c e 1.
The s t e r o i d - and DNA b i n d i n g
Steroid hormone
is c o m -
s i t e s of
ligand
steroid
separated.
B i n d i n g of the r e c e p t o r to D N A b i n d i n g of small
3.
The a n a l o g y
i.e.
that:
r e c e p t o r s are s p a t i a l l y 2.
is m o d u l a t e d by
their
molecules.
receptor action
is s e n s i t i v e
to
i n h i b i t o r s w h i c h m o d i f y c a t i o n i c a m i n o a c i d s at putative DNA binding 4.
and
determination
is b a s e d on
p r e s e n c e of a l i m i t e d , d e f i n e d s e q u e n c e p r e s e n t flanking
DNA.
i m p o r t a n c e b e c a u s e of the n o n s p e c i f i c
the
sites.
S t e r o i d h o r m o n e r e c e p t o r b i n d i n g to DNA is to a g e n t s w h i c h r e s t r u c t u r e a t the t e m p l a t e b i n d i n g
the s e c o n d a r y
site.
sensitive structure
532 Underlying the biological importance of interaction with a particular sequence heterogeneity is the ability of the steroid holoreceptor to discriminate among the nucleotide bases within the helix.
Numerous studies using homologous or
heterologous polyribonucleotides,
polydeoxyribonucleotides
and oligodeoxynucleotides indicating that steroid holoreceptors have common nucleotide base preferences for binding. These are dG or G > dT or U > dC or C >, dA or A.
Perhaps
the real meaning of all the nucleic acid, native and synthetic, binding studies are that receptors possess capabilities of interacting in particular ways with each of these bases in a distinct manner.
An indication of the
potential biological meaning of these affinities is the critical role that the three dG base residues play in the binding of glucocorticoid receptors to sequences flanking the promoters of MMTV and h metallothionein II transcription. Obviously, this clone is insufficient to explain the specificity of interaction for there are numerous regions containing dG residues on the same face of helix at two consecutive turns.
But it does underlie the anchoring role
that dG residues play in the receptor:specific sequence interact ion.
Two other aspects of DNA interaction may come to the fore as purified participants are studied.
First that the DNA
binding site of steroid receptors contain subsites - some stable and others malleable.
The latter probably are of
critical importance in deciphering the specific binding/ effector sequence.
Secondly, the latter malleable sites are
subject to allosteric modulation by neighboring chromosomal proteins.
The pendulum has swung very far from the time when
chromosomal proteins were considered the nuclear acceptor sites for steroid receptors but the protein composition surrounding the DNA binding sequence is probably of crucial importance -- in defining permissive or nonpermissive
533 chromatin targets, stabilizing or destabilizing sequence
steroid
receptor:specific
nucleotide
a c c e s s to b i n d i n g
s i t e s w i t h i n the g e n o m e or m o d u l a t i n g
r e g u l a t o r y a r e a s n e a r the g e n o m e , ments,
interactions,
i.e. e n h a n c e r - l i k e
i n d e p e n d e n t of the r e c e p t o r b i n d i n g
s e n s i t i v e to r e c e p t o r
blocking ele-
sites which
: DNA c o m p l e x a t i o n .
In this
are
regard,
the e v i d e n c e that t i g h t l y b o u n d n o n h i s t o n e p r o t e i n s of o v i d u c t c h r o m a t i n are r e q u i r e d for the s a t u r a t i o n a n d t a r g e t cell s p e c i f i c i t y of p r o g e s t e r o n e Chromatin alteration Z a r e t and Y a m a m o t o
kinetics
receptor
is c u r r e n t l y v i s u a l i z e d as a n
e a r l y c o n s e q u e n c e of s t e r o i d r e c e p t o r (85)
: DNA
chick
binding.
important
interaction.
found that a s i n g l e D N a s e 1 s i t e
was
h y p e r s e n s i t i v e w i t h i n a c h i m e r i c c o n s t r u c t of M M T V L T R - H S V
tk
transfected
to
nuclease
into tk
L cells.
The s e n s i t i v i t y of the s i t e
i n c r e a s e d w i t h e x p o s u r e of the r e c i p i e n t c e l l s
d e x a m e t h a s o n e and r e s c i n d e d w i t h w i t h d r a w a l of the Other sites were more modestly sensitive
to
hormone.
to DNase 1 d i g e s t i o n
w i t h h o r m o n e a d d i t i o n but r e m a i n e d so d e s p i t e h o r m o n e
deple-
tion.
chrom-
T h e s e a u t h o r s d e f i n e d three c l a s s e s of c h i m e r a
a t i n s t r u c t u r e a c o n s t i t u t i v e h y p e r s e n s i t i v e s i t e , as w e l l i r r e v e r s i b l e and r e v e r s i b l e
inducible hypersensitive
The l a t t e r c o i n c i d e c l o s e l y w i t h the r e g i o n of binding
and h o r m o n e r e s p o n s i v e n e s s
receptor
in t r a n s f o r m e d c e l l s .
i m p o r t a n c e of c h r o m a t i n s t r u c t u r e , as a d e t e r m i n e n t or and h i s c o w o r k e r s
(86) that
P l a s m i d s of M M T V L T R and the t r a n s f o r m i n g
The
conse-
q u e n c e of h o r m o n e a c t i o n , m a y be m o r e a p p r o a c h a b l e w i t h f i n d i n g of O s t r o w s k i
as
sites.
the
chimeric
f r a g m e n t of
bovine
p a p i l o m a v i r u s t y p e 1 c a n t r a n s f o r m c e l l s w i t h as m a n y as 200 c o p i e s of the c h i m e r i c m o l e c u l e s p e r d i p l o i d g e n o m e s . are unintegrated, extrachromosomal
e p i s o m e s w h i c h are
These sensi-
t i v e to g l u c o c o r t i c o i d
hormone regulation through sites
the M M T V L T R s e g m e n t .
Of m o s t
i m p o r t a n c e , they e x i s t
m i n i - c h r o m o s o m e s w h i c h p u t a t i v e l y c o n t a i n the
as
accessory
in
534 chromosomal proteins with a role in hormone receptor nuclear action.
This probably represents an important step forward
to the ultimate goal of a complete JJI vitro transcriptional system under steroid hormone control.
Acknowledgement Research work in the authors' laboratories has been supported by grants from the New York State Health Research, Inc. (BRS 35074), National Institutes of Health (AM 23075; HD 18406) and National Science Foundation (PCM 7825517).
References 1.
King, W.J., Greene, G.L.: Nature 307 , 745-747 ( 1984 ).
2.
Welshons, W.V., Lieberman, M.E., Gorski, J.: Nature 307 , 747-749 (1984) .
3.
Chamness, G.C., Jennings, A.W., McGuire, W.L.: Biochemistry 12, 327-331 (1974).
4.
Yamamoto, K.R., Alberts, B.M.: J. Biol. Chem. 249, 7076-7077 (1974).
5.
Yamamoto, K.R., Alberts, B.M.: Cell 4, 301-310 (1975).
6.
Andre, J., Rochefort, Η.: FEBS Lett. 5£, 319-323
7.
O'Malley, B.W., Speisberg, T.C., Schräder, W.T., Chytel, F., Steggles, A.W.: Nature 235, 141-145 (1972).
8.
Puca, G.A., Sica, V. , Nola, E.: Proc. Natl. Acad. Sei., U.S.A. 7 U 979-983 (1974).
9.
Speisberg, T.C., Webster, R.A., Pikler, G.M.: Nature 262, 65-67 (1976).
(1975).
10. Kallos, J., Hollander, V.P.: Nature 272, 177-179 (1978). 11. Thanki, K.H., Beach, T.A., Dickerman, H.W.: J. Biol. Chem. 253, 7744-7750 (1978). 12. Liao, S., Smythe, S., Tymoczko, J.L., Rossini, G.P., Chen, C., Hiipakka, R.A.: J. Biol. Chem. 255, 5545-5551 (1980) .
535 13. Kumar, S.A., Beach, Τ.Α., Dickerman, H.W.: Proc. Natl. Acad. U.S.A. 77, 3341-3345 (1980). 14. Gross, S., Kumar, S.A., Dickerman, H.W.: J. Biol. Chem. 257 , 4738 (1982) . 15. Payvar, F., Wränge, 0., Carlstedt-Duke, J., Okret, S., Gustafsson, J.Α., Yamamoto, K.: Proc. Natl. Acad. Sei. U.S.A. 78' 6628-6632 (1981). 16. Yamamoto, K.R., Alberts, B.: Ann. Rev. Biochem. 45, 721-746 (1976 ) . 17. Andre, J., Rochefort, Η.: FEBS Lett. 29, 135-140
(1973).
18. Turneil, R.W., Kaiser, N., Milholland, R.J., Rosen, F.: J. Biol. Chem. 249, 1133-1138 (1974). 19. Kumar, S.A., Dickerman, H.W.: Biochemical Actions of Hormones, Ed. G. Litwack, Vol. 10^, 259-301. Acad. Press, New York 1983. 20. Sala-Trepat, J.M., Vallet-Strove, C.: Biochim. Biophys. Acta. 371' 186-202 (1974). 21. Sherman, M.R., Pickering, L.A., Rollwagen, F.Μ., Miller, L.K.: Fed. Proc. 37, 167 (1978). 22. Vedeckis, W.V., Schräder, W.T., O'Malley, B.W.: in "Steroid Hormone Receptor Systems," Eds. Leavitt and J.H. Clark, 309-327, Plenum, New York 1979. ο 23. Wränge, 0., Gustafsson, J.-Α.: J. Biol. Chem. 253, 856-865 (1978). 24. Sherman, M.R., Berzilai, D., Pine, P.R., Tuazon, F.B.: Adv. Exp. Med. Biol. 1Γ7, 357-375 (1979). 25. Naray, Α.: J. Steroid. Biochem.
71-76 (1981 ).
26. Minghetti, P.P., Wiegel, N.L., Schräder, W.T., O'Malley, B.W.: Personal Communication (1983). 27. Simmons, S.S.: Biochim. Biophys. Acta. 496, 349-358 (1977) . 28. Rousseau, G.G., Higgins, S.J., Baxter, J.D., Gelfand, D., Tomkins, G.M.: J. Biol. Chem. 250, 6015-6021 (1975). 29. Romanov, G.A., Sokolova, N.A., Rozen, V.B., Varryushin, B.F.: Biokhimiya 4_1 , 2140-2141 (1976). 30. Andre, J., Pfeiffer, Α., Rochefort, Η.: Biochemistry 15, 2964-2969 (1976). 31. Thrall, C.L., Speisberg, T.C.: Biochemistry 1_9, 4130-4138 (1980) . 32. Milgrom, Ε., Atger, Μ., Baulieu, Ε.Ε.: Biochemistry 12, 5198-5205 (1973).
536 33. R o m a n o v , G . A . , V a n y u s h i n , Β . F . : B i o c h i m . B i o p h y s . 699 , 53-59 (1982) .
Acta.
34. K a l l o s , J . , F a s y , T . M . , H o l l a n d e r , V . P . , B i c k , M . D . : P r o c . N a t l . A c a d . S e i . USA 7_5, 4 8 9 6 - 4 9 0 0 (1978). 35. K a l l o s , J . , F a s y , T . M . , H o l l a n d e r , V . P . , B i c k , F E B S . L e t t . 9 8 , 3 4 7 - 3 4 9 (1979).
M.D.:
36. S l u y s e r , M . , E v e r s , S . G . , N i j s e n , T . : B i o c h e m .
Biophys.
R e s . C o m m . 6^1, 3 8 0 - 3 8 8
(1974).
37. R o m a n o v , G . A . , R o m a n o v a , Ν . Α . , R o z e n , V . B . , Β . F . : B i o c h e m . I n t l . 6, 3 3 9 - 3 4 8 (1983).
Vanyushin,
38. L i n , S., O h n o , S . : B i o c h i m . B i o p h y s . A c t a . 654, (1981) .
181-186
39. T h r o w e r , S . , H a l l , C . , L i n , L . , D a v i d s o n , A . N . : J. 160 , 271-280 (1976) .
Biochem.
40. T a k a h a s h i , Μ . , B l a z y , B., B a u d r a s , Α . : N u c l e i c A c i d 7 , 1 6 9 9 - 1 7 1 2 (1979) .
Res.
41. R e c o r d , Μ . Τ . , J r . , M a z u r , S . J . , M e l a n c o n , P . , R o e , J . - Η . , S h a n e r , S . L . , U n g e r , L.: A n n . R e v . B i o c h e m . 5£, 9 9 7 - 1 0 2 4 (1981) . 42. M u r p h y , L . C . , S u t h e r l a n d , R . L . : E n d o c r i n o l o g y 7 0 7 - 7 1 4 (1983).
112,
43. de H a s e t h , P . L . , L o h m a n , T . M . , R e c o r d , M . T . , J r . : B i o c h e m i s t r y 16^, 4 7 8 3 - 4 7 9 0 (1977). 44. H e n r i k s o n , K . P . , G r o s s , S . C . , D i c k e r m a n , E n d o c r i n o l o g y 1£9, 1 1 9 6 - 1 2 0 2 (1981).
H.W.:
45. Gross, S.C., Kumar, S.A., Dickerman, H.W.: Mol. E n d o c r i n o l . 22, 3 7 1 - 3 8 4 (1981).
Cell.
46. D i c k e r m a n , H . W . , K u m a r , S . A . : A d v . E x p . M e d . B i o l . 1 - 1 8 (1981). 4 7 . Y a m a m o t o , K . R . : J . B i o l . C h e m . 2 4 9 , 7068
138,
(1974).
4 8 . K i n g , R . J . B . : in " E f f e c t s of D r u g s o n C e l l u l a r C o n t r o l Mechanisms," Eds. B.R. Rabin and R.B. Freedman, 11-26. U n i v . Park P r e s s , B a l t i m o r e 1 9 7 2 . 49. F e l d m a n , Μ . , K a l l o s , J . , H o l l a n d e r , V . P . : J . B i o l . 256 , 1 1 4 5 - 1 1 4 8 ( 1981 ) .
Chem.
50. S p e i s b e r g , T . C . , L i t t l e f i e l d , B . A . , S e e l k e , R . , D a n i , G.M., Toyoda, H., Boyd-Leinen, P., Thrall, C., Kon, O.L.: R e c e n t P r o g . H o r m o n e R e s . 39.' 4 6 3 - 5 1 7 (1983). 51. Webster, R.A., Pikler, G.M., Speisberg, T.C.: Biochem. 156 , 4 0 9 - 4 1 9 (1976) . 52. P e r r y , B . N . , L o p e z , Α . : B i o c h e m . J . 176, 8 7 3 - 8 8 3
J.
(1978).
537
53. Ruh, T.S., Ross, P., Wood, P.M., Keene, J.L.: Biochem. J. 200 , 133-142 (1981). 54. Speisberg, T.C.: Biochemistry 22,13-21 (1983). 55. Speisberg, T.C., Goose, B.J., Littlefield, B.A., Toyoda, H., Seelke, R.: Biochemistry JJI press (1984). 56. Speisberg, T.C.: Personal Communication (1984). 57. Thanki, K.H., Beach, T.A., D'ickerman, H.W.: Nucleic Acid Res. 6, 3859-3877 (1979). 58. Fox, T.O., Bates, S.E., Vito, C.C., Wieland, S.J.: J. Biol. Chem. 254, 4963-4966 (1979). 59. Kallos, J., Fasy, T.M., Hollander, V.P.: Proc. Natl. Acad. Sei. USA 78, 2874-2878 (1981). 60. Massol, N., Lebeau, M.-C., Balieu, E.-E.: Nucleic Acid Res. 5, 723-738 (1978 ) . 61. Senior, M.B. , Frankel, F.R.: Cell 1_3 , 629-642 ( 1978). 62. Ringold, G.M., Yamamoto, K.R., Tomkins, G.M., Bishop, J.M., Varmus, H.E.: Cell 6, 299-305 (1975). 63. Yamamoto, K.R., Chandler, V.L., Ross, S.R., Ucker, D.S., Ring, J.C., Feinstein, S.C.: Cold Spring Harbor Symp. Q u a n t . Biol. £5, 681-705 (1981). 64. Buetti, E., Diggelmann, H.: Cell 23, 335-345 (1981). 65. Fasel, Ν., Pearson, Κ., Buetti, Ε., Diggelmann, Η.: EMBO J. 1., 3-7 (1982) . 66. Hynes, N., van Ooyen, A.J.J., Kennedy, N., Herrlich, P., Ponta, H., Groner, B.: Proc. Natl. Acad. Sei. USA 80, 3637-3641 (1983). 67. Buetti, E., Diggelmann, H.: EMBO J. 2, 1423-1429 (1983). 68. Majors, J., Varmus, H.E.: Proc. Natl. Acad. Sei. USA 80, 5866-5870 (1983). 69. Scheidereit, C., Geisse, S., Westphal, H.M., Beato, M.: Nature, 304, 749-752 (1983). 70. Scheidereit, C., Beato, M.: Proc. Natl. Acad. Sei. 81, 3029-3033 (1984). 71. Karin, Μ., Haslinger, Α., Holtgreve, Η., Richards, R.I., Krauter, P., Westphal, Η., Beato, Μ.: Nature 308, 513-519 (1984) . 72. Schmid, W., Scherer, G., Danesch, U., Zentgraf, H., Matthias, P., Strange, C.M., Röwekamp, W., Schutz, G.: EMBO J. 1287-1293 (1982).
538 73. Shinomaya, Τ., Scherer, G., Schmid, W. , Zentgraf, H., Schütz, G.: Proc. Natl. Acad. Sei. USA £1, 1346-1350 (1984 ) . 74. Compton, J.G., Schräder, W.T., O'Malley, B.W.: Biochem. Biophys. Res. Commun. 105, 96-104 (1982). 75. Mulvihill, E.R., LePennec, J.-P., Chambon, P.: Cell 28, 621-632 (1982). 76. Compton, J.G., Schräder, W.T., O'Malley, B.W.: Proc. Natl. Acad. Sei. USA 80, 16-20 (1983). 77. Dean, D.C., Knoll, B.J., Riser, Μ.Ε., O'Malley, B.W.: Nature (Lond.) 305, 551-554 (1983). 78. Dean, D.C., Gope, R., Knoll, B.J., Riser, Μ.Ε., O'Malley, B.W.: J. Biol. Chem. 259, 9967-9970 (1984). 79. Kunz, D.T.: Nature (Lond.) 291, 629-631 (1981). 80. Robins, D.M., Paek, I., Seeburg, P.H., Axel, R.: Cell 29, 623-631 (1982). 81. Doehmer, J., Barinaga, Μ., Vale, W. , Rosenfeld, M.G., Verma, I.M., Evans, R.M.: Proc. Natl. Acad. Sei. USA 79, 2268-2272 (1982) . 82. Renkawitz, R., Berg, H., Graf, T., Matthias, P., Grez, M., Schütz, G.: Cell 167-176 (1982). 83. Renkawitz, R., Danesch, U., Matthias, P., Schütz, G.: J. Steroid Biochem. 20, 99-104 (1984). 84. Page, M.J., Parker, M.G.: Cell 3_2 , 495-502 (1983 ). 85. Zaret, K.S., Yamamoto, K.R.: Cell 38^ 29-38 (1984). 86. Ostrowski, M.C., Richard-Foy, H., Wolford, R.G., Berard, D.S., Hager, G.L.: Mol. Cell Biol. 2' 2045-2057 (1983).
THE
RAT PITUITARY
RECEPTOR
IN
PROLACTIN
ESTROGEN
THE
GENE
RECEPTOR:
REGULATION AND
THE
OF
ROLE
OF
THE
NUCLEAR
TRANSCRIPTION
OF
THE
LOCALIZATION
OF
THE
NUCLEAR
UNOCCUPIED RECEPTOR
James
D.
Shull,
Wade
V.
Welshons,
Mara
E.
Lieberman,
Jack Gorski Departments of Biochemistry and Animal Science University of Wisconsin, Madison, WI
53706
Introduction We
have
recently
examined
estrogen on the synthesis by
nuclei
glands
which
of
are
intact
pituitary
cells.
stimulates
the
the
of prolactin
isolated
male Our
effects
from
rats
or
transcription
of
anterior
rat
cells
centrifugation in
Percoll
of
gradients
cytochalasin to
estrogen
gene
jji vivo
(1-4).
We have
also used a cell enucleation procedure based on density
anterior
that
Prl
through at least two independent mechanisms
equilibrium
B-treated
reexamine
the
receptor nuclei
we
observed
was (5).
that
associated This
and
most with
other
of the
the
In these
unoccupied
fraction
observations
that
have
estrogen contained
led
revision of the classical model of estrogen action
Molecular M e c h a n i s m of Steroid H o r m o n e Action © 1985 Walter de Gruyter & Co., Berlin · N e w York - Printed in G e r m a n y
GH^
subcellular
distribution of the unoccupied estrogen receptor. studies
RNA
pituitary
cultured
illustrate the
administered
(Prl) messenger
the from
results
of
to
(6).
the
540 Estrogen Regulation of Prolactin Gene Transcription Estrogen
has been
shown
pituitary
hormone
through
mechanism
a
Prl messenger RNA that this increase
Prl
to stimulate i^n
which
(11-14).
vivo
the
(7-9)
results
in
synthesis
and
_in
increased
is due at least
an increase in the transcription of the
the (10)
levels
It has more recently been
in Prl mRNA
of
vitro
shown
in part
rat Prl gene
of to
(1-4,
15, 18) .
From Shull and Gorski, Endocrinology,
1984
Figure 1. Stimulatory effect of 17ß-estradiol on prolactin gene transcription. Male rats were injected (10 yg, IP) at the indicated times prior to sacrifice. Anterior pituitary nuclei were then prepared and prolactin gene transcription was assayed (3). Each data point represents the mean and SEM (n=3) for the assay of prolactin RNA synthesized by nuclei prepared from 8-10 animals.
541
to m a l e rats
(6 w e e k s of age) as a single
IP),
in
(48
results to
Similar
72
a
hours)
results
rapid
(within
stimulation
were
Log
observed
Inhibitor
30
injection
minutes)
of
Prl
by
Maurer
gene
and
(10
pg,
prolonged
transcription.
when
he
examined
Concentrotion
From S h u l l and G o r s k i , E n d o c r i n o l o g y ,
1984
Figure 2. Concentration effects of transcriptional inhibitors on RNA s y n t h e s i s by isolated p i t u i t a r y n u c l e i . Anterior p i t u i t a r y nuclei w e r e p r e p a r e d , and the inhibitory e f f e c t s of increasing c o n c e n t r a t i o n s of α - a m a n i t i n (A) a n d a c t i n o m y c i n D (B) on RNA s y n t h e s i s w e r e d e t e r m i n e d . Each d a t a p o i n t r e p r e s e n t s the m e a n and SEM (n=3).
542
A. Sesame Oil ΙΑ ΙΑ
V
-C c>» βοο to < H
600 -
Ο Ο
400
-
w α. 2 200 α. α.
B. 17 B - E s t r a d i o l
i 1111 11II
1000
-
-
None
α-Amon
Act D
None
Inhibitor of RNA
a-Aman
Act. 0
Synthesis
From Shull and Gorski, Endocrinology, 1984 Figure 3. Effects of transcriptional inhibitors on Prl RNA synthesis by isolated pituitary nuclei. Anterior pituitary nuclei were isolated 24 hours after injection of the sesame oil vehicle (A) or 10 pg 17ß-estradiol (Β) and were incubated under normal conditions or in the presence of a-amanitin (α-Aman; 1 yg/ml) or actinomycin D (Act. D; 10 pg/ml). Each bar represents the mean and SEM (n=3) of Prl RNA synthesis in nuclei pooled from 8-10 animals.
the
effect
into
of
a single
ovariectomized
effects
of
injection
female
17B-estradiol
are
(20 y g )
rats
(15).
specific:
of The
17ß-estradiol stimulatory
no effects
estrogen on the transcription
of the evolutionärily
growth
observed
hormone
experiments, quantitating, the
level
Prl-specific
gene
Prl by
of
gene
were
hybridization
mRNA
In
was
assayed
sequences
to
immobilized
precursor by
anterior
cDNA
incorporated pituitary
this
related
(1-3).
transcription
radiolabeled
of
these by
probe, into nuclei
543
From Shull and Gorski, Endocrinology,
1984
Figure 4. Time course of the levels of the nuclear and cytosol forms of the pituitary estrogen receptor following a single injection (10 p g , IP) of 17ß-estradiol. Nuclear (A) and cytosol (B) receptors were assayed as described (3). Each data point represents the mean and SEM of specific binding measurements in individual anterior pituitaries (n=3).
isolated
at
treatment
(3).
well level
the This
characterized of
Prl
indicated
gene
nuclear
and
times
following
transcription
appears
to
transcription
reflect occurring
assay
estrogen has
accurately at
the
been the time
544
the
nuclei
mRNA
are
prepared
sequences
polymerase which
are
II.
nuclear
Briefly,
synthesized
from
Alpha-amanitin
specifically
total
(3).
inhibits
RNA
a DNA
by
Prl-specific
template
at 1 yg/ml, RNA
synthesis
these a
polymerase
65
to
75%
by
RNA
concentration II,
inhibits
(Fig.
2A)
while
the synthesis of Prl mRNA sequences is inhibited by greater than 95% 50
to
(Fig. 3).
60%
synthesis
total of
Actinomycin
nuclear
Prl
mRNA
RNA
D at
10
pg/ml
synthesis
sequences.
Thus
when expressed as parts per million
inhibits
(Fig. Prl
2B)
and
mRNA
total RNA
by the
synthesis
synthesis
is
uneffected (Fig. 3). The
prolonged
stimulation
17ß-estradiol
(Fig.
1)
of
Prl
does
not
gene
transcription
require
a
elevation in the level of the nuclear form of the estrogen receptor level
of
1 hour
(Fig. 4).
nuclear-form
of
pituitary
Figure 4A illustrates that the
receptor
17S-estradiol
by
continuous
peaked
injection,
within
approximately
decreased
approximately
70% from this peak value within 6 hours and returned to its control
value
17ß-estradiol stable
within
mechanism
chromatin
24
regulates which
proteins
or
hours. Prl
perhaps DNA
These
gene
data
suggest
transcription
involves
sequences
that
through
a
a modification
within
or
of
surrounding
the Prl gene (3) . To
investigate
of
intermediary
transcription in
the
possible
proteins
by
in
gene
following
a
single
transcription
saline-treated (Fig. 5B).
the
17ß-estradiol,
cycloheximide-pretreated
hours
requirement
(Fig.
was 5A)
we
animals injection
stimulated and
for
the
induction
of
examined
this
(3). of
When
synthesis Prl
examined
17ß-estradiol,
nearly
2-fold
17ß-estradiol incorporation
injection
(Fig.
in
cycloheximide-treated
Similar results were observed 8 hours
cycloheximide
6).
In
inhibited by greater 3 of [ H]leucine into
these than
gene
induction 3
Prl both
animals following
experiments, 80%
the
acid-precipitable
545
Α.
Β. Cycloheximide
Saline
I1
Ρ ι! mm
HI Oil
E 2 -I7ß
Oil
E.,-170
Treatment From Shull and Gorski, Endocrinology, 1984 Figure 5. The induction of prolactin gene transcription by 17ß-estradiol (10 u g , IP) under conditions of inhibited pituitary protein synthesis: an examination at 3 hours. Sterile saline (A) or cycloheximide (B) was injected 10 minutes before 17ß-estradiol or its sesame oil vehicle. The animals were killed 3 hours after hormone treatment and prolactin gene transcription was assayed as described (3). Each bar represents the mean and SEM (n=3) for the assay of prolactin RNA synthesized by nuclei prepared from 8-10 animals.
material
by
eliminate required
the
the
anterior
possibility
for
the
induction
17ß-estradiol
may
have
sufficient we
quantity
examined
anterior
this
pituitary
in
ρ ituitary t hat
been the
induction cells
of
a Prl
gland protein gene
synthesized
(Fig. (or
transcription in
a
reduced
cycloheximide-treated in in
primary which
7).
cultures
To
proteins) by but
animals, of
cycloheximide
rat had
546
A.
Saline
B. Cycloheximide
500
§
Φ « 400 CO
c ο 3 « α> >
«
fr Oil
l7/3-E2
Oil
Saline
Ι7/3-ε2
Oil
Cyclohex
I7ß-Ez
oil ΐ7β-εΖ
Saline
Cyclohex
Treatment From Shull and Gorski, 1984 Figure 7. Inhibitory effects of cycloheximide on pituitary protein synthesis. Injections are as illustrated and described in Figures 5 and 6. Each bar represents the mean and SEM of the relative level of leucine incorporation in individual pituitaries from a total of five to eight animals.
The
synthetic
estrogen,
16α-estradiol,
has
characterized as being "short acting" as a single of
this
early
hormone
estrogenic
induced
protein
estrogenic
into
immature
responses, synthesis
responses
such
by as
female
such the
as
been
injection
rats
stimulates
water
imbibition
uterus, but
uterine
DNA
not
the and
the
synthesis
late (16).
The rat uterine estrogen receptor has a lesser affinity 16a-estradiol than for 17ß-estradiol a more
rapid
decline
the uterine estrogen
in
the
receptor
level
(16). of
following
the
for
This results in nuclear
a single
form
of
injection
of 16a-estradiol than is observed following an injection of
548
17ß-estradiol
(17).
When the
levels
cytosol
forms
examined
following
an injection of
returned
to
control
In
of
the
their
contrast,
the
significantly equivalent
pituitary
level
injection
for
of
nuclear
within
least
6
17B-estradiol
and
receptor
16«-estradiol, 4
nuclear-form at
the
estrogen
values
of
elevated
of
hours
had
(4,
receptor hours
were
they
18).
remained
following
while
the
an
level
of
cytosol-form receptor remained diminished (4, 18). A
single
injection
of
16a-estradiol
stimulates
the
transcription of the rat Prl gene in a biphasic manner 4,
18).
of
injection
The
paralleling nuclear
initial and
phase was
continued
in duration
form
of
the
observed
through
the
at
elevation
pituitary
within
least
minutes
2 hours,
in the
estrogen
30
(2,
level
thus
of
the
receptor.
The
second phase of stimulated Prl gene transcription was
first
observed
after
the
approximately
level
of
6
hours
nuclear-form
following
receptor
had
injection, returned
control value
(4, 18).
The induction of the
of
Prl
transcription
stimulated
gene
by
to
initial
its phase
16a-estradiol
was
observed in animals pretreated with either cycloheximide puromycin
indicating
mechanism
which
synthesis. the
that this phase
is
independent
is mediated of
In contrast, cycloheximide
induction
stimulated
by
16 α-estradiol
transcription
of
(4,
pituitary
18).
second This
(6
hours
versus
following
8
induction
of
examined the
1
Prl
(Fig. 6).
induction
hour)
hours
of
of
gene
as
no
transcription
effect
effect
was
treatment by
second
phase
protein
although
of
of of
treatment observed when
the
17ß-estradiol
was
These data suggest the possibility the
transcription by 16a-estradiol intermediary
such
cyclohe ximide
blocked
phase
cycloheximide was not simply due to the prolonged
a
protein
pretreatment the
or
through
stimulated
Prl
that gene
requires the synthesis of an other
cycloheximide cannot be ruled out.
unknown
effects
of
549
Our
observations
that
16a-estradiol
stimulates
the
transcription of the Prl gene in a biphasic manner and the
induction
of
the
two phases
differs
cycloheximide
suggest
that this hormone
transcription
through
at
One
mechansim
appears
least
to
pituitary
estrogen
hypothesize
that this mechanism
estrogen-receptor
the
Prl
and
is
includes with
Gorski
to
gene
of
the
attractive
to
an
form
interaction
regulatory have
Prl
mechanisms.
nuclear
It
complex
Durrin
in sensitivity regulates
independent the
receptor.
the
gene.
two
involve
that
regions
localized
of of
regions
near the 5-prime terminus of the Prl gene, which exist in a chromatin
structure
during
a
limited
nuclei
(manuscript
hypersensitive
which
DNAse
is
hypersensitive
digestion
submitted).
sites
correspond
of
to
isolated
It
is
to
regulatory
nicking pituitary
possible
that
these
domains.
We
have hypothesized that the induction of the second phase of stimulated an
Prl
gene
transcription
estrogen-induced
regulator
alteration
of Prl gene
the
responsiveness
to
a
second
of
the
regulator
cells (3,
induction of Prl gene that
elevated
receptor
the
anterior
These
same mechanisms
transcription with
and
of
either
a
second in
pituitary
hypotheses
are
and
affinity
ability
to
animals
duration
injected
allows with
than the
two
receptor,
the being
to
the
maintain is
This
nuclear-form
in the
16a-estradiol
lesser
lesser
function
17ß-estradiol;
an
shorter
the
its
its
by
induces
injection.
of
of
initial phase of stimulated Prl gene transcription which of
levels
of
4).
17ß-estradiol
16a-estradiol,
estrogen
result
level
(18).
It seems likely that these between
the
the
transcription or to an alteration
currently being tested
difference
is
in
following phases
16a-estradiol
would overlap in animals treated with
to
while
17ß-estradiol be the
resolved two
17ß-estradiol.
in
phases
550 Intracellular Location of the Estrogen Receptor Since the direct effects of estrogen involve the of
transcription
not
receptor-steroid complex is recovered in the nucleus of
the
cell
the
after
location the
that
the of
of
at
on
0-4°
C
receptor-steroid was
proposed
of
to
cell,
tissue. has
This
in
(20). for in
received
assigned
based
on
cytosol of
the
wide
of
to the
subsequent nucleus
the
nucleus
recovery
(21,
acceptance
the
labeled
Translocation
the
22).
for
to
extracts
cells
from the cytoplasm
account
the
However,
been
was
receptors
it
estrogen,
autoradiography
complex
interpretation
the
cell.
complex
receptor-steroid
the
receptor
unfilled
and
of
administering
the
most
(19)
briefly
after
unoccupied
cytoplasm cells
nucleus
homogenization
of
appearance of
the
regulation is
surprising
in
of This
both
the
estrogen receptor and the other steroid hormones. Some data also
be
suggest, however, found
in
the
that the unfilled
nucleus,
localization
represents
an
include
appearance
using
the
fraction of receptor
in the
and
that
extraction nucleus
under
In
order
to
avoid
remove
possible
B-induced
cytoplasm
(as
cytoplasts)
of from
cells, without breaking open the cells. and the cell have they
an
fragment
intact plasma
can
be
fused been
containing membrane to used
the and
reform
Enucleation
has
to
show
polymerase,
extracted when the cell
a
data large
nontranslocating
artifacts, cells
we
(24,
used
25)
to
receptor-containing Both the
nucleus
are a
The
of
(see below).
extraction
enucleation
may
cytosolic
artifact.
autoradiography
conditions (23) and other observations
cytochalasin
receptor
the
still viable
that
a
cytoplast
(nucleoplast) alive,
since
cell
(26).
cytosolic
is homogenized,
cytoplasmic in the intact cell, but is instead nuclear
DNA
is not (27).
551
Not
all
cells
cytoplast
will
and
separated.
Freshly
cultures
the
so
we
of
turned
tumor
that
found
fractionation increased
the
were GH^
(28). in
well,
always
pituitary
cells
and
primary
not
enucleated
cell
line,
the
a
usual
cells
rat
receptor cell
to estrogen
The
exhibit the usual characteristics of an
from
estrogen
after
(30).
satisfactorily,
derived
contain
cytosol
synthesis
enucleated, not
(29), and the cells respond
prolactin
if
are
The cells the
and
fractions
dispersed
cells
to
pituitary is
enucleate
nucleoplast
with
therefore
estrogen-responsive
tissue, even though the cells are tumor-derived. We were
able to partially
forming
cytoplasts
that
enucleate
averaged
PREPARATION OF
85%
1/5
of
of
the GH^
the
size
CYTOPLASTS
Percoll, self-forming gradient Welshons, Lieberman and Gorski, unpublished. Figure 8.
Preparation of cytoplasts from GH3 cells.
cells, of
the
552 original
whole
a purified contained fraction more the
cells.
less from
than
cells
from
these
able that
cytoplasts
containing
We
we were
cytoplasts,
contaminating
the
which
removed.
of 1%
which
heterogeneous,
been
Importantly,
preparation
varying called
whole
had
the
The
removed
was
cells
proportions this
of
obtain
sometimes
cells.
been
some whole
to
as well
cytoplasm
cell
+
as had
nucleoplast
fraction.
If the unoccupied estrogen receptor concentration than we
the
in
cytoplasts
concentration
enucleated
GH^
centrifugation
in
the
cells
(Fig.
8),
SUBCELLULAR
is cytoplasmic
should
be
whole
high
cells.
using we
as
then
or
However,
cytochalasin found
the
its
higher when
Β
and
opposite
DISTRIBUTION OF ER
ER/protein
ER/DNA η 3.0
I 50 γ ί
i n
i
c 5 2.0
2 loo Q. σ>
er Ε
ε
er ÜJ
£E Iii 50
1.0
Ö
ö
ε
Ε Q-
WC
C + N CYT
WC
C+N
CYT
From Welshons et a^., Nature, 1984 Figure 9. Estrogen receptor (ER) concentration in whole cells (WC), in cells + nucleoplasts (C + N) and in cytoplasts (Cyt).
553 distribution per
protein
the
cells
9).
The
(5). was
+
The
low
concentration
in
cytoplasts
nucleoplasts,
concentration
of
of
and
estrogen slightly
compared
to
whole
receptor
per
DNA
hand was similar in all fractions
receptor higher
cells on
in
(Fig.
the
other
(Fig. 9), suggesting
that
the receptor was following the DNA content of the cell. the
experiment
detailed
in
Table
1
(from
ref.
receptor per protein was less than 10% of the in
the
whole
estrogen complete
cells.
receptor (Table
The after
2),
recovery
of
was
that
In the
concentration
protein,
enucleation
indicating
5),
DNA
and
essentially
receptor
was
not
selectively lost from the cytoplasts.
The cell + nucleoplast less
protein
fraction
than
average
TABLE 1.
the of
fraction
averaged
original
only
20%
whole
of
the
approximately cells,
so
cytoplasm
1/5
that had
a
been
ESTROGEN RECEPTOR IN ENUCLEATED CELLS
ER/ Prot.
ER/ DNA
Prot./ Cell
DNA/ Prot.
ER/Cell Equivalent
fmol/mg
pmol/mg
pg
ρ g / mg
molecules
Whole cells
113
2.7
363
42
25,000
Cells + nucleoplasts
146
2.9
336
50
30,000
10
1.4
69
Cytoplasts
7.5
2,100*
Estrogen receptor per protein, per DNA and per cell hemocytometer) in whole cells and enucleated cells. cytoplast fraction contained fewer than 1% whole cells.
(by The
*Number of molecules per 5 cytoplasts, since cytoplasts approximately 1/5 the size of whole cells.
are
Welshons et al., Nature, 1984.
554 TABLE 2. RECOVERY OF ESTROGEN BINDING, PROTEIN AND DNA AFTER ENUCLEATION Total Applied or Recovered Estrogen Binding pmol
Protein mg
DNA pg
Before enucleation: Whole cells
2.10
18.5
785
After enucleation: Cells + nucleoplasts Cytoplasts
2.26 0.024
15.5 2.3
777 18
96%
101%
Recovery
109%
Welshons, Lieberman and Gorski, removed.
But
microscopically, it
fraction contained some cells cytoplasm most
of
had the
receptor further that
been
removed.
cytoplasm
content,
contained
less
When
cell
on
that
the
from which much more of
the
To
still
the
fractionated
densities.
unpublished.
a
see
+
if
seen
the
cells
the
full
nucleoplast
density
step
were
estrogen
measured in these fractions,
be
contained
cytoplasm the
could
lacking estrogen
fraction
gradient.
found
at
receptor
the
higher
content
DNA
(per
cell)
There was no evidence
was
that
was
it was found that, while
receptor per protein more than doubled, the receptor tent per
was Cells
constant
(Fig.
10,
removing most of the
the
con-
ref.
5).
cytoplasm
of the cell removed any of the unoccupied receptor. The
enucleation
cells.
Dye
enucleation whole
cell
incorporated enucleation
procedure
exclusion throughout
uptake
of
measuring estradiol
[ H]leucine (Table
did
4).
not
continued
and In
seem
high the
(Table
damage just
receptor 3).
synthesized addition,
to from
content
The
(Table 5), and the steroid receptor
by
fractions
prolactin
incubation
enucleation medium had no apparent effect on the content
the after
after in
the
receptor
in the cell +
555
DISTRIBUTION
OF
ESTROGEN
RECEPTOR
400 Cells +
Nucleoplasts
I
• Cyt]
Ξ
w
c a> ο a. σ> Ε
< ζ Ω
σ> Ε ν er υ ιο ο Ε α.
ο Ε
Λ Cyt.
Ά
Α
Cell
Β
Ά
Fraction
Welshons et al., Nature, 1984 Figure 10. The cell + nucleoplast fraction was further fractionated on a density step gradient. The (intact) cells at higher density steps have had more cytoplasm removed. Arrowhead indicates density of cells before enucleation, and the position cytoplasts would have occupied is indicated in brackets. TABLE 3.
DYE EXCLUSION OF CELLS AND FRACTIONS
% Excluding Dye Initial
Whole cells Cells + nucleoplasts Cytoplasts Mean + standard
97 + 1 98 + 1 98 + 1
Final
95 + 1 93 + 1 73 + 4
error, n's of 6 to 9.
Trypan blue exclusion just after enucleation (Initial) and after measuring the receptor content by whole cell uptake at 37° C (Final). Welshons, Lieberman and Gorski, unpublished.
556 nucleoplast
fraction
just
after
enucleation
was
still
extracted into the cytosol when the cells were homogenized (31).
Therefore,
apparent
effect
on
the
enucleation
the
estrogen
procedure receptor
had
that
no
would
indicate that redistribution of the receptor had occurred.
TABLE 4.
PROLACTIN SYNTHESIS BY GH3 CELLS AND FRACTIONS Leucine Incorporation: ΙΟ" 6 χ DPΜ Per 10 6 Cells or Equivalent
Prolactin Synthesis: % of Total Protein Synthesis
Whole cells
6.2
1,.2 + 0.02
Cells + nucleoplasts
5.7
1,.3 + 0. 06
Cytoplasts
3.0*
3 .4 , + 0.2
Cells, cells plus nucleoplasts, or cytoplasts were incubated with [^Hjleucine to measure general protein synthesis by TCA-precipitable leucine incorporation, and to measure prolactin synthesis using precipitation with antiprolactin antibody. *Assuming 5 cytoplasts per whole cell equivalent. Welshons, Lieberman and Gorski, unpublished.
TABLE 5. EFFECT OF INCUBATION OF CELLS IN ENUCLEATION MEDIUM ON RECEPTOR CONTENT
Whole cell uptake, fmol/mg prot.
Untreated
After Incubation
102 + 2
98+1
Mean + standard error, n=2
Estrogen receptor content was measured in untreated cells and in cells incubated at 37° C for 2 hours in cytochalasin Β plus solvent DMSO in Percoll. Receptor content was not significantly affected. Welshons, Lieberman and Gorski, unpublished.
557 The
estrogen
receptor
using whole cell
[ 3 H]estradiol
of
fractions. uptake
at
Specific
in
hormone.
was measured
in these experiments
(or whole cytoplast or nucleoplast)
the
37°
C
uptake
presence
into
was
of
the
intact,
calculated
100-fold
by
excess
of
that
would
have
been
unlabeled
encountered
homogenized cells or cytoplasts in the 1 or 2 mg that we used
in assays.
The specific
instead
of
37°
C
(Table
had
we
quantities
uptake was more
90% inhibited when the cells or fractions were C
live
subtracting
Whole cell uptake was used to avoid any losses of
receptor
0°
by
uptake
6)
than
incubated
verifying
that
at the
receptors were inside the intact cells.
TABLE 6. TEMPERATURE-DEPENDENT UPTAKE OF ESTRADIOL BY INTACT CELLS OR CYTOPLASTS
Specific Uptake, DPM
37° C
Whole cells Cells + nucleoplasts Cytoplasts
0° C
855 3,570 143
39 120 13
Welshons, Lieberman and Gorski, unpublished. The
specific
Scatchard
uptake
analysis
(Figure 11). per
cell.
The
is observed 1
the
an
linearity the
was
of
as
this
nucleus,
not
it to
is
in
suggest
free
the
in
the
of
intact
solution
plot
binding
receptor
the
and
in
nM sites
intact
(32, 33)
that
concentration cell.
receptor (6),
by
0.34
25,000 binding
Scatchard
the that
saturable,
affinity
cooperative
in extracts when
nM,
interpreted
estradiol
showed
There were approximately
cells contrasts with
above
of
since
We
is bound a
is
have in
soluble
558
SATURATION
ANALYSIS
TOTAL
0
1 2
,c 50
3
4
Estradiol Concentration (nM)
Bound Estradiol (DPMxIO )
Welshons, Lieberman and Gorski, unpublished Figure 11. Saturation analysis of the whole cell uptake of [ 3 H ] estradiol at 37° C by G H 3 cells. receptor
would be expected
binding,
while
hydroxylapatite),
like
the
not show this cooperativity While our nuclear
finding to
lines
nuclear
indicate
of
receptor under
the
estrogen
Recent
are
in
that
autoradiography 2.
in
fact
is
Sheridan
of
(34,
was
even
is
been
several with
found
conditions in
studies
the
with
antibodies
by that
nucleus. to
in the nucleus, though
a
during
(23)
already
monoclonal
35),
receptor
that has
consistent
"nontranslocating" binding
set
does
location,
aK
receptor have detected antibody binding cytoplasm
cells,
extractable et:
immunohistochemical
best-characterized the
intact
(on
(33).
cytoplasmic
evidence 1.
of
receptor
hormone
receptor
that the unoccupied estrogen
homogenization. most
estrogen
contradicts a large body of evidence
interpreted recent
to show the cooperative
immobilized
the the not
preliminary
559
localization
was
reported
nuclear
translocation
receptor
would
compounds
that
the
full
range
also seem of
in
the
(36)). explain
to
bind
the
to
estrogenic
cytoplasm
3.
action
the
(but
Extraction of
receptor
(nuclear)
without of
the
estrogenic
and
stimulate
responses,
yet
are
found bound to the receptor
in the cytosol when the cell
homogenized
interpretation
(37).
homogenization compound
of
the
complex,
extracted
from
addition,
the
unfilled
The like
its
the
nuclear
unfilled
receptors
cell,
the
is
receptor-
unoccupied locus
receptors
that
of for
for thyroid hormone
estrogenic
receptor,
action. vitamin
is
upon
D
and dioxin
is
4.
In
and
the
(similar
to steroid receptors) have been reported to be nuclear
(38,
39, 40, 41).
CELL NUCLEUS
Estrogen
σα.
Figure 12. receptor.
Diagram
of
Induced Proteins
interaction
of
estrogen
with
its
560 Our
in
the
context
suggest
data
that
the
unoccupied
nuclear
in
receptor
the
near
intact the
of
the
cell
site
(Fig.
of
nuclear
nucleus hormone nuclear
when the
elements
and
the
is
cell
receptor
elements
is
cited
receptor
12).
action
absence of hormone, the receptor with
literature
estrogen at
This
all
places
develops
a
After
stronger
and resists extraction.
the
In
the
associated
extracted
homogenized.
mostly
times.
is only loosely usually
above
is
from
the
binding
the
affinity
for
kinetic
data
The
suggest that the receptor may be bound at all times to
its
site
the
of
action,
nucleus. in
the
and
is
not
a
soluble
protein
Although our data may apply only GH^
cell,
mechanisms makes
the
similarity
it tempting
of
the
to speculate
within
to the
receptor
steroid
receptor
that all
steroid
receptors are located in the nucleus.
References 1. Shull,
J.
D.,
(supplement), 292
Gorski,
J.:
Endocrinology
110
(1982).
2. Shull, J. D., Gorski, J.:
Fed. Proc. 42, 206
3. Shull, J. D., Gorski, J.:
Endocrinology
(1983).
114,
1550-1557
(1984) . 4. Shull,
J.
D.,
Gorski,
J.:
manuscript
submitted
for
publication. 5. Welshons, W. V., Lieberman,
Μ. E., Gorski, J.:
Nature
307, 747-749 ( 1984 ) . 6. Gorski, J., Welshons, W., Sakai, D.: 36, 11-15 7. Yamamoto,
Mol. Cell.
(1984). K.,
25, 645-658
Kasai,
K.,
Ieiri,
T.:
Jap.
84, 1475-1483 ( 1977 ) .
R.
J.
Physiol.
(1975).
8. MacLeod, R. M., Abad, Α., Eidson, L. L.: 9. Maurer,
Endo.
Endocrinology
(1969).
Α.,
Gorski,
J.:
Endocrinology
101,
76-84
561
10. L i e b e r m a n ,
Μ.
Ε.,
Maurer,
R.
N a t . A c a d . Sei. 75, 5946-5949 11. Stone, R. Τ.,
Maurer,
16, 4915-4921
Α.,
Gorski,
13. Seo,
R. Α . ,
Gorski,
J.:
H., R e f e t o f f ,
14. L i e b e r m a n ,
Μ.
S., V a s s a r t ,
E.,
16. Stack, G.: 17. K a s s i s ,
Maurer,
R.
G.,
Brocas,
H.:
Α.,
Claude,
P.,
Α.,
Gorski,
D.,
Seventh
Mellon,
S.
(1982).
J.
Biol.
Chem.
Shyamla,
Sei. 52, 1740-1743
Gorski,
Congress
J.:
Proceedings
of
Endocrinology
G.,
Gorski,
J.:
Proc.
Nat.
R e e . Prog. Horm. R e e . 2_4, 45-80 Ε.
V.,
(1968).
Suzuki,
Τ.,
23. S h e r i d a n ,
P.
Kawashima,
Stumpf,
P r o c . Nat.
J.,
Buchanen,
W.
Acad.
J.
M.,
Anselmo,
V.
C.:
(1979).
M e t h o d s in Cell Biology ]_, 211-249
W.,
2 6 , 360-366
Loeffler,
H.,
Bienz,
K.:
Exp.
(1973). Cell
Res.
(1975).
26. V e o m e t t , G . , P r e s c o t t ,
D.
M.,
Shay,
P r o c . N a t . A c a d . Sei. 71, 1999-2002 G.,
Spear,
B.
A c a d . Sei. T3, 1136-1139 28. T a s h j i a n , Α . , 47 , 61-70
Τ.,
( 1968) .
N a t u r e 282, 579-582 24. P o s t e , G.:
Notides,
(1968 ).
Ε., J u n g b l u t , P. W . , D e S o m b r e , Ε. R . : Sei. 5ji, 632-638
Acad.
(1967).
E n d o c r i n o l o g y 82/ 777-782
21. G o r s k i , J . , T o f t , D., S h y a m a l a , G . , S m i t h , D . ,
27. H e r r i c k ,
256,
(1984).
20. S t u m p f , W . Ε.:
25. Bossart,
Gorski,
(1983).
J.: R.,
International
D.,
22. J e n s e n ,
Proc.
(1981).
J.
A b s t r a c t 2140
Α.:
18,
(1982).
J. Biol. Chem. 257, 2133-2136
U.W. P h . D . T h e s i s
J.
7378-7382
19. T o f t ,
Biochemistry
(1979).
Mol. Cell. E n d o . 25, 277-294
15. M a u r e r , R. Α.:
18. Shull,
Biochemistry
(1979).
N a t l . A c a d . Sei. 76, 824-828 J.:
Proc.
(1977).
12. R y a n , R., Shupnik, Μ. Α . , G o r s k i , J . : 2044-2048
J.:
(1978).
Bancroft,
(1970 ) .
P.,
J.,
Porter,
K.
R.:
(1974).
Veomett,
G.:
Proc.
Nat.
(1976). F.,
Levine,
L.:
J. Cell
Biol.
562 29. Haug,
Ε.,
Naess,
0.,
Gautvik,
Κ.
Μ.:
Molec.
Cell.
Endocr. 12, 81-95 ( 1978) . 30. Haug, E., Gautvik,
Κ. M.:
Endocrinology
99,
1482-1489
(1976). 31. Welshons, W. V., Gorski, J.: 32. Notides,
A.
C.,
Lerner,
in preparation.
N.,
Nat. Acad. Sei. 78, 4926-4430 33. Sakai,
D.,
Gorski,
J.:
Hamilton,
D.
E. :
Proc.
(1981). 22,
Biochemistry
3541-3547
(1984) . 34. King, W. J., Greene, G. L.:
Nature 307, 745-747
(1984).
35. McClellan, H. C., West, N. B., Tacha, D. E., Greene, G. L.,
Brenner,
R.
M. :
Endocrinology
114,
2002-2014
( 1984) . 36. Jensen, E.
R.,
Ε. V., Greene, Nadji,
M. :
G. L·., Closs,
Ree.
Prog.
L.
Horm.
E.,
DeSombre,
Res.
3fi,
1-40
(1982). 37. Jordan, V. C., Tate, A.
C.,
Lyman,
Wolf, M. F., Welshons, W. V.:
S.
D., Gosden,
B.,
in preparation.
38. Walters, M., Hunziker, W., Norman, Α.:
J. Biol.
Chem.
255, 6799-6805 (1980 ) . 39. Samuels,
H.,
3488-3492
Tsai,
J.:
Proc.
40. Oppenheimer,
J.
H.,
Schwartz,
Koerner, D., Dillman, W. H.: 529-565
Acad.
Sei.
70,
Η.
L.,
Surks,
Μ.
Ree. Prog. Horm. Res.
I., 32,
(1976).
41. Whitlock, J. P., Galeazzi, 980-985
Nat.
(1973).
(1984).
D. R.:
J. Biol. Chem.
259,
CHARACTERIZATION
OF DIFFERENT
FORMS OF THE ANDROGEN
RECEPTOR
AND THEIR INTERACTION WITH CONSTITUENTS OF CELL NUCLEI
Eppo Mulder and Albert 0. Brinkmann Department of Biochemistry, Erasmus University Rotterdam, 3000 DR Rotterdam, The Netherlands
Introduction
It is now generally accepted that most, if not all, actions of steroid
hormones
are
mediated
by
an
effect
of
a
steroid
receptor complex on the transcription of specific parts of the genome in the nucleus (1). likely
interacts
with
In this process the receptor
chromatin
or
DNA
to
most
modulate
the
transcription of specific genes (2, 3, 4). Androgen
receptors
distribution.
are
characterized
by
a dipolar
charge
They are acidic proteins with an IEP of 5.8 (5)
and with a net negative charge at neutral or slightly alkaline pH.
Once the steroid has bound
protein,
the
resulting
to its intracellular
complex
undergoes
further
receptor changes,
termed a c t i v a t i o n , that increases its affinity for specific acceptor
sites within the cell nucleus.
Whether this process
o c c u r s e x c l u s i v e l y at the nuclear level is still a m a t t e r of debate but recently strong e v i d e n c e has been presented for a nuclear
locus
action (6, 7).
of
this
important
step
in estrogen
hormone
A c t i v a t i o n of androgen r e c e p t o r s is supposed
to be a c c o m p a n i e d by a change in the ionic p r o p e r t i e s of the complex
resulting
in a higher
isoelectric
point
(5).
dipolar behavior may represent an important characteristic relation to nuclear interaction. are reported and
Activated androgen
to bind to positively charged
nonhistone
basic
proteins
and
to
The in
receptors
chromatin
histones
negatively
charged
Molecular M e c h a n i s m of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
564 ribonucleic acids and nonhistone nuclear proteins (8, 9). Several forms of androgen receptors have been extracted nuclei
but
little
is
known
about
the
significance of these forms (10, 11, 12).
from
physiological
Alternatively the
occurrence of these different nuclear forms might
reflect
partial degradation of the native form during isolation as has been found for androgen receptors present in cytosol fractions of rat prostates
(13).
This chapter
deals with
different
aspects of the transformation process (activation) of androgen receptors to the nuclear binding state and the forms of the receptor
involved
in
this
characteristics
of
nuclear acceptor
sites and
receptor
with
forms
the
process.
interaction in vitro
DNA,
RNA
of
Furthermore
both
the
with
receptor
interaction of different
and
polynucleotides
are
described.
Results and discussion I
Characterization
οf the activation process of
androgen
receptors Activation of receptors can be accomplished by a variety of in vitro manipulations, such as heating, salt treatment, dilution or aging of the receptor preparations (14).
We have studied
this process for androgen receptors and have characterized the different changes that occur in the properties of the receptor during
this
interaction
process
with
respect
with polyanions,
to
sedimentation
dissociation
rate and
rate, charge
distribution. Interaction of androgen receptors from seminal vesicles of the ram with phosphocellul ose. Cytosols containing two distinct [ ^H ]-methy ltr ienolone
binding
proteins
(8S
and
4S)
were
565 dpm
χ ΙΟ"3
85
US
1
1
Α
ΧΑΛ dpm χ 10"2 C
KL
o-l
1
1
,
10
20
30
10
20
30
fraction number
F i g u r e 1_ B i n d i n g o f androgen r e c e p t o r s t o p h o s p h o c e l l u l o s e : a n a l y s i s by s u c r o s e g r a d i e n t c e n t r i f u g a t i o n . The l a b e l l e d c y t o s o l o b t a i n e d f r o m s e m i n a l v e s i c l e s o f t h e ram was s u b j e c t e d t o s u c r o s e g r a d i e n t c e n t r i f u g a t i o n ( f o r 210 min at 1°C in a Beckman V T i 65 r o t o r a t 3 7 0 , 0 0 0 χ g ) e i t h e r d i r e c t l y ( A ) , or a f t e r f i l t r a t i o n o v e r p h o s p h o c e l l u l o s e ( B ) . The r e c e p t o r s i n t h e r e s i d u a l f r a c t i o n p r e p a r e d as f o r p a n e l Β w e r e a c t i v a t e d and a g a i n s u b j e c t e d t o s u c r o s e g r a d i e n t c e n t r i f u g a t i o n b e f o r e (C) and a f t e r (D) f i l t r a t i o n o v e r p h o s p h o c e l l u l o s e .
incubated R1881,
with
affinity
for
sedimenting IB),
complex.
The
converted
the
3-4S
probably
Μ KCl.,
phosphocellulose
is a synthetic,
androgen
form
was
representing 8S
1A).
receptor.)
retained the
sedimenting
t o a 3-4S s e d i m e n t i n g
Sephadex
(fig.
(Methyltrienolone,
n o n - m e t a b o l i ζ able androgen w i t h by
was
form a f t e r
G-25 g e 1 f i 1 t r a t ion
the
high
slower
phosphocellulose
activated form
Only
(fig.
steroid-receptor almost
completely
incubation
and d i l u t i o n
with
(fig.
0.4 1C).
566 This
fraction
complexes, again
containing
originating
incubated
complete
with
retention
phosphoce1lulose
activated
androgen
from the n o n - a c t i v a t e d
phosphoce1lulose. of
the
(fig.
ID).
from p h o s p h o c e l l u l o s e
3-4S
This
sedimenting
extraction.
can be c o n c l u d e d
of
t h e a n d r o g e n r e c e p t o r can be c o n v e r t e d
faster
sedimenting
the n o n - a c t i v a t e d
form with a higher
D i s soc i a t i o n r a t e
οf
androgen
uterine
t issue.
cytosol
a temperature
complex
from a low a f f i n i t y
measurable
by
sedimenting in
at
calf
endogenous
the 5S
receptor,
in
(15,
16).
uterine
enzyme
binding
suppressed
of
(e.g.
obta ined in
the
calf
calf
uterine
steroid-receptor
dissociation the
state,
rate,
DNA-binding receptors with
activity. to
is
form
are
also
relatively
low
receptors
can
These
the e s t r a d i o l
androgens
form
from
to a high a f f i n i t y
a tissue
from
results
activated,
Androgen
tissue,
these
polyanions.
of
of
the
i n t o an
hormone
formation
independently
when
state
by
recovered
affinity for
receptor
change
in a
8S s e d i m e n t i n g
receptors
estrogen
induced
proteolytic
be measured properly
the
as a d e c r e a s e
accompanied present
For
form
From
it
was
resulted
The r e c e p t o r c o u l d be
by s a l t
that
receptor
8S f o r m ,
and
these
progesterone receptors
is
with a 500-fold excess
triamcinolone
molybdate
the
hormone-
androgen
receptor
acetonide). In
fig.
2 the
dissociation
effect
c o m p l e x e s i s shown. receptor
is
present
dissociation)
which
precipitation cytosol
in
capacity complex
the
with
is
at
a high
binds
to
of
(20
mM) on
these
of
from
observed. at low
affinity
DNA- o r
ammonium
the amount o f
transformation
25°C
In the a b s e n c e of m o l y b d a t e most of as
presence
increases
increase of
of
kinetics
state
phosphocellulose.
sulphate
of
the
20 mM m o l y b d a t e 5
to
65%
and
ionic
indicates
that
strengths,
the
the
(slow After
receptor
in
DNA-binding
concom i t t a n t l y
slowly dissociating
This
complex
an
steroid
receptor
molybdate
prevents
but does not
inhibit
567
Figure 2_ Dissociation rate at 25°C of R1881-androgen receptor complex from calf uterus. a) A c t i v a t e d f o r m , in t h e absence of molybdate. b) N o n activated form stabilized with 20 mM molybdate.
no
80 TIME
transformation
120 (min)
by high salt concentration.
have been described
for
the
foreskin fibroblasts (17).
androgen
Similar
receptor
findings
from
human
In sucrose gradients (0.4 Μ KCl)
all forms of the uterine androgen receptor sediment at 4.5S. A change
in sedimentation
value comparable
to the 4 to 5S
transformation as shown for estradiol receptors after receptor activation is not observed for the androgen receptor. These observations demonstrate
that transformation
androgen
with
receptor
to
a
form
polyanions and nuclear chromatin
a high
is accompanied
of the
affinity
for
by a 30-fold
increase in affinity for the steroid.
Anti-androgens
and
the
activation
of
androgen
receptors.
Because the role of the ligand in the transformation step of androgen receptors to the activated (i.e. DNA binding) state is hardly known the effect of androgens and the anti-androgen
568 cyproterone
acetate
on
the
activation
receptor
in the rat p r o s t a t e
In o r d e r
to e x c l u d e
tissue
obtained
from
[3H]-R1881
After
1
h
Metabolic R1881
were performed
castrated
(20 n M )
(18) a n d
the
were
incubation
with
The
show
incubation
3B
a nuclear
measured.
as
any
3.6S
in n u c l e i
after
anti-androgen.
exchange
were
The
Analogous
by e s t i m a t i o n Under
of
these
only w h e n
prostates
receptors
was the
further stability
dissociation
3A
ligand
the
nM
or
nuclear
of
χ
10-3
dissociated
acetate
t h a t of
constant
of
did
[3H]-R1881
was
could
(not be
shown). localized
obtained
cyproterone
the with
acetate
levels
androgen
be
nuclei
tissue with
were
using
receptors
incubated
with
with prostatic
receptor
in
vitro
anti-androgen
the
the
complexes complex
were at
min - -''. a
The
much
1 χ 10-2
min~l.
rate
with
studied 10°C. A s
to
complex For
of
the
shown at
in
this
approximately
receptor a
order
complex.
dissociated
anti-androgen
faster
in
androgen
receptor
R1881-receptor
kinetics
R1881-receptor
at
[3H]-
tissue
these
could
t e m p e r a t u r e w i t h a d i s s o c i a t i o n rate c o n s t a n t of 2.5
and of
the
receptor
conditions
the
this
fig.
results
investigated of
with
purpose
measured.
gradients
testosterone
in c o m p a r i s o n
radioactive
was
radioactivity
acetate
40
nM).
described
(18).
i n t e r a c t i o n of c y p r o t e r o n e
establish
in
extract
sucrose
(testosterone
assay.
measurable
minced
on
37°C
as
prostatic
only
of
salt
at (20
chromatography.
i n c u b a t i o n of t h e p r o s t a t i c
ligands
4 |ΛΜ) f o l l o w e d
that
cyproterone
tritiated
an
in a
peak
radioactive
unlabelled
layer
association
Radioactivity
sedimented Hardly
fig.
ligand
anti-
prostatic
incubated
isolated
minced
by thin
in
and
radioactive
not o c c u r , as w a s checked results
androgen
in vivo of the
[3H]-cyproterone acetate
d e g r a d a t i o n of
during
the
with minced
animals
nuclei
bound
of
[ 3 H ] - c y p r o t e r o n e acetate
and
incubation
previously
process
studied.
any rapid d e g r a d a t i o n
androgen, experiments
with
was
complex
dissociate
rate
569
Ln ( I Bound) 1.81 1.1 χ 1(P s i t e s / n u c l e u s R1881 , k _ 2 = 2 . 5 x 1 0 min
2.8 -
CA
_2
\ k _ 2 = 1 . 0 x 1 0 min
2.0 -
—I
1.2
1 120
60
30
—I
—I— 180
CA
R1881
210
minutes
Figure 3 A . D i s s o c i a t i o n k i n e t i c s a t 10°C o f a n d r o g e n c y t o s o l receptor complexes from r a t p r o s t a t e l i g a t e d e i t h e r w i t h [3H]-R1881 or with [3H]-cyproterone acetate. A represents the s t a b i l i t y o f t h e R 1 8 8 1 - a n d r o g e n r e c e p t o r c o m p l e x under t h e incubation conditions. B. A n d r o g e n r e c e p t o r l e v e l s i n p r o s t a t e n u c l e i 1 h a f t e r i n v i t r o i n c u b a t i o n a t 30°C o f m i n c e d p r o s t a t e s o b t a i n e d f r o m c a s t r a t e d r a t s w i t h 20 nM [ 3 H ] - R 1 8 8 1 o r [ 3 H ] - c y p r o t e r o n e a c e t a t e (CA).
The p r e s e n t receptors castrated acetate.
results
demonstrate
t o a DNA-binding rats
after
A possible
cyproterone
acetate
in
state
that is
vitro
incubation
explanation might
be
complex.
several
studies
cyproterone
specific
R1881
or
for
found
anti-androgen-receptor that
activation
impaired
in
the
with mode
the
Although
it
acetate
dihydrotestosterone
of
androgen
in p r o s t a t e s
cyproterone of
action
instability has can
receptor
from
been
of
the
shown
compete binding
of
in for
sites
570
the relative binding activity of the anti-androgen is low (18, 19, 20). The apparent lack of transformation of anti-androgenreceptor complexes found in the present study might therefore be explained in terms of a low affinity of the ligand and a rapid dissociation of the anti-androgen-receptor complex.
II
Molecular properties of androgen receptors
Multiple forms of the androgen receptor have been described (10,
11,
13).
(obtained containing receptors. between
Sedimentation
by sucrose gradient 0.4 Μ
KCl)
were
values
ranging
centrifugation
observed
for
from in
the
3-4.5S
gradients
transformed
Also for the nuclear receptor, forms with S-values
3 and
cytoplasmic
4S have
receptor
been
reported
involvement
(10,
21).
of proteolytic
For
the
enzyme
activity in the formation of the 3.0 and 3.6S forms in vitro has been described (13).
It can be envisaged that a similar
process might also occur in vivo in the nucleus. the
serine
protease
inhibitor
diisopropyl
Addition of
fluorophosphate
(5
m M ) and the thiol protease inhibitor leupeptin (0.25 m M ) to the buffers during not
isolation of the receptor from nuclei did
affect the sedimentation value
of the androgen receptors
Table I_ Size of androgen receptors obtained from different sources. Estimation of size in buffer with 0.4 Μ KCl after activation of the receptor. Small form
: 2.5-3.0 S; 1.8-2.2 NM; 20-30 kDa Rat prostate (non castrated rat) Ram seminal vesicle.
Intermediate form
: 3.6-4.0 S; 2.8-3.0 nm; 40-50 kDa Rat prostate.
Large form
: 4.5-5.0 S; 4.4-5.0 nm; 80-120 kDa Rat epididymis Calf uterus NHIK tumor cells
571
prepared
in
castrated) prostate
our
laboratory
o r ram s e m i n a l cytosol
is
from
prostates
vesicles
capable
to
(table
catalyse
of
I). the
S e £ a r a _ t i_££
of
differences. complexes steroid state
inhibitors
androgen Surface
receptor 15,
transformation
22,
23).
It
IEP o f
5.8 t o 6.3
more b a s i c opposite
to
receptors receptor
£Ü
steroid
for characterization
Obviously
androgen
and t h i s
the
that
DNA-binding in
for
shown
change
interaction
receptors
become
in s u r f a c e
of
charges
the complex
with
sites.
l i q u i d chromatography
(HPLC) o f
steroid
has been i n t r o d u c e d and was s u c c e s s f u l l y a p p l i e d forms
and
(24,
quantification
25).
In o r d e r
of
different
to c h a r a c t e r i z e
liquid
chromatography
system
for
steroid the
we a p p l i e d a n i o n
c h r o m a t o g r a p h y on a Mono Q column w i t h t h e r e c e n t l y protein
of
c o m p l e x i s a c c o m p a n i e d by a c h a n g e
p r o p e r t i e s of androgen r e c e p t o r s , "fast
£2ΐϋΕ£® receptor
of
c h a r g e d genomic a c c e p t o r
characterization
of the
activation
(5).
R e c e n t l y high p r e s s u r e
ί>££ί£
of
an a c t i v a t e d ,
has been
upon a c t i v a t i o n
m i g h t be i m p o r t a n t
££
changes
have been used a s p a r a m e t e r
(5,
forms in
shown).
£.££££i.££.£
charge
the a n d r o g e n - r e c e p t o r the
(not
(not
contrast
conversion
l a r g e ( 4 . 5 S ) t o i n t e r m e d i a t e and s m a l l r e c e p t o r absence of p r o t e a s e
rats In
ionic
exchange introduced
(FPLC)". T h i s
novel
approach to chromatography o f l a b i l e b i o m o l e c u l e s u s e s
columns
with
a
uniform
separation
and f a s t
increased
pressure
[^H]-R1881 prostate,
All
androgen
in
peak a t
receptor
allow
at only a
the
cytosol
presence
of
receptor
from
20 mM m o l y b d a t e
rat
eluted
0 . 3 2 Μ NaCl f r o m a Mono Q a n i o n e x c h a n g e with
activity the
fast
moderately
6 A ) . T h i s p e a k o f bound r a d i o a c t i v i t y
suppressed
constituting
which
flow c h a r a c t e r i s t i c s
labelled
column ( f i g .
spheres
(26).
prepared
as a s i n g l e completely
monodisperse
peak
a
was eluted
100-fold
molar
recovered at
0.32
in
could
excess the
of
be
R1881.
fractions
Μ NaCl and a
75-fold
572 purification of the androgen receptor was achieved in fraction 28 with a recovery of 71%. On sucrose gradients (high ionic strength) the FPLC peak sediraented as 3.6S entity, while a molecular
weight
of
48,000
was
found
chromatography. The molybdate-stabi1ized
after
ACA-44
gel
form of the androgen
receptor in cytosols prepared from rat epididymis and calf uterus were eluted
from the Mono Q column with a recovery of
85% and at the same ionic strength (0.32 M) as the prostatic androgen receptor. Further analysis of the eluted receptors on sucrose gradients and by ACA-44 gelchromatography
resulted in
Figure 4_ FPLC chromatography of androgen receptor complexes from the cytosol of rat prostates in the presence (A) or absence (B) of 20 mM sodium molybdate. 500 1 cytosol samples were applied on a Mono Q column. Elution was accomplished with a linear salt gradient (0-0.35 Μ NaCl). Each 1 ml fraction was assayed for total radioactivity. In figure Β only specific binding is represented.
DPM
χ
DPM χ
120 -
10
12 .
H-R. H - R , „ „ , + 100 f o l d molar e x c e s s 1881
R
1881
Μ
Μ
NaCl
r •*
40 -
NaCl
8-
- .2
.1
10
20 ml
30
40
2
-
-.4
573 sedimentation coefficients of 4-5S and molecular weights of 90,000
(see
also
table
I).
These
results
indicate
that
androgen receptors prepared in the presence of molybdate show a strong
interaction with anionexchange
resins,
indicating a
net negative surface charge of the molybdate stabilized Furthermore,
a
substantial
purification
of
the
form.
androgen
receptor could be obtained within a reasonable short time (40 min) . Prostate cytosol, prepared
in molybdate-free buffer, was also
analyzed on FPLC. The elution profile is shown in fig. 4B. A three-fold observed
reduction of the peak eluted at 0.32 Μ NaCl was
(recovery
receptor-like
35%).
In addition
androgen binding
were
three other peaks found,
indicating
of the
presence of multiple forms of the androgen receptor in the absence of molybdate. These multiple
forms eluted at a lower
ionic strength might represent androgen receptor which
became
procedure addition
activated
or
during
the
either
the
during
ionexchange
high proteolytic
the
complexes
homogenization
chromatography.
enzyme
activity
In
present
in
prostate cytosol might have caused further degradation of the androgen
receptor
due
to the
relative
instability
activated complex. Even generation of a mero-type
of
the
receptor
cannot be excluded (27; see table I, small receptor form). It is concluded powerful,
that
fast
tool
the for
FPLC-anion
exchange
characterization
system and
purification of steroid receptors. In addition
is a
partial
this technique
could be applied as a rapid procedure for the
quantitative
estimation of androgen receptors in small biological samples.
Εst imat ion
of
molecular
mass
of
androgen
receptors.
defining the molecular properties of the activated androgen
receptors,
several
investigators
have
By
form of used
the
elution volume during gelchromatography and the sedimentation coefficients
in sucrose gradients
for receptor
sizes and
the
574
ability
to
androgen
bind
to
receptor
DNA
for
receptor
proteins
are
activation.
extremely
Because
labile,
often
denaturation of the binding site occurs, which causes the loss of
the
(radioactive)
receptor
impossible.
ligand
and
In addition
makes
androgen
detection receptor
of
levels
the in
c y t o s o l p r e p a r a t i o n s of a n d r o g e n target tissues are 10 to 20 times
lower
than
progesterone molecular
the
generally
receptors.
mass
electrophoresis for
those
of
With
the
found
respect
receptors
application
of
this
to the e s t i m a t i o n
recently
has been successfully
attachment of the ligand
attached
to
conjugated
technique
proteins
is
and of
SDS-PAGE
prerequisite
the
covalent
to the steroid binding domain of the
in w h i c h
synthetic
also
applied. A
receptor m o l e c u l e (affinity labelling). have been published
for o e s t r o g e n
e.g.
Several p r o c e d u r e s
the steroid can be
via
covalently
photoactivation
of
highly
ligands and of ligands containing
groups
which become highly reactive upon irradiation with U.V. light. Chemical
linkages
acetylation steroids.
with
with
protein
bromo-
Affinity
or
might
be obtained
chloro-acetoxy
labelling
not
only
through
derivatives permits
of the
i d e n t i f i c a t i o n of p r o t e i n s p r e s e n t at very low abundancy in cytosolic
preparations
unequivocal
of
identification
stage of a purification
high
complexity,
of steroid
binding
but
also
the
proteins at any
procedure.
We have studied the molecular properties of a DNA-binding form of
the
androgen
affinity
receptor
labelling.
from
A partial
calf
uterine
purified
cytosol
(approx. 40
after times)
DNA-binding a n d r o g e n receptor p r e p a r a t i o n ligated w i t h
the
synthetic
and
androgen
ligand
[^H]-R1881
was
photolysed
s u b s e q u e n t l y p r e c i p i t a t e d w i t h t r i c h l o r o a c e t i c acid. A f t e r extraction
with
ethylacetate
the precipitate
was
solubilized
in S D S - s a m p l e buffer and applied on a 8% P o l y a c r y l a m i d e gel. A f t e r e l e c t r o p h o r e s i s the gel w a s sliced and each gel slice was
counted
for
radioactivity.
The
SDS-PAGE
profile
of
575
10
-τ
20 gel slice number
20 gel Stic« number
Figure A SDS-PAGE p r o f i l e s o f p h o t o l y s e d [3 Η]-R1881-cytοso X p r e p a r a t i o n s f r o m c a l f u t e r u s i n t h e p r e s e n c e o f 2.5 ^M t r i a m c i n o l o n e a c e t o n i d e . I r r a d i a t i o n of c y t o s o l was p e r f o r m e d a f t e r p a r t i a l p u r i f i c a t i o n w i t h ammonium s u l p h a t e p r e c i p i t a t i o n (40%) and D N A - c e l l u l o s e c h r o m a t o g r a p h y . D N A - c e l l u l o s e bound f r a c t i o n i r r a d i a t e d in the p r e s e n c e of 15 nM [ 3 H ] - R 1 8 8 1 ; D N A - c e l l u l o s e bound f r a c t i o n i r r a d i a t e d in the p r e s e n c e of 15 nM [ 3 H] -R1881 + 3 (ΛΜ d i h y d r o t e s t o s t e r o n e . SDS-PAGE profiles of photolysed [3H]-R1881 cytosol p r e p a r a t i o n s from ( W i s t a r ) rat p r o s t a t e a f t e r partial p u r i f i c a t i o n w i t h FPLC a n i o n e x c h a n g e c h r o m a t o g r a p h y , c y t o s o l + 5 nM [ 3 H ] - R 1 8 8 1 ο : c y t o s o l + 5 nM [ 3 H ] - R 1 8 8 1 + 500 nM R1881. photolysed uterus could 98,000
is
[3H]-R1881-androgen shown
be
detected
in f i g .
associated
D molecular
suppressed
additional
200-fold molar
present.
This
with
weight.
completely
finding
receptor
c o m p l e x e s from
5A. One m a j o r peak o f
in
The a
a protein radioactive
cytosol
excess
indicates
of
of
approximately peak
preparation
could where
dihydrotestosterone
that
calf
radioactivity
the s i t e s
to which
be an was the
576 ligand
is
cytosol
attached
20 t i m e s
are
saturable.
higher
f o u n d and t h e s y n t h e t i c progesterone
it
is very
t h e o b s e r v e d peak d o e s r e p r e s e n t D androgen
500-fold
molar
the
cytosol
receptor
excess
of
together
[3H]-R1881
binding
photoaffinity (a
resulted
two
in
the
to
in c a l f the
the of
tissue
Similar
favor
[3H]-R1881
progesterone
labelled
After
rats
as d e s c r i b e d fractions
or
protein
molybdate
at
of
represents
the
section
have
presence
uterine
mM).
native
form the
reported
that
study f o r
recently affinity
Whether
receptor
cytosol.
4 A ) . The
weight
in
The
peak
for
by a
the of
the
size
of
86
kD
receptor
labelling
for
of
the
prostate The
prostate
weight,
high
cytosol
despite
the
leupeptin
the
strain
In was
100-fold
the
PMSF ( 0 . 6 mM) and
from a d i f f e r e n t
(28).
of
receptor.
unanswered.
present
molecular
(20 mM),
molecular
calf
cytosol
androgen
remains
activities
androgen r e c e p t o r o b t a i n e d been
fig.
be s u p p r e s s e d
androgen
molybdate A
from
that
i s s h o w n . One m a j o r peak
which c o u l d
influenced
of
appearing
prostate
(see
dihydrotestosterone.
enzyme
bands
stabilized
with
on a Mono Q column d u r i n g FPLC
calf
labelled
the
proteolytic
second:
f u r t h e r p r o c e s s e d as d e s c r i b e d
46,000 D,
excess
rat
to
block
is concluded
receptor
with
added to
a
[3H]-R1881
98,000 D.
in the p r e v i o u s form of
with
of
first
either
androgen
performed the
was
in o r d e r
w i t h a MW of
was f r a c t i o n a t e d
ρhotoaffiηity
(0.25
the
5B t h e SDS-PAGE p r o f i l e
detected
might
were
27-29 w e r e
DNA-binding figure
of
is a protein
irradiation,
castrated
molar
form
the p r e s e n c e
receptor;
It
for that
and not
cytosol,
receptors
progestagen)
specifically
studies
were
to e s t a b l i s h
uterine
progesterone
synthetic
DNA-binding
uterine
levels
t h e androgen r e c e p t o r
a t 1 1 0 , 0 0 0 D and 8 1 , 0 0 0 D r e s p e c t i v e l y . uterine
calf
triamcinoloneacetonide
with
labelling
[3H]-R5020
important
r e c e p t o r . Two arguments
a 98,000
in
receptor
l i g a n d R1881 has a h i g h a f f i n i t y
receptors,
the p r o g e s t e r o n e
Since
progesterone
of
preparation
was m o r e p u r i f i e d
prostate rats used and
has in the
577 ligand
used
was
b r o m ο a c e t ο χ y d i h y d r ο t e s t o s te rone.
m e t h o d o l o g i c a l d i f f e r e n c e s might p r o b a b l y e x p l a i n extent
the
However,
discrepancies the
r e c e p t o r of activity
observed
observed.
molecular
proteolytic
of
46
kD
activity
in
the c o r t i c o i d
receptor
different
regions,
affinity,
one r e g i o n
region
that
is
a
might
androgen r e c e p t o r a s i m i l a r
enzymes.
weights
one
indicate
that
to
for
degradation
interaction
The a c t i v a t e d
androgen
for
for
but
including
receptor
chromatin,
interact
cibacron
blue
b u f f e r s were
of
displays
natural
2'5'-ADP
these
androgen
with and
and
by
proteolytic
is given
the
Under
d o e s not d i s s o c i a t e presence
the
an a f f i n i t y
RNA, is
of
a
molecule
obtained
for
rat prostates
from
added
with
to
nuclei, of
not
(10,
13,
low for
ionic
extraction
from of
are summarized
the
phosphate, strengths
the e x t r a c t i o n
DNA
cellulose reagents
binding
androgen
androgen in t a b l e
and the
region
binding
receptors II.
salt
inhibitors,
f r o m t h e r e c e p t o r , an i n d i c a t i o n
apart
30-35).
by high
these
chromatin
only
polyanions
Pyridoxal
effective
influence
separate
receptor
the
phosphoce1lulose,
disrupted
receptor.
heparin,
the
in
receptor
synthetic
sepharose
polyanions
shown t o be v e r y
receptors
sepharose.
binding
and a t h i r d
c o n c e n t r a t i o n s and i n a d d i t i o n by v a r i o u s o t h e r which
for
three
9.
nucleosomes,
and
with
as
sites
several
sepharose
Interactions
the
activated
steroid
such a s t r u c t u r e
Ill
of
the
affinity
in f i g .
nuclear acceptor
proteolytic
considerable
for
showing
DNA-binding
prone
Character!sties
with
androgen
can be p o s t u l a t e d
next s e c t i o n s and summarized
heparin
the
a receptor molecule with
region
with
most
tissue
structure
(29):
Further e v i d e n c e
DNA,
for
98 kD in a t i s s u e w i t h l o w e n d o g e n i c
and
These
to a certain
of
ADPsteroid for
the
in
the
site.
Data
from n u c l e i
of
578 Table II Extraction of labelled androgen receptors from nuclear pellets o b t a i n e d f r o m rat p r o s t a t e s i n c u b a t e d in v i t r o w i t h testosterone. extraction medium
fmoles receptor/100 mg tissue
buffer KCl, 0.4 Μ cibacron blue, 0.4 mM heparin, 0.2 mg/ml pyridoxal phosphate, 10 mM
8 53 45 60 53
Prostates obtained from one day castrated rats were incubated with 2.10 Μ [^H]-testosterone and in a parallel experiment with an additional amount of 2.10 - 6 Μ non-radioactive testosterone. A thoroughly washed nucler pellet was prepared and extracted for 1 h at 4°C. The amount of radioactive steroid extracted was estimated and corrected for nonspecifically bound steroid with the values obtained from the parallel incubation.
Cibacron
blue
localized
probably
acts
as
a
substance
cation exchange properties and
some
showing
both
hydrophobic
interactions. The lower optimal concentrations of heparin and Cibacron blue compared to pyridoxal phosphate required
for
interference with receptor binding to nuclear chromatin might indicate the involvement of a spatial arrangement of more than one negatively charged group separated by a less polar region. The effect of pyridoxal phosphate
might primarily
involve
binding of this molecule to an essential ε-amino group of the receptor
as was
first shown
for the corticoid
receptor by
Litwack and co-workers (36). The similarities for
the
in the effects of the various reagents used
extraction
elution of receptors suggests
of
receptors
from
that DNA-binding
from
DNA-cellulose is involved
nuclei
and
and related
for
the
matrices
in receptor binding
in
the nucleus, but do not necessarily imply that DNA is the sole m o l e c u l a r structure responsible for binding of the androgen
579
Figure Digestion with micrococcal nuclease of nuclear chromatin obtained from rat prostate nuclei with [ 3 H ] - D H T labelled androgen receptors. The sucrose density gradient profiles show both distribution of [ 3 H ] - D H T labelled receptors and different nucleosome fractions (the peak in the dotted line indicates the position of the mononucleosomes, sedimenting slightly faster than the marker with a sedimentation value of 11.2 S).
receptor to chromatin. In
studies
integrity
with of
nucleases
the
linker
Rennie
(30) observed
regions
of
the
that
nucleosomes
the in
chromatin is necessary for steroid binding and that most of the androgen receptor is associated
with fractions containing
large oligomers of nucleosomes. In addition we observed small amounts of 10S,
androgen-receptor
suggesting
complex
release of androgen
sedimenting
between
receptors partly
9-
coupled
to a chromatin fragment (fig. 6). Recent
studies
of
specific binding
Davies
by prostate
androgen receptors.
and
Thomas
(37)
showed
chromatin of partially
The highest binding capacity was observed
for oligonucleosome aggregates of up to twelve obtained
from
active genes.
the
tissue purified
fraction
enriched
in
nucleosomes
transcriptionally
580 IV
Interaction
of
androgen
receptors
with
DNA,
RNA
and
forms of
the
polyribonucleotides In our
studies
androgen ("3S",
we h a v e c o m p a r e d
receptor
castrated their
rats)
from
ability
to
On the
other
single
stranded
prostates,
interact
with
in t a b l e
different
to
with
the
"4S"
for
the
small
("4S",
from
with respect
polyanions. (fig.
DNA-sepharose
DNA) was r e d u c e d
compared
i.e.
I,
s t r o n g l y w i t h ADP-sepharose
hand b i n d i n g
particularly
rat
r a t s ) and i n t e r m e d i a t e
f o r m s as d e s c r i b e d
forms i n t e r a c t e d
when
obtained
from non-castrated
two d i f f e r e n t
Both
7).
(containing
mainly
the "3S" r e c e p t o r
receptor.
This
s i g n i f i c a n t when s m a l l amounts o f
to
form
effect
was
i m m o b i l i z e d DNA
w e r e u s e d and was n o t due t o d e g r a d a t i o n o f DNA, b e c a u s e
the
"3S"
The
receptor
preparation
specificity
of
the
preparations competitive
with
poly(UG)
are
sepharose of illustrates inhibits
The
the
of
of
form
to
high
investigated
"4S"
in
for
e.g.:
fragments
obtained
binding
from
of
a the
RNA and
binding
to
ADP-
the r e c e p t o r . F i g . 8
in
DNA-binding
calf
for
thymus DNA
the
hardly for
the
receptor.
receptor
perform
in
binding
( f i g . 8).
the
difference
obtained
sufficient
was s t r i k i n g
restriction
of
the "3S" f o r m , but c o m p e t e s w e l l
affinity
code f o r p r o s t a t i c were
was
androgen
inhibition
Double-stranded
the
polyribonucleotides for
using
significant
on the
form
and p o l y ( U ) ,
receptor
competitors
forms.
binding
The
(38).
the
complex to ADP-sepharose
be p r e p a r e d
purified (39).
assay,
potent
sites
"3S"
could
DNAse a c t i v i t y
b o t h " 4 S " and " 3 S " f o r m s o f
two r e c e p t o r binding
of of
nucleotides
binding
steroid receptor
was f r e e
interaction
a series of
the
of
poly(UG),
protein
regions
of
receptor
poly(AU),
genomic
with
clones
(39).
the
rat in
competition
"3S"
and c o n t r a s t e d of
from
quantities
partially experiments
for
certain
poly(I), the from
These
genes
prostates
a
low
genes
gene
which
poly(G) affinity which
fragments
contain
the
581
fmol bound
D i f f e r e n t i a l b i n d i n g o f two f o r m s o f t h e a n d r o g e n r e c e p t o r to A D P - a n d O N A - s e p h a r o s e .
20 '
ADP-s
1
DNA-s
4S
Figure 7_ Interaction of androgen r e c e p t o r s (25 f m o l e s ) e i t h e r in 3S- o r 4 S - f o r m w i t h 2 ' , 5 ' - A D P sepharose or DNA c e l l u l o s e . Each matrix c o n t a i n s a p p r o x i m a t e l y 10 pg of ( p o l y ) n u c l e o t i d e .
ADP-s
•
DNA-s
3S
Figure £ C o m p e t i t i o n e x p e r i m e n t s w i t h two d i f f e r e n t f o r m s of the androgen r e c e p t o r , ( f r o m 3 8 ) . BQ/B r e p r e s e n t s the r a t i o of androgen r e c e p t o r complex bound t o A D P - s e p h a r o s e in the absence (Bo) and presence (B) of a c o m p e t i t o r .
582 presumed hormone receptor binding site, located 5'-upstream from the transcription initiation site (40).
Our data suggest
that the "3S" form of the androgen receptor lacks the specific domain or conformation necessary for interaction with DNA, but retains a high affinity for certain forms of RNA. As discussed in the section on multiple receptor forms, the small
(3S) and
intermediate
(4 S) receptor
fragments of the transformed 4.5S receptor. speculate
that
forms
might
be
It is tempting to
in vivo transformation of the receptor to its
DNA-binding form is followed by processing to a form that has lost the ability to recognize specific binding sites on double stranded binding
DNA site
and
is
transported
through
its
away
binding
from
the
to RNA.
In
chromatin tissues
of
normal, mature animals the receptor would then be present for a substantial form.
part
in the intermediate
(4S) and small
(3S)
In this respect it is interesting to note that for rat
prostate nuclear receptors both a 3S form (11, 12, 21) as well as a 4S form (10, 12) have been reported.
Summary and conclusions Androgen
receptors
isolated
in a non-activated
(i.e. non-DNA-
binding) state can be converted in vitro to an activated (DNAbinding) state by treatment Activation of androgen increase
in affinity
with concentrated
receptors
salt
is accompanied
solutions.
by a 30-fold
for the androgen ligand and by a high
affinity of the complex for polyanions and nuclear
chromatin.
Mainly three different forms of androgen receptors could be isolated,
which
sedimentation certain
could
be distinguished
coefficients,
of their binding
polyribonucleotides,
estimated
by
denaturating
and
gelchromatography conditions
on
after
of and
their
basis of
to DNA, RNA and molecular
electrophoresis
affinity
their
labelling.
mass under It
is
583
TRANSFORMED ANDROGEN RECEPTOR
• 11 + 11 + I I I
hypothesized consists
of
that three
size
(region
high
affinity
fragment and
is
which
S)
kDa ( 1
S)
contains RNA.
formed
with
of
the
region the
regions
(*. 6S)
the monomeric androgen r e c e p t o r different
for
formof
different
kDa (3
15
80-120 kDa
contains
combination largest
I)
25
of
I,
regions
the s t e r o i d Together
and I I I
site
of
a
in t h e is
larger 45,000
Finally,
A model
receptor
in
and has a
II
approx.
domain.
results
molecule
smallest
region
weight
receptor.
androgen
the
binding
DNA-binding II
which
with
a molecular
androgen the
of
the
monomeric,
relating
shown
infig.
the 9.
Acknowledgements We
thank
Drs.
W.
de
Boer
and
J.A.
Foekens
for
their
584 contributions to this study and Dr. H.J. van der Molen for his many
helpful
discussions.
We
are
indebted
to Schering
(Berlin, FRG) for the supply of radioactive and
AG
radioinert
cyproterone acetate.
References 1. 2. 3. 4.
5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19.
Yaraamoto, K.R., Alberts, B.M.: Ann. Rev. Biochem. 45, 721746 (1976). O'Malley, B.W., Means, A.R.: Science 183, 610-620 (1974). Davison, B.L., Mulvihill, E.R., Egly, J.M., Chambon, P.: Cold Spring Harbor Symp. Quant. Biol. 47, 965-976. Yamamoto, K.R., Payvar, F., Firestone, G.L., Maler, Β.Α., W r ä n g e , 0, C a r 1 s t e d t - D u k e , J., G u s t a f s s o n , J.-A°., Chandler, V.L.: Cold Spring Harbor Symp. Quant. Biol. 47, 977-985 (1983). Mainwaring, W.I.P., Irving, R.: Biochem. J. 134, 113-127 (1973). King, W.J., Greene, G.L.: Nature 307, 745-747 (1984). Welshons, W.V., Lieberman, M.E., Gorski, J.: Nature 307, 747-749 (1984). Mainwaring, W.I.P., Symes, E.K., Higgins, S.J.: Biochem. J. 156, 129-141 (1976). Tymoczko, J.L., Liang, Τ., Liao, S.: In: O'Malley, B.W., Birnbaumer, L. (eds) Receptors and Hormone Action, Vol. 2, Academic Press, New York, pp. 121-156, 1978. Mainwaring, W.I.P.: The Mechanism of Action of Androgens, Springer-Verlag, New York 1977. Liao, S., T y m o c z k o , J.L., C a s t a n e d a , E., L i a n g , T: Vitamins and Hormones vol. 33, Academic Press, New York, pp. 297-317, 1975. M u l d e r , E., V r i j , Α., F o e k e n s , J.A.: M o l e c . C e l l . Endocrin. 23, 283-296 (1981). Wilson, E.M., French, F.S.: J. Biol. Chem. 254, 6310-6319 ( 1979) . Grody, W.W., Schräder, W.T., O'Malley, B.W.: Endocr. Rev. 3, 141-163 (1982). W e i c h m a n , B.M., Notides, A.C.: J. Biol. Chem. 252, 88568862 (1977). Bailly, Α., Le Fevre, B., Savouret, J.F., M i l g r o m , E.: J. Biol. Chem. 255, 2729-2734 (1980). Kovacs, W.J., Griffin, J.E., Wilson, J.D.: Endocrinology 113, 1574-1581 (1983). Brinkmann, Α.Ο., Lindh, L.M., Breedveld, D.I., Mulder, E., Van der Molen, H.J.: Mol. Cell. Endocrinol. 32, 117-129 (1983). Raynaud, J.P., Bouton, M.M., Moguilewsky, M., Ojasoo, T. Philibert, D., Beck, G., Labrie, F., Mornon, J.P.: J. Steroid Biochem. 12, 143-157 (1980).
585 20. Z a k a r , Τ . , T o t h , Μ.: J . S t e r o i d B i o c h e m . 17, 287-293 (1982) . 21. R e n n i e , P . S . , Van D o o r n , E., B r u c h o v s k y , N . : M o l e c . C e l l . E n d o c r . 9, 145-157 ( 1 9 7 7 ) . 22. H o l b r o o k , N . J . , B o d w e l l , J . E . , J e f f r i e s , M., Munck, Α . : J . B i o l . Chem. 258, 6477-6485 ( 1 9 8 3 ) . 23. B r i n k m a n n , Α . Ο . , B o l t - d e V r i e s , J . , De B o e r , W., L i n d h , L.M., M u l d e r E . , Van d e r M o l e n , Η.J.: J. Steroid. B i o c h e m . , in p r e s s ( 1 9 8 5 ) . 24. P a v l i k , E.J. Van N a g e l j r . J . R . , M u n c e y , M., D o n a l d s o n , E.S., H a n s o n , M., K e n a d y , D., R e e s , E.D., T a l w a l k a r , V . R . : B i o c h e m i s t r y 21, 139-145 ( 1 9 8 2 ) . 25. H u t c h e n s , T.W., W i e h l e , R.D., S h a h a b i , Ν . Α . , Wittliff, J . L . : J . C h r o m a t o g r . 266, 115-128 ( 1 9 8 3 ) . 26. S o d e r b e r g , L . , B e r g s t r o m , J . , A n d e r s s o n , K.: Protides B i o l . F l u i d s P r o c . C o l l o q . 30, 629-634 ( 1 9 8 3 ) . 27. S h e r m a n , M.R., P i c k e r i n g , L . A . , R o l l w a g e n , F.Μ., M i l l e r , L . K . : F e d . P r o c . 37, 167-173 ( 1 9 7 8 ) . 28. C h a n g , C . H . , L o b l , T . J . , R o w l e y , D . R . , T i n d a l i , D.J.: B i o c h e m i s t r y 23, 2527-2533 ( 1 9 8 4 ) . 29. C a r l s t e d t - D u k e , J . , O k r e t , S . , W r a n g e , O, G u s t a f s s o n , J . A ° . : P r o c . N a t l . A c a d . S e i . USA 79, 4 2 6 0 - 4 2 6 4 ( 1 9 8 2 ) . 30. R e n n i e , P . S . : J . B i o l . Chem. 254, 3947-3952 ( 1 9 7 9 ) . 31. D a v i e s , P . , T h o m a s , P . , B o r t h w i c k , N.M., G i l e s , M.G.: J . E n d o c r . 87, 225-240 ( 1 9 8 0 ) . 32. L i a o , S . , S m y t h e , S . , T y m o c z k o , J . L . , R o s s i n i , G . P . , C h e n , C . , H i i p a k k a , R . A . : J . B i o l . Chem. 255, 5541-5551 ( 1 9 8 0 ) . 33. M u l d e r , E., F o e k e n s , J . Α . , P e t e r s , M.J., Van d e r M o l e n , H . J . : FEBS L e t t e r s 97, 260-264 ( 1 9 7 9 ) . 34. M u l d e r , E., V r i j , L . , F o e k e n s , J . Α . : S t e r o i d s 36, 6 3 3 - 6 4 5 ( 1980) . 35. L i n , S . , Ohno, S . : Eur. J . Biochem. 124, 283-287 ( 1 9 8 2 ) . 36. C a k e , M.H., D i S o r b o , D.M., L i t w a c k , G.: J . B i o l . Chem. 253, 4886-4891 ( 1 9 7 8 ) . 37. D a v i e s , P . , T h o m a s , P . : J . S t e r o i d B i o c h e m . 20, 57-65 ( 1984 ) . 38. M u l d e r , E., V r i j , A . A . , B r i n k m a n n , Α . Ο . : B i o c h e m . B i o p h y s . R e s . Commun. 114, 1147-1153 ( 1 9 8 3 ) . 39. M u l d e r , E., V r i j , A . A . , B r i n k m a n n , Α.Ο., Van d e r M o l e n , Η.J., P a r k e r , M.G.: B i o c h i m . B i o p h y s . A c t a 7 8 1 , 1 2 1 - 1 2 9 (1984) . 40. P a r k e r , M., H u r s t , H., P a g e , M.: J . S t e r o i d . B i o c h e m . 20, 67-71 ( 1 9 8 4 ) .
DIFFERENTIAL SENSITIVITY OF SPECIFIC GENES IN NOJSE KIDNEY TO ANEROGENS AND ANTIANDROGENS
James F. Catterall, Cheryl S. Watson, Kinmo K. Kontula, Olli A. Jänne, C. Wayne Bardin The Population Council and The Rockefeller University, New York, N.Y. 10021
1230 York
and
Avenue,
Introduction Early studies on the action of testosterone emphasized t h a t t h i s steroid has a variety of actions on almost every organ in the bocfy. Those on the reproductive t r a c t were called androgenic while those on other organs were called anabolic actions. Androgen receptors were f i r s t identified in reproductive tissues such as prostate and seminal vesicle, and studies which showed t h a t antiandrogens could compete with testosterone or i t s metabolite, 5c(-dih/drotestosterone (DHT), for receptor binding s i t e s were the f i r s t t o clearly associate androgen receptors with the action of t e s tosterone and DHT. Hie ultimate proof, however, that androgen receptors were an essential link between testosterone and the androgen-induced g e n o type was the i d e n t i f i c a t i o n of receptor mutants in the r a t and mouse which were insensitive to mary of the e f f e c t s of testosterone and other androgens (1-4). Studies on these animals also emphasized that both the androgenic and the anabolic e f f e c t s of testosterone were mediated via androgen receptors (5).
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
588
The general concept of androgen action that has evolved holds that interaction of testosterone or EHT with the androgen receptor changes i t s conformation which allows i t to bind to an "acceptor s i t e . " In this manuscript the term acceptor is used to describe a functional site in chromatin to which the steroid-receptor complex binds. Current studies suggest that a portion of the acceptor s i t e i s formed ty a unique segment of DNA at the 5 '-end of hormonally responsive genes (6,7). Since the same gene is not responsive in all tissues, formation of acaeptor sites i s dependent upon organ specific differentiation, this iirplies that there are specific factors which are necessary for steroid-induced gene expression in some t i s sues. Interaction of the steroid-receptor complex with the acaeptor site results in the expression of genes which ultimately determines the hormone-induoed phenotype. Since the overall male phenotype for a given species i s relatively uniform, i t was assumed that androgen receptor interaction with acceptors resulted in the synthesis of a relatively uniform and characteristic group of mRNfts and proteins for a given organ, and that number of steroid receptor complexes on chromatin would determine the amount of each mRiR and protein produced. It was not known, however, how androgen receptor complexes were partitioned between the individual acaeptor sites of different genes. One possibility was that the receptor had the same affinity for each acceptor in the same way that each molecule of testosterone had equal acaess to activate each receptor binding site. If this were the case, then one might predict that the dose of testosterone (viiich ultimately relates to the nunber of receptors bound to chromatin in a given organ) required both to initiate and to produce maximal responses would be similar for most genes. Alternatively, androgen receptor complexes might exhibit differential a f f i n i t i e s for several acceptor sites. If this were the case, then the number of receptors required to initiate and to produce maximal activity would vary between different genes in the same cell. This latter possibility also predicts that the potency of a given androgen might not be strictly related to i t s affinity for a given receptor (5). Much of the work on androgen induced gene expression has involved analysis of the abundant gene products stimulated fcy androgens in the rat prostate (8,9) and seminal vesicle (10-12). However, no attempts were made in
589
these
studies to correlate specific gene expression with androgen receptor
dynamics or to compare the androgen sensitivity of these
different
genes,
the mouse kidney has become an irrportant syst an for the stud/ of the androgenic control of individual gene expression.
Gene-specific
complementary
DNA (cDNA) probes are now available for four mouse kidney mRNAs: two abundant species, kidney designated
MK908 (15)
androgen-regulated
protein
(KAP) (13,14),
an mRNA
and the non-abundant mRNfts for ornithine decarboxy-
lase (ODC) (16,17) and ρ-glucuronidase (ß-GLUC) (18,19). In the present review, we summarize studies in which we used cDNA probes for KAP, ODC and p-GLUC in establishing the patterns of gene-specific responses to testosterone in the mouse kidn^r. The availability of these cDNAs to one group of investigators permitted the simultaneous measurement of the mRNA accumulation in the kidne/s in response to a variety of stimuli. In addition, nuclear androgen receptor concentration has been correlated with the expression of each individual gene (20). The results reveal distinct responses of the three genes to physiological levels of testosterone, variations in nuclear receptor concentration, duration of hormone treatment, and to antiandrogens. Uie results are consistent with the hypothesis that androgen-responsive genes have differential sensitivities to the testosterone-androgen receptor complex.
Recent Advances in the Measursnent of Bound Nuclear Androgen Receptor Recent studies suggested that steroid receptors are nuclear However,
in
the absence
proteins (21).
of specific hormone, t h ^ are rapidly lost from
nuclei and are found in cytosol
when cells
are
disrupted
in hypotonic
buffers. When the appropriate steroid ligand is bound to the receptor, the conformation of this protein changes so that i t will bind to stituents.
con-
In this state, receptors are not readily lost into cytosol when
cells are broken. nuclear
nuclear
In this review these receptors are referred to as "bound
receptors." I t is these receptors that are believed to be bound to
acceptor sites and are correlated with hormone action.
590
The concentration of bound androgen receptor in renal nuclei of following
testosterone
treatment I d .xixp is
low
androgen-responsive tissues such as the prostate.
the mouse
relative
In addition,
to
other
apparent
receptor concentrations have varied under different conditions for preparation and extraction of nuclei.
For this reason, a rigorous analysis of the
various components of the nuclear receptor assay was undertaken in order to maximize i t s specificity and sensitivity (20). evolved
for
these
The assay
conditions
that
studies were based upon the observations that a large
fraction of bound nuclear androgen receptors was lost when nuclei were isolated
in
aqueous buffers and that another fraction of the bound receptors
was excluded from the final assay since i t could not be extracted ty KCL. To overcome these difficulties, nuclei were isolated hexylene
glycol (22)
in
the
presence
of
and bound nuclear receptor extracted with 5 mM j y r i -
doxal 5'-phosphate (20,23,24).
Nuclear receptor concentration was deter-
mined fcy incubating extracts, in triplicate, with a saturating concentration (22.5 nM) of [3H]methyltrienolone for 18 hrs at 4°C. total
Non-specific and
binding were determined in the presence and absence of a 1000—fold
molar excess of testosterone, respectively. f ran those
unbound ty
Bound ligands
adsorption to hydroxylapatite.
were
separated
Using these assay
conditions, 3-4 times more bound nuclear receptors are measured than when aqueous buffers are used for nuclear isolation and KCL is used for extraction.
Cloned cDNA Probes for mRNAs that Exhibit Unique Responses to Androgens For studies of differential gene expression in mouse kidney,
specific hybridization probes. which
codes
response
to
androgens
in
we have measured concentrations of three mRNAs with gene Hie KAP mRNA is an abundant gene product
for a protein (Mr=20,000) of unknown function.
The other two
are low abundance mRNAs which code for the androgen-induced renal p-GLUC and ODC.
enzymes,
591
Complementary DNA piasmids were prepared for each mRNA using two different approaches.
Since
KAP mRNA was shewn to be approximately 100-fold more
abundant than ODC or p-GLUC mRNA, KAP mRNA was purified
by
extraction
of
total mRNA from kidneys of androgen-treated fanale mice followed ty sucrose density phy (14).
gradient
centrifugation and
0.02%, respectively, of the c e l l ' s purified
oligo(dT)-cellulose
chromatogra-
CDC and p-GLUC mRNAs, which represent approximately 0.05% and from renal
mRNA after
followed by chromatography on protein modification of
androgen treatment,
were
polysemes fcy imminoadsorption to specific antibodies A-Sepharose (16,18).
This was a
the imrrunoadsorbent chromatographic method of Shapiro and
Young and resulted in a 300-fold purification of the ODC and p-GLUC mRt&s. The additional steps introduced into the procedure (16,18) (including passing of polysomes through protein A-Sepharose prior use
to antibody
addition,
of the ribonuclease inhibitor, RNasin, and inclusion of a high concen-
tration of heparin in the buffers) increased the purity of the two mRNAs. Purified mRJRs were assayed fcy translation _i_D vitro and used as for
preparation of
cDNA plasmid libraries.
ferential colory hybridization. and
templates
Ihese were screened by d i f -
In the case of KAP cDNA clones, the "plus"
"minus" probes were prepared from KAP mRNA-enriched gradient fractions
and mRNA from female mouse kidney, respectively.
A similar assay
for CDC
and p-GLUC cDNA clones was devised using probes prepared from protein ASepharose-bound ("plus") and drop-through tions.
In each case,
("minus")
polyscmal
colonies that preferentially bound the plus probe
over the minus probe were selected for further analysis. tion
of
RNA frac-
Final identifica-
the cDNA clones was made fcy hybridization-selected translation j j j
vitro, which correlated individual cDNA plasnids with
each
specific mRNA
activity.
Acute Response to Testosterone Following a single injection of a large dose of testosterone (10 mg), bound nuclear androgen receptor concentration increased to reach a maxinun at one hr.
By 2 hrs the receptor level was s t i l l seven times the control level or
592 182 fmoles/mg DNA (Fig. 1 ) . the receptor concentration in the nuclei then decreased ty approximately 50% over the next 48 hrs. The measurements of specific mRNAs indicated that there was no change at or before 2 hrs when receptor levels were highest. Thereafter, the response of these three mRNAs t o a single dose of testosterone varied greatly, emphasizing the d i f ferential effect of the hormone on genes in the same tissue. CDC and KAP mRNAs responded rapidly, increasing 2 . 1 - and 1.6-fold in 6 hrs, respectively . Hcwever, KAP mRNA was alnost maximally stimulated at this interval in that i t increased to only 2-fold by 48 hrs while CDC mRNA continued to accumulate to over eight times the untreated level fcy 24 hrs. p-GLUC mRNA remained unaffected until between 12 and 24 hrs of treatment when the f i r s t increase was detected; thereafter, i t rose to 1.7 times the control value a t 48 hrs. In another stud/, p-GLUC mRNA concentration reached maximal levels after 14 days of continuous androgen administration. These results indicated that for p-GLUC the lag before the f i r s t detectable response was evident and the time to reach the maximal response were strikingly d i f ferent from those of the other two genes. Hie magnitude of the increases in mRNA concentrations in these studies was determined ty densitanetric scans of autoadiograns of transfer blot hybridizations. This semiquantitative method revealed relative increases, rather than absolute values. Hcwever, t h i s type of analysis i s valid when comparing the proportional responses of several genes in the same tissue to hormones and/or drugs (Fig. 1). the results shown in Figure 1 indicate a differential responsiveness among the
three
genes
in
the
presence
of maximal levels of nuclear androgen
receptors after a single dose of testosterone. that,
in
addition
to
the
initial
response i s in part dependent on the receptor
complex
Previous studies
suggested
receptor concentration, the androgen length
of
time
remain tightly bound in nuclei (24).
that
the
androgen
I t was, therefore,
of interest to determine the relative expression of the three genes in presence
of
constant
submaximal
nuclear receptor levels.
the
To do t h i s we
determined the response of each mRNA to the physiological testosterone concentration present in normal male mice.
593
TIME AFTER TESTOSTERONE (h)
Figure Is Changes in mRNA accumulation and nuclear androgen receptor concentration a f t e r a single doee of testosterone. Testosterone (10 mg) was administered ty intraperitoneal injection of 0.2 ml of ethanol/sesame oil (1/9? v/v) t o female NCS mice. At the indicated times poly (A)-mRNA was prepared from kidney extracts and analyzed ty electrophoresis and blot transfer hybridization. Autoradiographs of each transfer f i l t e r were scanned with a densitometer (Shimadzu model CS-910). The untreated female level was assigned the value of 1. Androgen receptor measurements were made ty an exchange assay on nuclear extracts prepared from identically treated animals. Nuclear androgen receptor, (AR^) values represent the mean of 3 experiments. Kidneys from four animals were pooled a t each time point in a l l experiments. Abbreviations: KAP, kidney androgen-induced protein; ODC, ornithine decarboxylase; p-GLUC, ρ-glucuronidase.
594
The Effects of Endogenous Testosterone The relative differences in mRNA concentrations in intact females and intact males are shown in Table I. In each case, physiological amounts of testosterone secreted ky the t e s t e s of the male mice were s u f f i c i e n t t o cause an increase in mRNA concentration over the values in female animals. Hcwever, there was a major difference among the three genes as measured ky the abundance of t h e i r mRNAs. The autoradiograms of the Northern blots from which the data were derived were exposed t o achieve comparable s i g nals; t h i s required 24- and 13-fold longer exposure times for ρ-GLöC and ODC mRNAs, respectively, than for KAP mRNA. Table I Relative concentration of three mRNAs in intact female and male mice. Each mRNA concentration i s expressed as a percent of t h a t obtained a f t e r maximal stimulation with testosterone for 7 days. Gene KAP CDC p-GLOC
Female % 35 10 5
Relative mRNA Concentration Male % 100 30 35
Table I also indicates the extent t o which the individual RNAs could be increased with a maximal dose of exogenous hormone. Once again, variation among the gene products was evident. While p-GLUC and CDC mRNA concentrations were further increased ty exogenous testosterone administration, KAP mRNA was unaffected. Hie concentrations of androgen receptor in the nuclei of female, male and testosterone-treated male mice are shewn in Table I I . The receptor level in females was approximately 50% of that of intact males, whereas chronic testosterone treatment increased the level in males f i v e - f o l d . These l a t t e r nuclear receptor values represent the maximal concentrations attainable in mouse kidney and are associated with f u l l expression of CDC and p-GLUC genes. I t remains t o be elucidated, hewever,
595
whether
maximal
accumulation of these two mRNAs indeed requires t h i s high
nuclear receptor concentration. ferential
sensitivity
concentrations.
Taken together, these
suggest
of
at
a
nuclear androgen receptors, as i t cannot be further
stimulated by pharmacological steroid concentrations physiological
dif-
of the three genes t o lew nuclear androgen receptor
Maximal expression of the KAP gene appears to occur
low concentration with
data
hormone levels.
bound nuclear receptors resulted in
above
that
achieved
By contrast the same concentration of CDC and p-GLUC mRNft concentrations
which were only 30 and 35 percent of maximal. Table I I Concentrations of bound androgen receptors in renal nuclei fran intact female, intact male, and testosterone-inplanted male mice. Animal group Intact females Intact males Testosteroneinplanted males'3
Androgen receptor concentration 3 150 + 60 280 + 100 1,540 + 390
(13) c ( 6) (5)
The receptor concentrations (mean + SD) are expressed as molecules/cell assuming that receptors are evenly distributed within the kidney with 6 pg DNA/cell. a
^The animals were treated with testosterone-containing inplants (release rate, 200 yg steroid/day) for 7 days. c
Aninals per group are shown in parenthesis.
KAP mRNA i s Induced by Testosterone in Androgen Insensitive Tfn/Y Mice The androgen insensitive Tfn/Y mouse i s resistant to almost a l l of the actions of testosterone even when high doses are administered (25,26). In t h i s respect, i t differs fran the Tfm rat which has a reduced quantity of presumably normal androgen receptors and responds in a dose-dependent manlier to a 200-fold higher amounts of testosterone than normal rats (27-
596
29).
the Tfn/Y mouse also has a low concentration of androgen receptor but
i t i s disputed whether these are normal or mutant receptors (30-32). The relative concentrations of the three mRNAs were determined after
testosterone
treatment
of
Tfn/Y mice.
treatment increased the KAP mRNA concentration that
found
in
the
before
Unexpectedly, testosterone approximately
kidneys of untreated animals.
2-fold
These
observations
respond t o the lew
suggested
concentration
of
that
androgen
over
Neither CDC nor p-GLUC
mRNA concentrations were significantly affected fcy testosterone animals.
and
the
in
these
KAP gene was able to
receptor
in
Tfn/Y
mice,
whereas the CDC and p-GLUC genes were not. These results do not resolve the issue as to whether the receptors in Tfn/Y mice are normal. I f the receptors in these animals are the same as wildtype, the results could be interpreted as indicating that the KAP gene responds to a lewer concentration of bound nuclear receptors than almost ary other gene in the mouse gencme. Alternatively, i f the receptors in Tfn/Y mice are abnormal, then the acceptor for KAP must be sufficiently different frcm that of other genes to accommodate the mutant receptor.
Differential Inhibition of Individual mRNAs fcy Flutamide IVie results reported above complex
indicate
accumulation, expression
these results also
is
testosterone-androgen
suggest
that
this
differential
very
variation
in
gene
If this i s the case, then one would
gene responses when the availability of receptor com-
plexes i s changed in the presence of an antiandrogen, is
receptor
due to the different responsiveness of each gene to a given
amount of androgen-receptor complexes. expect
that
interacts with dissimilar genes to produce unique patterns of mRNA
sensitive
to
that i s , a gene that
low concentrations of androgen-receptor complexes
should be more resistant t o antiandrogens since there would always be a few receptors antagonist. containing
occupied
ty testosterone even in the presence of large doses of
Accordingly, Silastic
female
animals were
treated
with
flutamide-
rods (releasing either 150 jug/day or 650 jjg/day) with
597
Table III Inhibition of testosterone-induced mRNA accumulation fcy flutamide Treatment group T*3 Τ + Fl Τ + F2
iLeJLative_SQ^J^ajAor^ .KAP
ODC
ß-GLUC
4.5 3.7 3.4
5.0 2.9 0.7
11.6 5.1 1.0
*Hie mRNA concentration i s expressed relative to the untreated female level (1.0) of each group.
a
^Female NCS mice were inplanted with Silastic rods containing testosterone (T, release rate: 40 jug/day) alone or in combination with similar inplants of flutamide (Fl, 150 ;ug/day; F2, 650 Mg/day). Renal poly(A)-mRNA was prepared after 8 days of treatment. Table IV. SuraTary_of Jielative _Gene^Sgeci f i c JResgonses in _Mouse JÜdney.^ Animal/treatment group
KAP
ODC
g-GLoc__
Female Male Male + Τ
++ ++++ ++++
+ ++ JJJJ
+ ++ ±±++
Duration of Treatment 12-24 hrs 2 days 14 days
++++ ++++ ++++
+++ ++++ +Ü+
+ ++ ++++
+ +
+ _+
++++ +++ +++
++++ ++ +
Tfn/Y Tfn/Y + Τ Female + Τ Female + Τ + Fl Female + Τ + F2
++-H++ +_.
^Ihis table i s presented as a brief summary of the qualitative differences in sensitivity of the three gene markers to various conditions of androgen exposure. The qrmbols do not represent quantitative changes. T, testosterone; Fl, F2, flutamide, 150 and 650 /jg/day, respectively. and without testosterone-containing rods (releasing 40 jig/day). Hie results dicwn in Table I I I suggest that the sensitivity of the three mRNAs
598
to flutamide was essentially the inverse of their terone.
sensitivity
to
testos-
KAP mRNA, which was shewn t o be unusually responsive to testos-
terone, was l e a s t affected ty the non-steroidal antagonist. mRNAs were both
ODC and p-GLUC
much more sensitive to flutamide inhibition in that l e s s
than 10-15% of the testosterone-induoed mRNA concentrations remained treatment
with
the higher dose of antiandrogen.
after
Flutamide alone resulted
in no significant variation in the concentrations of
ary
mRNA (data
not
shewn).
Summary and Conclusions 1. Androgens stimulate the epithelium of the proximal tubule c e l l s of the mouse kidney to increase the s/nthesis of several proteins (5). Cloned complementary DNA probes have recently been prepared and characterized for the mRNAs for three of these proteins: p-GLUC (18,19), ODC (16,17), and KAP (14). Previous studies had shown that p-GLUC and ODC enzyme a c t i v i t i e s were regulated differently by testosterone in t h i s tissue (24,33) in that ODC responded t o testosterone with more rapid kinetics than p-GLÜC. KAP induction kinetics have not been demonstrated as the protein has been ident i f i e d only fcy translation j j j j ö t r P (13). KAP mRNA i s a relatively abundant species while those of p-GLUC and ODC were of the non-abundant mRNA class. Hie availability of these three gene-specific probes allowed us t o measure a unique spectrum of responses t o testosterone. 2. In order to fully characterize the regulation of renal
gene
expression
fcy testosterone, i t was necessary to measure the concentration of the bound androgen receptor in nuclei under the same conditions as the sion
studies.
A reliable
gene
expres-
method for the measurement of bound androgen
receptor in mouse renal nuclei was established (20). 3. In t h i s stuc^ a general trend of androgen with
the
following
ranking:
KAP mRNA »
sensitivity
was
established
ODC mRNA > p-GLUC mRNA. The
results suggest gene-specific variations in response were related t o tion
of
exposure
to
dura-
testosterone, physiological levels of testosterone,
599 concentration of bound nuclear androgen receptors, and treatment by antiandrogens (Table IV). 4. As the bound androgen receptor concentration in kidney nuclei was maximal ty 1 hr a f t e r a single steroid do9e, i t i s clear that subsequent biological responses which occurred over the next 4-48 hrs were determined in part by factors other than the i n i t i a l receptor concentration. Indeed, our previous studies have suggested t h a t , under these conditions, i t i s the product of nuclear receptor concentration and the residence time of the receptor that predicts the biological response (24). This product appears t o be, however, dissimilar for the three mRNAs studied. In accordance with t h i s notion, Watson .et ü l . (34) hypothesized that a minimum number of receptor molecules must bind in the region of the [Gus] genetic complex in chromatin in order t o achieve an induction response. This hypothesis i s now extended t o include d i f f e r e n t i a l kinetics of interaction between androgen receptors and chromatin binding s i t e s on separate genes consistent with the data presented here. Furthermore, i t has been suggested that effector molecules such as steroid hormone receptors bind t o nuclease sensitive domains in chromatin (35,36). Differential responsiveness of individual genes t o a hormone may reside in the size and/or complexity of the "active" domain with which the receptor must interact. 5. A related hypothesis was developed in order t o explain the differences in expression of the conalbumin and ovalbumin genes in response t o steroid hormones (37). In t h i s case, multiple binding s i t e s for the steroid receptor were postulated for the l e s s sensitive gene which thus requires longer duration of treatment or higher receptor concentration t o become f u l l y induced. The same d i f f e r e n t i a l responsiveness could also be explained if the acceptor of various genes bound receptor complexes with d i f f e r e n t effectiveness. The r e s u l t s reviewed here provide evidence in support of such a hypothesis based on gene-specific sensitivity t o the androgenreceptor complex. The KAP gene, which i s the most hormonally "sensitive" gene studied, i s maximally induced in males fcy physiological testosterone levels. Thus, the KAP gene m^ require the fewest nrntber of bound receptor-androgen complexes for activation because i t s acceptor has either multiple binding s i t e s or a high a f f i n i t y for receptors.
600 6. Ihe results reviewed here shew that androgen-resistant Tfir/Y animals exhibit a condition in which receptor concentration appears adequate with respect to the KAP gene, but too 1CM to have e f f e c t s on ODC or p-GLUC mRNA, even with pharmacological doses of androgens. The induction of KAP mRNA in Tfn/Y animals suggests that a l l or part of the androgen receptor in this variant (30-32) is biologically active. The results do not exclude the possibility that these androgen receptors ma/ be qualitatively different from wild-type receptors (38), but s t i l l capable of effecting the response of KAP mRNA. Further experiments will be required to distinguish this from other p o s s i b i l i t i e s . 7. Hie antiandrogen flutamide was also androgen
sensitivities
of
the
used to
three
evaluate
the
dissimilar
gene products in mouse kidney. We
reasoned that expression of the most sensitive gene should be affected to a lesser
extent than those requiring higher concentrations of nuclear andro-
gen receptors for f u l l expression. sensitivity
On the basis of
differential
of the three genes observed in other experiments, the KAP gene
was predicted to exhibit the least inhibition fcy flutamide, while gene was expected to be l e s s affected than that of p-GUJC. tions were verified providing further evidence that the stimulated
androgen the CDC
ihese predic-
KAP gene
can be
a t very low functional receptor levels, consistent with a lewer
required threshold of androgen receptor binding to chromatin s i t e ( s )
asso-
ciated with this gene.
Acknowledgement This work was supported fcy NIH grants HD-13541 and 3 F05 TW3192-0151.
We
wish to thank Ms. Susan Richman for preparing the manuscript.
References 1. 2.
Iyon, M.F. and Hawkes, S.G.: Nature Lond. 227,1217-1219 (1970). Bardin, C.W., Bullock, L . , Schneider, G., Allison, J . E . , and Stanley, A . J . : Science l£7fH36-1137 (1970).
601
3.
Bullock, L. and Bardin, C.W.: J. Clin. Endocrinol. Metab. (1970).
4.
Bullock, L . P . , Bardin, C.W., and Ohno, Commun. M , 1537-1543 (1971).
5.
Bardin, C.W. and Catterall, J.F.: Science 211,1285-1294 (1981).
6.
Compton, J.G., Schräder, W.T., and O'Malley, B.W.: Proc. Natl. Sei. USA _8£), 16-20 (1983).
7.
Gustafsson, J.A., Carlstedt-Duke, J . , Okret, S., Wikstrom, A.C., Wrange, 0 . , Payvar, F . , and Yamamoto, K.: J. Steroid Biochem. 2Qr 1-4 (1984).
8.
Page, M.J. and Parker, M.G.: Cell 32,495-502 (1983).
9.
Dodd, J.G., Sheppard, P.C., .258,10731-10737 (1983).
and
S.:
Matusik,
Biochem.
R. J . :
.21,113-115
Biophys.
J.
Biol. Acids
Res.
Acad.
Chan.
10.
Mansson, P.-E., Sugino, Ε., and 5,935-946 (1981).
Harris,
S.E.:
Nucleic
11.
Kandala, J.C., K i s t l e r , M.K., Lawther, Nucleic Acids Res. 11,3169-3186 (1983).
R.P.,
and
12.
McDonald, C., Williams, L . , McTurk, P., Fuller, F . , Mclntoäi, Ε., and Higgins, S . : Nucleic Acids Res. 11,917-930 (1983).
13.
Toole, J . J . , Hastie, N.D., and Held, W.A.: Cell 17,441-448 (1979).
14.
Watson, C.S., Salomon, D., and Catterall, J.F.: Ann. (in press) (1984).
15.
Berger, F.G., Gross, K.W., and Watson, G.: J. B i o l . 7013 (1981).
16.
Kontula, K.K., Torkkeli, T.K., Bardin, C.W., and Janne, Natl. Acad. Sei. USA ül,731-735 (1984).
17.
McConlogue, L . , Gupta, Μ., Wu, L . , and Coffino, P . : Proc. Natl. Acad. Sei. USA jJl,540-544 (1984).
18.
Catterall, J.F. and Leary, S.L.: Biochemistry 22,6049-6053 (1983).
19.
Palmer, R., Gallagher, P.M., Bcyko, W.L., and Ganschcw, Natl. Acad. Sei. USA _8£>,7596-7600 (1983).
20.
Isanaa, V . , Pajunen, A . E . I . , Bardin, C.W., and Janne, O.A.: nology 111,833-843 (1982).
Kistler,
NY Acad.
Res. W.S.:
Sei.
Chem. 256,7 0 06O.A.:
R.E.:
Proc.
Proc.
Endocri-
21.
Greene, G.L., Sobel, N.B., King, W.J., and Jensen, E.V.: Blochen. 20,51-56 (1984).
22.
Wriy, W., Conn, P.M., and Wr a / , V.P.: Meths. Cell Biol. .14,69 (1977).
23.
Cidlcwski, J.A. and Hianassi, .22,1140-1146 (1978).
24.
Pajunen, A.E.I., Isomaa, V.V., Janne, Biol. diem. 257,8190-8198 (1982).
25.
Bardin, C.W., Bullock, L.P., Sherins, R. J . , Mowszowicz, Blackburn, W.R. s Ree. Prog. Hormone Res. 25,65-109 (1973).
26.
Sclienkein, I . , Levy, Μ., Bueker, E.D., and Wilson, J.D.: ogy .24,840-844 (1974).
27.
Sherins, R. J . , Bullock, L., G ^ , V.L., Variha-Perttula, Τ., din, C.W.: Endocrinology .28,763-770 (1971).
J.W.: Biochem. O.A.,
Bioptys.
J.
Pes.
and Bardin,
2fi. Grosanan, S.H., Axelrod, Β., and Bardin, C.W.: Life (1971).
Steroid
Comm.
C.W.:
J.
I.,
and
Endocrinol-
Sei.
and Bar15,175-180
29.
Sherins, R.J. and Bardin, C.W.: Endocrinology .29,835-841 (1971).
30.
Attardi, B. and Ohno, S . : Cell 2,205-215 (1974).
31.
Gehring, U. and Tonkins, G.M.: Cell 3,59-64 (1974).
32.
Fox, T.O.: Proc. Natl. Acad. Sei. USA 12 , 4303-4307 (1975).
33.
Swank, R.T., Paigen, Κ., Davey, R., Chapman, V., Labarca, C., Watson, G., Ganschow, R., Brandt, E . J . , and Novak, E.: Recent Prog. Horm. Res. 34,401-436 (1978).
34.
Watson, G., Davey, R.A., Labarca, C., and Paigen, K.: J . Biol. 256,3005-3011 (1981).
35.
Lawson, G.M., Knoll, B. J . , March, C. J . , Woo, S.L.C., Tsai, O'Malley, B.W.: J . Biol. Oian. 257,1501-1507 (1982).
36.
Bloom, K.S. (1982).
37.
Pal miter, R.D., Mulvihill, E.R., Shephard, J.H., and McKnight, J . Biol. Chem. 255,7910-7916 (1981).
38.
Fox, T.O. and Wieland, S. J . : Endocrinology JJ29,790-791 (1981).
and Anderson,
J.N.:
J.
Biol.
Chem.
M-J,
and
Chem. 257,13018-13027 G.S.:
MOLECULAR PHARMACOLOGY ANTITUMOR V. Craig
PROPERTIES
OF TAMOXIFEN;
IN A N I M A L S A N D
AN Α Ν Τ Ι E S T R O G E N
WITH
MAN
Jordan
D e p a r t m e n t of H u m a n O n c o l o g y , W i s c o n s i n C l i n i c a l Center, U n i v e r s i t y of W i s c o n s i n , Madison, W I USA
Cancer 53792
Introduction In 1 9 5 8 ,
Lerner and coworkers
cal p r o p e r t i e s of M E R (Fig.
1).
25,
The compound
the
(1) d e s c r i b e d
(1-3).
Clinical
antiestrogenic
activity
and the o c c u r r e n c e alternatives.
trials with MER
25 h a s
(5).
clomiphene
Although
animals, The
the d r u g
commercial
is n o w r o u t i n e l y
used
derivatives tested
however,
f o c u s of
breast cancer. (ICI
46,474)
effect
for
only
for
than MER
25,
Nafoxidine
(10,11)
in
animals
properties
in
in s u b f e r t i l e w o m e n a mixture
of
(enclomiphene)
for the
(6).
estrogenic geometric
i n d u c t i o n of
of
triphenylethylene 1970's
ovulation
were
tamoxifen
have
investigators
from contraception
upon the clinical
however,
a search
been
antiestrogenic/antifertility
in t h e e a r l y
research
potency
(7).
synthesized the
its
low
(4) c a u s e d
Clomid®,
Many structural activity,
the
is m o r e p o t e n t
induces ovulation
in a n n o v u l a t o r y w o m e n
and
25 c o n f i r m e d
has antifertility
and antiestrogenic
antiestrogen species
laboratory
some estrogenic properties
preparation
(zuclomiphene) isomers,
(MRL 41)
in
however,
of C N S s i d e e f f e c t s
but unlike MER
in a l l
properties
in p a t i e n t s ,
Clomiphene
pharmacologi-
first non-steroidal
is a n t i e s t r o g e n i c
tested and also has a n t i f e r t i l i t y animals
the
(U-11,100A)
to
(8,9) a n d
b o t h s h o w n to h a v e a c o u r s e of a d v a n c e d
is a v a i l a b l e
b e c a u s e of t h e l o w r e p o r t e d
shifted
hormone-dependent tamoxifen
beneficial
breast
for b r e a s t
cancer,
cancer
incidence of side e f f e c t s
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
therapy (12).
604 /C2H5
/C2H5 och2ch2n
OCH2CH2N c
2h5
enclomiphene och2ch2n
ch30
tamoxifen
nafoxidine
Ο
D
NCHjCHJO
trioxifene
S\ keoxifene
Fig. 1. Structure of non-steroidal antiestrogens described in the text.
Tamoxifen (Nolvadex®) is available for the treatment of breast cancer in more than 70 countries throughout the world; in dollar sales alone, it is one of the most important drugs used in cancer therapy.
This fact has stimulated interest in the
discovery of new, and perhaps more specific, antitumor agents.
Trioxifene is antiestrogenic in laboratory animals
(13,14) and possesses antitumor activity in animals (15) and man (16), but the drug is not available for general clinical use.
Keoxifene (LY 156758) and the related compound LY 117018
have weak estrogenic activity in laboratory animals and a high binding affinity for the estrogen receptor (17-19).
These
drugs have a short duration action because of their polar
605 n a t u r e , w h i c h m a y f a c i l i t a t e their, r a p i d c o n j u g a t i o n excretion
(20).
and
T h i s p r o p e r t y may e x p l a i n the low p o t e n c y
the L Y - c o m p o u n d s as a n t i t u m o r a g e n t s in a n i m a l s
In this c h a p t e r I w i l l r e v i e w the s t u d i e s u n d e r t a k e n l a b o r a t o r y d u r i n g the p a s t d e c a d e , to d e s c r i b e the
in my
molecular
p h a r m a c o l o g y of t a m o x i f e n and to s u p p o r t the use of the as an a n t i t u m o r
General
of
(21).
drug
agent.
pharmacology
Tamoxifen has a particularly plexing, pharmacology
i n t e r e s t i n g , and o f t e n
in l a b o r a t o r y a n i m a l s .
its p r e d o m i n a n t l y e s t r o g e n i c p r o p e r t i e s
per-
Tamoxifen
exhib-
in m o u s e u t e r i n e
It is p o s s i b l e , h o w e v e r ,
and
vaginal assays
(22-24).
refractoriness
in the o v a r i e c t o m i z e d m o u s e v a g i n a s u c h that
cannot r e s p o n d to e x o g e n o u s e s t r o g e n s t i m u l a t i o n weeks following a large subcutaneous (25).
During
this p e r i o d
a n d there is a n i n c r e a s e vagina, h o w e v e r ,
u t e r i n e g r o w t h is fully
contrast tamoxifen
for
fully
stimulated,
vaginal cornification assays
The
in r e s p o n s e
is a p a r t i a l a g o n i s t w i t h
to
antiestrogenic
(22,26,27).
s t i m u l a t i o n of the cell t y p e s .
Tamoxifen
an increase
in the s i z e of the luminal e p i t h e l i a l c e l l s
very little
increase
levels
(14,27-29).
Stromal and myometrial cells
a p p a r e n t l y not a f f e c t e d by t a m o x i f e n . increase the u t e r i n e (30-32).
a
causes but
in m i t o t i c a c t i v i t y or w h o l e u t e r i n e
hydroxylated metabolite,
4-hydroxytamoxifen
DNA
are
T a m o x i f e n and
level of p r o g e s t e r o n e
Paradoxically,
In
Allen-Doisy
T h e rat u t e r u s is a c o m p l e x o r g a n and t a m o x i f e n p r o d u c e s differential
it
many
l e u k o c y t i c for 3-4 w e e k s .
in rat u t e r i n e w e i g h t a s s a y s and
a
tamoxifen
in v a g i n a l w e t and d r y w e i g h t .
is u n a b l e to c o r n i f y
e s t r a d i o l and the s m e a r r e m a i n s properties
i n j e c t i o n of
to induce
its
(Fig. 2) a l s o receptors
in v i v o
t a m o x i f e n and 4 - h y d r o x y t a m o x i f e n
do
606
tamoxifen
4-hydroxytamoxifen /CHj
R
CH3 4-methyltamoxifen CI 4-chlorotamoxifen
Fig. 2. The m e t a b o l i c a c t i v a t i o n of t a m o x i f e n to 4 - h y d r o x y t a m o x i f e n and the f o r m u l a e of the t a m o x i f e n d e r i v a t i v e s r e s i s t a n t to h y d r o x y l a t i o n . not increase progesterone cells
in c u l t u r e ,
receptor
i n d u c t i o n by r a t
but b o t h c o m p o u n d s
estradiol-stimulated
progesterone
reversibly
uterine
inhibit
receptor induction
(33).
Metabolism It is p o s s i b l e that the s p e c i e s d i f f e r e n c e s
in the
cology of t a m o x i f e n are the r e s u l t of d i f f e r e n c e s b o l i c t r a n s f o r m a t i o n of the d r u g .
pharmain the
As y e t , no q u a l i t a t i v e
f e r e n c e s have been found b e t w e e n the m e t a b o l i s m of
metadif-
tamoxifen
607 in rats, m i c e and c h i c k e n s
(34).
t a m o x i f e n in all t h r e e s p e c i e s
The p r i n c i p a l m e t a b o l i t e
is 4 - h y d r o x y t a m o x i f e n .
the a d m i n i s t r a t i o n of 4 - h y d r o x y t a m o x i f e n does n o t r e s u l t the a p p e a r a n c e of a d d i t i o n a l
major metabolites
(34).
p h a r m a c o l o g y of the p a r e n t
is the r e s u l t of the
actions of 4 - h y d r o x y t a m o x i f e n
and t a m o x i f e n
metabolites not yet described). hydroxytamoxifen
(35).
occurs
the
individual
(and any
other
H o w e v e r , the p o t e n c y of
is g r e a t e r than t a m o x i f e n b e c a u s e 50 times g r e a t e r than that of
4-
4-hy-
d r o x y t a m o x i f e n h a s a b i n d i n g a f f i n i t y for the e s t r o g e n tor a p p r o x i m a t e l y
in
The
m e t a b o l i c a c t i v a t i o n of t a m o x i f e n to 4 - h y d r o x y t a m o x i f e n in the rat and m o u s e so that the final e x p r e s s i o n of
recep-
tamoxifen
S t u d i e s w i t h d e r i v a t i v e s of t a m o x i f e n s u b s t i t u t e d
methyl or h a l o g e n
of
Indeed
in the 4 (para) p o s i t i o n of t a m o x i f e n
with (Fig.
2) w h i c h are u n a b l e to be m e t a b o l i c a l l y a c t i v a t e d ,
show a
lower p o t e n c y
tamoxifen
in u t e r i n e w e i g h t t e s t s in vivo than
a l t h o u g h the r e l a t i v e b i n d i n g a f f i n i t i e s equivalent
in v i t r o
are
(36).
The k n o w n m e t a b o l i t e s of t a m o x i f e n shown in Fig.
3.
in a n i m a l s and m a n are
The h i g h a f f i n i t y m e t a b o l i t e
4-hydroxy-
t a m o x i f e n is a m i n o r m e t a b o l i t e of t a m o x i f e n in p a t i e n t s whereas
the m a j o r m e t a b o l i t e
is N - d e s m e t h y l t a m o x i f e n
(37),
(38,39).
M e t a b o l i t e Y is a m i n o r m e t a b o l i t e of t a m o x i f e n in p a t i e n t s (40,41) and this is b e l i e v e d
to be formed from
t a m o x i f e n v i a an i n t e r m e d i a t e M e t a b o l i t e Ζ tamoxifen)
(39).
Metabolite
D, M e t a b o l i t e Ε and t a m o x i f e n
oxide have only been described animals
(42,43).
genic activity
in v i t r o or in
Metabolite D expresses
in r a t
(35) o r m o u s e
and is a w e a k a n t i e s t r o g e n .
N-desmethyl-
(didemethylated
little or no
estro-
(44) u t e r i n e w e i g h t
This c a t e c h o l d e r i v a t i v e
tests
of
t a m o x i f e n h a s , h o w e v e r , b e e n s h o w n to be u n s t a b l e
in v i t r o
because
affinity
it is r e a d i l y o x i d i z e d
(45).
The b i n d i n g
M e t a b o l i t e D for the e s t r o g e n r e c e p t o r is e q u i v a l e n t to of e s t r a d i o l .
Metabolite
N-
laboratory
E, t a m o x i f e n w i t h o u t the
of
that
dimethyl-
608
OCH2CH2N
metabolite Ε t OCH2CH2N
,CH3 'CHJ
*
tamoxifen N - o x i d e
HO
metabolite D OCH2CH2N
// CH Ι
OCH2CH2OH
4 - h y d r o x y tamoxifen (monohydroxy tamoxifen, metabolite B)
metabolite Y t
OCH2CH2NH2
Ν - d e s m ethyl tamoxifen metabolite X metabolite Ζ
Fig. 3.
The m e t a b o l i t e s of t a m o x i f e n in a n i m a l s and
aminoethyl vitro
side chain,
(45,46).
is fully e s t r o g e n i c in vivo
man.
(14) a n d
in
609 M e c h a n i s m s of a c t i o n in v i v o T h e fact t h a t n o n - s t e r o i d a l a n t i e s t r o g e n s w i l l c o m p e t i t i v e l y ο inhibit the b i n d i n g of [ J H ] e s t r a d i o l to e s t r o g e n r e c e p t o r s d e r i v e d f r o m rat u t e r i
(47) f o c u s e d a t t e n t i o n u p o n
receptor mediated mechanisms. 4-hydroxytamoxifen
The a n t i e s t r o g e n s
inhibit estradiol-stimulated
estrogen
LY 117018 increases
and in
immature rat u t e r i n e w e t w e i g h t but the i n h i b i t i o n can be r e v e r s e d by i n c r e a s i n g d o s e s of e s t r a d i o l uterotrophic reversibly
(48).
Similarly
the
a c t i v i t y of t a m o x i f e n in the m o u s e u t e r u s can be
i n h i b i t e d by M E R 25
predominantly
(49).
These results
indicate a
e s t r o g e n r e c e p t o r m e c h a n i s m for the
expression
of both the a n t i e s t r o g e n a n d e s t r o g e n i c a c t i o n of
tamoxifen.
Tamoxifen
(27,50) and 4 - h y d r o x y t a m o x i f e n
(31,50) cause
l o c a l i z a t i o n of o c c u p i e d e s t r o g e n r e c e p t o r c o m p l e x e s the n u c l e a r c o m p a r t m e n t of rat u t e r i n e c e l l s .
a
within
Antiestrogenic
p r o p e r t i e s are p r o b a b l y e x p r e s s e d t h r o u g h a c o m p e t i t i v e ance of a g o n i s t and a n t a g o n i s t at sites w i t h i n the n u c l e u s essary
receptor complexes
(27,50).
(though p r o b a b l y an a d v a n t a g e )
estrogen receptor pool completely effects.
Apparent differences
bal-
interacting
It is, h o w e v e r , not to o c c u p y the
to p r o d u c e
nec-
cytosolic
antiestrogenic
in the n u c l e a r o c c u p a n c y
times
of e s t r o g e n s and a n t i e s t r o g e n s are r e f l e c t e d by d i f f e r e n c e s the levels of a v a i l a b l e
cytosolic estrogen receptors
a d m i n i s t r a t i o n of c o m p o u n d s
(51,52).
plexes with estrogen receptors the b l o o d .
Antiestrogens
in the n u c l e u s but these
receptors.
is c l e a r e d
h a v e a long b i o l o g i c a l
as such c o n t i n u e to m a i n t a i n
following
Estradiol rapidly
lost o v e r the n e x t few h o u r s as the s t e r o i d
half
low l e v e l s of a v a i l a b l e
comare from
life
and
cytosolic
This e f f e c t has been s h o w n to be a p r o p e r t y
t h e i r d u r a t i o n of a c t i o n and not t h e i r m e c h a n i s m of
in
of
action
(53). T h e s y n t h e s i s of r a d i o l a b e l l e d
4 - h y d r o x y t a m o x i f e n has
per-
m i t t e d the d i r e c t s t u d y of the d i s t r i b u t i o n and t a r g e t l o c a t i o n of an a n t i e s t r o g e n .
[ Η]4-hydroxytamoxifen
tissue
binds
to
610
estrogen receptors
in the u t e r u s , but a l s o to
s p e c i f i c s i t e s in the u t e r u s and liver
antiestrogen
(54).
Antiestrogen
b i n d i n g s i t e s w e r e f i r s t d e s c r i b e d by S u t h e r l a n d a n d
coworkers
(55) and have b e e n s h o w n to be l o c a t e d in the m i c r o s o m a l t i o n of rat t i s s u e s
(56).
M a n y d i f f e r e n t c l a s s e s of
bind to the a n t i e s t r o g e n b i n d i n g site t h e r e f o r e ,
frac-
drugs
their
precise
role in the m o l e c u l a r m e c h a n i s m of a c t i o n of a n t i e s t r o g e n s controversial.
Indeed,
c o m p o u n d s can be i d e n t i f i e d that
to the a n t i e s t r o g e n b i n d i n g s i t e in v i t r o b u t d o n o t e i t h e r e s t r o g e n i c or a n t i e s t r o g e n i c p r o p e r t i e s
and e s t r o g e n s
in v i v o
that are u n l i k e l y to be
cally a c t i v a t e d to c o m p o u n d s w i t h a h i g h a f f i n i t y estrogen receptor tamoxifen).
(e.g., t a m o x i f e n c o n v e r t e d
The c o m p o u n d s
to
for
rat u t e r i n e g r o w t h and
"translocated"
to the n u c l e a r
In the m o d e l
ligands w i t h e i t h e r h i g h or low a f f i n i t y form a complex finity
receptors
compartment.
that has the u n o c c u p i e d
a l r e a d y in the n u c l e a r c o m p a r t m e n t .
receptor
receptor (Fig.
in the n u c l e u s to p r o d u c e b i o l o g i c a l
the low a f f i n i t y
ligand d i s s o c i a t e s
can
effects.
the h i g h
ligand r e c e p t o r c o m p l e x r e m a i n s w i t h the n u c l e a r
tion w h e r e a s
4)
for the r e c e p t o r
is d i s r u p t e d and f r a c t i o n a t e d ,
Ε
proges-
t h e s e d a t a to s u p p o r t a n e s t r o g e n
model for the u t e r i n e cell
W h e n the t i s s u e
the
4-hydroxy-
t e r o n e r e c e p t o r s y n t h e s i s but the c y t o s o l i c e s t r o g e n are a p p a r e n t l y not
with
metaboli-
(4-methyltamoxifen, Metabolite
and ICI 47,699) all s t i m u l a t e
W e have interpreted
bind
exhibit
(49).
R e c e n t l y w e h a v e o b s e r v e d some i n t r i g u i n g e f f e c t s antiestrogens
is
affrac-
from the
re-
ceptor during homogenization.
T h e u n o c c u p i e d r e c e p t o r thus
leached out into the c y t o s o l .
We have recently
t h e s e o b s e r v a t i o n s are
suggested
inconsistent with a cytoplasmic
tion for the e s t r o g e n r e c e p t o r w i t h a r e q u i r e m e n t l o c a t i o n to p r o d u c e a b i o l o g i c a l
response
for
that
locatrans-
in the n u c l e u s .
We
have a r g u e d that if the r e c e p t o r can be l e a c h e d out of the c l e u s w h e n a low a f f i n i t y unoccupied
receptor
ligand d i s s o c i a t e s t h e n p e r h a p s
is i n i t i a l l y
located
is
nuthe
in the n u c l e u s and
is
611
only extracted tissue
into cytosol during homogenization of the
(57,58).
A in vivo
Estrogenic Responses
i
High Affinity Ligand H
Unoccupied Receptor
Β CELL DISRUPTION in vitro
Fig. 4. A functional model for estrogen action. High affinity ligand (H) enters the cell and binds to the estrogen receptor (R) in the nucleus to produce an activated complex HR* and estrogenic responses. During cell disruption, this complex is retained in the nucleus. Low affinity ligands (L) enter the cell and bind to nuclear receptor to produce an activated complex LR*. During homogenization in vitro, the LR* complex dissociates and unoccupied R, and presumably ligand, leaks out of the nucleus into the cytosolic fraction.
612
Mechanism of action studies in vitro The potential mechanisms of action of antiestrogens are illustrated in Fig. 5.
In general, antiestrogens have been found
to inhibit the synthesis of estrogen regulated proteins (46, 59-62) and alter the rate of proliferation of hormone responsive cells (63-65).
Antiestrogens apparently induce a G^
block in the cell cycle (65,66).
B i n d i n g to AEBS?
Dynamics of N u c l e a r Receptor Complex
In this regard, it is
SECRETION PROTEIN SYNTHESIS
I
\
PROGESTERONE RECEPTOR 24K and 3 6 K PROTEINS
52K PROTEIN PROLACTIN GONADOTROPINS Effect on E s t r o g e n Regulated Protein Synthesis
Altered Receptor Interaction E f f e c t o n Cell Proliferation CALMODULIN
C i Block
CYTOPLASM
E f f e c t on Nuclear Receptor Form
AE
Fig. 5. Potential mechanisms of action of antiestrogens in vitro.
(AE)
interesting to note that tamoxifen has been found to be one of the most potent inhibitors of calmodulin mediated enzyme systems (67).
613 ο [ Η]antiestrogen have resulted
Studies with
tion of a b i n d i n g of c e l l s
(56).
component
The component
antiestrogen binding
site
interaction
(65) but this
The s t r u c t u r a l
fraction
s p e c i f i c i t y of l i g a n d s has b e e n
deter-
binding
The role of b i n d i n g s i t e s
(68).
convincing
M o s t s t u d i e s have
and no involved
actions.
f o c u s e d upon the i n t e r a c t i o n of
antiestro-
g e n s w i t h the e s t r o g e n r e c e p t o r in o r d e r to d e t e r m i n e any d i f f e r e n c e s
b e t w e e n e s t r a d i o l - and a n t i e s t r o g e n
whether
receptor
c o m p l e x e s c a n be o b s e r v e d to a c c o u n t for the a c t i o n of estrogen antagonists.
The a v a i l a b i l i t y of t r i t i a t e d
t r o g e n s has f o c u s e d a t t e n t i o n u p o n a s e a r c h for cal d i f f e r e n c e s complexes.
Similarly, precise assay systems
receptor
in v i t r o
r e s e a r c h w i l l be b r i e f l y
site.
olized
to the 8S e s t r o g e n r e c e p t o r
(69,70), h o w e v e r , [^H]estradiol.
the i n t e r a c t i o n ligand
of
is w e a k
S i n c e t a m o x i f e n c a n be
vi_vo^ to the a n t i e s t r o g e n i c
w h i c h has a h i g h a f f i n i t y
the
Each of these a r e a s of
antiestrogens
[^H]Tamoxifen binds directly the rat u t e r u s
and
reviewed.
Studies with radiolabelled
compared with
to
r e l a t i o n s h i p s of e s t r o g e n s
a n t i e s t r o g e n s has e n a b l e d the d e v e l o p m e n t of a m a p of estrogen receptor binding
the
anties-
physicochemi-
b e t w e e n e s t r o g e n and a n t i e s t r o g e n
d e s c r i b e the s t r u c t u r e - a c t i v i t y
for
in the
in c o n t r o v e r s i a l
e v i d e n c e has been p r e s e n t e d that they are
in e i t h e r a g o n i s t or a n t a g o n i s t
geo-
for the A E B S
side c h a i n is v e r y i m p o r t a n t
to the A E B S
of
like LY 117018 h a v e a
mined; an alkylaminoethoxy
m e c h a n i s m of a c t i o n of a n t i e s t r o g e n s
the
is s o m e w h a t
(49,56) and the e s t r o g e n i c cis
m e t r i c i s o m e r of t a m o x i f e n has a h i g h a f f i n i t y (49).
identifica-
is g e n e r a l l y r e f e r r e d to as
(AEBS)
a m i s n o m e r as s o m e p o t e n t a n t i e s t r o g e n s low a f f i n i t y
in the
l o c a t e d in the m i c r o s o m a l
metab-
4-hydroxytamoxifen
i n t e r a c t i o n w i t h the e s t r o g e n
recep-
614 tor, it is o n l y n a t u r a l this s u p e r i o r r e s e a r c h
that s t u d i e s s h o u l d h a v e f o c u s e d
M o n o c l o n a l a n t i b o d i e s r a i s e d to the e s t r o g e n r e c e p t o r
are
k n o w n to i n t e r a c t at d i f f e r e n t s i t e s o n the p r o t e i n . D547
Antibody
(raised to the e x t r a n u c l e a r r e c e p t o r f r o m M C F - 7
which apparently
i n t e r a c t s at a site far r e m o v e d
tamoxifen receptor complexes
receptor complex.
li-
4-hydroxy-
from h u m a n b r e a s t tumor
T h e r e are no d i f f e r e n c e s w h e t h e r D 5 4 7 is
w i t h the r e c e p t o r b e f o r e
cells)
from the
g a n d b i n d i n g s i t e , b i n d s e q u a l l y w i t h e s t r a d i o l and (71).
upon
probe.
cytosols
pre-incubated
the ligand or i n c u b a t e d w i t h
the
In c o n t r a s t a p o l y c l o n a l a n t i b o d y r a i s e d
the calf u t e r i n e e s t r o g e n r e c e p t o r
in the g o a t a p p e a r s
a b l e to d i s c r i m i n a t e b e t w e e n the c o n f o r m a t i o n a l in the r e c e p t o r by e s t r o g e n s and a n t i e s t r o g e n s
to be
shapes (72).
induced Based
u p o n the s t r u c t u r e s of e s t r o g e n s and a n t i e s t r o g e n s we
have
p r o p o s e d the f o l l o w i n g
the
h y p o t h e t i c a l m o d e l to d e s c r i b e
observed experimental results Estradiol
(Fig.
to
6).
first b i n d s w i t h the r e s t i n g r e c e p t o r
in the
nucleus
by an i n t e r a c t i o n of the C^ p h e n o l i c g r o u p w i t h a p h e n o l i c a c c e p t o r site on the p r o t e i n . f o l l o w e d by a c h a n g e
The initial b i n d i n g s t e p
in the t e r t i a r y s t r u c t u r e of the
that locks the s t e r o i d
into the r e c e p t o r and as a
d e v e l o p s the i n t r i n s i c e s t r o g e n i c a c t i v i t y of the These changes
s o c i a t i o n rate of the s t e r o i d mation)
i.e., u n t r a n s f o r m e d
by a l t e r a t i o n s
following activation
receptors have a rapid
tion of the l i g a n d c o m p a r e d with t r a n s f o r m e d (73,74).
The antiestrogen
tamoxifen)
4-hydroxytamoxifen
complex. receptor
in the
dis-
(transfordissocia-
complexes (monohydroxy-
b i n d s w i t h h i g h a f f i n i t y via the i n t e r a c t i o n of
p h e n o l i c g r o u p w i t h the p h e n o l i c s i t e o n the However,
result
in the i n t e r a c t i o n of the s t e r o i d and
have been described experimentally
is
protein
the t e r t i a r y
n e c e s s a r y to d e v e l o p
changes
receptor.
in the r e c e p t o r that
intrinsic activity
p r e v e n t e d by the a l k y l a m i n o e t h o x y
side
are
in the c o m p l e x , chain.
are
the
615
Ligand Binding Activation Estradiol
IIHIIIIIIIIII
Resting
Receptor
Resting
Receptor
Complex
Ill III
D e v e l o p m e n t of Intrinsic Activity
Formation
Manohydroxy tamoxifen Complex Formation
Low Intrinsic
Activity
Fig. 6. H y p o t h e t i c m o d e l s to d e s c r i b e the b i n d i n g of e s t r a d i o l or 4 - h y d r o x y t a m o x i f e n w i t h the ligand b i n d i n g s i t e o n the e s t r o g e n . E s t r o g e n c a n induce a c o n f o r m a t i o n a l c h a n g e in the r e c e p t o r to lock the ligand into the r e c e p t o r w h e r e a s the a n t i e s t r o g e n p r e v e n t s these c h a n g e s from o c c u r r i n g .
S t u d i e s with the p o l y c l o n a l
a n t i b o d y r a i s e d to the
r e c e p t o r tend to s u p p o r t the t e r t i a r y c h a n g e m o d e l
estrogen (72).
i n c u b a t i o n of a n t i b o d y w i t h c y t o s o l i c e s t r o g e n r e c e p t o r s h u m a n b r e a s t t u m o r s i m p a i r s the s u b s e q u e n t b i n d i n g of estradiol
and r e d u c e s
tein interaction. to the r e c e p t o r the a n t i b o d y .
However,
the b i n d i n g of
is u n i m p a i r e d Similarly,
pro-
4-hydroxytamoxifen
by e q u i v a l e n t c o n c e n t r a t i o n s
the i n t e r a c t i o n of the a n t i b o d y 4-hydroxytamoxifen-estrogen
p r o p o s e d m o d e l to e x p l a i n these o b s e r v a t i o n s
The
is i l l u s t r a t e d
T h e p o l y c l o n a l a n t i b o d y m a y i n t e r a c t w i t h the r e c e p t o r to p r e s e n t the
of with
receptor
c o m p l e x e s d o e s not a f f e c t the b i n d i n g of the l i g a n d s .
filled or r e s t i n g
from
[^H]-
the a f f i n i t y of the 1 i g a n d - r e c e p t o r
p r e f o r m e d e s t r a d i o l - and
Fig. 7.
Pre-
un-
conformational
in
616
Fig. 7. H y p o t h e t i c a l m o d e l to d e s c r i b e the b i n d i n g of e s t r a diol or 4 - h y d r o x y t a m o x i f e n to the e s t r o g e n r e c e p t o r . The i n t e r a c t i o n of the p h e n o l i c site (PS) o n the r e c e p t o r p r o t e i n induces a high a f f i n i t y b i n d i n g (HAB) to s i t u a t e the ligand in the c o r r e c t p o s i t i o n . T h e i n t e r a c t i o n of the p o l y c l o n a l a n t i b o d y w i t h the e s t r o g e n r e c e p t o r is i n d i c a t e d by Ab. The a n t i b o d y ( i e s ) i n t e r a c t s w i t h an u n k n o w n s i t e to a f f e c t the c o n f o r m a t i o n a l c h a n g e s that o c c u r at the ligand b i n d i n g s i t e . c h a n g e s that s u b s e q u e n t l y o c c u r to lock e s t r a d i o l receptor.
Thus,
the s t e r o i d
into
falls out of the b i n d i n g
H o w e v e r , the a n t i e s t r o g e n c a n still w e d g e
into the
the site.
exposed
617 binding site because
it d o e s not r e q u i r e f u r t h e r
conforma-
tional c h a n g e s to p r o d u c e h i g h a f f i n i t y b i n d i n g .
We
further
s u g g e s t that o n c e the c o n f o r m a t i o n c h a n g e d o e s o c c u r to the s t e r o i d
into its b i n d i n g
r e v e r s e the
process.
The u l t i m a t e
site, the a n t i b o d y
lock
is u n a b l e
fate of e s t r o g e n and a n t i e s t r o g e n r e c e p t o r
to
com-
p l e x e s w i t h i n the n u c l e u s of c a n c e r c e l l s is unknown,
however,
studies with radiolabelled
provoca-
tive r e s u l t s .
ligands have provided some
H o r w i t z and M c G u i r e
estradiol-estrogen
(75) p r o p o s e d that
r e c e p t o r c o m p l e x e s are d e s t r o y e d
nuclear
(or p r o -
cessed) d u r i n g the f i r s t few h o u r s of n u c l e a r o c c u p a n c y . contrast, antiestrogen-estrogen
receptor complexes
do not p r o c e s s
The d i f f e r e n c e
but a c c u m u l a t e .
In
apparently
in the
nuclear
b i o c h e m i s t r y of the r e c e p t o r c o m p l e x e s
is e m p h a s i z e d by the
observation
complexes have a
that a n t i e s t r o g e n - r e c e p t o r
ferent sedimentation plexes
(76).
We have recently confirmed
r e p o r t s by c o m p a r i n g
[^H] 4 - h y d r o x y t a m o x i f e n
There
tamoxifen-estrogen readily extracted.
the s e d i m e n t a t i o n
receptor
(1 to 6 hr) h o u r s and the Further work
is r e q u i r e d to
Nevertheless,
and
rat in the complexes
4-hydroxy-
r e c e p t o r c o m p l e x e s a c c u m u l a t e and
true loss of r e c e p t o r .
original
is c e r t a i n l y a d e c r e a s e
this r e s u l t r e f l e c t s d i f f e r e n t i a l
com-
[ ^H]estradiol
in M C F - 7 b r e a s t c a n c e r and G H 3
nuclear estradiol-estrogen
d u r i n g the f i r s t few
whether
(77) these
the n u c l e a r r e c e p t o r of
pituitary tumor cells. salt e x t r a c t a b l e
dif-
c o e f f i c i e n t that e s t r a d i o l - r e c e p t o r
are
determine
salt e x t r a c t i o n
or
there are d i f f e r e n c e s
c o e f f i c i e n t s of e s t r a d i o l - and
in
4-hydroxy-
t a m o x i f e n - e s t r o g e n r e c e p t o r c o m p l e x e s f r o m M C F - 7 c e l l s that d o not alter d u r i n g a 24 hr p e r i o d .
A l t h o u g h the
o b s e r v e d in M C F - 7 c e l l s m a y be r e l a t e d to the c o n d i t i o n s used,
results experimental
these d i f f e r e n c e s are not o b s e r v e d
p i t u i t a r y t u m o r c e l l line
(77,78).
in the
GHj
618 Structure-activity
relationships
P r i m a r y c u l t u r e s of rat p i t u i t a r y c e l l s r e s p o n d to
physio-
l o g i c a l c o n c e n t r a t i o n s of e s t r a d i o l by a s p e c i f i c i n c r e a s e prolactin synthesis
(79).
a c t i o n has b e e n v a l i d a t e d
This m o d e l s y s t e m for
antiestrogens.
inhibit
for the e s t r o g e n r e c e p t o r .
related
4-Hydroxy-
is 30 times m o r e p o t e n t than t a m o x i f e n , h o w e v e r ,
e n s u r e that t a m o x i f e n
is n o t m e t a b o l i c a l l y a c t i v a t e d
in v i t r o , s e v e r a l p a r a s u b s t i t u t e d
t i v e s of t a m o x i f e n
(4-methyl,
(59).
4 - c h l o r o , Fig. 2) have
derivabeen
The s u b s t i t u t i o n does not a f f e c t b i n d i n g
ity for the e s t r o g e n r e c e p t o r and the d e r i v a t i v e s of inhibit e s t r a d i o l - s t i m u l a t e d tration-related manner.
prolactin synthesis
Although
t a m o x i f e n to be m e t a b o l i z e d
in a
concenfor
it is
c l e a r l y not a r e q u i r e m e n t for a n t i e s t r o g e n a c t i v i t y . e s t r o g e n a c t i o n in the p i t u i t a r y
cells
is, h o w e v e r ,
p e t i t i v e and r e v e r s i b l e w i t h the a d d i t i o n of e x c e s s
affin-
tamoxifen
it is an a d v a n t a g e
to 4 - h y d r o x y t a m o x i f e n ,
to
to
4-hydroxytamoxifen tested
and
prolactin synthesis, with potency
to the b i n d i n g a f f i n i t y tamoxifen
activity
estrogens
T a m o x i f e n and 4 - h y d r o x y t a m o x i f e n
estradiol-stimulated
estrogen
for the study of s t r u c t u r e
r e l a t i o n s h i p s w i t h i n g r o u p s of n o n - s t e r o i d a l
in
Antiboth
com-
estradiol
(59). A s e r i e s of k n o w n e s t r o g e n s and a n t i e s t r o g e n s has b e e n to e s t a b l i s h s t r u c t u r e - a c t i v i t y
relationships.
The
relative
p o t e n c y of e s t r o g e n s to s t i m u l a t e p r o l a c t i n s y n t h e s i s diethylstilbestrol
ξ estradiol
the d i m e t h y l a m i n o e t h a n e
> ICI 77,949
side c h a i n )
isomer of e n c l o m i p h e n e ) .
(cis
e s t r o g e n s to inhibit e s t r a d i o l - s t i m u l a t e d The c o m p o u n d LY 126412
without
(_cis_ g e o -
prolactin
> trioxifene
was
geometric
T h e r e l a t i v e p o t e n c i e s of
w a s 4 - h y d r o x y t a m o x i f e n ξ LY 117018 Ξ tamoxifen.
(tamoxifen
> ICI 47, 699
m e t r i c isomer of t a m o x i f e n ) Ξ z u c l o m i p h e n e
tested
antisynthesis
> enclomiphene
(trioxifene without
the
side c h a i n ) d o e s not i n t e r a c t w i t h e s t r o g e n r e c e p t o r s up to
619 test c o n c e n t r a t i o n s of 10 estrogenic properties
Μ or exhibit estrogenic or
using the p r o l a c t i n s y n t h e s i s
A m o n g the t r i p h e n y l e t h y l e n e s , trans g e o m e t r i c
anti-
assay.
c o m p o u n d s that h a v e c i s and
i s o m e r s are e x t r e m e l y
i m p o r t a n t for the
devel-
o p m e n t of a l i g a n d - r e c e p t o r m o d e l b e c a u s e the i s o m e r i c
mole-
cules e n c o m p a s s e s t r o g e n i c and a n t i e s t r o g e n i c a c t i o n s .
The
trans isomers
( t a m o x i f e n a n d e n c l o m i p h e n e ) are
w i t h zero i n t r i n s i c a c t i v i t y w h e r e a s 47,699 a n d z u c l o m i p h e n e ) a c t i v i t y of
the cis
antiestrogens
isomers
are e s t r o g e n s w i t h a n
(ICI
intrinsic
1.
T o d e s c r i b e the i n t e r a c t i o n of the g e o m e t r i c i s o m e r s w i t h estrogen receptor,
the trans s t i l b e n e - l i k e
t a m o x i f e n and e n c l o m i p h e n e site w i t h low a f f i n i t y
structure
c o u l d sit l o o s e l y at the
b i n d i n g so that the p h e n y l
the
of binding
ring
substi-
tuted w i t h the p - a l k y l a m i n o e t h o x y side c h a i n is p r o j e c t e d from the b i n d i n g
site
(Fig.
8).
The e s t r o g e n i c
ligands,
z u c l o m i p h e n e a n d ICI 4 7 , 6 9 9 w i t h t h e i r low a f f i n i t y e s t r o g e n r e c e p t o r can c r e a t e a trans s t i l b e n e - l i k e w i t h the p a r a s u b s t i t u t e d p h e n y l ring. the a m i n o e t h o x y (Fig. 8).
the
In this b i n d i n g
and, as a r e s u l t ,
i n t e r a c t i o n t h r o u g h the
state,
a n t i e s t r o g e n r e g i o n of the
no i n h i b i t i o n of e s t r o g e n a c t i o n .
tiary c h a n g e s that are n e c e s s a r y to d e v e l o p a h i g h for the c o m p l e x can o c c u r
(80).
tuted phenyl ring
The
ter-
intrinsic
into t h r e e
categories
Antiestrogens have a side
c h a i n e x t e n d i n g a w a y f r o m the b i n d i n g site, p a r t i a l have a bis p h e n o l i c s t r u c t u r e
side
receptor
unimpeded.
O v e r a l l c o m p o u n d s can be c l a s s i f i e d based upon their s t r u c t u r e
site
ether
T h e r e w o u l d be no i n t e r a c t i o n of the
chain with a hypothetical
activity
for
structure
side c h a i n w o u l d lie next to the p h e n o l i c
o n the r e c e p t o r , w i t h a w e a k oxygen
away
and a g o n i s t s h a v e an
(or no p h e n y l ring at
all).
agonists unsubsti-
620
liLLililiiliiilU
trans monohydroxytamoxifen
estradiol-17/
Β
trans geometric i s o m e r s
cis geometric i s o m e r s
Fig. 8. H y p o t h e t i c a l m o d e l s for e s t r o g e n i c and a n t i e s t r o g e n i c ligand b i n d i n g to the e s t r o g e n r e c e p t o r . E s t r a d i o l - 1 7 8 is a n c h o r e d at a p h e n o l i c site (PS) w i t h high a f f i n i t y b i n d i n g (HAB). t r a n s M o n o h y d r o x y t a m o x i f e n h a s the same h i g h a f f i n i t y b i n d i n g but this a n t i e s t r o g e n i c ligand b i n d s to the r e c e p t o r s i t e so that the a l k y l a m i n o e t h o x y s i d e c h a i n can i n t e r a c t w i t h a h y p o t h e t i c a l a n t i e s t r o g e n r e g i o n (AER) on the p r o t e i n . Comp o u n d s w i t h o u t a p h e n o l i c h y d r o x y l h a v e low a f f i n i t y b i n d i n g (LAB). The trans a n d cis g e o m e t r i c isomers r e f e r to A) t a m o x i f e n ( R = C H 3 , R 2 = C 2 H 5 ) and e n c l o m i p h e n e ( R = C 2 H 5 , R = C 1 ) ; B) ICI 47,699 ( R = C H 3 , R = C 2 H 5 ) and z u c l o m i p h e n e ( R = C 2 H 5 , R2=C1). T h e g e m i n a l bis p a r a h y d r o x y p h e n y l c o m p o u n d s bisphenol)
that are p a r t i a l a g o n i s t s
interesting.
(e.g.,
in v i t r o are
particularly
Belleau's macromolecular perturbation
(45), w h i c h was o r i g i n a l l y p r o p o s e d to e x p l a i n
theory
agonist,
p a r t i a l a g o n i s t a n d a n t a g o n i s t a c t i v i t y of d r u g s at the c a r i n i c c h o l i n e r g i c r e c e p t o r , m a y be used to e x p l a i n agonists
in t e r m s of the e s t r o g e n r e c e p t o r m o d e l .
to B e l l e a u ' s h y p o t h e s i s ,
mus-
partial
According
an a g o n i s t b i n d s to the r e c e p t o r
induces a specific conformational perturbation
(SCP).
An
and
621 a n t a g o n i s t b i n d s to the r e c e p t o r and p r o d u c e s a conformational perturbation intrinsic activity.
non-specific
(NSCP) but the c o m p l e x has
B e t w e e n these e x t r e m e s a p a r t i a l
zero agonist
binds to the r e c e p t o r and p r o d u c e s an e q u i l i b r i u m m i x t u r e a g o n i s t and a n t a g o n i s t r e c e p t o r c o m p l e x e s . definitions
to the e s t r o g e n r e c e p t o r
Applying
of
these
(Fig. 9), e s t r a d i o l
binds
w i t h h i g h a f f i n i t y to the r e s t i n g r e c e p t o r and i n d u c e s a S C P which results site.
in the ligand being
4-Hydroxytamoxifen
locked into the
(antagonist) wedges
r e c e p t o r and p r o d u c e s a N S C P .
Bisphenol
binding
into the
(partial
resting
agonist)
i n t e r a c t s at the l i g a n d b i n d i n g site b u t w h i l e s o m e of r e c e p t o r s can be i n d u c e d to lock the l i g a n d into the
the
protein,
o t h e r l i g a n d i n t e r a c t i o n s are o n l y a b l e to induce a N S C P the
complex.
T h e s t u d y of the s t r u c t u r e - a c t i v i t y an u n d e r s t a n d i n g of s e v e r a l predict pharmacological 1.
in
f e a t u r e s that are d o m i n a n t
activity
(Fig.
A phenolic hydroxyl equivalent diol
is e x t r e m e l y
relationships has
provided and
10).
to the C3 p h e n o l of
estra-
i m p o r t a n t for h i g h a f f i n i t y b i n d i n g
the e s t r o g e n r e c e p t o r .
This s t r u c t u r a l
to
feature permits
v a r i e t y of " s p a c i n g g r o u p s " to o c c u p y the r e c e p t o r
a
binding
site. 2.
Alkylethers have a decreased affinity
for the
receptor
(but an i n c r e a s e d d u r a t i o n of a c t i o n in v i v o ) . 3.
S u b s t i t u t i o n of the p h e n y l ring e x t e n d i n g a w a y from the binding
site g o v e r n s p h a r m a c o l o g i c a l
activity.
w i t h o u t s u b s t i t u t i o n are e s t r o g e n s b u t a p a r a predicts partial agonist activity
in v i v o .
side c h a i n p r e d i c t s a n t a g o n i s t a c t i v i t y
Compounds hydroxyl
E x t e n s i o n of a
in v i t r o .
622
Bisphenol
Fig. 9. A d a p t a t i o n of B e l l e a u ' s m a c r o m o l e c u l a r p e r t u r b a t i o n theory to d e s c r i b e the i n t e r a c t i o n of a g o n i s t , a n t a g o n i s t s and p a r t i a l a g o n i s t s w i t h the e s t r o g e n r e c e p t o r (ER). The p h e n o l g r o u p o n the ligand i n t e r a c t s w i t h the p h e n o l i c site o n the E R (closed t r i a n g l e ) and p r o d u c e a h i g h a f f i n i t y i n t e r a c t i o n if the g e o m e t r y of the l i g a n d is c o r r e c t . E s t r a d i o l (Ej), o n a g o n i s t , i n d u c e s a s p e c i f i c c o n f o r m a t i o n a l p e r t u r b a t i o n (SCP) w h e r e a s 4 - h y d r o x y t a m o x i f e n (OHTAM), a n t a g o n i s t , o n l y i n d u c e s a n o n - s p e c i f i c c o n f o r m a t i o n a l p e r t u r b a t i o n (NSCP). Bisphenol (partial a g o n i s t ) p r o d u c e s a m i x t u r e of SCP and N S C P in the ER.
623
Area of Antagonist Activity
^ O H
Estrogenic Activity (Agonist)
Low Affinity RO
HO High Affinity
Partial Agonist
y Spacing / Groups /
Fig. 10. A general ligand model to describe the structural requirement to control biological activity in vitro.
Antitumor actions in animals The dimethylbenz(a(anthracene
(DMBA)-induced rat mammary car-
cinoma model first described by Huggins et al. (81) has been used extensively to study hormone-dependent cancer and to evaluate potential therapies for breast cancer. The early definition of hormone dependency was based on regression of tumors after ovariectomy and hypophysectomy
(81).
Since estrogen stimulates tumor regrowth in ovariectomized rats but not in animals which are also hypophysectomized
(82),
the pituitary gland clearly plays a central role in the growth and homoestasis of DMBA-induced tumors.
Since
'hormone-
responsive' DMBA-induced tumors have cytosol estrogen
624 r e c e p t o r s a d i r e c t s t i m u l a t i o n of t u m o r g r o w t h by e s t r o g e n possible.
However,
the
interesting observations
tin a d m i n i s t r a t i o n o r i n c r e a s e s perphenazine
stimulate
increases
in e s t r o g e n r e c e p t o r
in this m o d e l are a m a r k e r of h o r m o n e
Tamoxifen tumors
inhibits
(84-88).
estro-
respon-
action.
the g r o w t h of e s t a b l i s h e d
DMBA-induced
T o e x p l a i n the m e c h a n i s m of a c t i o n of
tamoxi-
fen in this m o d e l m o s t i n v e s t i g a t o r s have c o n s i d e r e d an a c t i o n w i t h t u m o r e s t r o g e n r e c e p t o r s to be of importance.
Terenius
(89) first p r o p o s e d
antiestrogens DMBA-
induced rat t u m o r s and that this m i g h t be their p r i m a r y antiestrogens
inter-
fundamental
that
d i r e c t l y b l o c k the b i n d i n g of e s t r o g e n to h u m a n a n d n i s m of a c t i o n .
by
concen-
(83) m a y i n d i c a t e that
s i v e n e s s r a t h e r t h a n a m e d i a t o r of h o r m o n e
mecha-
Many studies have subsequently confirmed
i n h i b i t the b i n d i n g of
is
prolac-
in s e r u m p r o l a c t i n c a u s e d
t r a t i o n s as w e l l as t u m o r g r o w t h gen r e c e p t o r s
that
[^H]estradiol
to
that
DMBA-
i n d u c e d t u m o r t i s s u e s d e t e r m i n e d b o t h in v i v o and in v i t r o (85,90,91). b i n d i n g of
At the s u b c e l l u l a r [^H]estradiol
from D M B A - i n d u c e d
tumors
level,
tamoxifen
inhibits
to the 8S e s t r o g e n r e c e p t o r (90).
The i n t e r a c t i o n of
w i t h the e s t r o g e n r e c e p t o r s y s t e m of D M B A - i n d u c e d been s t u d i e d e x t e n s i v e l y
t a m o x i f e n may the p i t u i t a r y
tumors
tumor,
i n h i b i t t u m o r g r o w t h by a n u m b e r of o t h e r 11.
The a b i l i t y of t a m o x i f e n to
g l a n d has been c o n s i d e r e d e a r l i e r .
cluded, therefore,
It is
in the h o r m o n a l m i l i e u
affect con-
However,
there
is little d o u b t that the
antagonist,
perphenazine, which
by
and
both pituitary
g l a n d can h a v e a n o v e r r i d i n g e f f e c t since a d m i n i s t r a t i o n
of
stimulates
prolactin secretion, will reverse tumor regression tamoxifen.
mecha-
that tamoxifen causes tumor regression
d i r e c t b i o c h e m i c a l e f f e c t s w i t h i n the t u m o r cell are
the d o p a m i n e
has
in v i v o .
multiple mechanisms; alterations important.
obtained
tamoxifen
In a d d i t i o n to a d i r e c t a c t i o n o n the D M B A - i n d u c e d n i s m s as s h o w n in Fig.
the
induced
by
625
Interferes W i t h G o n a d o t r o p i n Release . Ovary Hypothalamo Pituitary Axis Inhibit
Inhibit Prolactin Release
Oestradiol Synthesis
^ D M B A - Induced Mammary Tumour
Inhibit Oestradiol Binding
IS2I Oestradiol Η Gonadotropin mm Prolactin
Fig. 11. S i t e s p o t e n t i a l l y s e n s i t i v e to a n t i e s t r o g e n in the D M B A - i n d u c e d rat m a m m a r y c a r c i n o m a m o d e l . In a d d i t i o n to e f f e c t s o n e s t a b l i s h e d that t a m o x i f e n p r e v e n t s or r e t a r d s tumor induction with DMBA. a large dose of t a m o x i f e n
t u m o r s there
the e v e n t s
inhibits
T a m o x i f e n m a y be e x e r t i n g of c a r c i n o g e n e s i s to m a k e the tissue as a n a n t i e s t r o g e n . be i m p o r t a n t insult.
(92), a n d DMBA
the a p p e a r a n c e of t u m o r s
to the c a r c i n o g e n ,
Alternatively,
for c a r c i n o g e n e s i s
the
the local a c t i v a t i o n of
the c e l l u l a r b i o c h e m i s t r y
to al-
process DMBA
sufficiently rather
than
since prolactin appears
then the i n h i b i t i o n of
(q.v.) m i g h t p r e v e n t the
of
(86).
its e f f e c t by i n h i b i t i n g
refractory
tin r e l e a s e by t a m o x i f e n
in
(5 mg χ 2 s.c.), w h i c h is k n o w n
by p r e v e n t i n g
o r p e r h a p s by a l t e r i n g
is e v i d e n c e
involved
The simultaneous administration
p r o d u c e a long t e r m a n t i e s t r o g e n i c e f f e c t most completely
action
to
prolac-
carcinogenic
626 O t h e r d r u g r e g i m e n s h a v e p r o v i d e d d a t a of g r e a t r e l e v a n c e adjuvant therapy
in the c l i n i c a l s i t u a t i o n .
Four w e e k s
DMBA a d m i n i s t r a t i o n t u m o r i n i t i a t i o n has o c c u r r e d b u t no pable
tumors can be d i s c e r n e d .
to
after pal-
At this time a s h o r t c o u r s e
t r e a t m e n t w i t h t a m o x i f e n for 30 d a y s w i l l d e l a y the
of
appearance
of tumors and r e d u c e the c u m u l a t i v e n u m b e r of t u m o r s
found
(93,94).
classical
A l t h o u g h m o r e p o t e n t as an a n t i e s t r o g e n
pharmacological
models,
4-hydroxytamoxifen
is less
t h a n t a m o x i f e n w h e n g i v e n for 30 d a y s in this tumor model
than c o n t i n u o u s
treatment
effective
DMBA-induced
(95); this m a y be due to d i f f e r e n c e s
In this m o d e l , s h o r t c o u r s e s of t h e r a p y are, less e f f e c t i v e
in
in
half-life.
in g e n e r a l ,
(93,94,96).
example, continuous daily treatment with
much
For
4-hydroxytamoxifen,
s t a r t i n g 4 w e e k s a f t e r DMBA a d m i n i s t r a t i o n , w i l l
dramatically
r e d u c e the total n u m b e r of t u m o r s a p p e a r i n g , w h e r e a s the d o s e s g i v e n as a s h o r t c o u r s e without effect
for 4 w e e k s are
same
virtually
(96).
C o n t i n u o u s t r e a t m e n t w i t h a n t i e s t r o g e n s s h o u l d not be s i d e r e d to be a n a l o g o u s
to o v a r i e c t o m y .
Ovariectomy
con30 d a y s
a f t e r D M B A d e l a y s the a p p e a r a n c e of t u m o r s but e v e n t u a l l y to 50% of a n i m a l s d e v e l o p
tumors
(97).
In c o n t r a s t ,
up
continu-
ous treatment with tamoxifen prevents tumor appearance
in
a b o u t 90% of a n i m a l s e v e n a f t e r
greater
200 d a y s
(93,97).
The
e f f i c a c y of t a m o x i f e n m a y be due to its a b i l i t y to
antagonize
all e s t r o g e n w h e t h e r p r o d u c e d by the o v a r y o r formed by t i z a t i o n of a d r e n a l a n d r o g e n s . appearing
in o v a r i e c t o m i z e d
C e r t a i n l y m a n y of the
aroma-
tumors
rats are h o r m o n e - r e s p o n s i v e
a d d i t i o n a l t h e r a p y w i t h t a m o x i f e n r e d u c e s the t u m o r
since
growth
(97).
In s u m m a r y t h e s e d a t a i n d i c a t e t h a t a f t e r c a r c i n o g e n e s i s i n i t i a t e d by DMBA,
the s u b s e q u e n t a p p e a r a n c e of t u m o r s
v e n t e d by a d m i n i s t r a t i o n of t a m o x i f e n a n d If t r e a t m e n t c e a s e s the t u m o r s d e v e l o p . induced tumor model has limitations
is
is p r e -
4-hydroxytamoxifen. However,
(i.e.,
it d o e s
the not
DMBA-
627 metastasize and, unlike human mammary tumors, is dependent on prolactin) and so other potential models are being developed. N-nitrosomethylurea
(NMU) will also produce mammary tumors in
rats (98) but the degree of hormone dependency is influenced by the schedule of NMU administration
(99).
At this time the
precise hormone dependency of the tumors is unclear but they do appear to grow in response to estrogen and prolactin. Treatment with tamoxifen prevents growth of NMU-induced and reduces the tumor incidence
tumors
(100).
Treatment with tamoxifen in an adjuvant setting 2 weeks after NMU administration for 5 weeks completely inhibits tumor incidence but when therapy stops the tumors subsequently appear (101).
However, continuous therapy with tamoxifen (500 yg or
100 pg daily) will completely prevent the appearance of tumors (101).
These studies have important implications for the
clinical application of tamoxifen for the adjuvant therapy of breast cancer.
Antitumor action in patients Tamoxifen is an effective, non-toxic palpiative treatment for advanced breast cancer (10-12).
The mode of action is con-
sidered to be via the estrogen receptor because a) inhibits the binding of
tamoxifen
3
[ H]estradiol to estrogen receptors
derived from breast tumors (102), b)
estrogen receptor con-
taining breast cancer cells have their growth in vitro retarded by the antiestrogen
(63) and, c)
patients with an
estrogen recetor positive tumor are more likely to respond to tamoxifen therapy than those with an estrogen receptor negative tumor
(103).
The addition of tamoxifen to chemotherapy regimens (104) or the use of tamoxifen alone following mastectomy (105) is generally found to improve the disease free interval in node
628 positive breast cancer.
However, the one or two years of
tamoxifen therapy may not be optimal.
If tamoxifen is tumor-
istatic rather than tumoricidal then continued therapy may be necessary to control recurrence in patients with sensitive disease.
In 1977 Dr. Douglass Tormey of the Wisconsin Clinical Cancer Center initiated a pilot clinical study of long term
(greater
than 5 years of therapy) tamoxifen therapy in patients having up to 2 years of adjuvant chemotherapy following mastectomy. The study compared three groups of patients (no tamoxifen, 2 years of tamoxifen or continuous tamoxifen) has shown a disease free survival advantage for the group receiving continuous tamoxifen therapy
(106).
The additional aims of the study
were to determine whether tamoxifen could be given safely for more than 5 years and to determine whether continual therapy with tamoxifen would result in metabolic tolerance.
We were
particularly interested to establish that tamoxifen was neither inactivated nor converted to estrogens during the years of therapy.
The results of the HPLC assays using post-
column fluorescence activation (107) are illustrated in Fig. 12.
It is clear that tamoxifen does not develop meta-
bolic tolerance or induce the appearance of estrogenic metabolites.
These data have been used to establish the
Eastern Cooperative Oncology Group protocols EST 5181 and EST 4181 to test the value of 5 years of tamoxifen in a broad based, randomized clinical trial.
629 // CHEMOTHERAPY
TAMOXIFEN
' y •
· ·
• . •·· 1
.1 150
,,
ι 300
β β •
ι 450
1
•• ν-'·· ', · ·% ·*· ·· ··. Ι·· ·*
1 1
*>« · ·
1
t/ Λ ι 600 750
•
·
· · •
ι
ι 900
ι
ι 1050
ι
ι
ι
ι ι
ι ι ι ι ι 1200 1350 1500 1650 1 8 0 0
1950
D A Y S OF T A M O X I F E N T H E R A P Y ( l O r n g b i d )
N-desmethyltomoxifen
Metabolite Y
DAYS OF T A M O X I F E N T H E R A P Y ( 1 0 m g b i d )
Fig. 12. The level of tamoxifen and its metabolites Ndesmethyltamoxifen and Metabolite Y during long-term adjuvant therapy with tamoxifen (10 mg bid).
630 Acknowledgements The studies described
in t h i s c h a p t e r w e r e s u p p o r t e d
the p a s t 12 y e a r s by ICI Pic
(Pharmaceuticals
E n g l a n d ; the Y o r k s h i r e C a n c e r R e s e a r c h C a m p a i g n , Stuart Pharmaceuticals, Wilmington, I n s t i t u t e s of H e a l t h and
during
Division), England;
D e l a w a r e ; and
(USA) g r a n t s P 3 0 - C A - 1 4 5 2 0 ,
National
P01-CA-20432
ROl-CA-32713.
References 1.
Lerner, L.J., Holthaus, J.F., Thompson, E n d o c r i n o l o g y 62, 295-318 (1958).
2.
Segal, J . S . , N e l s o n , W . L . : 98, 4 3 1 - 4 3 6 (1958).
3.
Chang, M.C.:
4.
Kistner, (1961) .
5.
Holtkamp, D.E., Greslin, S.C., Root, C.A., Lerner, Proc. Soc. Exp. B i o l . M e d . 105, 1 9 7 - 2 0 1 (1960).
6.
G r e e n b l a t t , R . B . , Roy, S., M a h e s h , V . B . , B a r f i e l d , W . E . , Jungck, E.C.: Am. J. O b s t e t . G y n e c . £ 4 , 9 0 0 - 9 1 2 (1962).
7.
Huppert, L.C.:
8.
Bloom, H.J.G., Boesen,
9.
H e u s o n , J . C . , E n g e l s m a n , Ε., B l a n k - v a n der W i j s t , J., M a a s , Η., D r o c h m a n s , Α., M i c h e l , J., N o w a k o w s k i , M,, Garins, Α.: B r . M e d . J. _2, 7 1 1 - 7 1 3 (1975).
10.
Cole, M . P . , J o n e s , C . T . A . , T o d d , 25, 2 7 0 - 2 7 5 (1971).
11.
Ward, H.W.C.:
12.
Legha, S.S., C a r t e r , (1976).
13.
J o n e s , C . D . , S u a r e z , Τ., M a s s e y , E . H . , B l a c k , L.J., Tinsley, F.C.: J. Med. C h e m . 22j 9 6 2 - 9 6 6 (1979).
14.
Jordan, V.C., Gosden, B.: 291-306 (1982).
15.
Rose, D.P., Fischer, A.H., Jordan, V.C.: C a n c e r C l i n . O n c o l . 17, 8 9 3 - 8 9 8 (1981).
R.W.,
P r o c . Soc. Exp. B i o l .
Endocrinology_65, Smith, O.W.:
339-342
S.K.:
12,
121-141 L.J.:
(1979).
Br. Med. J. _2, 7-10
I.D.H.:
Br. M e d . J. I, 13-14
Med.
(1959).
Fert. S t e r i l .
F e r t . S t e r i l . _31, 1-8 E.:
C.R.:
Br. J.
(1974).
Cancer
(1973).
C a n c e r T r e a t Rev.
3,
Mol. C e l l . E n d o c r i n o l . Europ.
205-216
27, J.
631 16.
H a n n i , Α . , A r a f a h , Β., P e a r s o n , Ο . Η . : In, N o n - s t e r o i d a l Antioestrogens. (R.L. S u t h e r l a n d , V.C. J o r d a n , E d s . ) , pp. 435-452. A c a d e m i c Press, S y d n e y (1981).
17.
B l a c k , L.J., G o o d e , R . L . : (1980).
Life Sei. 26,
1453-1458
18.
Black, L.J., Goode, R.L.: (1981).
Endocrinology
109,
19.
B l a c k , L . J . , J o n e s , C . D . , G o o d e , R.L. E n d o c r . 22, 9 5 - 1 0 3 (1981).
20.
J o r d a n , V . C . , G o s d e n , B.: (1983).
21.
C l e m e n s , J . Α . , B e n n e t t , D.R., B l a c k , L.J., C.D.: Life Sei. _32' 2 8 6 9 - 2 8 7 5 (1983).
22.
Harper, M.J.K., Walpole, A.L.: (1966).
23.
Terenius,
24.
M a r t i n , L. , M i d d l e t o n , (1978).
25.
Jordan, V.C. :
26.
Harper, M.J.K., Walpole, 1 0 1 - 1 1 9 (1967).
27.
J o r d a n , V . C . , Dix, C . J . , R o w s b y , Mol. Cell E n d o c r i n o l . J j 177-192
28.
C l a r k , E . R . , Dix, C . J . , J o r d a n , V . C . , P r e s t w i c h , G., S e x t o n , S.: Br. J. P h a r m a c o l . 6J2, 4 4 2 P - 4 4 3 P (1978).
29.
Furr, B.J.Α., Jordan, V.C.: (1984).
30.
J o r d a n , V . C . , P r e s t w i c h , G.: (1978).
31.
Dix, C . J . , J o r d a n , V . C . :
J. E n d o c r . JJ5, 393-404
32.
Dix, C.J., J o r d a n , V . C . : (1980).
Endocrinology
33.
C a m p e n , C . A . , J o r d a n , V . C . , G o r s k i , J.: (in p r e s s ) .
L.:
Mol.
Endocrinology
Acta. Endocr. E. :
Nature
987-989
Cell.
113,
463-468
Jones,
(Lond) 212,
(Copenh)_64,
47-58
87
(1970).
J. E n d o c r . 18_, 1 2 5 - 1 2 9
J. R e p r o d . F e r t . _ 5 2 , A.L.:
251-258
J. R e p r o d .
(1975). Fert.
L., P r e s t w i c h , (1977).
Pharmacol. Ther. J. E n d o c r . 76,
34.
Lyman, S.D., Jordan, V.C.:
35.
Jordan, V.C., Collins, M.M., Rowsby, J. E n d o c r . J b j 3 0 5 - 3 1 6 (1977).
36.
A l l e n , K.E., C l a r k , 71, 8 3 - 9 1 (1980).
37.
D a n i e l , C . P . , G a s k e l l , S . J . , B i s h o p , H., R.I.: J. E n d o c r . 83, 401-408 (1979).
107,
13, G.:
(in p r e s s ) 363-364 (1980).
2011-2020
Endocrinology ·
Biochem. Pharm,
(in p r e s s ) .
L., P r e s t w i c h ,
E.R., J o r d a n , V . C . :
Br. J.
G.:
Pharmac.
Nicholson,
632 38.
Adam, H.K., Douglas, E.J., Kemp, J.V.: Pharmacol. _27, 145-147 (1979).
Biochem.
39.
Kemp, J.V., Adam, H.K., Wakeling, A.E., Slater, R. : Biochem. Pharmacol. _32' 2045-2052 (1983).
40.
Bain, R.R., Jordan, V.C.: 375 (1983).
41.
Jordan, V.C., Bain, R.R., Brown, R.R., Gosden, Β., Santos, M.A.: Cancer Res. _43, 1446-1450 (1983).
42.
Fromson, J.M., Pearson, S., Bramah, S.: 693-709 (1973).
43.
Foster, A.B., Griggs, L.J., Jarman, M., van Maanen, J.M.S., Schulten, H.R.: Biochem. Pharmacol. 29, 19771979 (1980).
44.
Jordan, V.C., Dix, C.J., Naylor, K.E., Prestwich, G., Rowsby, L. : J. Toxicol. Environ. Health A, 364-390 (1978).
45.
Jordan, V.C., Lieberman, M.E., Koch, R., Cormier, E.M., Bagley, J., Ruenitz, P.: Mol. Pharmacol. 26, 272-278 (1984) .
46.
Lieberman, M.E., Gorski, J., Jordan, V.C.: Chem. 258, 4741-4745 (1983).
47.
Skidmore, J.R., Walpole, A.L., Woodburn, J.: 52, 289-298 (1972).
48.
Jordan, V.C., Gosden, B.: 1258 (1983).
49.
Lyman, S.D., Jordan, V.C.: press).
50.
Jordan, V.C., Naylor, K.E.: (1979).
51.
Clark, J.H., Anderson, J., Peck, E.J.: 707-718 (1973).
52.
Clark, J.H., Peck, E.J., Anderson, J.L.: 251, 446-448 (1974).
53.
Jordan, V.C., Rowsby, L., Dix, C.J., Prestwich, G.: Endocr. 18_· 71-81 (1978).
54.
Jordan, V.C., Bowser-Finn, R.A.: 1281-1291 (1982).
55.
Sutherland, R.L., Murphy, L.C., Foo, M.S., Green, M.D., Whybourne, A.M., Krozowski, Z.S.: Nature (Lond) 288, 273-275 (1980).
56.
Sudo, K., Monsma, F.J., Katzenellenbogen, B.S.: Endocrinology 112, 425-434 (1983).
57.
Jordan, V.C., Gosden, B., Tate, A.C.: Endocrin. Soc. Proc. (San Antonio) Abstract 1049 (1983).
Biochem. Pharmacol. 32, 373-
Xenobiotica 3,
J. Biol. J. Endocr.
J. Steroid Biochem. 19, 1249Biochem. Pharmacol, (in Br. J. Pharmac. 65, 167-173 Steroids 22, Nature
(Lond) J.
Endocrinology 110,
633 58.
Jordan, V.C., Tate, A.C., Lyman, S.D., Gosden, Β., Wolf, Μ., Welshons, W.V.: Endocrinology (submitted).
59.
Lieberman, Μ.Ε., Jordan, V.C., Fritsch, Μ., Santos, Μ.Α., Gorski, J.: J. Biol. Chem. 258, 4734-4740 (1983).
60.
Westley, B., Rochefort, Η.:
61.
Edwards, D.P., Adaras, D.J., Savage, N., McGuire, W.L.: Biochem. Biophys. Res. Commun. 93, 804-809 (1980).
Cell _20, 353-362 (1980).
62.
Miller, W.L., Huang, E.S.R.: (1981).
63.
Lippman, M.E., Bolan, G.: (1975).
64.
Edwards, D.P., Murthy, S.R., McGuire, W.L.: 40, 1722-1726 (1980).
65.
Sutherland, R.L., Green, M.D., Hall, R.E., Reddel, R.R., Taylor I.W.: Europ. J. Cancer Clin. Oncol. 19, 615-621 (1983).
66.
Osborne, C.K., Boldt, D.H., Clark, G.M., Trent, J.M.: Cancer Res. 4_3, 3583-3585 (1983).
67.
Lam, D.H.Y.: (1984).
68.
Murphy, L.C., Sutherland, R.L.: Comm. 100, 1353-1360 (1981).
69.
Jordan, V.C., Prestwich, G. : 179-188 (1977).
70.
Capony, F., Rochefort, Η.: 181-198 (1978).
71.
Tate, A.C., DeSombre, E.R., Greene, G.L., Jensen, E.V., Jordan, V.C.: Breast Cancer Res. Treat. _3/ 267-277 (1983) .
72.
Täte, A.C., Greene, G.L., DeSombre, E.R., Jensen, E.V., Jordan, V.C.: Cancer Res. 4_4, 1012-1018 (1984).
73.
Notides, A.C., Hamilton, D.E., Auer, H.E.: Chem. 250, 3945-3950 (1975).
74.
Rochefort, Η., Borgna, J.L.: (1981).
75.
Horwitz, K.B., McGuire, W.L.: 8191 (1978).
76.
Eckert, R.L., Katzenellenbogen, B.S.: 257, 8840-8846 (1982).
77.
Täte, A.C., Jordan, V.C.: 211-219 (1984).
78.
Tate, A.C., Lieberman, M.E., Jordan, V.C.: Biochem. 20, 391-395 (1984).
Endocrinology 108, 96-102
Nature (Lond) 256, 592-595 Cancer Res.
Biochem. Biophys. Res. Comm. 118, 27-32 Biochem. Biophys. Res.
Mol. Cell. Endocrinol. _8_,
Mol. Cell. Endocrinol. 11,
J. Biol.
Nature (Lond) 292, 257-259 J. Biol. Chem. 253, 8185J. Biol. Chem.
Mol. Cell. Endocrinol. 36, J. Steroid
634 79.
Lieberman, Μ.Ε., Maurer, R.A., Gorski, J.: Acad. Sei. USA _7_5, 5946-5949 (1978).
80.
Jordan, V.C., Lieberman, M.E.: 285 (1984).
81.
Huggins, C., Briziarelli, G., Sutton, Η.: 104, 25-41 (1959).
82.
Sterental, Α., Dominguez, J.Μ., Weissman, C., Pearson, O.H.: Cancer Res. _23, 481-484 (1963).
83.
Sasaki, G.H., Leung, B.S.:
84.
Jordan, V.C.:
85.
Nicholson, R.I., Golder, M.P.: 579 (1975).
Proc. Natl.
Mol. Pharmacol. 26, 279J. Exp. Med.
Cancer 35, 645-651 (1975).
J. Steroid Biochem. 5, 354 (1974). Eur. J. Cancer 11, 571-
86.
Jordan, V.C.:
Europ. J. Cancer J ^ , 419-424 (1976)
87.
Jordan, V.C.:
Cancer Treat. Rep. ^0, 1409-1419
88.
Jordan, V.C., Koerner, S.: (1976).
89.
Terenius, L.:
90.
Jordan, V.C., Dowse, L. J. : (1976).
91.
Jordan, V.C., Jaspan, T.: (1976).
92.
Emmens, C.W.:
93.
Jordan, V.C.: Rev. on Endocrine-Related Cancer, Oct. Suppl. 49-55 (1978).
94.
Jordan, V.C., Dix, C.J., Allen, K.E.: In, Adjuvant Therapy of Cancer II, eds. S.E. Salmon, S.E. Jones, 1926 (1979).
95.
Jordan, V.C., Allen, K.E., Dix, C.J.: Rep. 6±, 745-759 (1980).
96.
Jordan, V.C., Allen, K.E.: (1980).
97.
Jordan, V.C., Dix, C.J., Allen, K.E.: In, Nonsteroidal Antioestrogens, eds. R.L. Sutherland, V.C. Jordan, 261280 (1981).
98.
Gullino, P.W., Pettigrew, H.M., Grantham, F.H.: Natl. Cancer Inst. _54_, 401-404 (1975).
99.
Rose, D.P., Pruitt, B., Stauber, P., ErtUrk, E., Bryan, G.T.: Cancer Res. _40, 235-239 (1980).
100.
Rose, D.P., Fischer, A.H., Jordan, V.C.: 17, 893-898 (1981).
(1976).
J. Endocr. ββ_, 305-310
Eur. J. Cancer 2< 57-64 (1971). J. Endocr. 68_, 297-303 J. Endocr. 68, 453-460
J. Reprod. Fert. _26_,
175-182 (1971).
Cancer Treat.
Eur. J. Cancer 16, 239-251
J.
Eur. J. Cancer
635 101.
Jordan, V.C., Mirecki, D., Gottardis, H.H.: In, Adjuvant Therapy of Cancer IV, eds. S.E. Salmon, S.E. Jones. Grüne & Stratton (in press).
102.
Jordan, V.C., Koerner, S.: (1975).
103.
Patterson, J.S., Edwards, D.G., Battersby, L.A.: Japanese J. Cancer Clinics. Suppl. 157-183 (1981).
104.
Fisher, B., Redmond, C., Brown, Α., Wolmark, N. and other members of NSABP. New Engl. J. Med. 305, 1-6 (1981).
105.
Baum, M. and other members of the 'Nolvadex' Adjuvant Trial Organization. Lancet _1_, 251-261 (1983).
106.
Tormey, D.C., Jordan, V.C.: _4, 297-302 (1984).
107.
Brown, R.R., Bain, R.R., Jordan, V.C.: 351-358 (1983).
Eur. J. Cancer J^, 205-206
Breast Cancer Res. Treat. J. Chromat. 272,
STUDIES ON GLUCOCORTICOID RECEPTORS IN NORMAL AND NEOPLASTIC RODENT AND HUMAN LEUKOCYTES:
STRUCTURE, DEGRADATION,
KINETICS OF FORMATION AND ACTIVATION * Nikki J. Holbrook , Jack E. Bodwell, Dirk B. Mendel, Allan Munck Department of Physiology, Dartmouth Medical School, Hanover, NH, USA * Present address:
Laboratory of Pathology, National Cancer
Institute, Bethesda, MD, USA
Introduction Over the past several years a major goal of our laboratory has been to characterize corticoid-receptor cell
under
functional studies
the various
complex
physiological and
was
kinetic the
chromatographic
which
forms of the gluco-
exist
conditions,
within
and
to define
relationships.
development
procedure
for
receptor complexes in cytosols.
of
a
the
Central rapid
analyzing
to
intact their such
minicolumn
glucocorticoid-
This procedure has enabled
us to perform studies which would otherwise be impossible. In this review we will attempt to summarize findings from several
of
our
recent
glucocorticoid-receptor
studies
aimed
at
characterizing
complexes in normal and neoplastic
cells both biochemically and functionally.
Results Characterization complexes.
of
rat
thymus
glucocortioid
As a prelude to more detailed
receptor
studies of the
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
638 cytoplasmic glucocorticoid-receptor complexes we first characterized by standard physicochemical procedures the nonactivated (non-DNA-binding) and activated or transformed (DNA-binding) complexes formed in rat thymus cells (1). For this purpose we used buffers containing sodium molybdate (2, 3) to block activation and stabilize the complexes. In
rat
acetonide
thymus (TA)
cells at
incubated
0°C,
the
with
cytosolic
[3H]-triamcinolone complexes
almost entirely of a non-activated species. activated and nonactivated activated
species
activated
to nonactivated
consist
At 37°C, both
complexes are present with the
predominating.
However,
the
ratio
complexes varies with
of
different
steroids as will be discussed below.
Traces of mero-recep-
tor
proteolytic
and
related
complexes
products of the native
(small
receptor
complex which
cleavage
retain the
steroid binding site) are also found, but these complexes may have been formed rapidly after the cells are broken. TABLE 1 CHARACTERISTICS OF GLUCOCORTICOID-RECEPTOR COMPLEXES FROM RAT THYMUS CELLS
COMPLEX PROPERTI ES NONACTIVATED
ACTIVATED
MER0-RECEPT0R
BINDS TO DNA
NO
YES
NO
ELUTION FROM DEAE CELLULOSE (mM KCl)
200
50
DOES NOT BIND
STOKES RADIUS (nm)
8.3
5.0
2.3
SEDIMENTATION COEFFICIENT
9.2
H]-TA AT 10 TIMES FINAL CONCENTRATION IN KRBg-HEPES AT 37"C WAS ADDED AT TIME 0 TO A THYMUS CELL SUSPENSION IN KRBg-HEPES AT 37'C, TO CIVE A FINAL CONCENTRATION OF ABOUT 15 nM. AT THE IMHCATED TIMES, ALI0U0TS OF CELL SUSPENSION WERE REMOVED FOR ASSAY OF HR, HR', AND HR'n. NONSATURABLE BIWINC, DETERMINED FROH A PARALLEL INCUBATION KITH 1 UM TA, GAVE CORRECTIONS (INDEPENDENT OF TIME) OF 1280 CPM FOR HR'n AND OF LESS THAN 2« FOR HR ANO HR'.
With the results in Figure 2, we can ascribe most of this delay to the time required for generation of of HR', the
644 presumed
intermediate between HR and HR'n, rather than to
the time required
for translocation and binding of HR' to
while the formation of HR1 clearly lags behind
the nucleus:
that of HR, no obvious delay is detectable in formation of HR'n relative to HR'. To further distinguish the rates of activation and nuclear binding these
we
performed
experiments,
incubated
for
glucocorticoid
'temperature a
cell
several to
jump
experiments'.
suspension
hours
at
which
0-3°C
form HR was warmed
had
with
rapidly
In been
labeled
to a given
temperature by dilution with 10 volumes of warmed buffer, left
for
the desired
amount
of
time, then
cooled,
lysed
rapidly by further dilution with cold t-lgCl2 and assayed for HR,
HR'
and
HR'n.
Such
experiments
warming step at 37°, 25°, formation
of complexes decreased
temperatures, no delay discernible
at any
were
and 15°C.
done
significantly
in formation of HR'n
temperature.
with
the
Though the rate of
Thus, we
with
lower
from HR' was
concluded
that
nuclear binding is much faster than activation, with a time constant of less than 10 sec. Our results with minicolumns also provided convincing support for our earlier suggestions (14) that triamcinolone acetonide and dexamethasone give higher steady state ratios of HR' to HR than Cortisol and corticosterone.
Cyclic
model
of
relationships.
receptor
kinetics
and
agonist-antagonist
To account for the results just outlined we
devised a cyclic model of receptor kinetics that accounts quantitatively for most of our own results and for results of others.
The model
(Fig. 3) assumes
reaction with rate constants k^ and
(i) a
reversible
for formation of
nonactivated complex HR from hormone Η and receptor R; (ii) an irreversible
reaction with rate constant
kn
for acti-
645
vation
of
HR
to
HR';
(iii)
a
rapid
reversible
(essentially an equilibrium) between HR' and bound
form HR'n;
reaction
its nuclear-
(iv) an irreversible reaction with rate
constant k ^ (the same as that for dissociation of HR) for regeneration of R from HR' and HR'n. coids are assumed required
to differ
only
Different glucocorti-
in
.
All
constants
for predicting kinetic behavious can be measured
experimentally, so that the model can be tested without ad hoc assumptions.
FIC. 3.
CYCLIC MODEL OF RECEPTOR KINETICS (13). HORMONE, H, IS ASSUMED TO REACT REVERS IBLY WITH FREE RECEPTOR, R, TO FORM A NONACTIVATED COMPLEX, HR, THAT THROUGH AN IRREVERSIBLE REACTION PRODUCES THE ACTIVATED COMPLEX HR·. HR' RAPIDLY EQUILIBRATES WITH THE NUCLEAR-BOUND COMPLEX, HR'n. HR' AND HR'n BOTH REGENERATE R THROUCH IRREVERSIBLE REACTIONS.
With measured values for TA and Cortisol the model not only predicts accurately the kinetic results in Fig. 2, but gives steady-state ratios of HR' to HR for the two steroids in quantitative agreement with those found experimentally even though
the
activation
steroid-specific
control
reaction of
has
no
activation.
provision The
for
different
646 ratios turn out to be dynamic consequences of the choice of for the rate of the regeneration reactions. The cyclic model predicts that steroids with high be partial antagonists.
should
Mathematically it can be shown (un-
published) that the cyclic model gives biological agonistantagonist
relations
essentially
indistinguishable
those of the steric-allosteric model (15). antagonism
should
be
from
According to the
cyclic
model,
predictable
from
k
alone.
However, the model does not exclude other mechanisms
of antagonism, such as allosteric equilibria or formation of covalent complexes; it provides an additional mechanism. Since the model includes irreversible steps, it also predicts that normal receptor function requires energy.
That
prediction is consistent with earlier studies in which we found
metabolic
proposed
a
evidence
receptor
for
cycle
an
energy
with
an
requirement,
ATP-dependent
and step
(possibly phosphorylation) for regenerating R (16).
Effects of ATP and pyrophosphate
(PP^) on activation
stability of cytosolic glucocorticoid-receptor complexes.
and Λ
number of studies have suggested a possible role for ATP in the
activation
function
(i.e.
of
steroid-receptor
translocation
activated complexes. reported
that ATP
or
complexes
nuclear
or
in
the
binding)
of
the
In particular, Moudgil and John (17)
at 5-10 mM
promotes
liver cytosolic complexes at 4°C.
activation
of
rat
In agreement with that
observation we have found that ATP promotes activation of rat thymus complexes at 4 C C however,
our
findings
(18) .
indicate
that
Somewhat
surprisingly,
this
is
effect
not
limited to ATP, as other nucleoside triphosphates and PP^ at the same concentrations are similarly effective.
Thus it is
unlikely that the activation seen in vitro is related to the
647
energy dependence of glucocorticoid-receptor
complex form-
ation seen in vivo (16). Two
additional
findings
of
interest
were
noted
when
we
looked further into the effects of PP^ and ATP on rat thymus receptor
complexes
(18) .
We were
initially
surprised
to
find that if we used these compounds to activate cytosolic complexes we achieved much higher levels of DNA binding than by warming cytosols to 25°C, with virtually no mero-receptor formation.
In fact, more than 95% of the total complexes
were converted to the DNA binding form, and that level was maintained for up to 24 hours.
This is in marked contrast
to warmed cytosols, in which by 24 hours more than 80% of total
complexes
are
converted
to
mero-receptor
forms.
Further analysis by gel filtration in the presence of ATP or PP^
revealed
conversion
to
that
these
compounds
mero-receptor.
do
However,
complex was not the 5.6 nm native
indeed the
prevent
DNA-binding
form but had a Stokes
radius of 3.1 nm. While the 5.6 and 3.1 nm DNA-binding complexes could not be distinguished by our standard minicolumn procedure, they could be separated using minicolumns in which the order of the DEAE and DNA columns were reversed, as the intact 5.6 nm DNA-binding complex binds to DEAE while the 3.1 nm complex does not. The 3.1 nm complex was subsequently shown to be formed in a time-dependent manner from the 5.6 nm form. It accumulates in ATP-treated cytosols because its conversion to meroreceptor is prevented. The protection against mero-receptor formation is dose-dependent and requires concentrations similar to those that activate complexes.
We also found that ATP and PP^ in the same
dose range interfere with binding of activated complexes to DNA-cellulose.
648 The ability of ATP and PP^ to activate glucocorticoid-receptor complexes and weaken binding of activated complexes to DNA-cellulose is most likely due to the charge properties of the
DNA-binding
domain
of
the
receptor.
Since
binding domain appears to be positively charged
the
DNA-
(19, 20) it
is reasonable to suppose that the strongly negative PP^ and ATP can both unmask DNA-binding sites on the receptor and weaken
binding
of
those
sites to DNA, by competing
negatively charged groups. prevent
formation
accounted
of
with
The ability of ATP and PP^ to
mero-receptor
can
for by the same properties.
probably
also
be
This hypothesis is
supported by the fact that the DNA-binding site appears to contain lysine residues (19) and lysine seems to be present at
the
sites
for
enzymatic
cleavage
that
yields
mero-receptor (21).
Sulfhydryl
groups
on
the
thymus
glucocorticoid
receptor
complex.
Glucocorticoid receptors in rat thymus and liver
cytosols
are
sensitive
to
sulfhydry1-modifying
reagents.
Treatment of unbound receptors with such reagents prevents binding
of
complexes
glucocorticoid (22-24).
to
However,
form once
glucocorticoid-receptor the
glucocorticoid
has
bound to the receptor, these reagents usually have little effect on the integrity
of the complex
(25-27).
We have
suggested that there is a sulfhydryl group in or near the DNA-binding domain of the activated thymic complex that must remain
reduced
for
the
suggestion originated highly
specific
methanethiosulfonate
complex
to
bind
to
DNA.
from the observations that:
sulfhydryl-modifying
reagent
This i) the methyl
(MMTS) and 5,5'dithiobis(2-nitrobenzoic
acid) (DTNB) substantially inhibit binding of the activated complex
to
DNA-cellulose
sulfhydryl-modifying
(27);
ii)
when
these
reagents are removed from the complex
with reducing agents such as dithioerythritol, the complex regains the ability to bind DNA
(27).
Not all sulfhydryl
649 modifying reagents produce these results.
The commonly used
reagents iodoacetamide and N-ethylmaleimide are ineffective at
inhibiting
DNA
binding
(27)
and
preventing
activated
liver complexes from binding to nuclei (26). A
central
question
that has concerned
us
is whether
the
sulfhydryl group involved with the inhibition of DNA binding after modification by MMTS and DTNB is the same sulfhydryl group whose modification
prevents the glucocorticoid
binding to the receptor.
In other words, is there a sulf-
hydryl group domains,
or
common to both is
there
a
the DNA- and
separate
group
from
steroid-binding
for
each
domain?
Evidence for the latter situation has come from our studies involving chromatography of receptor complexes on reactive sulfhydryl matrices. Reactive sulfhydryl columns (28) function as shown in Figure 4A.
A
thioanion
on
the
glucocorticoid-receptor
complex
(GRC) undergoes a thio-disulfide interchange reaction with the disulfide of the matrix, thereby
covalently
the complex to the matrix (I).
I Motrin - S-S-R + "S-GRC —
Matrix - S-S-GRC + "S-R
1
II Matrix-S-S-GRC + "S-R —'Matrix -S-S-R' + "S-GRC
DSCT — 0 0 0 Ι-0-C-N-CH-CH-N-C-CH-CH-C-N-CH-CH-S-S^Ö) 2 Η 2 2Η 2 2 Η ι V COO" C00" DSTT
ο
9 μ
2
2u
FIC. H] STEROID APPLIED TO COLUMNS
H» STEROID (CPH) RETAINED OW COLUMNS DNACELLULOSE DSTT DSCT
Γ Ή 1 Τ Α LABELED CVT0S0L5 UNMARKED
»796
162
-
133
«ARMED
3696
2359
-
2334
UNMARKED
4941
327
4938
WARMED
4807
2717
4940
UNWARNED
1412
76
1334
0
»ARMED
3890
3611
3880
3307
[3H1DM LABELED CYT0S0LS
* GLUCOCORTICOID RECEPTORS MERE LABELED IN INTACT TOYHUS CELLS MITH EITHER 20 nH [ ^ T R I AMCINOLONE ACETONIDE (TA) OR 50 nH [ S H]DEXAMETHASONE 21 MESYLATE (DH) f o r 2 HOURS AT 0 * C A W THE RESULTANT CYT0S01 EITHER MARMED FOR 15 MIN AT 25*C OR KEPT ON ICE. CYTOSOLS WERE THEN BOUND TO DNA CELLULOSE, DSTT, OR DSCT (291.
Two pieces of evidence suggest that the interaction of the complex with the DSCT matrix is through a sulfhydryl group in or near the DNA-binding domain. First, soluble DNA inhibits the binding of the activated complex to both the DSCT matrix and DNA-cellulose by a similar amount (29);
651
second, treating purified complexes with sulfhydryl modifying reagents inhibits binding to DNA cellulose to the same extent that DSCT-binding is inhibited (29). Evidence to support the idea that these are separate sulfhydryl groups associated experiments binding
in which
domain
receptor
with
was
the
with
the two domains comes
sulfhydryl
covalently
dexamethasone
group
blocked
in the
by
21-mesylate,
steroid
labeling
and
the
from the
complex
then allowed to react with the DSCT matrix.
If a common
sulfhydryl
the
existed
between
the
two
domains,
complex
should not bind to the DSCT matrix, but if there were 2 separate sulfhydryls it should bind.
As shown in Table 3,
the complex did react with the DSCT matrix, indicating the probable existence of a sulfhydryl group located near the DNA-binding domain. The sulfhydryl group associated with the DNA-binding domain appears to be located in a portion of the complex resistant to degradation.
We have digested the activated complex with
immobilized trypsin, thermolysin, subtillisin and endogenous thymic protease (29) to a point where DNA cellulose binding was lost, but there was only a moderate decrease in binding to the DSCT matrix. be
retained
though
Thus, this sulfhydryl groups appears to
on mero-receptor
the DNA
binding
and
function
related is
lost.
complexes, Using
even
similar
types of experiments Harrison et al. (30) also demonstrated the existance
of more
than one
activated
trypsin
digested
and
sulfhydryl complexes.
group
on both
However,
they
were unable to associate these sulfhydryls with functional areas of the complex.
Stability of cytosolic glucocorticoid complexes in leukemic cells. Glucocortiocids have been used in the treatment of leukemia for over 30 years. The benefit derived from
652 Steroid
therapy, however, varies widely within the parti-
cular subtype of di sease. lack
of
glucocorticoid
It is possible that in some cases responsiveness
is
the
result
of
subtle alterations either in the properties of the receptor itself
or
in
McCaffrey leukemia kemia
its regulation.
et
al.
(31)
subtypes,
(ANLL),
In
reported
particularly
appear
to
support
that
of
this
notion
from
some
acute nonlymphocytic
leu-
have
receptors
altered
characteristics
compared to those from normal lymphoid tissues when analyzed by
DNA
and
DEAE
chromatography.
They
hypothesized
that
these abnormal characteristics would correlate with lack of patient response to therapy. We have surveyed a number of leukemia specimens using the minicolumn procedure to determine the relative proportion of activated and nonactivated complexes in cytosols before and after warming cytosols to 25°C (cell-free activation) What
we
found
leukemia
was
cells
that
(CLL)
cytosols
contained
of
chronic
(32).
lymphocytic
glucocorticoid
receptor
complexes in proportions similar to those seen with normal lymphoid tissue.
At 0°C, most complexes were in the non-
activated
with
state,
mero-receptor
forms.
little In
evidence
contrast,
for
activated
specimens
of
or ANLL
classification displayed a much higher proportion of meroreceptor complexes and much lower proportion of DNA-binding complexes
than
CLL
or
normal
specimens.
Of
particular
interest was the question of whether these differences were due to degradation taking place after the cells were broken, or reflected
intrinsic differences
in receptors
from ANLL
cells. We undertook extensive studies to determine the cause of the lability from
of glucocorticoid
ANLL
accumulated broken.
cells rapidly
(33). in
receptor We
ANLL
complexes
found cytosols
that after
in
cytosols
mero-receptor cells
were
The accumulation was most rapid in cytosols which
653 contained
activated complexes or under conditions used to
produce activated complexes, but also occurred in cytosols containing only nonactivated forms. the
lability
of
cytosolic
It was of interest that
receptors
within
the
ANLL
specimens were related to the differentiation state of the cells. of
That is, cytosols of ANLL specimens with properties
monocytoid
differentiation
[M^
French-American-British
(FAB) class] in general contained more stable complexes than specimens primarily of myelocytic differentiation (M^ - M^ FAB classes) . cytosols
of
patterns
Consistent with this observation,
polymorphonuclear
cells
isolated
from
normal
blood were much more labile than those of monocytes. Most important, if cells were first incubated at 37°C with radiolabeled
steroid
to form activated
complexes in vivo,
then broken and analysed on minicolumns, there was in all cases clear evidence for activated or DNA binding complexes. From no experiments did we obtain evidence to suggest any difference in the native receptors of ANLL and CLL cells. We have concluded that the high proportion of mero-receptor in ANLL specimens was due to in vitro proteolysis of otherwise normal receptor complexes.
Further
support for this
conclusion is given by the studies below. We first hypothesized that the differences in lability of cytosolic preparations were due to the relative amounts of proteolytic enzymes capable of degrading the receptors.
If
so, then mixing labile and stable cell preparations prior to lysis should allow us to demonstrate the presence of such receptor-degrading enzymes. stable
preparations
in
In other words, complexes from
mixed
cytosols
should
no
longer
appear stable, but should be converted to mero-receptor by the proteolytic enzymes from the labile cell preparations. Unexpectedly, what the mixing experiments rather
than
the
labile
cytosols
causing
showed was that degradation
of
654
complexes from stable cytosols, the reverse was true; the stable
cytosols
cytosols
stabilized
(Figure 5).
stabilizing proportion
receptor
complexes
Further experiments
in
showed
labile
that the
effect was dose-dependent with respect to the of
characterize
stable the
cytosol
stabilizing
used.
Further
factor
from
attempts
human
to
leukemic
cells were hampered by the lack of availability of tissue. For this reason we looked for such a factor in other cell types.
These studies are discussed below.
pHlTA-ANLL + TA-ANLL
|3H|TA-CLL pHjTA-ANLL · TA-CLL • TA-CLL
| 3 H|TA-CLL * TA-ANLL
ANLL-CLL COMBINATIONS FIC. 5.
DISTRIBUTION OF CLUCOCORTI CO ID-RECEPTOR COMPLEXES IN WARMED CYTOSOLS OF MIXED ANLL AND CLL CELL PREPARATIONS. CELLS OF ANLL AND CLL SPECIMENS WERE INCUBATED WITH [3H]TRIAMCINOLONE ACETON I DE ([JH]TA) OR UNLABELED TRIAMCINOLONE ACETON I DE (TA) FOR 2 HOURS AT 0"C. EQUAL ALIQUOTS OF SUSPENSIONS WERE MIXED AT A RATIO OF 1:1 IN VARIOUS COMBINATIONS; FROM THESE MIXTURES, CYTOSOLS WERE PREPARED. Th€ CYTOSOLS WERE WARMED TO 25°C FOR 15 MIN AND ANALYZED ON MINICOLUMNS.
Calpastatin, a stabilizer of glucocorticoid-receptor complexes. In addition to human CLL cells the stabilizing factor is also present in many tissues including WEHI-7 mouse thymoma cells and rat liver and spleen cells (34). Interestingly, it is not present in rat thymus cells which contain relatively labile cytosolic complexes (8,34). Table 4 summarizes the properties of stabilizing factor partially purified from rat liver cytosol. As shown in the table, it appears to be very similar to calpastatin, a naturally occur-
655 ring
inhibitor
of
a
family
of
neutral
proteases called calpains (35-37). a physiological statin
and
relationship
Whether or not there is
between
glucocorticoid-receptor
further investigations.
calcium-activated
the calpains, complexes
must
calpaawait
An important practical consequence
of our findings however, is that the addition of calpastatin to thymus cytosols and to cytosols such as those from cells of
patients
with
ANLL
greatly
enhances
the
stability
of
complexes.
table k
PROPERTIES OF THE GLUCOCORTICOID-RECEPTOR STABILIZING FACTOR (CRSF) AND CALPASTATIN PROPERTY HEAT STABLE (100°C, 30 MIN) ELUTION FROM OEAE CELLULOSE (mM NaCl)
APPROXIMATE MOLECULAR WEIGHT OF NATIVE AGGREGATE
GRSF YES
CALPASTATIN YES
110
110 (100)
280,000
280,000 (280-300,000)
ISOELECTRIC pH
5.1
EFFECTS ON ACTIVATION OF GLUCOCORTICOID RECEPTOR COMPLEXES
NONE
5.1 Ct.55) NONE
VALUES ARE FROM B0DWELL, J.E., H0LBR00K, N.J. AND MUNCK, A. (UNPUBLISHED) FOR RAT LIVER CALPASTATIN. VALUES IN PARENTHESIS FOR NaCl CONCENTRATION AND MOLECULAR WEICHT ARE FROM MURACHI ET AL. (36), AND FOR ISOELECTRIC pH ARE FROM TAKANO AND MURACHI (37) FOR HUMAN ERYTHROCYTE CALPASTATIN.
Acknowledgements This research was supported by research grants AM03535 and CA17323 from the National Institutes of Health, and by the Norris Cotton Cancer Center Core Grant U. S.
Public
Health
Service.
(CA23108) from the
D.B.M. is a fellow of the
656 Albert
J.
Ryan
Foundation.
N.J.H.
was
supported
by
a
fellowship from the Leukemia Society of America.
References 1.
Holbrook, N.J., Bodwell, J.E., Jeffries, M.R., Munck, Α.: J. Biol. Chem. 25ji, 6477 (1983).
2.
Nielsen, C.J., Sando, J.J., Vogel, W.M., Pratt, W.B.: J. Biol. Chem. 252, 7568 (1977).
3.
Sherman, M.R., Moran, M.C., Neal, R.M., Niu, E.-M., Tuazon, F.B.: In Lee, H.J., Fitzgerald, T.J. (eds.): Progress in Research and Clinical Applications of Corticosteroids, Philadelphia:Heyden, p. 45 (1982).
4.
Raaka, B.M., Samuels, H.H.: (1983) .
5.
Vedeckis, W.V.:
6.
Simons, S.S., Jr., Schleenbaker, R.E., Eisen, H.J.: Biol. Chem. 2S8_, 2229 (1983).
7.
Sherman, M.R., Tuazon, F.B., Somjen, G.J.: In Soto, R.J., DeNicola, Α., Blaquier, J. (eds.): Physiopathology of Endocrine Diseases and Mechanisms of Hormone Action, New York:Liss, p. 321 (1981).
8.
Holbrook, N.J., Bodwell, J.E., Munck, Α.: Biochem. 20_, 19 (1984).
9.
Weatherill, P.J., Bell, P.A.: (1982) .
10.
Vedekis, W.V. :
11.
Sherman, M.R., Moran, M.C., Tuazon, F.B., Stevens, Y.-W.: J. Biol. Chem. 258, 10366 (1983).
12.
Simons, S.S. Jr., Thompson, E.B.: Sei. USA 78, 3541 (1981) .
13.
Munck, Α., Holbrook, N.J.: (1984) .
14.
Munck, Α., Foley, R. : (1980) .
15.
Sherman, M.R.: In Baxter, J.D., Rousseau, G.G. (eds): Glucocorticoid Hormone Action, Berlin:Springer, p. 123 (1979) .
J. Biol. Chem. 258, 417
Biochemistry _22: 1983
(1983). J.
J. Steroid
Biochem. J. 20β_, 633
Biochemistry 22^, 1975
(1983).
Proc. Natl. Acad.
J. Biol. Chem. 259, 820
J. Steroid Biochem. 12_: 225
657
16.
Munck, Α., Wira, C.H., Young, D.A., Mosher, K.M., Hallahan, C., Bell, P.A.: J. Steroid Biochem. 3, 567 (1972) .
17.
Moudgil, V.K., John, J.K.: (1980) .
18.
Holbrook, N.J., Bodwell, J.E., Munck, Α.: Chem. 25£, 14885 (1983) . DiSorbo, D.M., Phelps, D.S., Litwack, G.: Endocrinology 106, 922 (1980).
19.
Biochem. J. 190, 79 9 J. Biol.
20.
Schmidt, T.J., Litwack, G.: (1982) .
21.
Moran, M.C., Tuazon, F.B., Stevens, Y.-W., Sherman, M.R.: Fed. Proc. 60%),
the
synthetic At
to
60%,
inhibits the
time
progestins
whose
effects
progestins,
physiological
10
translocate
with
synthetic
1 or
partially
of R 5 0 2 0
progesterone,
in the m e d i u m .
50
either
coincides
Other
does
unlike
that,
concentrations these
1 hr p u l s e
blocked. as
have
treatment
extensively
4 days
is
in
approximately
a brief
growth,
rapidly metabolized
Ten days
more
least
replenishment cell
We
physiologic
concentrations or
are
proliferation
7).
Even
know
accumulation
It w o u l d be
changes
ER,
cell
the
cytoplasmic
attenuated
below.
or
inhibit
suppresses
elements,
not
antipromotional
of T 4 7 D ( , n c e l l s .
(Figure
do
changes
are
R5020-treated
T h i s m a y be the
or
contain
therapy.
estradiol
cells
consistent
cells.
further
We
filamentous
degenerative
cytostatic
inhibition
absence
progestins
are
although and
ultrastructural
after
Growth
nM
the
described
regressing
the
this,
cells
cytoskeletal
t o n o f i 1 a m e n t s.
differentiated
reflection see
of
regressive
common
inclusions, which
not f o u n d in the c o n t r o l are
a
biosynthesis.
Electron micrographs large
hormones
hormone
it
is
concentra-
t i o n s (0.1 μ Μ ) , e s t r a d i o l , a n d r o g e n s , g l u c o c o r t i c o i d s , a n d 1 , 2 5 d i h y d r o x y v i t ami η
D3
indicate
have
that
the
effects
proliferation
can
be
that
antiestrogens
no of
direct, and
effect
on
progestins and
cell
independent
progestins
can
growth.
on m a m m a r y target
of
Our
tumor
estrogen, different
data cell and cell
681 populations. in
T h i s m a y e x p l a i n the c l i n i c a l e f f i c a c y of p r o g e s t i n s
otherwise
endocrine
hormone-resistant
therapy
Progestins
are
and
outlined
insulin
culture
is u n d e r c o m p l e x
factors
added
to
the
tumors;
regulation
but
synthesized
exogenous
I n s u l i n is a c o m m o n m e d i u m s u p p 1 e m e n t a n d is growth
of all
by
the
and
cells required
human breast
cell l i n e s i n w h i c h it h a s b e e n t e s t e d ( 4 3 - 4 5 ) .
in
stimulatory
themselves.
serum-free
be
growth
factors
the c o n t i n u o u s
for
proliferation
i n v o l v i n g not o n l y
medium, can
Cell
inhibitory for
that
implications
below.
receptors.
growth
the
Moreover,
cancer insulin
and steroid hormones can reciprocally regulate each others actions (46-49).
We
among
heterologous
the
levels,
an
have
shown
effect
simultaneous
that
in
hormones
that
seems
cell-growth
T47DC0 that
to
be
inhibition
to
first
r o u n d of
control
cell
levels.
little
if a n y g r o w t h
number
of
peak
on
insulin
days
paralleled control
2
(42).
to
3. in
where
insulin
a new
real
increase
in
shows
the
that
during
1 to 3) the
then
first
increase cell
state the
of
settle
down
3 days,
when
4
the and
to a b o u t
8000
there are
in u n t r e a t e d To
insulin
binding
binding
is
receptors,
cells were
of
below
receptors
steroid
hormone hormones
to b i n d a n d
drοtestosterone
specific
specificity incubated or
translocate
pharmacological was
due
(days
compared
to
(42).
the
sufficient
systems.
cells
twice
sites/cell
i n s u 1 i n - b i n d i ng s i t e s / c e l l
determine
classes but
18 , 000
is
established.
increased
insulin
sets, 5-fold
proliferation
levels is
to
a n d not d u e to a c h a n g e in b i n d i n g a f f i n i t y . At s t e a d y s t a t e 5 to 9)
the
cells,
receptor
number
to
In u n t r e a t e d
slow
steady
related
in R 5 0 2 0 - t r e a t e d
sites/cell
are
receptor
increase slightly
during
Thereafter,
Scatchard analysis to a
(Days
is d e m o n s t r a b l e
binding
by a fall
values,
division
In c o n t r a s t ,
progestins insulin
closely
the n u m b e r of i n s u l i n b i n d i n g s i t e s / c e l l the
cells,
regulate
to
analogs, their
levels. R5020;
for
The neither
of
the
increase
5 days with at
concentrations
respective increase estradiol
receptors, in
dexamethasone,
insulin
nor
had any e f f e c t , c o n s i s t e n t with reports
The synthetic glucocorticoid
in
several
dihy-
in o t h e r decreased
682 the n u m b e r of known
variable the
insulin
depending
studies.
corticoid on
insulin binding
to m o d u l a t e
on
RU38
the
cell
486,
a
receptor
by 5 0 % .
are are
type
and
actions
levels when
together with R5020,
Glucocorticoids
levels, and their e f f e c t s
synthetic
and antiprogestiη
insulin
R5020.
sites
receptor
(see
to d i s t i n g u i s h
progestins
and
had
no
effect alone;
receptor
induction
that r e g u l a t i o n of
the
on i n s u l i n
antiestrogen
(ΙΟηΜ),
synthetic antiprogestational
as
experimental
tation or
clinical
486
tools,
inhibitors
--
(ΙμΜ).
studies.
contraceptives
been
However,
available
a candidate
for
antiprogestational clinical
trials
has
and
recently
been
implanbasic RU38
a-(1-propyn1)that
activity
in
has early
of a c t i o n a r e
unclear.
F u r t h e r m o r e , d e v e l o p m e n t of t h i s d r u g u n d e r s c o r e s an o l d
bioassay
problem:
that
progestins
is c o m p l e x
that among
effects
system.
of
circumvented
This
unknown when
therefore
actions
of
this
screening
because
progestational,
properties have
biological
progestational
estrogenized
Its m e c h a n i s m s
and
either
described
antigl u c o c o r t i c o i d
(50,51).
agents,
antiprogestiη,
[17ß-hydroxy-1lß(4-dimethy1 aminopheny1)-17
estra-4,9-dien-3-one ]
promise
a g e n t s - - as a n t i c a n c e r
have
Other
21-hydroxyproges-
nafoxidine
as m i d - c y c l e
none
marker
1,25-dihy-
T h e a n t i p r o g e s t i η , R U 3 8 4 8 6 . D e s p i t e the t h e o r e t i c a l of
by
insulin
in T 4 7 D C 0 .
receptors were
testosterone
in
to the c e l l s
from antiprogestins
that h a d no e f f e c t
(lOnM);
used
antigluco-
i n d u c i b l e p r o t e i n ) m a y be a u s e f u l
d r o x y v i t a m i n D3 ( Ο . Ι μ Μ ) : terone
with
below),
blocked
W e a r e t e s t i n g the p o s s i b i l i t y
hormones
conditions
it w a s a d d e d
it p a r t i a l l y
r e c e p t o r s (or a n y o t h e r
the
steroid
of
the
must
of be
has m a d e
progestins
physiological
superimposed
it d i f f i c u l t
antiprogestational, agents,
T47DC0
been used
are
a
problem
used
for
to c o n t r a s t
interesting
drug
to
and that
the
nm, and drug
to
this w a v e l e n g t h PR
concentrations
in (10
situ. nM)
of
upon
an
distinguish be
screening.
the a g o n i s t
entirely
These
and
cells
antagonist
(52).
can be u s e d Like
anti-
antiestrogenic can
W e f i n d that l i k e R 5 0 2 0 , R U 3 8 4 8 6 a b s o r b s U V at 300
and
requirement
the
[3H]RU38
synthetic
486
approximately
to c o v a l e n t l y bind
photolink
progestin,
two P R s u b u n i t s
low in
683 nuclei
of
T47Deo;
competition for
studies,
unlabeled
[3H]R5020
in s i t u
RU38
glucocorticoid binding
486 has a h i g h a f f i n i t y
n M at 0 - 4 ° C ) a n d transform more state.
Like
in i n t a c t
so
of
is a
nuclear
for P R in v i t r o
cells,
These
biochemical progestins,
To b i o a s s a y
as
we
a 1 hour
asked
RU38
486-pulsed the c e l l s
shown
Thus, conclude with
no
cells
for
have
is
a
it
evidence
cell of
R5020 R5020
alone,
growth
486
When
replenishment, effect
on
cell
the g r o w t h of 1 h o u r
at
least
4 days,
similar
to
that
after of
the
long-acting,
RU38
effects.
were
486
at
This
alone,
number
of
60 or
we
would
properties,
is, h o w e v e r ,
measured
incubated
486
the
marker,
progestiη-1ike is hrs the
not
level
with two
insulin
concentrations
the
hormones
binding
sites
sufficient
cell g r o w t h r a t e , h a d no e f f e c t o n increase,
o n the c o n c e n t r a t i o n
if i n s u l i n
levels
are
properties
used as
of e a c h h o r m o n e .
a biological expected
Thus,
marker,
RU38
of a n a n t a g o n i s t
486 (52).
of
medium
to
these
W h e n the two h o r m o n e s w e r e a d d e d to c e l l s t o g e t h e r ,
of
is
inhibited.
38 486 b l o c k e d 20 to 5 0 % of the R 5 0 2 0 - i n d u c e d
the
insulin
by 5 5 % .
remains
a biological
end-point
RU38
increased
but
as
agonist
T47DC0
translocate PR and alter proteins.
has
antagonist
receptors.
expected,
growth
486
the b i o l o g i c a l
together.
and
inhibition;
long-term for
are pure
RU38
receptor
at a r a t e
486 from
in g r o w t h
controls,
suppressed growth
RU38
PR
R5020.
RU38
containing as
would
is n o t
suppresses
of
2
results.
growth
486 b l o c k s
to h o r m o n e - f r e e
resumed
using
that
the c a s e w h e n insulin
of R U 3 8
cell
B.
binding
the c o m p o u n d
Other synthetic progestins are similarly here
inhibitor
(6 to 8 n M )
both growth
suppresses
combined,
this
Compared
controls. as
pulse
whether
growth. which
are
In
(K500 mg/day
( T a b l e 2), w i t h 789
induration and
to b e e q u a l l y
sub-
using
f r o m 2 to 23+ m o n t h s
was well
have developed
been
those
chosen
reported
patients of
treatment
the d a t a s h o u l d be
17 p a t i e n t s ,
injection the
of
in
the r e s u l t s of 11 c e n t e r s
progestins
in the
studies
treat m e t a s t a t i c
study
compiled
that
of
lesions.
objective positive
ranges
muscular showing
products
months.
et
using high-dose M P A prompted
the
therapy.
progestins
(54-81).
of
versus
have arbitrarily
p a t i e n t s h a v e a c c r u e d , a n d the total rate
sum
all m e a s u r a b l e
suggests
dose"
dose
the
u s e of p r o g e s t i n s
using
We
"high
in
with
side
effects
proven
(90)
than
progestins (90),
antiestrogens,
the
and
has
found are
their
hormones
687 T a b l e 3.
Responses Clinical
to T a m o x i f e n vs. P r o g e s t i n s
Proges t i η
Tamox i f e n Mattsson, Morgan,
in Same
Centers
1980 1982
15/32
(47%)
14/26
(54%) MPA
17/48
(36%)
14/46
(30%) MA
7/27
(26%)
4/28
(14%) MA*
Pannut i,
1982
7/26
(27%)
10/27
(37%) MPA
Johnson,
1983
14/49
(28%)
20/49
(41%) MA
17/58
(29%)
18/45
(40%) MPA*
17/80
(21%)
31/136
(23%) MA*
94/320
(29%)
111/357
Ingle,
1982
Van V e e l e n ,
1983
Al e x i e v a - F i g u s c h ,
1983
TOTAL
*low dose p r o g e s t i n MPA = m e d r o x y p r o g e s t e r o n e MA = m e g e s t r o l a c e t a t e R e f e r e n c e s 86, 94-99
T a b l e 4.
1979
v o n Mai 1 l o t , Forestiere, Bruno,
(25%)
concurrent
(100%)
concurrent
4/23
(17%)
concurrent
14/55
1980 1981
1982
1983
Garcia-Giralt, TOTAL
acetate
R e s p o n s e to C o m b i n a t i o n T a m o x i f e n / P r o g e s t i n R e f e r e n c e s 1 0 3 t o 108
Mouridsen,
Trodella,
(31%)
1984
4/4 8/18
(44%)
concurrent
19/36
(53%)
sequent ial
17/33
(52%)
concurrent
21/35
(60%)
sequent i al
87/204
(43%)
Therapy
688 That the
antiestrogens
treatment
clinical also
trials
from
a
combined
treated
with
studies
of
to
the p r o g e s t i n s ALL
brings
treatment
us
(described negative
further can
there are
still
hormonal
who
agents
data
hormonal
propose
mechanisms
these
to in
periods
(100-102).
Thus may
subsequent
regression
by
tamoxifen
not
treated preclude
combination
of
progestins Our
(T47DQQ),
this
setting.
become or
failed
and
Show
whose
that
tumors
relapsed
as
our
benefit to
other
tumors
report
or
ER that
Similarly,
can be of
whose
in
studies
resistant
studies
progestins
as
are
had
from
are
34%
of
been
previous
these
progestins; other
the
have
latter thereby
treatment
In
PR
pre-treatment of
ER-positive
should conferring
are
addition,
tumors
increased
brief
data,
different
two
tumors.
sensitivity
the
pathways
or
by
Antiestrogens
antiestrogens,
agents,
simultaneous increase
act
Therefore,
positive of
experimental
progestins
conceivable.
properties
with
well
and
estrogen-receptor
antiestrogens to
to
of
progestins
remission.
progestins
due to the e s t r o g e n i c short
show
tumors.
cells
or
Several
clinical,
promote
successful
were
did
role
antiestrogens,
antiestrogens
using
patients tamoxifen
postmenopausal.
this
the
in
to,
had
has
trial.
(83,84,88,90-92).
that
strategies
for
or
but
antiestrogen-resistant
that
dose
each,
therapy
tamoxifen.
tumor
respond
to high
resistant,
on
yet
or
growth
negative.
therapy
Based we
were
for
separate
had been p r e v i o u s l y
and
with
showing
to
357 with
consideration
breast
including
responded
antiestrogen
a
inhibit
fail
estrogen-receptor patients
women
(86,94,95)
below)
for
a n d 29% r e s p o n d i n g
these
therapy,
human
clinical
patients
which
treated
the p a t i e n t s
to
data
progestin
antiestrogen-resistant
cultured
progestins in
of
in
progestins
antiestrogen/progestiη the
of
chemotherapy
subsequent
This
7
useful
from
in t h e same c l i n i c a l
and 320 w e r e
these studies, to
which
results progestins
not o n l y
response
in
tamoχ i f e n
cytotoxic
response
similar
studies
3 )( 8 6 , 9 4 - 9 9 ) .
In many of with
of
may b e e q u a l l y
is suggested
compared with
31% r e s p o n d i n g (Table
cancer
reporting
number
been d i r e c t l y The
and p r o g e s t i n s
of b r e a s t
then
treated levels with tumors promote
synergistic
689 therapeutic
effects.
this
a
model:
breast and
There
total
cancer
of
have been
progestins,
sequentially
(Table 4). remissions
This
level
response
of
for
whose
The
still
a
total
is
as
good
Of
patient found
These in
a
44%
results
an
probably
be
estrogen
should
using to
Only
alternating clinical
the
trials
of
better,
than
not
22%
the
or and 43%. the
with
complete
Though by
combined
warrant rates
further
of
present
the t w o h o r m o n e s one
to
the
two
the p r o g e s t i n
could
a hormone-insensitive has
explored
two
hormones
of
these
(108).
the
antiin
interval
result
in
loss
cell
population
of
repeatedly
value
Clearly,
we 11-tolerated
can
weeks
E x c e s s i v e l y p r o l o n g i n g the
and
with
remissions.
theoretically,
progestin
al.
respectively).
rate
therapy
29%
et
pretreated
response
together, the
leaving study
response
therapy.
precede
one
tamoxifen
11% c o m p l e t e
heavily
combination
administered
the a n t i e s t r o g e n
(102).
of
response
(61% a n d 83%
included
increase
hormonal
of P R a l t o g e t h e r ,
if
support advanced
s t u d y by T r o d e l l a
was
objective
order t o m a x i m a l l y induce PR. between
the
therapy
which
attempt
day c o n v e n t i o n a l
rate was
as,
to
with
simultaneously
objective
note was
population
tamoxifen/progestiη,
study
either
response
or
data
women
a combination
given
chemotherapy and/or hormonal They
clinical
t a m o x i f e n or p r o g e s t i n s w h e n u s e d s i n g l y ;
and 31% respectively. (106)
treated with
response
rates
some
postmenopausal
(103-108)
34%
partial
are
204
more
extensive
hormonal
agents
are
warranted. 2)
The
second strategy
for
u s e of
progestins
is b a s e d
our s t u d i e s w i t h E R n e g a t i v e , P R p o s i t i v e , a n t i e s t r o g e n T47DC0 such
cells, which
cells.
Small
show
that
clinical
progestins
studies
MA, support
the i d e a t h a t a s i m i l a r
have become
resistant
using
therapy.
be c a n d i d a t e s 123
patients
Such
patients
for e n d o c r i n e show
that
22%
respond
to
tamoxifen
(Table
5).
(8%)
if
they
to
but
further
growth
of
of M P A
or
failed
to
tumors tumors
benefit
from
not c o n s i d e r e d
four
trials
progestins
In c o n t r a s t ,
have
doses
t r e a t m e n t , or w h o s e
are usually
therapies,
from tamoxifen (86,95,98,99).
inhibit
high
set of p a t i e n t s , w h o s e
to a n t i e s t r o g e n
h a v e no E R b u t a r e P R p o s i t i v e , m a y a c h i e v e progestin
can
tumors respond
on
resistant
based
to on
after
relapse
rarely
respond
to
progestins
690 Table
5.
Tamoxifen Studies
vs.
Progestin
Cross-Over:
Same
Center
Objective Mattsson,
Ingle,
1980
1982
Van V e e l e n ,
1983
Al e x i e v a - F i g u s c h ,
1983
Tam->fai 1 MPA+fai 1
MPA ΤΑΜ
6/10 0/10
(60%) (0%)
Tam-^fai 1 MA* -*f a i 1
MA* Tarn
2/16 2/18
(12%) (11%)
Tarn -»f a i 1 MPA+fai 1
MPA Tam
5/14 0/14
(36%) (0%)
Tarn MA*
MA* Tam
14/83 12/132
(17%) (9%)
Prog Tam
27/123 14/174
(22%) (8%)
* l o w dose p r o g e s t i n MPA = m e d r o x y p r o g e s t e r o n e MA = megestrol acetate Prog = p r o g e s t i n References 86,95,98,99
Table
ai1 ai1
Tam+fai 1 Prog-+f a i 1
TOTAL
6.
Receptor Content T h e r a p i es
acetate
and
Response
to
Objective
Endocrine
Response
ER+ ER-
312/586 33/264
(53%) (13%)
PR+ PR-
240/352 108/498
(68%) (22%)
ER+ ER+
PR+ PR-
230/323 85/263
(71%) (32%)
ERER-
PR+ PR-
10/29 23/235
(34%) (10%)
Cumulative References
Response
d a t a 14 s e r i e s 1978-1983 1,2,16,78,124-135
691 That breast
progestins
tumor
cells
implications, populations, agents
can
and by
and we
antiestrogens
different
propose
that,
the c o m p l e m e n t a r y be
used
to
inhibit
paths by
has
the
targeting
in
the
of
design
of
clinical
different
therapeutic actions
advantage
growth
important
cell
these
of
two
treatment
protocols. F i n a l l y , an area in
combination
have
been
with
performed
combined with 112)
have
after of
in w h i c h p r o g e s t i n s cytotoxic comparing
tamoxifen.
been
reported,
tamoxifen
addition
combination
reported
randomized response 218
of
and
by
obtained
two
et
non-randomized
(54%)
an
with
two
vs.
randomized
studies
showing
chemotherapy studies
showing
patients
that
al.
in
benefit
a significant
benefit
1973
studies
on
been
then
performed
with
In 6 s t u d i e s ,
progestin/chemotherapy
However,
chemotherapy
the
alone,
treatment
arms.
Nevertheless,
3
studies
with
p r o g e s t i n t h e r a p y , w e r e u n a b l e to s h o w a s t a t i s t i c a l l y between
was
Since
(114-118).
combined
response.
compared
chemotherapy
( 113 ).
have
f r o m 2 7 % to 7 5 %
objective
(114,116,117) difference
(109-
no
in c o n j u n c t i o n w i t h
Stott
rates varying
402
recent
studies
chemotherapy/tamoxifen.
T h e u s e of p r o g e s t i n s first
Similar
chemotherapy
Four and
h a v e a l s o b e e n u s e d is
chemotherapy.
chemo-
significant the
patients
t r e a t e d w i t h the p r o g e s t i n s e e m e d to h a v e a n i n c r e a s e d p e r f o r m a n e e status,
increased
and a protective MPA
has
induced it
is
been by
shown
of
of w e l l
to p r o t e c t
that
B.
patients
adriamycin
with
a progestin,
c h e m o t h e r a p y , a n d be m o r e of
being,
less
pain,
weight
on the b o n e m a r r o w ( 1 1 6 , 1 1 8 - 1 2 0 ) .
vincristine,
possible
presence
sense effect
reduced patients likely
and
against
the
marrow
toxicity
Since
neutropenia
cyclophosphamide
could
gain,
due
receive more
to s t a y o n the p l a n n e d
(121), to
the
intensive schedule
therapy.
Progesterone tumors
receptors
as
markers
of
hormone-dependent
692 E s t r o g e n receptors
(ER) have been used since 1971
(122) as
a guide to t h e r a p y , and they c o r r e c t l y predict a p o s i t i v e r e s p o n s e in 5 0 - 5 5 %
of
patients
(1,2,26,28,124-135)
(123). is
However,
even
improving
predictive
contrast,
receptor-negative
more
accuracy
assessment
useful
by
an
tumors
as
table
additional
rarely
of
tumor 6
shows,
15-20%.
respond
to
In
endocrine
t h e r a p i e s and such p a t i e n t s s h o u l d be c o n s i d e r e d c a n d i d a t e s alternate treatments.
PR
for
Not s u r p r i s i n g l y , few tumors are ER-, PR+
t h o u g h some of these may be falsely n e g a t i v e due to m e t h o d o l o g i c a l r e a s o n s (136).
O t h e r s may have E R that are either s e q u e s t e r e d in
an u n m e a s u r e d c o m p a r t m e n t or n o n f u n c t i o n a l , a n d m a y resemb/le the variant
T47Deo
subline
progestin sensitive. for p r o g e s t i n
that
is
antiestrogen
resistant
but
S u c h tumors s h o u l d be c o n s i d e r e d c a n d i d a t e s
therapy
(see
above).
P r o g e s t e r o n e receptors have also p r o v e n to be m o r e
accurate
than ER in p r e d i c t i n g p r o g n o s i s of limited stage (I a n d II) breast cancer
(3,137-140);
patients with
PR+
tumors
are 3 to 4
times
less likely to d e v e l o p m e t a s t a s e s than those w i t h P R - ones (137). an
independent
p r o g n o s t i c v a r i a b l e , a n d m o r e useful for p r e d i c t i n g
In
more
disease-free
survival Clark
advanced than
grade
either
III
clinical
disease, or
et al (3) r e p o r t e d similar
PR
are
pathological
results
staging
in p a t i e n t s w i t h
II b r e a s t cancer who w e r e u n d e r g o i n g a d j u v a n t therapy. study due
(141)
had
to the small
failed
to detect
number
these
of p a t i e n t s
(138). stage
A n earlier
relationships,
perhaps
evaluated.
References
1.
Horwitz
KB,
Science
189:726-727.
2.
H o r w i t z K B and M c G u i r e W L
3.
C l a r k G M , M c G u i r e WL, Hubay C A , P e a r s o n O H a n d M a r s h a l l 1983
McGuire
N e w Eng J M e d
WL,
Pearson OH 1975
and
Segaloff
Steroids
309:1343-1347.
A
1975
25:497-505. JS
693 4.
H o r w i t z KB, Z a v a DT, T h i l a g a r A K , J e n s e n E M a n d M c G u i r e 1978
Cancer Res
5.
H o r w i t z KB, M o c k u s M B a n d L e s s e y BA
6.
Keydar
I, C h e n L, K a r b e y
Chaitcik 7.
WL
38:2434-2437.
S and Brenner
1982
S, W e i s s
HJ
1979
Cell
28:633-642.
FR, D e l a r e a J, R a d u
Eur J C a n c e r
M,
15:659-670.
Horwi tz K B a n d M c G u i re W L
1978
J Biol C h e m 253 : 2 2 2 3 - 2 2 2 8 .
8.
Horwi tz K B and M c G u i re W L
1978
J Bi ο 1 C h e m 253 : 8 1 8 5 - 8 1 9 1 .
9.
Yamamoto
KR,
A c a d Sei
71:3901-3905.
10.
Gruol
Stampfer M R and Tomkins G M
DJ, K e m p n e r
ES a n d B o u r g e o i s
S
1974 1984
Proc
Natl
J Biol
Chem
259:4833-4839 . 11.
Li p p m a n M , B o l a n Κ a n d Huf f Κ
12.
Mockus
13.
M o c k u s M B and H o r w i t z K B
MB,
Lessey
Endocrinology
BA,
1976
Bower
C a n c e r Res 36 : 4 5 9 5 - 4 6 0 1 .
MA
and
Horwitz
KB
1982
110:1564-1571. 1983
J Biol C h e m i s t r y
258:4778-
4783. 14.
H o r w i t z KB, M o c k u s M B , Pike A W , F e n n e s s e y PV a n d RL
1983
J Biol C h e m
15.
S t e l l w a g e n RH a n d T o m k i n s G M
16.
K a l l o s J, F a s y TM, H o l l a n d e r BP a n d Bick M D
17.
Garcia M, Westley
18.
M c K n i g h t G S , Hager L a n d P a l m i t e r R D
19.
S a m u e l s HH, S t a n l e y F, C a s a n o v a J and Shao T C
A c a d Sei
Sheridan
258:7603-7610. 1971
J Mol Biol
56:167-182.
1978
P r o c Nat
75:4896-4900. Β and Rochefort
Η
1981
Eur J
Biochem
116:297-301.
Chem 20.
1980
Cell 2 2 : 4 6 9 - 4 7 7 . 1980
J Biol
255:2499-2508.
L e d e r A and L e d e r Ρ
21.
Hagino Ν
1972
22.
Zava
Landrum
DT,
Endocrinology
1975
Cell
5:319-322.
J Clin Endocrinol Metab B,
Horwitz
KB
and
35:716-721. McGuire
WL
1979
104:1007-1012
23.
Horwitz KB and McGuire WL
1978
J Biol C h e m 2 5 3 : 6 3 1 9 - 6 3 2 2 .
24.
Horwi tz K B a n d M c G u i re W L
1980
J Biol C H e m 255 : 9 6 9 9 - 9 7 0 5 .
25.
S h e r m a n M R , P i c k e r i n g LA, R o l l w a g e n F M and M i l l e r L K Fed Proc
26.
S t e v e n s J, S t e v e n s YW, R h o d e s J a n d S t e i n e r G Cancer
1978
37:167-173.
Inst
61:1477-1485.
1978
J Natl
694 27.
Lurquin
28.
P a c k m a n V and R i g l e r
PF
1974
29.
Compton
JG,
C h e m Biol
Schräder
B i o p h y s Res C o m m u n 30.
Compton Acad
31.
JG,
Sei
R
Interact
1972
WT
8:303-313.
Exp Cell Res
and
O'Malley
72:602-608.
BW
1982
Biochem
105:96-104.
Schräder
WT
and O ' M a l l e y
BW
1983
Proc
Natl
80:16-20.
Mul vihi 11 ER, L e P e n n e c J - P and C h a m b o n ER
1982
Cell
24:621-
Trends
Biochem
632 . 32.
Berg O G , Winter R B and Von Hippel
33.
L-°mb DJ and B u l l o c k
34.
H o r w i t z KB and A l e x a n d e r
Sei
PH
1982
7:52-55. DW
1984
Endocrinology
PS
1983
114:1833-1840.
Endocrinology
113:2195-
2201 . 35.
R a a m S, N e m e t h E, T a m u r a H, O ' B r i a n D S and C o h e n JL J Cancer Clin Oncol
36.
1982
Eur
18:1-12.
Dure L S , Schräder W T and O ' M a l l e y BW
1980
Nature
283:784-
785 . 37.
N o r d e e n SK, Lan N C , S h o w e r s M O and Baxter Chem
JD
1981
J Biol
256:10503-10508.
38.
Wegener
39.
M a r k a v e r i c h BM, R o b e r t s RR, A l e j a n d r o M A and C l a r k JH Cancer
A D and J o n e s
Res
LR
1984 J Biol C h e m
1984
44:1575-1579.
40.
J u d g e S M and C h a t t e r t o n R T
41.
Shiu R P C and P a t e r s o n
JA
1983 1984
C a n c e r Res Cancer
42.
H o r w i t z K B and F r e i d e n b e r g G R
43.
Allegra
44.
Barnes
D and Sato G
1979
Nature
D and Sato G
1980
Cell
J C and L i p p m a n M E
45.
Barnes
Butler W, K e l s e y W H and G r e e n Ν
47.
Knutson
VP, Ronnett
GV
and
1985
1978
46.
Sei
259:1834-1841.
Res
43:4407-4412. 44:1178-1186.
C a n c e r Res
Cancer
Res
In P r e s s .
38:3823-3829.
281:388-389.
22:649-655. 1981
Lane MD
C a n c e r Res 1982
Proc
41:82-88. Natl
Acad
79:2822-2826.
48.
Moore M R
49.
O s b o r n e CK, M o n a c o M E , K a h n R, Huff K, B r o n z e r t D and L i p p m a n ME
1979
1981
Cancer
J Biol C h e m
Res
256:3637-3640.
39:2422-2428.
695 50.
H e r r m a n n W , W y s s R, R i o n d e l A , P h i l i b e r t D, T e u t s c h G , Ε and Baulieu EE
1983
C R A c a d Sei
51.
J u n g - T e s t a s I a n d B a u l i e u EE
52.
Horwitz KB
53.
Beatson GT
54.
Escher 1951
1985
Lancet
Heber
JM,
In P r e s s .
i i : 104-107 .
Woodard
HQ,
Farrow
JH
and A d a i r
IN S y m p o s i u m of s t e r o i d s in e x p e r i m e n t a l
practice.
White A
Sakiz
294:933-938.
Exp Ce11 Res 1 4 7 : 1 7 7 - 1 8 2 .
Endocrinology
1896
GC,
1983
(Paris)
FE
and clinical
P. B l u k i s t o n , P h i l a d e l p h i a pp 3 7 5 - 4 0 2 .
55.
T a y l o r S G III a n d M o r r i s R S . 1951
56.
G o r d o n D, H o r w i t t BN, S e g a l o f f A, M u r i s o n PJ and S c h l o s s e r JV.
1951
Cancer 57.
Hormonal
59.
in cancer
of
35:51-61.
the breast
III.
5:275-277.
J o n s s o n U, C o l s k y J, L e s s n e r HE, R o a t h O S , Al per R G and J o n e s R Jr. 1959
58.
therapy
M e d C l i n Ν Amer
Cancer
Lewin
I, S p e n c e r
Cancer
Res 3:37
Douglas M, Med
12:509-520.
Η and
Herrmann
J.
1959
Proc Am
Assoc
Abst.
Loraine
JA and S t r o n g
JA.
1960
Proc Roy
Soc
53:427-431.
60.
Baker W H , Kel ley R M and Sohi er W D .
61.
Jo 11 es Β.
62.
B u c a l o s s i P, D i p i e t r o s J a n d G e n n e r i 191:702
1961
1960
A m J Surg 99 : 5 3 8 - 5 4 3 .
16:209-221. L. 1963
Practitioner
Abst.
63.
C u r w e n J.
64.
Stoll BA.
1963
Clin Rad
1965
steroids. 64a. Stoll
Brit J C a n c e r
RP Shearman
BA. 1967
(Ed.)
Brit M e d J
Cunningham
in o v a r i a n and s y n t h e t i c
Globe, Sydney
pp
147-155.
3:338-341.
65.
Segaloff
66.
M u g g i a FM, C a s s i l e t h PA, O c h o a Μ Jr, M, F l a t o w FA, G e l l h o r n
67.
Goldenberg
68.
Jones
Cancer
A,
14:445-446.
IN R e c e n t a d v a n c e s
M,
Rice
BF
and
Weeth
JB.
1967
20:1673-1678.
A and Hyman GA. V,
IS
1968 1969
Joslin
Ann
Int M e d
Cancer
CAF,
Jones
68:328-337.
23:109-112. RE,
Davies
G l e a v e EN a n d C a m p b e l 1 HF, F o r r e s t A P M
DKL,
1971
Roberts
Lancet
MM,
ϊ : 1049-
1050 . 69.
Edelstyn GA
70.
W e e t h JB.
1973 1975
Cancer
32:1317-1320.
P r o c A m A s s o c C a n c e r Res 16:38
Abst
150.
696 71.
R u b e n s RD, K n i g h t R K and H a y w a r d JL
1976
Europ J Cancer
12 : 5 6 3 - 5 6 5 . 72.
K l a a s s e n DJ, R a p p EF and H i s t e W E
1976
Cancer Treat
Rep
60:251-253. 73. 74.
Teulings
FAG,
vanGilse
HA,
1980
Henkelman MS,
Cancer Res
Portengen
Alexieva-Figusch
J
Alexieva-Figusch
J, v a n G i l s e HA, Hop W C J , P h o a C H ,
van der W i j s t J a n d T r e u r n i e t R E
1980
75.
Ross M B , B u z d a r A U a n d B l u m e n s c h e i η G R
76.
Clavel
Η
and
40:2557-2561. Cancer 1982
Blonk-
46:2369-2372. Cancer
49:413-
417. B, P i c h o n M F ,
C a n c e r C l i n Oncol 77.
Ansfield Obst
78.
FJ,
Pallud C and M i l g r o m Ε GJ
and
Singson
JP.
1982
PA, Bonomi
PD, A n d e r s o n K M , W o l t e r 1983
Hal 1 er DG, Gl i ck JH a n d Et t i nger NA. 86s
Abst
Alexieva-Figusch HA
1984
J,
JM, B a c o n
Pannuti
Villa
Res
Blankenstein MA,
S and DiFronzo
1983
J S t ero i d Bi o c h e m
Hop W C J , K l i j n
F, M a r t o n i
Mattsson W
84.
DeLena Μ,
JGM,
HandVanGilse
20:33-40.
G.
1984
Recent
Results
91:243-247. A , L e n a z G R , D i a n a Ε and Nanni
C a n c e r Treat R e p o r t s 83.
LD,
257.
Eur J C a n c e r C l i n O n c o l
DeLena Μ, Cancer
82.
Gyne
C a n c e r Treat R e p 67 : 717-720 .
L a m b e r t s SWJ , D e J o n g F H , D o c t e r R, A d l e r c r e u t z 81.
Surg
155:888-890.
Johnson
19 (suppl): 80.
Eur J
18:821-826.
Kallas
R o s s o f A H a n d E c o n o m o u SG 79.
1982
1978
Acta Radiologica Oncology
Brambilla C, Valagussa
Cancer Chemotherapy 85.
Castiglione
86.
MattssonW
Μ
and
Ρ
1978
62:499-504.
Pharmacology Cavalli
F.
17:387-400.
Ρ and B o n a d o n n a G
1979
2:175-180. 1980
Schweiz
Med
Wschr
110: 1 0 7 3 - 1 0 7 6 . related
1980
Press, New York 87.
I Ν Ro 1 e of M e d r o x y p r o g e s terone
tumors.
Iacobelli pp
S and
DiMarco
A
Medroxyprogesterone
Iacobelli 93-96.
Raven
65-71.
M a d r i g a l PL, A l o n s o A , M a n g a G P a n d M o d r e g o SP of
inEndocrine(Eds)
S and DiMarco A
in
1980
Endocrine-related
(Eds)
IN R o l e Tumors.
Raven Press, New York
pp
697 88.
Izuo Μ ,
lino Y a n d
Treatment 89. 90.
Morgan
Endo
Κ
1981
Breast
Cancer
Research
1:125-130.
LR,
Donley
PJ
and
Savage
C a n c e r R e s 24:134
Abst
529.
Pannuti
MRA,
DiMarco
F, G e n t i i i
J
1983
Proc Am
AR, Martoni
A,
Assoc
Giambiasi
M E , B a t t i s t o n i R, C a m a g g i C M , B u r r o n i P, Strocchi E, I a f e l i c e G , P i a n a E, a n d M u r a r i G
1983
INRoleofMedroxyprogesterone
in E n d o c r i n e - R e l a t e d T u m o r s V o l u m e 11 . C a m p i o L , R o b u s t e l l i Deila Cuna G and Taylor
R W (Eds) R a v e n P r e s s , N e w York
pp
95-104. 91.
Funes
HC, M a d r i g a l
PL, M a n g a s G P a n d M e n d i o l a G
of M e d r o x y p r o g e s t e r o n e II.
1983
C a m p i ο L, R o b u s t e l l i
(Eds) R a v e n P r e s s , 92.
Cavalli
New York
group
for
pp
clinical
Volume
II.
Campio
cancer
93.
DiCarlo
85s
Abst
Morgan
LR
Ingle
JN,
and
Donley
1978
97.
Ahmann
and
Taylor
J Steroid
Biochem
IN Breast
DL, G r e e n 1982
IN R e v i e w pp
SJ,
Volume
modern
II.
McGuire WL
of
Endocrine-
155-204.
1982 9
cancer:
301-310.
Edmonson
A m J C l i n Oncol
JH, C r e a g a n
ET,
5:155-160.
Pannuti F, M a r t o n i A , F r u e t F, B u r r o n i P, C a n o v a Ν and Hall S
1982
S
(Ed) R a v e n P r e s s , N e w York
IN The R o l e of T a m o x i f e n in B r e a s t C a n c e r . pp
Iacobelli
85-92.
J o h n s o n PA, Bonomi PD, W o l t e r JM, A n d e r s o n K M , E c o n o m o u and Abst
98.
PJ
pp
Supplement
Hahn RG and Rubin J 96.
1983
to therapy and r e s e a r c h
Related Cancer. 95.
Delia Cuna G
Ε.
(Ed) P l e n u m P r e s s , New Y o r k 94.
1983
255.
93a. H o r w i t z K B a n d M c G u i r e W L approaches
(SAKK)
69-75.
F, B u m m a C and G a l l o
19 ( s u p p l ) :
research
for
in E n d o c r i n e - r e 1 a t e d T u m o r s
L, R o b u s t e l l i pp
RW
77-83. F, M a r t z G , A l b e r t o P,
IN R o l e of M e d r o x y p r o g e s t e r o n e R W Raven Press, New York
Volume
Deila Cuna G and Taylor
F, G o l d h i r s c h A, Jungi
the S w i s s
IN R o l e
in E n d o c r i n e - R e l a t e d T u m o r s
DePeyster
FA
1983
Proc Am Assoc Cancer
Res
SG
24:172
680.
v a n V e e 1 en H, Rodi ng TJ, Schwei t z e r M J H , S l e i j f e r DT, T j a b b e s Τ and Willemse PHB Abst
259.
1983
J S t e r o i d B i o c h e m 19 (suppl)
86s
698 99.
Al e x i e v a - F i g u s e h van P u t t e n WLJ
J, K l i j n
1983
JGM,
Blonk-van
der
Wijst
J
J S t e r o i d B i o c h e m 19 ( s u p p l ) 87s
and Abst
260 . 100.
Horwitz KB,
Koseki
Y and M c G u i r e
WL
1978
Endocrinology
103:1742-1751. 101. Namer M , L a l a n n e C and B a u l i e u EE
1980
C a n c e r Res 4 0 : 1 7 5 0 -
1752 . 102. W a s e d a N, K a t o Y,
Imura Η and K u r a t a Μ
1981
Cancer
Res
41:1984-1988. 103. M o u r i d s e n HT, E l l e m a n n Κ, M a t t s s o n W , Palshof T, D a e h n f e l d t JL and R o s e C 104. V o n M a i l l o t
1979
Cancer
K, G e n t s c h
Res C l i n Oncol
Treat
Reports
HH, Gunselmann
63:171-175.
W.
1980
J
Cancer
98:301-313.
105. F o r a s t i e r A A , B r a u n T J , W i t t e s R E , Hakes TB and K a u f m a n R J . 1981
12th Int C o n g r e s s C h e m o t h e r a p y
Florence,
Italy Abst
265 . 106. T r o d e l l a Venturo 107. B r u n o M ,
L,
Ausi11i-Cefaro
I and M i n o t t i Roldan
(supp1):87 s
Ε and
Abst
108. G a r e i a - G i r a l t
G
E,
GP,
Turriziani
1982
Diaz
Β
109. Link
H,
3:129
Ruckle
Wochenschr
Saccheri
S,
5:495-499.
1983
Biochem
J Steroid
19
261. Jouve
M,
Palangie
T,
M a g d e l e n a t H, A s s e l a i n Β and P o u i l l a r t Ρ Clin Oncol
A,
Am J C l i n Oncol
Abst
Bretandeau
1984
B,
Proc Am Soc
C-504.
H, W a l l e r
HD and W i l m s
Κ
1981
Dtsch
Med
106:1260-1262.
110. T o r m e y D C , F a l k s t o n G , C r o w l e y J, F a l k s o n HC, V o e l k e l J and Davis
TE
1982
Am J Clin Oncol
5:33-39.
111. K r o o k J E , Ingle J N , G r e e n SJ and B o w m a n W D Jr Soc CIi η Oncol
1983
Proc A m
2:106.
112. C o c c o n i G , DeLisi V, Boni C , Mori P, M a l a c a r n e P, Amadori and G i o v a n e l 1 i Ε
1983
Cancer
113. Stott PB, Z e l k o w i t z L and T u c k e r W G Reports
57:106
Abst
D
51:581-588 . 1973
Cancer Chemotherapy
66.
114. B r u n n e r K W , S o n n t a g R W , A l b e r t o Ρ, S e n n HJ , M a r t z G , O b r e c h t Ρ and M a u r i c e
Ρ
1977
Cancer
39:2923-2933.
699 115
B u z d a r A U , T a s h i m a C K , B l u m e n s e h e i n G R , Hortobagyi HY, K r u t c h i k
AN, Bodey G P
and L i v i n g s t o n RB
GN,
1978
Yap
Cancer
41:392-395. 116
Rubens 1978
RD,
Cancer
Robustel1i 117
Begent
Role
of
RHJ,
Knight
Sexton
SA,
Hayward
JL
42:1680-1686.
Deila
Cuna G
and
Bernardo-Strada
Medroxyprogesterone
Iacobelli
RK,
S and
DiMarco Α
MR
1980
in E n d o c r i n e - R e l a t e d
(Eds) R a v e n
Press,
IN
Tumors.
N e w York
pp
53-64. Wander 118
Role
HE, B a r t s c h
Volume RW
119
II.
Campio
Pellegrini
A,
Muggiano
and
A
DiMarco Α
1983
Wils
RW
J,
Bioohem
Raven
Ε
V,
Borst
A,
pp
in
P r e s s , N e w York Η and
Taylor
Scheerder
Ionta
of
S and
29-51. Ρ and B e r n a r d o G
Endocrine-related Deila Cuna G
pp
131-140.
Η
1983
J
122
McGuire al.
123
and
Sugano
Cancer. Bloom
125
1980 Raven
M a t s u m o t o K, Ochi R
124
Inst M o n o g
WL
(Eds)
Cancer
Steroid
Η
IN H o r m o n e
Tobin
and C a n c e r . pp
E,
IN H o r m o n e s ,
(Ed) R a v e n Schreibman
Iacobelli
Izuo M , O k a m o t o
Receptors
and
Degenshein
Res C l i n Oncol
Breast 43-58.
GA
1980
1980
J Cancer
98:301-313.
D e g e n s h e i η G A , B l o o m N, T o b i n Ε
1980
127 128
M a n n i A , A r a f a h Β and P e a r s o n OH
129
Osborne CK, Yochmowitz MG, Knight WA Cancer
pp
45:2992-2997.
von M a i l l o t K , G e n t s c h HH and G u n s e l m a n n W 126
and
P r e s s , New Y o r k Β
S et
337-343.
H, N o m u r a Y , Takatani O, 1978
1971
34:55-70.
P r e s s , N e w York
McGuire WL
ND,
and
(suppl):85s.
J e n s e n EV, Block G E , Smith S, Kyser Κ and D e S o m b r e ER Nat C a n c e r
MT,
Medroxy-
Iacobelli
C a m p i o L, R o b u s t e l l i
Bron
IN
Tumors,
and
MG,
IN Role
P r e s s , N e w York
Raven
1983
Cuna G
Lippi
1980
of M e d r o x y p r o g e s t e r o n e
(Eds)
19
Deila
Deila C u n a G , C u z z o n i Q , Preti
II.
GA
85-93.
Mascia
Carboni-Boi
Volume
Taylor
Β,
pp
Nagel
Endocrine-Related
in E n d o c r i n e - R e l a t e d T u m o r s .
IN Role
Tumors
H C and
in
Robustelli
Massidda
(Eds)
Robustelli
121
L,
R a v e n P r e s s , N e w York
progesterone
120
HH, B l o s s e y
of M e d r o x y p r o g e s t e r o n e
46:2884-2888.
1980
Cancer
46:2789-2793.
Cancer
46:2838-2841.
III, M c G u i r e W L
1980
700 130. K i n g R J B 131. M c C a r t y
1980 KS
Jr,
Cancer
46:2818-2821.
Cox
Silva
C,
JS, W o o d a r d
BH, M o s s i e r
JA,
H a a g e n s e n D E Jr, B a r t o n TK, M c C a r t y KS Sr and W e l l s SA Jr 1980
Cancer
132. N o m u r a
Y,
46:2846-2850.
Takatani
Steroid Biochem
O,
Sugano
Η and Matsumoto
Κ
1980
J
13:565-566.
133. S k i n n e r LG, B a r n e s D M a n d R i b e i r o G G
1980
Cancer
46:2939-
1980
Cancer
46:2961-
2945 . 134. Y o u n g PCM, E h r l i c h C E a n d E i n h o r n LH 2963 . 135. H o l d a w a y
IM and S k i n n e r
SJM
1981
Eur J C a n c e r C l i n O n c o l
17:1295-1300. 136. Sarrif A M a n d D u r a n t J R
1981
Cancer
48:1215-1220.
137. P i c h o n M F , P a l l u d C , Brunet «M and M i l g r o m Ε Res
1980
Cancer
40:3357-3360.
138. Saez S, P i c h o n M F , C h e i x F, M a y e r M , P a l l u d C , B r u n e t Μ a n d Milgrom
Ε
1983
IN P r o g e s t e r o n e
C W , M i l g r o m Ε and M a u v a i s - J a r ν i s Ρ York
pp
and Progestins.
Bardin
(Eds) R a v e n P r e s s ,
New
355-366.
139. Saez S, C h e i x F a n d A s s e l a i n Β Treatment
1983
Breast Cancer
Research
3:345-354.
140. S c h u c h t e r L, B i t r a n J, R o c h m a n H, D e s s e r RK, M i c h a e l A a n d Recant W 141. S t e w a r t 1983
1984
P r o c A m Soc C l i n O n c o l
3:111 A b s t
432.
JF, R u b e n s RD, Mi 11 is RR, K i n g R J B a n d H a y w a r d
Eur J C a n c e r C l i n O n c o l
19:1381-1387.
JL
STEROID HORMONES, RECEPTORS AND NEUROTRANSMITTERS
Gary Dohanich, Bruce Nock and Bruce S. McEwen Laboratory of Neuroendocrinology, The Rockefeller University New York, NY
10021
Introduction The brain is characterized by its diversity of chemical signals and modes of communication, just as it is also known for its incredible anatomical complexity.
The two features are,
of course, closely linked, for it is one group of neuronal products which direct nerve cells to form specific contacts and then hold them together during development and another category of diverse cellular products which allows mature neurons to communicate with each other.
It is now recognized
that besides the traditional neurotransmitter substances released from synapses to act upon defined postsynaptic junctions to trigger electrical activity, there are other neuroactive substances with a less precisely-defined mode of action.
These substances, sometimes called "neuromodulators"
show their effects by modifying what other neuroactive chemicals do rather than by acting on their own to excite neurons (1).
Neuromodulators may have other, more-or-less "silent"
effects to influence energy metabolism or the capacity of cells to make, break down or respond to neurotransmitters or other neuromodulators - such modulatory effects may only show themselves under times of stress or prolonged activity. Among the "neuromodulators" are hormones arising from outside of the brain which gain access to the CNS from the cir -
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
702
culation or through the cerebral ventricles.
Protein and
peptide hormones such as prolactin (2) and ACTH (3-5) or TRH (6-8) are reported to alter nerve cell function and influence behavior.
Steroid hormones are also important regu-
lators of brain structure and function and produce effects during early development and in adult life which alter chemical transmission and neuromodulation and influence behavior and affective state.
Steroid hormones gain access to the
brain from the circulation and interact with receptors in certain groups of target neurons; mapping these receptor sites has occupied the efforts of a number of laboratories over the past 16 years (9-13).
Recently, emphasis has shif-
ted from locating receptor sites to how steroids affect brain function (eg. 14).
In these studies the effects of steroid
hormone exposure on neurochemical parameters has revealed a large variety of effects, ranging from direct interactions of certain estrogens with neurotransmitter receptors and metabolizing enzymes to more long-term actions to increase neurotransmitter receptor number or enzyme amount.
In addi-
tion, a new facet has been added by the observation that neural activity, and in particular certain neurotransmitters, may influence how steroid hormones act.
This review will
summarize selected aspects of these studies to provide a picture of the diversity of steroid hormone interactions with neural tissue. Steroid hormone receptors and actions in the brain The brain is responsive to estrogens, androgens, progestins, glucocorticoids and mineralocorticoids (15), and the actions of these hormones in neural tissue follow the general pattern of steroid hormone action throughout the body, which involves intracellular receptors that bind the hormone to the cell nucleus. However, there are three special features of steroid action in brain which deserve emphasis and will be described below.
703 Localization of receptors and effects Steroid receptors are not uniformly distributed throughout the brain but are discretely localized to groups of nerve cells in some brain areas (9-13).
In addition, glial cells
have receptors for at least one class of steroids, namely, glucocorticoids (16).
Each class of steroid receptor has its
own pattern of distribution.
For example, glucocorticoid
receptors are concentrated in hippocampus, septum and amygdala (13), whereas estrogen receptors are found predominantly in hypothalamus, preoptic area and amygdala (9—12). Steroid effects on these receptor-containing neural cells are highly diversified.
In many cases, this is a reflection of
the neurotransmitter phenotype of the cells in question: eg., estrogens regulate cholinergic enzymes in some neurons of the basal forebrain (see below) and tyrosine hydroxylase in some neurons of the arcuate nucleus (17-19) .
There are
many cholinergic and catecholaminergic neurons throughout the nervous system which are not apparently regulated by estrogens, and this is presumably due to the absence of estrogen receptors in these cells.
Sometimes, however, the regulatory
effects are not so clearly delineated according to neurotransmitter phenotype or presence or absence of hormone receptor. For example, estrogens regulate serotonin-1 and alpha-2 adrenergic receptors in some, but not all, estrogen-sensitive cell groupings where these neurotransmitter receptor types are also found (20-22).
And estrogen-sensitive neurons of
hypothalamus, preoptic area and amygdala may also be categorized on the basis of whether they show aromatase activity (conversion of testosterone to estradiol), progestin receptor induction, or both (23). Besides regional differences in hormone response, there are also sex differences in response to hormone which do not
704
coincide with obvious differences in hormone receptor level: eg., estrogenic regulation of cholinergic receptors and enzymes (see below), progestin receptors (24) and serotonin-1 receptors (21).
In such cases as these, there may be addi-
tional regulatory factors besides presence or absence of hormone receptor which determine the response of hormonesensitive cells to hormone (25). Developmental versus activational effects of hormones on neural tissue Receptors for gonadal and adrenal steroids appear early in development.
In the rat, this occurs just prior to or imme-
diately after birth (26).
In neurons, the elaboration of
receptors appears to follow the final cell division and coincides with the beginning of neuronal differentiation
(26).
The effects mediated by these receptors in early development are often qualitatively different from the effects which are mediated by the same receptors in mature neurons.
For
example, glucocorticoids promote the expression of the catecholaminergic phenotype in cells of the autonomic nervous system (27) and promote the development of the serotonergic phenotype in the CNS (28); once these phenotypes are established, they are not so susceptible to hormonal influence. Estrogens, on the other hand, promote neurite outgrowth in groups of neurons of the hypothalamus and preoptic area (29). Such growth is believed to form part of the process of sexual differentiation of the brain, whereby male and female brains become structurally and functionally somewhat different from each other (26).
During this period of morphogenesis and
synaptogenesis, estrogens do not have effects as they do in mature neurons, such as the induction of progestin receptors (30) .
705
Direct versus genomic effects of steroids Besides affecting gene expression via interactions with receptors in the cell nucleus, steroid hormones have direct effects on membrane-mediated processes and enzyme reactions. For example, glucocorticoids facilitate serotonin formation throughout the forebrain via a rapid action at nerve endings (31); and estrogens alter electrical activity of preoptic area and hypothalamus neurons within milliseconds after local application (32).
Moreover, the 2-hydroxylated metabolite
of estradiol interacts with enzymes such as tyrosine hydroxylase and catechol-O-methyl transferase and with receptors for noradrenaline, dopamine and serotonin, albeit at supraphysiological concentrations (33). It is frequently difficult to assess
the contribution which
such direct effects make to overall physiological regulation. On the basis of latency of effect, many steroid actions require minutes to hours (34); furthermore, they are often susceptible to interruption following treatment with RNA or protein synthesis inhibitors (12) leading to the conclusion that genomic actions are involved.
Nevertheless, non-geno-
mic direct effects of steroids may be superimposed upon genomic actions, as is apparently the case for progesterone facilitation of monoamine oxidase (MAO) activity in estrogen-primed hypothalamus (35).
Whereas the ability of pro-
gesterone to increase MAO activity is not blocked by protein synthesis inhibitors, it is dependent on prior estrogen priming in vivo over several days which involves, presumably, a genomic action. In the remainder of the chapter we shall examine in some detail other examples of gonadal hormone-neurotransmitter interactions, which may represent both direct and genomic effects. We shall, however, be looking at them from the standpoint of
706
their relevance to the mechanism of hormone action in regulating sexual behavior and neuroendocrine function related to reproduction.
Gonadal steroids and the cholinergic system of the brain Overview Steroid hormones are known to exert prominent effects on many complex physiological functions.
These actions can range
from a discrete fine-tuning of a particular function to the full activation of a system.
Research on peripheral target
structures indicates that one mechanism by which steroids may influence cellular activity is through the regulation of protein synthesis (36).
Clearly, if central neurons that
concentrate steroid hormones behave in a similar fashion, the consequences for neuronal activity could be profound. Although classical neurotransmitters are not proteins, their synthesis, degradation, and uptake involves enzymes, carriers and receptors, all of which are proteins.
Consequently, one
way that steroids might regulate neurotransmitter activity is by altering the concentrations of proteins associated with these transmitters.
Conceptually, this capacity to regulate
neurotransmitter activity provides a mechanism by which steroids can activate intricate physiological and behavioral responses. In this section, we review evidence pertaining to steroid effects on one neurotransmitter system - acetylcholine. Within this framework, we attempt to implicate the hormonal regulation of the cholinergic system in the mediation of a specific reproductive behavior.
It is now clear that gona-
dal steroids such as estradiol,testosterone, and progesterone
707 have the capability of altering the concentrations and activities of the various neurochemicals involved in cholinergic transmission.
Furthermore, sexually-dimorphic functional
responses to gonadal hormones may arise, in part, from the existence of sex differences in the hormonal regulation of cholinergic neurochemistry.
The exact manner in which these
hormone-induced changes in cholinergic activity might be translated into biological function remains speculative. However, available evidence suggests that certain biological systems which are controlled by steroid hormones have a cholinergic component that is itself regulated by these hormones. One system that is clearly dependent upon the action of gonadal steroids is reproductive behavior.
Lordosis is a posture
assumed by the female rat when mounted by the male during the period of sexual receptivity.
Removal of the ovaries aboli-
shes the capacity for lordosis in female rats while systemic administration of estrogen (estradiol) for several days followed by progesterone restores lordosis in ovariectomized females 4-8 hr after progesterone injection (37). It has been demonstrated that intracerebral administration of agents which elevate cholinergic activity stimulate the occurrence of this behavior in ovariectomized female rats (38-42) . In addition, if ovariectomized females are primed with low doses of estradiol which are behaviorally inactive, the stimulatory effect of cholinergic agonists on lordosis is dramatically enhanced (41) .
This facilitation of lordosis by
cholinergic agonists is prevented if females are pretreated with cholinergic receptor blockers.
Conversely, agents that
antagonize cholinergic activity within the central nervous system have been found to reduce the incidence of lordosis in sexually-receptive female rats (39, 41, 43).
708
The minimum physiological dose of estradiol required to activate lordosis is also capable of inducing cholinergic receptors in the hypothalamus (44) and elevating cholinergic enzyme activity in the basal forebrain (45).
In addition,
both of these cholinergic changes are evident within 24 hr after estradiol treatment, the precise time at which the onset of sexual receptivity occurs (44).
These data indicate
that the regulation of cholinergic neurochemicals by estradiol may be one mechanism by which this gonadal steroid controls sexual behavior in the female rat.
The following sec-
tions review some of the effects of gonadal hormones on cholinergic neurochemistry within the brain.
Muscarinic receptors Cholinergic muscarinic binding is influenced by estrogen in brain regions that mediate female sexual behavior.
Estradiol
increases the number of muscarinic binding sites in the medial basal hypothalamus of ovariectomized female rats (44, 46-49).
In microdissected samples, discrete subregions of
the hypothalamus that heavily concentrate estradiol such as the ventromedial hypothalamus and anterior hypothalamus display similar estrogen-induced increases in muscarinic binding (46).
These increases are dependent upon protein synthesis
since they are not observed when a protein-synthesis inhibitor is administered in conjunction with estradiol (44).
Male
rats, which are capable of only low levels of lordosis behavior, fail to display changes in muscarinic binding in the hypothalamus following estrogen treatment (44, 47-49). Olsen et al have suggested that this regulation of muscarinic binding by estrogen in the medial basal hypothalamus is not relevant physiologically since they have detected significant changes in muscarinic binding over the estrous cycle only in
709
the medial preoptic region (48).
However, available data are
inconsistent in the medial preoptic region of ovariectomized female rats where estrogen has been reported to increase (48), decrease (47), or not alter (49) muscarinic binding.
A varie-
ty of dissection procedures and estradiol regimens might explain these discrepancies.
Reliable changes in muscarinic
binding induced by estrogen have not been observed in other brain regions, including the arcuate nucleus, cerebral cortex, striatum, and amygdala (46, 47, 49). Using a novel tritiated muscarinic antagonist, N-methyl-4piperidyl benzilate, Sokolovsky and coworkers (50) reported that ovariectomy increased muscarinic binding in the median hypothalamus of rats and estradiol replacement returned binding to intact estrous levels.
In an earlier study, these
investigators failed to find differences in total muscarinic binding between males and females at three stages of the estrous cycle (51).
However, a competition analysis of high and
low affinity subtypes of the receptor revealed that the percentage of the high affinity subtype was significantly greater in the preoptic area of proestrous females compared to estrous and diestrous females and males.
Furthermore, when
preoptic homogenates from proestrous females were preincubated with estradiol, the percentage of high affinity sites was substantially reduced (52).
These results suggest that est-
rogen may have important membrane-mediated effects on muscarinic receptor subtypes, in addition to those effects mediated by intracellular receptors. Consequently, the medial basal hypothalamus and the medial preoptic area appear to exhibit alterations in muscarinic receptor density following estrogen treatment. Since both of these brain regions have been implicated in the control of lordosis by a variety of techniques, it is likely that this hormonal regulation of muscarinic receptors contributes
710
to the expression of this behavior.
Cholinergic enzymes Choline acetyltransferase. Anatomically the origin of cholinergic fibers that innervate the preoptic and hypothalamic regions has not been identified.
One possible source of in-
nervation, however, is the vast continuum of cholinergic neurons that populate the basal forebrain areas of the medial septum, diagonal band nuclei, substantia ventral palladium.
innominata, and
Although no distinct anatomical connec-
tion with preoptic and hypothalamic neurons has been discovered to date, cholinergic cells of the basal forebrain are particularly intriguing since their neurochemical activity can be influenced by gonadal steroids. Choline acetyltransferase (CAT) is the major enzyme controlling the synthesis of acetylcholine.
A variety of studies
have detailed alterations in CAT activity in the forebrain region following treatment with steroid hormones.
Work from
this laboratory (45) indicates that estradiol increases the activity of CAT in the horizontal limb of the diagonal band of Broca in female rats.
In minimal treatment paradigms,
ovariectomized females are exposed to pure estradiol from Silastic capsules (1 cm) for 6 to 24 hrs and sacrificed 24 hrs after capsule implantation.
This elevation of CAT acti-
vity in the horizontal limb appears to reflect a protein synthesis-dependent increase in the concentration of CAT (53) Interestingly, a portion of the cholinergic neurons in this region have been reported to concentrate estradiol (54). Although male rats fail to show a similar increase in the horizontal limb, estradiol was found to decrease the activity of CAT in the vertical limb of the diagonal band in males
711
(45).
Several adjacent regions, including the bed nucleus,
medial preoptic area, and anterior hypothalamus failed to exhibit any alteration in CAT activity following estrogen treatment of either sex (45).
Estradiol treatment also did
not affect CAT activity in the medial basal hypothalamus (55). Similar elevations of CAT activity in the horizontal limb of female rats were not observed by Muth et al (56) following estrogen treatment; however, difference in tissue dissection and estrogen regimens may account for this discrepancy. These investigators did observe a significant reduction in CAT activity in the vertical limb of the diagonal band in castrate males following testosterone propionate treatment similar to that observed by this laboratory in the male vertical limb following estradiol administration (45).
In intact cycling female rats, the activity of CAT has been reported to be lower in the anterior portion of the hypothalamus during estrus compared to other stages of the cycle (57).
A similar, though insignificant, reduction has been
observed during estrus compared to diestrus in the preoptic suprachiasmatic area of intact female rats (58).
At present,
the relationship between these lower levels of hypothalamic CAT activity during estrus and increases in basal forebrain CAT activity following estradiol treatment of ovariectomized females is not understood. Cholinergic neurons located in the horizontal limb are known to project to various telencephalic structures (59, 60) and two areas that receive such projections, the hippocampus and amygdala, also display small but significant increases in CAT activity after estrogen treatment of female rats (55). Since these areas probably do not contain cholinergic cell bodies, it is possible that the alterations in CAT activity arise from afferent projections from the cholinergic neurons
712
of the horizontal limb.
Another area that receives projec-
tions from the horizontal limb, the cerebral cortex (59, 60), does not appear to display changes in CAT activity over the estrous cycle of female rats (58).
However, James and Kanun-
go (61) have reported age-dependent increases in CAT activity in the cerebral cortex of male rats within four hours after administration of testosterone or estradiol.
Males
sacrificed more than 12 hours after hormone treatment failed to exhibit increases in cortical CAT activity.
This rapid
cortical effect appears to be quite different from the results obtained in the basal forebrain where alterations in CAT activity are observed at least 24 hrs after the initiation of hormone treatment (45). Acetylcholinesterase. Steroid hormones also have been found to affect the activity of the major degradative enzyme of acetylcholine, acetylcholinesterase regions.
(AChE), in several brain
Work from this laboratory has demonstrated that
estradiol increases the activity of AChE in the horizontal limb of the diagonal band in ovariectomized female rats, an effect that parallels the actions of estrogen on CAT activity (45).
Estrogen did not alter AChE activity in the
vertical limb of the diagonal band, the bed nucleus of the stria terminales, the medial preoptic areas, or the anterior hypothalamus.
Nor did estrogen affect AChE activity in any
brain area examined in castrated male rats. In the cycling female rat, Libertun et al (58) reported significantly lower activity of AChE at estrus compared to diestrus in preoptic-suprachiasmatic area.
No stage differen-
ces were detected in the cortex or arcuate-mammillary region. Changes in AChE activity induced by gonadal steroids have been observed in the cerebral cortex of male rats (61, 62),
713
a region that is devoid of cholinergic cell bodies but which receives cholinergic projections from basal forebrain neurons. Generally, gonadectomy was found to decrease the activity of AChE in male cortex while testosterone and estradiol increased enzyme activity 4 hrs after administration.
Estradiol
was also found to increase AChE activity in the cortex and cerebellum of ovariectomized females 4 hrs after treatment (62).
These increases may have been mediated by induction
of intracellular protein synthesis since actinomycin D, a protein synthesis inhibitor, prevented the elevations in AChE activity in both cortex and cerebellum when administered in conjunction with estradiol (62). Using a similar hormone regimen, Iramain et al reported that estradiol increases AChE activity in the amygdala of castrated male rats and in the amygdala and adenohypophysis of ovariectomized females 4 hrs after injection (63, 64) while progesterone alone increased AChE activity in the amygdala, cerebral cortex, and mesencephalon
of ovariectomized female
rats 4 hrs after treatment (65). Several investigators have noted various sex differences in baseline activity and distribution of AChE in certain brain regions.
In this laboratory, the baseline activity of AChE
was found to be significantly higher in the horizontal limb of long-term ovariectomized female rats when compared to long-term castrated males (45).
AChE activity has also been
reported to be significantly higher in the preoptic-suprachiasmatic area of intact female rats compared to intact males (58).
In the gerbil, the distribution of cells that
stain histochemically for AChE in the preoptic-anterior hypothalamic region is clearly different in males and females (66).
Neurons in this preoptic-anterior hypothalamic region
do not stain darkly enough to be classified as cholinergic cells, rather they may represent a population of cells that
714
receive cholinergic innervation.
Female gerbils display a
rounder and more diffuse distribution and appear to possess a lower level of activity in this area compared to males as determined by densitometry.
Gonadectomy reduced the activi-
ty of AChE in both sexes while treatment with testosterone stimulated the activity of the enzyme. While gonadal hormones induce a variety of effects on CAT and AChE activities in a number of brain regions, the functional significance of these changes is unclear at present. Estrogen does not appear to alter the activities of these two enzymes in the preoptic area or medial basal hypothalamus (45,55 ), two regions where muscarinic receptor density changes following estradiol treatment.
On the other hand,
both enzymes display variations over the estrous cycle in the preoptic and anterior hypothalamic regions (57, 58).
In ad-
dition, the existence of reliable sex differences in the activity, distribution, and hormone inducibility of these enzymes (45, 58, 66) may have important implications for the regulation of sexually-dimorphic functions, such as reproductive behavior.
Acetylcholine The effect of gonadal steroids on the actual release of acetylcholine would be of particular value to the understanding of how hormones regulate cholinergic neural activity.
How-
ever, the effects of steroids on the concentration of acetylcholine have not been well documented, partly due to the difficulties inherent in direct measurement of this transmitter. Furthermore, the turnover of acetylcholine which may represent a useful index of cholinergic activity, has proven to be even more difficult to measure.
Using a radioenzymatic
715
technique, Muth, Crowley and Jacobowitz (56) found that castration of male rats elevated the level of acetylcholine in three discrete brain areas; the rostral diagonal band, medial preoptic nucleus, and ventral tegmental area.
These increa-
ses were partially prevented by treatment of castrates with testosterone propionate.
In female rats, treatment with
estradiol benzoate in combination with progesterone reduced the concentration of acetylcholine in periventricular nucleus and ventral tegmental area compared to ovariectomized control females.
There were no changes observed in acetylcholine
level in either sex in a number of other brain areas that concentrate testosterone and estrogen.
The significance of
these results remains to be determined.
Functional implications Although the precise nature of the changes in cholinergic neurochemistry induced by hormones is controversial, the major conclusion that emerges from these experiments is that steroid hormones, acting as neuromodulators, are indeed capable of regulating cholinergic events within the central nervous system.
Perhaps, the variety of observations made by
investigators reflects the dynamic quality of this regulation, which may be unusually sensitive to the subtle effects of time and environment.
In support of this suggestion, a wide
circadian variation in muscarinic binding in rat forebrain has been observed (67).
Additionally, significant strain and
species differences in cholinergic neurochemistry have been demonstrated by a number of studies (68, 69).
And, in a more
specific instance, the activity of the membrane-bound uptake system for choline, a precursor for acetylcholine, has been shown to be influenced by the simple act of handling the animals prior to sacrifice (70).
716
Evidence of a cholinergic component in hormone-dependent functions other than reproductive behavior, such as gonadotropin release (71-74) and scent marking (75), indicates that this particular hormone-dependent interaction may have important implications for the regulation of certain complex systems of physiology and behavior.
Clearly, the ability of
hormones to alter the level of neurotransmission within the brain is a critical feature of central hormone action.
Modulation of steroid action by neurotransmitters Overview Behavioral, environmental and age related factors can influence steroid-dependent processes.
Often, changes in
steroid secretion mediate the effects of these factors.
How-
ever, responses to steroid hormones are not "hard-wired"; and not all changes in steroid-dependent processes are accompanied by changes in circulating steroid levels.
For example,
time of day and season of year can have important effects on the sensitivity of reproductive processes to steroid hormones (76-85).
Shifts in responsiveness to steroids also occur
during early development, puberty and old age (86-91). At present, only a few modulators of steroid action are known. One modulator of progestin action that has been extensively studied is estrogen.
Exposure to estrogen increases the num-
ber of progestin receptors in some central and peripheral tissues (92, 93) and, thereby, plays a major role in regulating the sensitivity of those tissues to progestins.
Some
nucleotides can influence the binding of steroids to receptors and, therefore, might also modulate steroid action (94-98).
In this section, we review recent evidence for ano-
717
ther class of steroid modulator, neurotransmitters. An obvious site for the modulation of steroid action by neurotransmitters is the brain, where steroid target cells receive many neural afferents of diverse origin.
Surprising-
ly, however, much of the research in this area has been conducted with peripheral organs such as pineal, pituitary and uterus. (99-102).
This work has been discussed in detail elsewhere Here, we focus on research concerning the regula-
tion of steroid action by neurotransmitters in the brain. It should be kept in mind that the idea that neurotransmitters can affect steroid action in brain is relatively new and, therefore, there is not as yet incontrovertible evidence for any given neurotransmitter modulating the action of any particular steroid.
However, taken together with findings
with peripheral organs the existing evidence strongly supports the concept that neurotransmitters can modulate target cell sensitivity to steroid hormones.
Dopaminergic regulation of estrogen action The hypothalamus is an important site of steroid action in brain. Interestingly, a number of cell bodies that concentrate radioactive steroid in hypothalamus appear to be surrounded by catecholamine terminals (103-104). One of the first indications that this catecholamine input might influence the sensitivity of the steroid concentrating cells to steroids was provided by experiments with the catecholamine neurotoxin 6-hydroxydopamine (6-OHDA). Marks et al (105) found that infusion of 6-OHDA into a lateral cerebral ventricle of rats caused a decrease in the concentration of a "soluble estrogen binding protein", presumably cytosol estrogen receptors. Later, Thompson et al (106) found a similar effect with the catecholamine synthesis inhibitor α-methy1-p-tyrosine.
718
Acute treatment of female rats with AMPT decreased receptor-mediated 3H estradiol uptake in anterior and basal hypothalamus (by 35-40%).
Estradiol uptake in dorsal hypothala-
mus and in cerebral cortex and the level of radioactivity in plasma were not affected by AMPT. Experiments with dopamine receptor agonists and antagonists indicate that the effects of 6-OHDA and of AMPT on hypothalamic estrogen receptors might be attributable tc changes in dopamine function.
Acute treatment with the dopamine agonist
apomorphine or bromocriptine increased (by 60-90%) receptormediated 3H estradiol uptake in the nuclear fraction of ante^ rior and basal hypothalamus of female rats.
Estradiol uptake
in cerebral cortex and plasma levels of radioactivity were not affected by the agonists (107, 108).
Some caution should
be exercised with regard to dopamine agonists.
Some dopamine
agonists bind to estrogen receptors (but not progestin or androgen receptors) with a relatively high affinity.
For
example, bromocriptine competitively inhibits 3H estradiol binding to hypothalamic estrogen receptors in vitro with a Ki of about 25 uM.
Also, some agonists,including bromocrip-
tine, might induce estrogen-inducible proteins such as progestin receptors through the estrogen receptor system although this has been tested only in gonadally intact immature rats thus far (109).
Thus, it is conceivable that dopamine
agonists might affect estradiol uptake in hypothalamus through an interaction with estrogen receptors rather than through dopamine receptors.
However, pretreatment with the
dopamine antagonist perphenazine blocked the agonist-induced increase in estradiol uptake in hypothalamus (107, 108). Phenothiazines such as perphenazine do not bind to estrogen receptors, at least up to a drug to 3H estradiol ratio of 1:100,000 (110, 111).
Thus, it seems likely that the ago-
nist-induced increase in estradiol uptake in hypothalamus and
719
the blockade of that effect by perphenazine is attributable to effects on dopamine rather than estrogen receptors. Although the above findings indicate that dopamine might influence estrogen action in hypothalamus, two additional findings should be mentioned.
First, although dopamine ago-
nists dramatically increase 3H estradiol uptake in hypothalamus of female rats, they do not affect estradiol uptake in male rats (107, 108).
Thus, there might be a strong sex dif-
ference with regard to dopamine modulation of estrogen action.
Secondly, whereas Thompson et al (106) found that AMPT
decreased receptor-mediated estradiol uptake in female rat hypothalamus, Carrillo et al (101) found no effect of this drug on hypothalamic estrogen receptors.
One potentially
important methodological difference between the two studies is that in the experiment of Thompson et al (106) AMPT was injected just two hours before 3H estradiol administration (a design similar to that used in experiments with agonists and antagonists) but in the experiment of Carrillo et al (101) the rats were injected for two days with AMPT and estrogen receptors were measured on day three.
It seems likely
that with processes as dynamic as those related to neurotransmission numerous factors, including sex and time course of drug treatment, might interact to determine the effects of neurotransmitter on steroid action.
Noradrenergic regulation of progestin action Interest in the question of whether noradrenergic transmission affects steroid action in brain grew from work with the lordosis response of female guinea pigs.
Lordosis in guinea
pigs, as in rats, is strictly dependent on the synergistic
720 action of ovarian estrogen and progestin (112-114).
However,
despite treatment with an optimal hormone regimen ovariectomized guinea pigs do not display lordosis when norepinephrine is depleted in brain or when αi-noradrenergic receptors are blocked (115-118).
Stimulation of αΐ-receptors with Cloni-
dine potentiates steroid-induced lordosis responding (115, 117, 119). The hypothalamus is thought to be the primary site where estradiol and progesterone act to induce lordosis in guinea pigs; small amounts of crystalline hormone implanted into this area induces lordosis but implants into other areas do not (120, 121).
To determine whether the noradrenergic
innervation of the hypothalamus might affect lordosis responding by modulating the sensitivity of hypothalamic cells to steroid hormones, steroid receptors were assayed after drug treatments that inhibit or potentiate lordosis. In initial experiments (116, 118), cytosol progestin receptors were measured 0.5 - 12 hours after drug injection. The animals were primed with estradiol 24-34 hrs prior to drug injection to approximate as closely as possible experiments with lordosis. Under these conditions, blockade of αχ-receptors (with phenoxybenzamine or prazosin) or inhibition of norepinephrine synthesis (with the dopamine-ß-hydroxylase inhibitor U-14, 624) decreased by about 30% the concentration of cytosol progestin receptors in hypothalamus. Drug treatment had no effect on progestin receptors in other brain areas, including preoptic area, midbrain, and cerebral cortex. Progestin receptor concentration was significantly decreased in hypothalamus by 4 hrs and remained depressed for at least 12 hrs after α^-receptor blockade. Direct stimulation of a^-receptors by injection of Clonidine reversed the effects of norepinephrine synthesis inhibition and restored cytosol progestin receptor concentration in hypothalamus to control levels.
721
Interestingly, recent experiments indicate that it might not be the total number of progestin receptors that noradrenergic transmission affects in hypothalamus.
Whereas interference
with noradrenergic transmission decreases the number of cytosol receptors, the number of nuclear progestin receptors in hypothalamus is increased (122).
This increase in nuc-
lear receptors does not appear to be attributable to a drug-induced release of adrenal progesterone.
First, no
drug-induced increase in plasma progesterone was detected by radioimmunoassay (116, 122) and, secondly, the effect on progestin receptors was limited to hypothalamus (116, 118, 122).
Adrenal progesterone, on the other hand, would be
expected to decrease the number of cytosol progestin receptors throughout the brain.
Also, the drugs themselves do
not bind to progestin receptors (116, 122), therefore, it seems unlikely that the shift in the distribution of the receptors is due to a direct interaction of the drugs with the receptors.
Rather, it seems that noradrenergic function
in some way influences where hypothalamic progestin receptors partition upon cell disruption.
Interference with noradre-
nergic transmission decreases the number of receptors in cytosol and increases the number of receptors found in nuclear preparations.
There are two ways this effect of nor-
adrenergic transmission might be described, depending on whether unoccupied receptors normally reside in cytoplasm or nucleus of target cells. In the past, it has been considered almost dogma that most, if not all, unoccupied steroid receptors reside in the cytoplasm of steroid target cells.
According to this model,
the receptors measured in cytosol are cytoplasmic receptors. When interpreted within this framework, the finding that interference with noradrenergic transmission decreases the
722 number of receptors in cytosol and increases the number in nuclear preparations suggests that noradrenergic transmission affects the distribution of unoccupied receptors within hypothalamic cells.
Depressed noradrenergic function favors a
shift in the distribution of the receptors out of the cytoplasm and into the nuclear compartment. Recently, however, the idea that unoccupied receptors reside in the cytoplasm has been challenged.
Based on new evidence,
it has been argued that virtually all unoccupied steroid receptors are in the cell nucleus (123, 124).
In the absence
of steroid, according to this model, the loose association of the receptor with nuclear elements causes the receptor to partition into the cytosol when the cell is disrupted. When interpreted within this framework, the finding that interference with noradrenergic transmission decreases the number of receptors in cytosol and increases the number in nuclear preparations suggests that noradrenergic transmission affects the strength of the association of unoccupied receptors with nuclear elements.
A reduction in noradrenergic
transmission favors a stronger association between the unoccupied receptor and nuclear elements; therefore, fewer receptors are extracted into cytosol and more receptors are seen in nuclear preparations. At present, both interpretations of the drug effects on unoccupied progestin receptors are viable and until additional information is available concerning the location of unoccupied receptors within target cells, it will be difficult to choose between these alternatives.
Also, at present we can
say little concerning differences in the functional consequences of these alternatives.
However, regardless of whe -
ther noradrenergic transmission affects the distribution of progestin receptors or their strength of association with nuclear elements it remains clear that some aspect of pro-
723 gestin receptor dynamics in hypothalamic cells is sensitive to noradrenergic function.
Other neurotransmitters and steroids Although most research on neurotransmitter modulation of steroid action in brain have been concerned with dopamine effects on estrogen action and noradrenergic effects on progestin action, there have been some experiments with other neurotransmitters and other steroids.
For example, Clark
et al (125) recently found that α^-noradrenergic receptor blockade with prazosin decreases the concentration of nuclear estrogen receptors in hypothalamus and preoptic area of estradiol treated female guinea pigs suggesting that noradrenergic transmission might modulate estrogen action in those areas. The sensitivity of brain regions to adrenal steroids might also be influenced by neural input.
For example, Feldman and
associates have postulated an important role for extrahypothalamic sites in modulating hypothalamic sensitivity to glucocorticoids in rat (126-130) .
Complete or posterior hypo-
thalamic differentiation, dorsal hippocampectomy, or dorsal fornix section decreased the inhibitory effect of dexamethasone on the adrenal secretory response to ether stress.
On
the other hand, electrolytic lesions of the mammillary peduncle or the medial forebrain bundle or bilateral infusion of 6-OHDA into the medial forebrain bundle enhanced the inhibitory effect of dexamethasone (126-130).
Various other
CNS operations did not affect the feedback effect of dexathasone in rats (126-130).
Experiments with species other
than rats also indicate a possible role for extrahypothalamic sites in modulating hypothalamic sensitivity to glucocorticoids.
Stith et al found that electrical stimulation
724
of the dorsal hippocampus, but not amygdala, increased the uptake and nuclear binding of the glucocorticoid 3H hydrocortisone in hypothalamus of male and female cats (131).
Also,
infusion of 6-OHDA into the 3rd ventricle of adrenalectomized dogs has been shown to decrease the concentration of glucocorticoid receptors in hypothalamus with no effect in hippocampus (126) . There is much that is not yet known about the modulation of steroid action by neurotransmitters.
We know almost nothing
concerning the mechanism(s) of neurotransmitter effects on steroid action although there has been speculation in this area (100,106,133).
We also know little about the functional
consequences of neurotransmitter-induced changes in sensitivity to steroids.
There are, however, numerous known phenomena
that might be relatable to the operation of such a mechanism. For example, neurotransmitter-induced changes in sensitivity to steroids might underlie circadian and seasonal changes in behavioral and endocrine responsiveness to steroids and, in addition, shifts in sensitivity to steroids that occur during early development, puberty and old age (76-91,134,135).
From
the finding that neurotransmitters can influence the action of steroids in postsynaptic cells, it also is not a large conceptual jump to envisioning this as an important mechanism by which environmental, behavioral and perhaps emotional events can rapidly and selectively influence steroid-dependent processes. Conclusions In this chapter we have presented a view of steroid hormones and brain function from the perspective of the interaction of various "neuroactive" substances (sometimes called, collectively, "neuromodulators") on brain function, including
725
behavior and neuroendocrine responses.
The picture which
is beginning to emerge is of multiple interactions - of steroids upon neuromodulatory processes and neurotransmitters, and of neurotransmitters upon responsiveness to steroid hormones.
These interactions are often highly specialized and
localized within restricted regions of the brain.
Their
occurrence is also frequently dependent on the stage of development, with permanent effects occurring during early development and qualitatively different, reversible effects occurring in later life. Many of the effects can be related to intracellular steroid receptors, which are produced by neurons in restricted brain regions.
These receptors have characteristics which make
them similar, if not identical, to receptors in other parts of the body.
One of the challenges for future research is to
understand the features of cellular differentiation which explain the diverse effects of steroids, acting via apparently identical receptors, on different tissues and different brain regions.
Another important question for future re-
search is to elucidate the mechanisms by which neurotransmitter activation can modify steroid receptor number or cellular uptake and cell nuclear binding of steroid hormones.
Acknowledgments Research in the author's laboratory is supported by NIH grant NS 07080, by fellowships HD 06258 (Gary Dohanich) and NS 06966 (to Bruce Nock) and by an institutional grant RF 81062 from the Rockefeller Foundation for research in reproductive biology.
We wish to thank Ms. Inna Perlin for editorial
assistance.
726 References 1.
Dismukes, R.K.: The Behavioral and Brain Sciences _2, 409-448 (1979) .
2.
Gudelsky, G.A., Simpkins, J., Mueller, G.P., Meites, J., Moore, K.E.: Neuroendo. 22, 206-215 (1976).
3.
Fekete, Μ., DeWied, D.: Pharm. Biochem. Behav. 17, 177-182 (1982).
4.
Markey, K.A., Sze, P.Y.: Neuroendo. 38, 269-275
5.
Delanoy, R.L., Kramarcy, N.R., Dunn, A.J.: Brain Res. 231, 117-129 (1982) .
6.
Wei, E., Sigel, S., Loh, Η., Way, E.L.: Nature 253, 739-780 (1975).
7.
Cott, J. Μ., Breese, G.R., Cooper, B.R., Barlow, T.S., Prange, A.J.: J. Pharm. Exp. Therap. 196, 594-604 (1975).
8.
Kalivas, P.W., Horita, Α.: Nature 278, 461-462
9.
Stumpf, W.E., Sar, M., Keefer, D.A.: In: Anat. Neuroendo. 104-119 (W.E. Stumpf and L.D. Grant, Eds.) S. Karger, Basel 1975.
(1984).
(1979).
10.
Warembourg, M.: In: Biol. Cell. Proc. Neurosecret. Hypothai., 221-237 (J-D. Vincent, C. Kordon, Eds.) CNRS, Paris 1978.
11.
Pfaff, D.W.: In: Estrogens and Brain Function, 281pp., Springer-Verlag, New York 1980.
12.
McEwen, B.S., Biegon, Α., Davis, P.G., Krey, L.C., Luine, V.N., McGinnis, M.Y., Paden, C.M., Parsons, B., Rainbow, T.C.: Ree. Prog. Horm. Res. 21/ 41-92 (1982).
13.
McEwen, B.S.: In: Current Topics in Neuroendocrinology, 1-22 (D. Ganten and D.W. Pfaff, Eds) Springer-Verlag, Berlin 1982.
14.
McEwen, B.S., Parsons, B: Ann. Rev. Pharm. Toxicol. 22, 555-598 (1982).
15.
McEwen, B.S., Davis, P.G., Parsons, B., Pfaff, D.W.: Ann. Rev. Neurosci. 2, 65-112 (1979).
16.
Meyer, J.S., McEwen, B.S.: J. Neurochem. 3_9, 436-442 (1982) .
17.
Luine, V.N., McEwen, B.S., Black, I.B.: Brain Res. 120, 188-192 (1977).
18.
Sar, M.: Science 223, 938-940
19.
Blum, Μ., McEwen, B.S., Roberts, J.L.: Abstr. Soc. Neurosci. 14th Annual Meeting, 308.3 (1984).
(1983).
727
20. 21. 22. 23.
24.
Biegon, Α., Fischette, C., Rainbow, T.C., McEwen, B.S.: Neuroendo. 35, 287-291 (1982) . Fischette, C.T., Biegon, Α., McEwen, B.S.: Science 222, 333-335 (1983). Johnson, A.E., Nock, B., McEwen, B.S., Feder, H.H.: Brain Res., submitted (1984). McEwen, B.S.: In: Biological Regulation and Development, 203-219 (R.F. Goldberger and K.R. Yamamoto, Eds.) Plenum Press, New York 1982. Rainbow, T.C., Parsons, B., McEwen, B.S.: Nature 300, 648-649 (1982).
25.
McEwen, B.S.: In: Fetal Neuroendocrinology (F. Ellendorff Ν. Parvizi, P. Gluckman, Eds.) Perinatology Press, New York, in press 1985.
26.
McEwen, B.S.: In: Reproductive Physiology IV, 99-145 (R.O. Greep, Ed.) University Press, Baltimore 1983. Patterson, P.: Ann. Rev. Neurosci. 1, 1-17 (1978).
27. 28.
Sze, P.Y.: In: Serotonin: current aspects of neurochemistry and function, 507-523 (B. Haber, S. Gabay, M.R. Issidorides and S.G.A. Alivisatos, Eds.) Plenum Press, New York 1981.
29.
Toran-Allerand, C.D.: In: Bioregulators of Reproduction, 43-57 (G. Jagiello, H.J. Vogel, Eds.) Academic Press, New York 1981.
30.
MacLusky, N.J., McEwen, B.S.: Brain Res. 189, 262-268 (1980) .
31.
Azmitia, E.C.Jr., McEwen, B.S.: Brain Res. T8, 291-302 (1974) . Kelly, M.J., Moss, R.L., Dudley, C.A.: Exp. Brain Res. 30, 53-64 (1977) .
32. 33.
McEwen, B.S., Biegon, Α., Fischette, C.T., Luine, V.N., Parsons, Β., Rainbow, T.C.: In: Frontiers in Neuroendocrinology, J3, 153-176 (L. Martini, W. Ganong, Eds.) Raven Press, New York 1984.
34.
McEwen, B.S., Krey, L.C., Luine, V.N.: In: The Hypothalamus, 255-268 (S. Reichlin, R.J., Baldessarini, J.B. Martin, Eds.) Raven Press, New York 1978.
35.
Luine, V.N., Rhodes, J.C.: Neuroendo. 36.' 235-241 (1983).
36.
0'Malley, B.W., Means, A.R.: Science 183, 610-620 (1974).
37.
Boling, J.L., Blandau, R.J.: Endocrinology 2_5, 359-364 (1939).
38.
Clemens, L.G., Humphrys, R.R., Dohanich, G.P.: Pharm. Biochem. Behav. 13, 81-88 (1980).
39.
Clemens, L.G., Dohanich, G.P., Witcher, J.A.: J. Comp. Physiol. Psychol. 9_5, 763-770 (1981).
40.
Dohanich, G.P., Clemens, L.G.: Horm. Behav. 1J5, 157-167 (1981) .
41.
Clemens, L., Dohanich, G., Barr, P.: Hormones and Behavior in Higher Vertebrates, Springer-Verlag, Berlin Heidelberg 1983.
42.
Dohanich, G.P., Barr, P.J., Witcher, J.Α., Clemens, L.G.: Physiol. Behav. 32_, 1021-1026 (1984).
43.
Clemens, L.G., Dohanich, G.P.: Pharm. Biochem. Behav. 13, 89-95 (1980). Rainbow, T.C., Snyder, L., Berck, D.J., McEwen, B.S.: Neuroendo. 3_9, 476-480 (1984) .
44. 45.
Luine, V.N., McEwen, B.S.: Neuroendo. 3JL' 475-482 (1983).
46.
Rainbow, T.C., DeGroff, V., Luine, V.N., McEwen, B.S.: Brain Res. 198, 239-243 (1980).
47.
Dohanich, G.P., Witcher, J.Α., Weaver, D.R., Clemens, L.G.: Brain Res. 241, 347-350 (1980).
48.
Olsen, K.L., Edwards, E., McNally, W., Schechter, N., Whalen, R.E.: Soc. Neurosci. Abstr. jj, 423 (1982).
49.
Dohanich, G.P., Witcher, J.A., Clemens, L.G.: Pharm. Biochem. Behav., in press.
50.
Egozi, Y., Avissar, S., Sokolovsky, M.: Neuroendo. 35, 93-97 (1982).
51.
Avissar, S., Egozi, Υ., Sokolovsky, M.: Neuroendo. 32, 295-302 (1981). Egozi, Y., Kloog, Y.: 7th International Congress of Endocrinology 762 (1984) .
52. 53. 54.
Luine, V.N., Park, D., Tong, J., Reis, D., McEwen, B.S.: Brain Res. ]JU, 273-277 (1980). Fallon, J.H., Loughlin, S.E., Ribak, C.E.: J. Comp. Neurol. 2JL8, 91-120 (1983).
55.
Luine, V.N., Khylchevskaya, R.I., McEwen, B.S.: Res. £6 , 293-306 (1975).
56.
Muth, E.A., Crowley, W.R., Jacobowitz, D.M.: Neuroendo. 30, 329-336 (1980) .
57.
Kobayashi, T., Kobayashi, T., Kato, J., Minaguchi, H.: Endocrinol. Japon. Π), 175-182 (1963) .
58.
Libertun, C., Timiras, P.S., Kragt, C.L.: Neuroendo. 12, 73-85 (1973). Saper, C.B.: J. Comp. Neurol. 222, 313-342 (1984).
59.
Brain
729 60. 61.
Wenk, Η., Meyer, U., Bigl, V. : Neurosci. 2, 797-800 (1977) James, T.C., Kanungo, M.S.: Biochim. Biophys. Acta 538, 205-211 (1978).
62.
Moudgil, V.K., Kanungo, M.S.: Biochim. Biophys. Acta 329, 211-220 (1973).
63.
Iramain, C.A., Egbunike, G.N., Owasoyo, J.O.: Experientia 35, 1678-1679 (1979).
64.
Iramain, C.A., Owasoyo, J.O., Egbunike, G.N.: Neurosci. Letts. JL6, 81-84 (1980) .
65.
Iramain, C.A., Owasoyo, J.O.: Neuroendo. Letts. 2^, 93-96 (1980).
66.
Commins, D., Yahr, P.: (1984).
67.
Kafka, M.S., Wirz-Justice, Α., Naber, D., Wehr, T.A.: Neuropharm. _20/ 421-425 (1981) .
68.
Marks, M.J., Patinkin, D.M., Artman, L.D., Burch, J.B., Collins, A.C.: Pharm. Biochem. Behav. Γ5, 271-279 (1981).
69.
Gilad, G.M., Rabey, J.M., Shenkman, L: Brain Res. 267, 171-174 (1983).
70.
Burgel, P., Romme1spacher, H.: Life Sei. 2423-2428 (1978) . Everett, J.W., Sawyer, C.H., Markee, J.E.: Endocrinology 44 , 234-250 (1949) .
71.
J. Comp. Neurol. 224, 123-131
72.
Libertun, C., McCann, S.M.: Endocrinology 92, 1714-1724 (1973).
73.
Libertun, C., McCann, S.M.: Proc. Soc. Exp. Biol. Med. 147 , 498-504 (1974) . Bagga, N., Chhina, G.S., Mohan Kumar V. , Singh, Β.: Physiol. Behav. '32, 45-48 (1984).
74. 75.
Yahr, P.: Chemical Signals in Vertebrates, Vol. 2, Plenum Press, New York 1983.
76.
Beach, F.A., Levinson, G. Proc. Soc. Exp. Med. 72, 78-80 (1949). Goodman, R.L., Karsch, F.J.: In: Progress in Reproductive Biology (P.O. Hubinont, Ed.), Karger, Basel 1980.
77. 78.
Hansen, S., Soderten, P., Enroth, B., Serbro, Β., Hole,K: J. Endocrinol. £3, 267-274 (1979).
79.
Hansen, S., Sodersten, P. Serbro, B.: J. Endocrinol. 77, 381-388 (1978).
80.
Harlan, R.E., Shivers, B.D., Moss, R.L., Shryne, J.E., Gorski, R.A.: Biol. Reproduction _23, 64-71 (1980).
81.
Hinde, R.A., Steel, E.: In: Advances in the Study of Behavior, Vol. 8 (J.S. Rosenblatt, R.A. Hinde, C. Beer, M.-C. Busnel, Eds.) Academic Press, New York 1978. Morin, L.P., Fitzgerald, K.M., Rusak, B., Zucker, I.: Psychoneuroendo. 1, 265-279 (1977).
82. 83.
Morin, L.P., Zucker, I.: J. Endocrinol. Tl_, 249-258 (1978).
84.
Roberts, J.S.: Endocrinology 53^, 1309-1314 (1973).
85.
Ellis, G.B., Turek, F.W.: Neuroendo. 31,, 205-209 (1980).
86.
Davidson, J.M.: In: The Control of the Onset of Puberty (M.M. Grumbach, G.D. Grave, F.E. Mayer, Eds.) John Wiley, New York 19 74.
87. 88.
Goldman, B.D.: In: Neuroendocrinology of Reproduction (N.T. Adler, Ed.) Plenum Press, New York 1981. MacLusky, N.J., Lieberburg, I., McEwen, B.S.: In: Ontogeny of Receptors and Reproductive Hormone Action (J.H. Clark, T.H. Hamilton, W.A. Sadler, Eds.), Raven Press, New York 1979.
89.
Roth, G.S.: Mech. Aging Develop. 9, 497-514 (1979a).
90.
Roth, G.S.: Fed. Proc. 38., 1910-1914 (1979b).
91.
Wise, P.M., Camp, P.: Endocrinology 114, 92-98 (1984).
92.
MacLusky, N.J., Clark, C.R.: In: Proteins of the Nervous System (R.A. Bradshaw and D.M. Schneider, Eds.) Raven Press, New York 1980.
93.
Muldoon, T.G.: Endocr. Rev. .1, 339-364 (1980).
94.
Fleming, H., Blumenthal, R., Gurpide, E.: Endocrinology 111, 1671-1677 (1982) .
95.
Fleming, H., Blumenthal, R, Gurpide, E.: Proc. Natl. Acad. Sei. USA 80, 2486-2490 (1983).
96.
Sando, J.J., Hammond, N.D., Stratford, C.A., Pratt, W.B.: J. Biol. Chem. 2J34, 4779-4789 (1979).
97.
Toft, D., Moudgil, V. , Lohmar , P. , Miller, J.: Ann. N.Y Acad. Sei. 281, 29-42 (1977).
98.
Weigel, N.L., Tash, J.S., Means, A.R., Schräder, W.T., O'Malley, B.W.: Biochem. Biophys. Res. Commun. 102, 513-519 (1981).
99. 100.
Cardinali, D.P.: Trends Neurosci. 2, 250-253 (1979). Nock, B., Feder, H.H.: Neurosci. Biobehav. Rev. _5, 437-447 (1981).
731
101.
Carrillo, A.J., Steger, R.W. , Chamness, G.C.: nology 112.' 1839-1946 (1983) .
Endocri-
102.
Di Carlo, F., Rebani, Portaleone, P., Viano, J., Genazzani, E.: In: Pharmacological Modulation of Steroid Action (Ε. Genazzani, F. Di Carlo, W.I.P. Mainwaring, Eds.), Raven Press, New York 1980.
103.
Grant, L.D., Stumpf, W.E.: In: Anatomical Neuroendocrinology (W.E. Stumpf, L.D. Grant, Eds.), S. Karger, Basel 1975.
104.
Heritage, A.S., Stumpf, W.E., Sar, Μ., Grant, L.D.: Science 207, 1377-1379 (1980).
105.
Marks, B.H., Wu, T-K., Goldman, H.: Res. Communs. Chem. Pathol. Pharmac. _3< 595-600 (1972).
106.
Thompson, M.A., Woolley, D.E., Gietzen, D.W., Conway, S.: Endocrinology 113, 855-865 (1983).
107.
Gietzen, D.W., Hope, W.G., Wooley, D.E.: Life Sei. 33, 2221-2228 (1983).
108.
Woolley, D.E., Hope, W.G., Geitzen, D.W., Thompson, M. Τ., Conway, S.B.: Proc. West Pharm. Soc. 25, 437-441 (1982) .
109.
Liel, Y., Marbach, M., Aflalo, L., Glick, S.M., Levy, J.: Biochem. Pharm, _31' 707-710 (1982).
110.
Shani, J., Givant, Y., Sulman, F.G., Eylath, U., Eckstein, B.: Neuroendocrinology 8, 307-316 (1971).
111.
Shani, J., Roth, Z., Givant, Υ., Goldhaber, G., Sulman, F.G.: Israel J. Med. Sei. 12, 1338-1339 (1976).
112.
Feder, H.H.: In: Biological Determinants of Sexual Behavior (J.B. Hutchinson, Ed.), John Wiley, New York 1978.
113.
Young, W.C.: In: Sex and Internal Secretions, Third Edition (W.C. Young, Ed.), Williams and Wilkins, Baltimore 1961.
114.
Young, W.C.: In:Advances in the Study of Behavior, Vol. 2 (D.S. Lehrman, R.A. Hinde, Shaw, E., Eds.), Academic Press, New York 1969.
115.
Crowley, W.R., Feder, H.H., Morin, L.P.: Pharm. Biochem. Behav. 4, 67-71 (1976) .
116.
Nock, Β., Blaustein, J.D., Feder, H.H.: Brain Res. 207, 371-396 (1981).
117.
Nock, B., Feder, H.H.: Brain Res. 166, 369-380 (1979).
118.
Nock, Β., Feder, H.H.: Brain Res., in press (1984).
119.
Crowley, W.R., Nock, B., Feder, H.H: Pharm. Biochem. Behav. 8, 207-209 (1978).
120.
Morin, L.P., Feder, H.H.: Brain Res. Ί0_, 81-93
121.
Morin, L.P., Feder, H.H.: Brain Res. 70.' 95-102
(1974). (1974).
122.
Blaustein, J.D.: Brain Res., in press
123.
King, W.J., Greene, G.L.: Nature 307, 745-747
(1984).
124.
Welshons, W.V., Lieberman, M.E., Gorski, J.: Nature 307, 747-749 (1984).
125.
Clark, A.S., Nock, B., Feder, H.H., Roy, E.J.: Brain Res., in press (1984).
126.
Feldman, S., Siegel, R.A., Weidenfeld, J., Conforti, N., Melamed, E.: Brain Res. 260, 297-300 (1983).
127.
Feldman, S., Conforti, N.: Horm. Res. 12.' 289-295
128.
Feldman, S., Conforti, N.: Acta Endocrinol. 8_2, * 785-791 (1976).
(1984).
(1980)
129.
Feldman, S., Conforti, N. : Horm. Res. ]_, 56-60
130.
Feldman, S., Conforti, N., Chowers, I.: Acta Endocrinol. (Kbh) 73, 660-664 (1973).
(1976).
131.
Stith, R.D., Person, R.J., Dana, R.C.: J. Neurosci. Res. 2, 317-322 (1976) .
132.
Stith, R.D., Person, R.J.: Neuroendocrinology 34, 410-414 (1982) .
133.
Nock, B.: In: Reproduction: A Behavioral and Neuroendocrine Perspective (B.R. Komisaruk, H.I. Siegel, H.H. Feder, M-F. Cheng, Eds.), New York Academy of Science, in press, 1984.
134.
Roy, E.J., Wilson, M.A.: Science 213, 1525-1527
135.
Speisberg, T.C., Boyd, P.A., Halberg, F.: In: Steroid Hormone Receptor Systems (W.W.Leavitt, J.Η. Clark, Eds.) Plenum Press, New York 1978.
(1981).
THE STEROID RECEPTOR OF ACHLYA
AMBISEXUALIS
Robert M. Riehl, David O. Toft D e p a r t m e n t of Cell B i o l o g y , M a y o Rochester, Minnesota, USA
Clinic,
Introduction T h e m e c h a n i s m of a c t i o n of s t e r o i d h o r m o n e s despite
the a c c u m u l a t i o n of s t u d i e s o n the
involved
remains
in the m o l e c u l a r e v e n t s a s s o c i a t e d
steroid-induced
responses.
Information
unclear
individual
steps
with
r e l e v a n t to the
s t r u c t u r e , s t a b i l i z a t i o n and t r a n s l o c a t i o n of
cytosolic
r e c e p t o r s and some of the b i o c h e m i c a l e v e n t s a s s o c i a t e d
with
nuclear steroid-receptor
c o m p l e x e s has b e e n o b t a i n e d
from a
n u m b e r of m o d e l s y s t e m s .
T h e s e c l a s s i c a l m o d e l s are
mainly
c o m p o s e d of t a r g e t t i s s u e s a n d / o r c e l l s from w h i c h r e p r e s e n t o n l y a small of k n o w n s t e r o i d r e s p o n s i v e animal
kingdoms
(1-3).
systems may provide defining
vertebrates
f r a c t i o n of the total s y s t e m s among
population
the p l a n t
Studies utilizing other
and
nonclassical
new i n f o r m a t i o n or insight u s e f u l
the m e c h a n i s m of a c t i o n of s t e r o i d h o r m o n e s
g e n e r a l and b r o a d e n o u r v i e w of the b i o l o g i c a l s t e r o i d a l c o m p o u n d s as i n t e r c e l l u l a r belonging
possess steroid binding proteins a m b i s e x u a l is, is u n d e r study s u b j e c t of this
role of
communication
In this r e g a r d , r e c e n t s t u d i e s have s h o w n that eukaryotic microorganisms
molecules.
some
to the k i n g d o m
(4-8).
in in
Fungi
One of t h e s e ,
Achlya
in our l a b o r a t o r y and is the
chapter.
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
734 Background A brief description of the relevant aspects of the biology of Achlya will be presented here and the reader is urged to consult the more extensive reviews to be found in the list of references (3,9,10).
Notably, Achlya is unique in its
ability to synthesize and respond to steroid hormones.
It is
the only microbe known in which sexual reproduction is controlled by steroid hormones. Reproduction in Achlya is accomplished by either asexual or sexual modes of sporulation.
The asexual mode is thought to
be independent of the steroid hormones and occurs predominantly in response to depletion of exogenous nutrient supplies.
Germination and culture of the asexual spores
(zoospores) is a common laboratory technique for obtaining Achlya cultures in which the process of sexual reproduction can be studied.
Spore germination is evidenced by the
outgrowth of a small tube of protoplasm encased by the plasmalemma and cell wall.
The germ tube continues to
elongate and form apical branches that also grow and branch to ultimately form a meshwork of interconnected tubes called hyphae (somatic cell type) which are collectively known as a mycelium.
Sexual reproduction occurs when male and female
mycelia are in close physical proximity.
Female hyphae
synthesize and release the steroid antheridiol (Figure 1) into the environment from which it is detected by male hyphae that respond by the growth and differentiation of the male sex organs known as antheridial branches and by the production and release of a second steroid, oogoniol. Oogoniol acts upon the female hyphae inducing the formation of the egg-bearing structures or oogonia.
Chemotropic growth
of the male antheridial branches toward the oogonia along a concentration gradient of antheridiol results in contact of the two sex organs followed by syngamy and production of oospores.
The induction of antheridial branches can also be
735 observed by the addition of exogenous synthetic (and chemical analogs) to the culture medium.
antheridiol Within two
hours following exposure to antherdiol, male hyphae produce thin, contorted subapical branches that are readily observable with ordinary light microscopy
(Figure
The following characteristics confer exceptional
2).
advantages
to the Achlya steroid hormone system compared to the classical vertebrate systems:
1) The somatic cells
(hyphae)
of Achlya are a tubular coenocytium, consequently the entire mycelium
is composed of a single "cell" type and
the "target tissue".
represents
2) One facet of the hormone response is
a rapid and readily observable morphological
differentiation.
3) Male mycelia do not synthesize antheridiol;
therefore,
when in axenic culture, there is absence of previous to the hormone.
4) Achlya possess a relatively
exposure
simple
genetic endowment having three sets of chromosomes and a genome size that is only a few times larger than that of Ε. coli .
5) Cultivation of mycelia
in the laboratory can be
accomplished with media of simple composition laboratory glassware and on the bench
in ordinary
top.
The role of steroid hormones in the process of sexual reproduction in Achlya has been well studied
(3,9,10).
However, the mechanism of action of antheridiol strain has received
the majority of experimental
in the male attention
because the chemical synthesis and availability of oogoniol has only been of recent occurrence pure antheridiol has been available
(11).
Since
chemically
(12), some of the
biochemical actions of this steroid have been studied
(10).
The development of antheridial branches has been shown to be dependent on continued RNA and protein synthesis
(13,14).
The synthesis of RNA (14,15) and levels of specific activities of RNA polymerase II (16) and cellulase
(13,17)
are increased by antheridiol.
indirect
studies, it was suggested
From the results of
that chemorecognition of
736 antheridiol could be mediated through a cytosolic receptor in a similar manner to the steroid hormone receptor systems of vertebrates (18). In our studies, we have used a tritium-labeled analogue of antheridiol, 7-deoxy-7-dihydro-antheridiol biologically active.
(7dA), that is
Our objectives were to use the
tritium-labeled ligand to detect the binding protein (7) and characterize the biological significance of binding by analysis of the saturability, specificity and affinity. Following identification of the receptor, the physicochemical properties of the macromolecule could be determined
(8) and
compared with those of steroid receptors in higher organisms.
Methods Chemical Nonradioactive antheridiol and its congeners were supplied by Trevor C. McMorris, Department of Chemistry, University of California-San Diego.
The radioactive analog of antheridiol,
[1,2- 3 H]-7-deoxy-7-dihydro-antheridiol
([ 3 H]-7dA,
specific activity = 40 Ci/mmol) was prepared as described elsewhere (Meyer et al., in preparation). structures of antheridiol and
The chemical
3
[ n]-7dA are shown in
Figure 1. Cell culture
Achlya ambisexualis Raper strains E87 (male) and 734 (female) were cultured as previously described
(7).
Asexual spores
(19) were germinated in PYG medium (20) for 18-24 hrs at 29°C and subsequently innoculated into 2 liters of Ml medium (14)
737 HO
Antheridiol HO
[ 1 , 2 - 3 H ]-7-deoxy-7-dihydro-Antheridiol Figure 1. Chemical Structures of Antheridiol and the Tritium-labeled Analog Employed for Binding Studies.
for growth in aerated suspension culture at 24°C for various time periods.
Mycelia were routinely harvested
for study
after 2-3 days of incubation except where described d i f ferently.
Preparation of fungal cytosol
The techniques for mycelial harvest and disruption are described
in detail elsewhere
(8).
Because preliminary
738 s t u d i e s r e v e a l e d that the a n t h e r i d i o l unstable
in v i t r o , c o n s i d e r a b l e
to o p t i m i z e employed
binding protein
experimentation was
the c o n d i t i o n s and c o m p o s i t i o n of
for h o m o g e n i z a t i o n
optimum binding capacity.
was
performed
buffers
and p r e p a r a t i o n of c y t o s o l P r e s e r v a t i o n of c y t o s o l i c
binding
a c t i v i t y was h i g h l y d e p e n d e n t on the c o n c e n t r a t i o n s of molybdate (8).
and m e r c a p t o e t h a n o l
in the h o m o g e n i z a t i o n
of 25 m M K 2 H P 0 4 , 25 m M
10 m M 4 - m o r p h o l i n e e t h a n e s u l f o n i c
using
KH2P04,
a c i d , 25 m M N a 2 M o 0 4
10 m M 2 - m e r c a p t o e t h a n o l , pH 7.5 at
and
0°C.
The m y c e l i a w e r e h a r v e s t e d by f i l t r a t i o n , m i n c e d
with
s c i s s o r s and a d d e d to PM3 b u f f e r at a ratio of 1:4 wet to v o l u m e . vessels were
immersed
in an i c e / m e t h a n o l
homogenate was filtered
through Miracloth
the f i l t r a t e c e n t r i f u g e d at 2 5 0 , 0 0 0 x g
slush.
resultant cytosol
The
for 1 - 2 hrs at (0.45
a d j u s t e d to pH 7.0 at 0 ° C .
mycelia were frozen
0°C.
μ) and
f l u o r i d e , pH 7.5 at 0 ° C .
e i t h e r by u l t r a f i l t r a t i o n (Millipore
For some
phenylmethylanalytical
a c t i v i t y was
using an i m m e r s i b l e
Corp.) with a molecular weight
concentrated probe
limit of 1 0 , 0 0 0
by p r e c i p i t a t i o n w i t h a m m o n i u m s u l f a t e at 95% of (8).
The a m m o n i u m s u l f a t e p e l l e t was r e s u s p e n d e d
c o n s i s t i n g of 10 m M N a 2 M o 0 4 propanesulfonic studies.
in
of
2 - m e r c a p t o e t h a n o l , 50 m M
a c i d , a n d 0.5 mM
the c y t o s o l i c b i n d i n g
the
to a p o w d e r
a b l e n d e r cup and t h a w e d to 0°C in Τ b u f f e r c o n s i s t i n g 4-morpholinepropanesulfonic
and
Alternatively,
in l i q u i d n i t r o g e n , g r o u n d
100 m M KCl, 25 m M N a 2 M o 0 4 , 10 m M
ten
while
(Calbiochem)
The s u p e r n a t a n t was c l a r i f i e d by f i l t r a t i o n
sulfonyl
weight
D i s r u p t i o n of h y p h a e w a s a c c o m p l i s h e d by four
s e c o n d b u r s t s of a p o l y t r o n at the m a x i m u m s e t t i n g
procedures,
sodium
buffer
Except where noted, most studies were performed
PM3 b u f f e r c o n s i s t i n g
with
and 10 m M
a c i d , pH 7.0 at 0°C
or
saturation in a
buffer
4-morpholine-
(MoM b u f f e r ) for
further
739 Analytical
procedures
Radioligand binding assay. All steroid stock solutions were stored at -20°C in redistilled ethanol and added to 12 χ 75 mm disposable culture tubes immediately prior to addition of sample.
The final concentration of ethanol
volume was no greater than 1%.
in the assay
Incubation was routinely
performed at 0°C in an ice/water slush for the time periods and at the steroid concentrations described the figures and tables.
in the legends to
Unbound steroid was adsorbed
to
dextran-coated charcoal over a 4-minute period after the addition of a 200 μΐ aliquot of a dextran-coated suspension
(5% Norit-A, 0.5% Dextran T-70, 0.01% N a N 3 ) for
each ml of incubation volume and pelleted by at 2000xg for 4 m i n . steroid was measured
The amount of bound
centrifugation
tritium-labeled
in aliquots of the supernatant by liquid
scintillation spectrophotometry
in Beckman Ready
cocktail at an efficiency of 33% determined by standardization. amount of
charcoal
Solv-HP
internal
Nonspecific binding was defined as the
[ 3 H ] - 7 d A bound
in the presence of a fifty-fold
excess of unlabeled antheridiol.
Specific binding was
calculated by subtracting the amount of nonspecific from the total amount of unlabeled
3
[ H ] - 7 d A bound
binding
in the absence of
antheridiol.
Determination of the steroid specificity of [ 3 H ] - 7 d A binding. The amount of
[ 3 H ] - 7 d A bound
in the presence of
increasing concentrations of nonradioactive steroids was determined
to assess their relative binding affinities
the receptor. resuspended
Ammonium sulfate-precipitated
in MoM buffer pH 7.0 at 0°C and 1 ml aliquots
containing 280-320 yg protein were incubated of
for
receptor was
in the presence
[ 3 H ] - 7 d A at a final concentration of 2.5 χ 1 0 - 9
Nonradioactive steroids were added at final ranging from 1 χ 1 0 - 1 1 of specifically bound
to 1 χ 10~ 5 M.
M.
concentrations
The amount
[ 3 H ] - 7 d A in the presence of each
740
F i g u r e 2. S t e r o i d - i n d u c e d r e s p o n s e of A c h l y a a m b i s e x u a l i s male. P h o t o g r a p h s (45x) w e r e t a k e n b e f o r e (left) and 1.5 h a f t e r (right) e x p o s u r e to 1.2 nM [^H]-7dA. c o n c e n t r a t i o n of c o m p e t i t o r i n c u b a t i o n at 0 ° C .
Relative
was m e a s u r e d a f t e r
1.5 h of
binding affinities
(RBA)
c a l c u l a t e d by d e t e r m i n a t i o n s of the c o n c e n t r a t i o n competitor
that r e d u c e d s p e c i f i c
[3H]-7dA binding
the a m o u n t b o u n d
in the a b s e n c e of c o m p e t i t o r
according
equation
to the C
RBA = c
Q-5
0.5
7 d A
to 50% of
(Cg 5)
.
competitor
Sucrose density gradient sedimentation. gradients,
were
of
the c y t o s o l was c o n c e n t r a t e d
s i x - f o l d by u l t r a f i l t r a t i o n
Prior to layering approximately
using an i m m e r s i b l e
( M i l l i p o r e Corp.) w i t h a m o l e c u l a r w e i g h t
[3H]-7dA was then a d d e d to the c y t o s o l at a concentration
probe
limit of
10,000.
final
of 4 nM in the a b s e n c e and p r e s e n c e of 200 nM
on
741
antheridiol. or
S u c r o s e was d i s s o l v e d
in PM3 b u f f e r at pH
in the s a m e b u f f e r w i t h o u t N a j M o C ^ but c o n t a i n i n g
KCl and l i n e a r 5-20% w / w g r a d i e n t s concentrated cytosol proteins were 150,000xg
formed.
Aliquots
(0.3 m l = 227 pg p r o t e i n )
and
7.0
1 Μ of
reference
l a y e r e d o n 4.5 ml g r a d i e n t s and c e n t r i f u g e d
for 16 hrs at 2 ° C .
F r a c t i o n s were c o l l e c t e d
the tube b o t t o m w i t h a n ISCO f r a c t i o n c o l l e c t o r and r a d i o a c t i v i t y d e t e r m i n e d by l i q u i d
at
from
the
scintillation
spectrophotometry.
Results The morphological exogenous
r e s p o n s e of an A c h l y a m a l e m y c e l i u m
3
[ H ] - 7 d A is i l l u s t r a t e d
in Figure 2.
The
p h o t o g r a p h at the left was t a k e n p r i o r to e x p o s u r e hormone. extensive Additional
to 1.2 χ 1 0 ~ 9 Μ
lateral b r a n c h
[ 3 H ] - 7 d A and shows
formation
steroid.
s t u d i e s have s h o w n this r a d i o l a b e l e d a n a l o g u e a c t i v e at c o n c e n t r a t i o n s
10-12 μ .
it is not as p o t e n t as the
While
(22), these r e s u l t s
a very suitable
i n d i c a t e that
indicated
natural [3H]7dA should
in A c h l y a c y t o s o l was v e r y low and v a r i a b l e . a g e n t such as
have b e e n s h o w n to be i m p o r t a n t s t a b i l i z i n g steroid receptors
for the A c h l y a s y s t e m as w e l l .
mercaptoethanol
agents
for
Total e x c l u s i o n of
sites.
in the b u f f e r s o l u t i o n s
true
sodium
from the m e t h o d d e s c r i b e d
p r e p a r a t i o n of the f u n g a l c y t o s o l
resulted
This requirement
is i l l u s t r a t e d
we
activity.
in g e n e r a l , and this was found to be
m o l y b d a t e and m e r c a p t o e t h a n o l binding
activity
Therefore,
to o p t i m i z e b i n d i n g
S o d i u m m o l y b d a t e and a r e d u c i n g
be
analysis.
that s t e r o i d b i n d i n g
t e s t e d a v a r i e t y of c o n d i t i o n s
to
as low as 2 χ
l i g a n d for r e c e p t o r d e t e c t i o n and
initial s t u d i e s
detectable
the
i n d u c e d by the
be b i o l o g i c a l l y
Our
to
The p h o t o g r a p h at the r i g h t w a s taken a f t e r 2 h o u r s
of e x p o s u r e
steroid
to
in an a b s e n c e for
in F i g u r e
Na2Mo04 3 which
for of
742
F i g u r e 3. E f f e c t of S o d i u m M o l y b d a t e o n S p e c i f i c B i n d i n g of [^H]-7dA. The h o m o g e n a t e (· ·) w a s p r e p a r e d as d e s c r i b e d in E x p e r i m e n t a l P r o c e d u r e s and a d j u s t e d to the final c o n c e n t r a t i o n s of s o d i u m m o l y b d a t e i n d i c a t e d on the a b s c i s s a . A l i q u o t s of e a c h c y t o s o l (1 m l = 595 g p r o t e i n ) w e r e i n c u b a t e d for 1.5 h at 0°C in the p r e s e n c e of 2 χ Μ [-^H]-7dA. S p e c i f i c b i n d i n g is s h o w n as a p e r c e n t a g e of the m a x i m u m s p e c i f i c b i n d i n g m e a s u r e d in the p r e s e n c e of the o p t i m u m c o n c e n t r a t i o n of s o d i u m m o l y b d a t e . The m e a n v a l u e s (N = 2) for the m a x i m u m level of s p e c i f i c b i n d i n g in the c y t o s o l was 1 5 , 3 0 3 d p m / m l . depicts
the r e s u l t s of a d j u s t i n g
r a n g e of Na2MoC>4 c o n c e n t r a t i o n s the c y t o s o l . to an i n c r e a s e 25 m M Na2MoC>4. concentration
Specific binding
the h o m o g e n a t e
increased
in Na 2 MoC>4 c o n c e n t r a t i o n Further resulted
to c o n t a i n a
p r i o r to p r e p a r a t i o n
increases
in d i r e c t
in the Na2MoC>4
in d e c r e a s e s
in s p e c i f i c b i n d i n g .
of 5 m M , 10 m M a n d 20 m M m e r c a p t o e t h a n o l l e v e l s of c y t o s o l i c b i n d i n g
98% of the m a x i m u m The total a m o u n t of
relation
to an o p t i m u m of
c o n t r a s t to the d r a m a t i c e f f e c t of Na 2 MoC>4, the increased
of
level, respectively
In
addition
resulted
in
that w e r e 9 3 % , 100% (data not
shown).
[3H]-7dA b o u n d at a c o n s t a n t
protein
and
c o n c e n t r a t i o n was d e p e n d e n t on the pH of the b u f f e r
solution
b u t n o n s p e c i f i c b i n d i n g was i n d e p e n d e n t of the p H .
Maximum
l e v e l s of s p e c i f i c b i n d i n g were m e a s u r e d at pH
7.0.
743 Cytosolic specific binding expressed as a percentage of the maximum specific binding measured at pH 7.0, was 41%, 78%, 97% and 66%, at pH 6.0, 6.5, 7.5 and 8.0, respectively.
Figure 4A shows the results of incubating cytosol for 1 h at 0°C with a range of
[ 3 H ] - 7 d A concentrations
(0.1-4.5 nM) .
The level of nonspecific binding under these conditions was approximately
11% of the total
[ 3 H ] - 7 d A concentration
ranged for 26-66% of the total amount bound.
and
Saturation of
the specific binding sites was achieved at approximately 3 nM with a plateau of specific binding at 1200 fmoles/mg protein.
Scatchard
approximately
(23) analysis of the
specific binding data in Figure 4A is shown in Figure 4B.
ui m oc < TJ
ο m < •o
0
1
2
3
4
[ 3 H]7dA Concentration (nM)
0.1
0.2
0.3
[ 3 H ]7dA BOUND (nM)
Figure 4. Amount of [ 3 H ] - 7 d A Bound as a Function of the [ 3 H ] - 7 d A Concentration in A. ambisexualis E87 Cytosol. Bound steroid was determined as described in Materials and Methods. (A) The amount of [ 3 H ] - 7 d A bound in the absence (o o) and presence (Δ Δ ) of a 50-fold excess of unlabeled antheridiol and the amount specifically bound (· ·) calculated as the difference between the two. (B) Scatchard analysis of the specific binding data.
744 The m e a n e q u i l i b r i u m d i s s o c i a t i o n e x p e r i m e n t s w a s 0.73 nM +
b i n d i n g c a p a c i t i e s of 1 1 0 0 - 2 0 0 0 Specific binding
[^H]-7dA w a s d e t e c t e d not r e s p o n d
fmoles/mg
indicating
A. ambisexualis.
to a n t h e r i d i o l ,
these r e s u l t s
site has "target tissue"
c h r o m a t o g r a p h y of
site
is
of
from c e l l s of Since f e m a l e s i n d i c a t e that
specificity.
[3H]-7dA extracted
Fraction Number
treatment
that the binding
in c y t o s o l s p r e p a r e d
maximum
protein.
In a d d i t i o n , no s p e c i f i c b i n d i n g
the female s t r a i n 734 of binding
from 4 s e p a r a t e
in the c y t o s o l w a s d e s t r o y e d by
w i t h p r o n a s e or t r y p s i n proteinaceous.
constant
.17 S . E . w i t h a range of
from m a l e
Thin
do
the
layer
cytosol
Fraction Number
F i g u r e 5. S u c r o s e g r a d i e n t a n a l y s i s of [^H]-7dA B i n d i n g in Fungal Cytosol. Panel A: S e d i m e n t a t i o n p r o f i l e Γη low i o n i c strength gradients containing molybdate. Panel B: S e d i m e n t a t i o n p r o f i l e in h i g h ionic s t r e n g t h g r a d i e n t s without molybdate. S y m b o l s for b o t h P a n e l s A and B: (· ·) p r o f i l e in the p r e s e n c e of [^H]-7dA a l o n e , (o o) p r o f i l e of [^H]-7dA in the p r e s e n c e of a 5 0 - f o l d e x c e s s of unlabeled antheridiol. Arrows denote fractions containing the peak level of r a d i o a c t i v i t y from [ l ^ C ] - o v a l b u m i n (3.6S) a n d from [ 1 4 C ] - a l d o l a s e ( 7 . 9 S ) . Sedimentation was f r o m left to r i g h t .
745 a f t e r 1 to 6 h o u r s of i n c u b a t i o n at 0 - 2 ° C or a f t e r 1 h o u r 2 3 ° C r e v e a l e d that no m e t a b o l i s m of
at
3
[ H]-7dA occurs
iη v i t r o . The s e d i m e n t a t i o n p r o f i l e of density gradients
[3H]-7dA binding
is s h o w n in F i g u r e 5.
gradients containing a p p e a r e d as a peak
sodium molybdate, specific
in the 8S r e g i o n
a b s e n c e of s o d i u m m o l y b d a t e
and
(Panel A ) .
Additional experiments
in the low salt g r a d i e n t .
test s a m p l e s marked
binding In the
in the 3.6S
region
(data not shown)
that a n 8S form is o b s e r v e d w h e n m o l y b d a t e b u t not
salt
in the p r e s e n c e of 1 Μ K C l ,
s p e c i f i c b i n d i n g d i s t r i b u t e d as a peak (Panel B) .
in s u c r o s e
In low
revealed
is in the
sample,
It w a s not p o s s i b l e
to
in the total a b s e n c e of m o l y b d a t e due to the
i n s t a b i l i t y of the b i n d i n g c o m p o n e n t .
We h a v e
also
f o u n d that the b o u n d s t e r o i d s e d i m e n t s at 3.6S in high gradients
(1 Μ KCl)
in the p r e s e n c e of 10 m M
salt
sodium
molybdate. The a m o u n t of
[3H]-7dA specifically bound
in the
of v a r i o u s c o n c e n t r a t i o n s of n o n r a d i o a c t i v e in Figure
6.
steroids
binding
for the b i n d i n g
7dA = 1 . 0
(by
(natural p h e r o m o n e )
22R,23S-antheridiol
= 0.1 a n d 7 d A - 3 - a c e t a t e = 0 . 0 3 .
i n h i b i t i o n of
[ H ] - 7 d A b i n d i n g by o t h e r
(e.g. C o r t i s o l a n d 7 d A - 3 - a c e t a t e ) , The r e a s o n
Some
at
steroids
at c o n c e n t r a t i o n s w h e r e
competition occurred, were consistently
found to e n h a n c e
for this is u n k n o w n .
is that these s t e r o i d s m a y
c o n c e n t r a t i o n of
A
3
c o n c e n t r a t i o n s g r e a t e r t h a n 1 χ 10~6 m .
possibility
in
= 7.5;
s t e r o i d s and s t e r o i d h o r m o n e s was d e t e c t e d o n l y
[3H]-7dA.
site.
definition);
22S,23R-antheridiol
b i n d i n g of
and
a f f i n i t i e s , c a l c u l a t e d as d e s c r i b e d
M e t h o d s w e r e as f o l l o w s :
significant
is s h o w n
Of the c o m p o u n d s t e s t e d , o n l y a n t h e r i d i o l
its a n a l o g s e x h i b i t e d high a f f i n i t y The r e l a t i v e
presence
[ 3 H ] - 7 d A by r e d u c i n g
increase
the
no
the
One
effective
the a s s o c i a t i o n
of
746 this h y d r o p h o b i c c o m p o u n d w i t h v a r i o u s c o m p o n e n t s of assay
the
system.
When eluted
from D E A E - S e p h a d e x
chromatography
l i n e a r c o n c e n t r a t i o n g r a d i e n t of K C l , b o u n d as a s i n g l e peak at a p p r o x i m a t e l y of c y t o s o l i c p r o t e i n s
columns with a
[3H]-7dA
0.24 Μ K C l .
The
elutes
majority
80%) do not bind t i g h t l y to D E A E
a n d flow t h r o u g h the c o l u m n or are r e m o v e d by w a s h i n g
with
120
10-11
10-10
10-9
10"8
ΙΟ"7
10"6
10-5
STEROID CONCENTRATION (M) F i g u r e 6. S p e c i f i c i t y of [3n]-7dA B i n d i n g . A l i q u o t s of the ( N H 4 ) 2 S O 4 - p r e c i p i t a t e d r e c e p t o r in MoM b u f f e r were i n c u b a t e d in d u p l i c a t e for 1.5 h at 0°C in the p r e s e n c e of [ 3 H ] - 7 d A at a final c o n c e n t r a t i o n of 2.5 χ Ι Ο - 9 Μ and i n c r e a s i n g c o n c e n t r a t i o n s of the i n d i c a t e d s t e r o i d s . The a m o u n t of [-^H]-7dA s p e c i f i c a l l y b o u n d in the a b s e n c e of any c o m p e t i t o r (total s p e c i f i c = 1 5 , 5 0 0 d p m / m l ) was d e f i n e d as 100%. N o n s p e c i f i c b i n d i n g was d e t e r m i n e d as d e s c r i b e d in Experimental Procedures. Each p o i n t r e p r e s e n t s the m e a n v a l u e from two s e p a r a t e e x p e r i m e n t s . Symbols: A =f (22S,23R)-antheridiol; R , S - A = (22R,23S)- antheridiol; 7dA = 7-deoxy-7-dihydro-antheridiol; 7dA-3-acetate = 7-deoxy-7-dihydro-3-ß-aceto-antheridiol; Cort = Cortisol; Choi = c h o l e s t e r o l ; Test = t e s t o s t e r o n e ; Prog = p r o g e s t e r o n e ; Est = e s t r a d i o l ; and Preg = p r e g n e n o l o n e .
747 MoM b u f f e r .
The a m o u n t of
mg of p r o t e i n
[ 3 H ] - 7 d A specifically bound
is e n r i c h e d a p p r o x i m a t e l y
7-fold after
from D E A E c o l u m n s w i t h a d r a m a t i c d e c r e a s e nonspecific binding
(data not
in the level of
shown).
Gel f i l t r a t i o n c h r o m a t o g r a p h y of the a m m o n i u m precipitated
per
elution
sulfate
r e c e p t o r on c o l u m n s of S e p h a c r y l S - 3 0 0 was
p e r f o r m e d and e a c h f r a c t i o n of the e l u a t e w a s a s s a y e d
for
[ 3 H ] - 7 d A b i n d i n g and p r o t e i n c o n t e n t .
four
separate analyses were similar.
The r e s u l t s of
S p e c i f i c binding
of
[ 3 H ] - 7 d A was g r e a t e s t at an e l u t i o n v o l u m e c o r r e s p o n d i n g a K A V v a l u e of 0 . 2 5 8 . linear regression
to
This K A V v a l u e was fit to the
line of the s t a n d a r d curve r e s u l t i n g
e s t i m a t i o n of a S t o k e s r a d i u s
for the b i n d i n g p r o t e i n .
Stokes radius coupled with a sedimentation coefficient
in a n The of
8 . 3 S was used to c a l c u l a t e an a p p a r e n t m o l e c u l a r w e i g h t of 1 9 2 , 0 0 0 by the m e t h o d of S i e g a l and M o n t y
Table
1.
(24).
P h y s i c o c h e m i c a l P r o p e r t i e s of Achlya Steroid Receptor
Sedimentation Coefficient
A summary
of
the
3.6S
(High salt w i t h o u t
Na2MoC>4)
8.3S
(Low salt w i t h N a 2
Mo04)
Stokes Radius
56.6 Ä
Molecular Weight
192,000
Frictional Coefficient
1.5
Axial Ratio
8.9
S e d i m e n t a t i o n c o e f f i c i e n t s w e r e d e t e r m i n e d by c e n t r i f u g a t i o n in s u c r o s e g r a d i e n t s (5-20% w / w ) p r e p a r e d in PM3 b u f f e r as d e s c r i b e d in M e t h o d s . The S t o k e s r a d i u s of the m o l y b d a t e - s t a b i l i z e d (8.3S) f o r m was d e t e r m i n e d by S e p h a c r y l S - 3 0 0 c o l u m n c h r o m a t o g r a p h y in b u f f e r c o m p o s e d of 100 m M K C l , 10 m M N a 2 M o 0 4 , 20 m M 3 - [ N - m o r p h o l i n o ] p r o p a n e s u l f o n i c a c i d , pH 7.0 at 4 ° C .
748 the m o l e c u l a r p r o p e r t i e s of the A c h l y a s t e r o i d r e c e p t o r g i v e n in T a b l e A very
i n t e r e s t i n g a s p e c t of the A c h l y a s t e r o i d
system
is the r e g u l a t i o n of c y t o s o l i c r e c e p t o r
c a n be a c h i e v e d by a l t e r a t i o n s growth medium. Achlya
is
1. receptor levels
in the c o m p o s i t i o n of
A c o m m o n m e t h o d w h i c h we use for
in s u s p e n s i o n c u l t u r e
involves
that the
growing
the g e r m i n a t i o n
of
a s e x u a l s p o r e s in PYG, a rich m e d i u m , for one day f o l l o w e d dilution usually
into a m i n i m a l m e d i u m three d a y s .
(Ml m e d i u m )
for a p e r i o d of
This p r o v i d e s ample a m o u n t s of
mycelia
(about 18 g p e r 2 - l i t e r flask) w i t h g o o d b i n d i n g a c t i v i t y hormone
responsiveness,
illustrates
as d e m o n s t r a t e d a b o v e .
the r e s u l t s of e x p e r i m e n t s four d a y s of g r o w t h
d a y of g e r m i n a t i o n
in P Y G ) .
transferred
Figure 7 24-hour
in Ml m e d i u m
Mycelia containing
l e v e l s of r e c e p t o r a f t e r three d a y s to an e n r i c h e d m e d i u m
maximum
in Ml m e d i u m
(PYG) and the
l e v e l s w e r e f o u n d to d r a m a t i c a l l y d e c r e a s e .
(after one were
receptor
In c o n t r a s t
this d o w n - r e g u l a t i o n of r e c e p t o r , m y c e l i a c u l t u r e d enriched medium possess relatively
and
in w h i c h the m y c e l i a l
l e v e l s of c y t o s o l i c r e c e p t o r w e r e m e a s u r e d at intervals during
by
low levels of
to
in an
receptor
that can be i n c r e a s e d by t r a n s f e r and i n c u b a t i o n in a nutrient-free
salt s o l u t i o n
receptor levels response
to h o r m o n e
We have found that the
(Figure
2) is m o r e o b v i o u s
in a m i n i m a l m e d i u m than in an e n r i c h e d
However, attempts
the
r e c e p t o r m a y be i n v o l v e d .
in
cultures
medium.
in a d d i t i o n
response to
The a b i l i t y to m a n i p u l a t e
levels should prove valuable regulation.
factors
with
visual
to a c t u a l l y c o r r e l a t e b i n d i n g and
h a v e not been d o n e and s e v e r a l
s y n t h e s i s and
Thus,
in A c h l y a show an inverse c o r r e l a t i o n
the s u p p l y of n u t i e n t s . grown
(data not s h o w n ) .
in f u t u r e s t u d i e s on
receptor
receptor
749
α>
5
Ο) \ «ο 0)
ο Ε α
4 o n o t h e r s t e r o i d h o r m o n e documented
receptor systems
effect
in A c h l y a .
r e q u i r e d to p r e s e r v e b i n d i n g In o t h e r s y s t e m s , Na2MoC>4
of
is well
( 2 5 - 2 7 ) , the p r e s e n c e of N a 2 M o 0 4 has not
s h o w n to be a b s o l u t e l y as o b s e r v e d
binding
A l t h o u g h the s t a b i l i z i n g
been activity
serves
750 to s t a b i l i z e
the s t e r o i d r e c e p t o r
in a n o n t r a n s f o r m e d
state
that d o e s not b i n d to n u c l e i but r e t a i n s the c a p a c i t y to hormone.
This nontransformed
state
by a s e d i m e n t a t i o n c o e f f i c i e n t that of the n u c l e a r b i n d i n g
is c o m m o n l y
that is larger
(8 to 10S)
form of the r e c e p t o r
A n u m b e r of p r o p o s a l s r e g a r d i n g
(3 to
i n h i b i t i o n of p h o s p h a t a s e activity
to the r e c e p t o r
than
5S).
the m e c h a n i s m of a c t i o n
Na2Moc>4 o n s t e r o i d h o r m o n e r e c e p t o r s have been m a d e include either direct coupling
bind
characterized
of
that
molecule,
a c t i v i t y or i n h i b i t i o n of
protease
(26,27).
The m e c h a n i s m of a c t i o n of Na2MoO,j in A c h l y a is u n k n o w n but m a y r e l a t e ,
in p a r t , to i n h i b i t i o n of p r o t e a s e
The A c h l y a b i n d i n g p r o t e i n enzymes
(7) and b i n d i n g
is v e r y s e n s i t i v e
activity
to
is d e s t r o y e d by
w i t h p r o n a s e e v e n at low t e m p e r a t u r e s .
activity.
proteolytic treatment
S i n c e this
organism
g r o w s r e a d i l y using c o m p l e x p r o t e i n as a m a i n n u t r i e n t , l i k e l y to c o n t a i n an a r r a y of p r o t e a s e a c t i v i t i e s . of the p r o t e a s e
inhibitors:
(0.5 m M ) , l e u p e p t i n (10 yg/ml)
i^-macroglobulin
buffers without molybdate
not p r e v e n t the loss of c y t o s o l i c b i n d i n g shown).
Clearly,
further research
e f f e c t of m o l y b d a t e w e l l as in o t h e r
activity
that m o l y b d a t e
i n t e r a c t s w i t h the
complex.
W i t h the a v i a n p r o g e s t e r o n e
molybdate
is not d i m i n i s h e d
protein
system
not the as
systems.
It is also p o s s i b l e
that
did
(data
is r e q u i r e d to d e f i n e
in the A c h l y a s t e r o i d b i n d i n g
p r o t e i n d i r e c t l y and forms a s t a b l e or slowly
indicating
Inclusion
phenylmethylsulfonylfluoride
(10 pg/ml) or
in h o m o g e n i z a t i o n
it is
binding
dissociating
r e c e p t o r , the a c t i o n of
after extensive
purification
it i n t e r a c t s d i r e c t l y w i t h the
receptor
(28).
In a d d i t i o n to the e f f e c t s of s o d i u m m o l y b d a t e , the p r o p e r t i e s of the A c h l y a s t e r o i d b i n d i n g p r o t e i n remarkably
s i m i l a r to the m o l e c u l a r p r o p e r t i e s of
molecular
are the
751 well-characterized organisms
(25,27).
s t e r o i d h o r m o n e r e c e p t o r s of
higher
It is an a c i d i c p r o t e i n w i t h a m o l e c u l a r
w e i g h t of a b o u t 192,000 and it does not a p p e a r to be since
it has a f r i c t i o n a l
c o e f f i c i e n t of 1.5 (Table
with other steroid receptors,
globular 1).
As
the 8S form in c y t o s o l can be
c o n v e r t e d to a 4S form by h i g h salt
treatment.
A l t h o u g h the A c h l y a s t e r o i d b i n d i n g p r o t e i n and o t h e r
steroid
r e c e p t o r p r o t e i n s are s i m i l a r , the A c h l y a r e c e p t o r
is v e r y
s p e c i f i c for fungal s t e r o i d
binding
a f f i n i t i e s of a n t h e r i d i o l
ligands.
and its c o n g e n e r s are
consistent with their relative morphogenesis a f f i n i t y of in v i t r o
The r e l a t i v e
in the A c h l y a m a l e E87
[3H]-7dA binding
generally
a b i l i t y to induce (22).
(Kd = 0.7 nM)
is c o n s i s t e n t w i t h o u r and o t h e r
sexual
Also,
the
measured (22)
observations
that the m a l e E87 r e s p o n d s to a 7dA c o n c e n t r a t i o n of 0.24 a n d the r e s p o n s e a b o v e this
i n c r e a s e s w i t h i n a 1 0 - to 20-fold
concentration.
As with other steroidal expression
nM
range
s y s t e m s , the m o d u l a t i o n of
is an e a r l y e v e n t
gene
in a n t h e r i d i o l a c t i o n
(10);
h o w e v e r , the e x i s t e n c e of n u c l e a r r e c e p t o r forms has not yet b e e n t e s t e d in A c h l y a . The p r e s e n t s t u d i e s are of proposals
regarding
molecules. observed
interest
in light of
the e v o l u t i o n of c e l l u l a r
Vertebrate
recent
communication
h o r m o n e s and t h e i r r e c e p t o r s have
in m i c r o o r g a n i s m s
suggesting
that these
been
forms of
c e l l u l a r c o m m u n i c a t i o n m i g h t have a r i s e n v e r y e a r l y in the e v o l u t i o n of e u k a r y o t e s and have b e e n h i g h l y c o n s e r v e d
(29).
To our k n o w l e d g e , A c h l y a
is the only fungal o r g a n i s m , and
only primitive eukaryote
b e l o w the
r e c e p t o r has b e e n d e s c r i b e d .
insects, where a
However, recent
by F e l d m a n and c o w o r k e r s have d e m o n s t r a t e d estrogen binding proteins
steroid
investigations
the p r e s e n c e
in S a c c h a r o m y c e s c e r e v i s i a e
and Paracoccidioides brasiliensis
(6).
the
They have
also
of
(5),
752 i d e n t i f i e d a p r o t e i n that b i n d s g l u c o c o r t i c o i d s albicans
(4).
U n l i k e the a n t h e r i d i o l
p r o t e i n s do not show a strong r e s e m b l a n c e receptors
in h i g h e r o r g a n i s m s .
of m u c h i n t e r e s t
evolutionary predecessors higher
However,
to
binding
steroid
they are
in that they c o u l d be i n v o l v e d
p e r c e p t i o n of e n v i r o n m e n t a l
in C a n d i d a
r e c e p t o r , these
s i g n a l s or they m a y
certainly
in the represent
to s t e r o i d a l c o n t r o l s y s t e m s
in
organisms.
B e c a u s e of its n o v e l t y , A c h l y a p r o v i d e s some opportunities antheridiol
receptor
understanding systems.
for i n v e s t i g a t i o n .
is of c l e a r s i g n i f i c a n c e
the e v o l u t i o n a r y
unusual
The c h a r a c t e r i z a t i o n
organism offers unique advantages
s i m p l i c i t y of
for
the
to
a s p e c t s of s t e r o i d a l
F u r t h e r m o r e , the r e l a t i v e
of
control
this
laboratory
i n v e s t i g a t i o n s on the m e c h a n i s m of s t e r o i d h o r m o n e
action.
References 1.
Geuns, J.M.C.:
2.
Callard, I.P., Klotz, K.L.: 314-321 ( 1 9 7 3 ) .
T r e n d s B i o c h e m . S e i . 7, 7-9
(1982).
3.
O'Day, D.H., Horgen, P.A.: S e x u a l I n t e r a c t i o n s in E u k a r y o t i c M i c r o b e s , A c a d e m i c P r e s s , N e w York 1 9 8 1 .
4.
L o o s e , D . S . , F e l d m a n , D.: ( 1982) .
5.
F e l d m a n , D., Do, V . , B u r s h e l l , Α . , S t a t h i s , P., D.S.: S c i e n c e 218, 2 9 7 - 2 9 8 ( 1 9 8 2 ) .
6.
Loose, D.S., Stover, E.P., Restrepo, A, Stevens, D.A., F e l d m a n , D.: P r o c . N a t l . A c a d . Sei. U . S . A . 80, 7 6 5 9 - 7 6 6 3 ( 1983) .
7.
Riehl, R.M., Toft, D.O., Meyer, M.D., Carlson, G.L., McMorris, T.C.: E x p . Cell R e s . 153, 5 4 4 - 5 4 9 ( 1 9 8 4 ) .
Gen. Comp. Endocrinol.
J . B i o l . C h e m . 257,
J . B i o l . C h e m . in the
21,
4925-4930 Loose,
8.
Riehl, R.M., Toft, D.O.:
9.
Griffin, D.H.: in F u n g a l P h y s i o l o g y , p p . 2 8 6 - 2 9 1 , a n d S o n s , N e w York ( 1 9 8 1 ) .
press. Wiley
753 10.
Timberlake, W.E., Orr, W.C.: in Biological Regulation and Development, Vol. 3B, Hormone Action (Goldberger, R.F. and Yamamoto, K.R., eds.) pp. 255-283, Plenum Press, New York (1984).
11.
McMorris, T.C., Le, P.H., Preus, M.W., Schow, S.R., Weihe, G.R.: J. Org. Chem. 48, 3370-3372 (1983).
12.
McMorris, T.C., Sheshadri, R., Arunachalam, T.: Chem. 39, 669-676 (1974).
13.
Kane, B.E., Jr., Reiskind, J.B., Mullins, J.T.: Science 180, 1192-1193 ( 1973) . Timberlake, W.E.: Dev. Biol. 51, 202-214 (1976).
14. 15. 16.
J. Org.
Silver, J.C., Horgen, P.A.: Nature (London) 249, 252-254 (1974). Horgen, P.A., Iwanochko, M., Bettiol, M.F.: Arch. Microbiol. 134, 314-319 (1983).
17.
Thomas, D. des S., Mullins, J.T.: ( 1967) .
18.
Horgen, P.A.: Biochem. Biophys. Res. Commun. 75, 1022-1028 ( 1977) . Griffin, D.H., Breuker, C.: J. Bacteriol. 98, 689-696 (1969) .
19. 20. 21.
Science 156, 84-85
Cantino, E.C., Lovett, J.S.: Physiol. Plant. 13, 450-458 (1960) . Barksdale, A.W.: Mycologia 62, 411-420 (1970).
22.
Barksdale, A.W., McMorris, T.C., Seshadri, R., Arunachalam, T., Edwards, J.Α., Sundeen, J., Green, D.M.: J. Gen. Microbiol. 82, 295-299 (1974).
23.
Scatchard, G.: ( 1949) .
24.
Siegel, Μ., Monty, K.J.: 346-362 (1966).
25.
Niu, E.-M., Neal, R.M., Pierce, V.K., Sherman, M.R.: Steroid Biochem. 15, 1-10 (1981).
26.
Housley, P.R., Grippo, J.F., Dahmer, M.K., Pratt, W.B.: in Biochemical Actions of Hormones, (Litwack, G., ed.) Vol. 11, pp. 347-376, Academic Press, Orlando (1984).
27.
Sherman, M.R., Tuazon, F.B., Stevens, Y.-W., Niu, E.-M.: in Steroid Hormone Receptors: Structure and Function, (Eriksson, H., Gustafsson, J.-Α., eds.) pp. 3-21, Elsevier, Amsterdam (1983).
28.
Puri, R.K., Grandics, P., Dougherty, J.J., Toft, D.O.: J. Biol. Chem. 257, 10831-10837 (1982). LeRoith, D., Shiloach, J., Berelowitz, M., Frohman, L.A., Liotta, A.S., Krieger, D.T., Roth, J.: Federation Proc. 42, 2602-2607 (1983).
29.
Ann. Ν. Y. Acad. Sei. 51, 660-672 Biochim. Biophys. Acta 112, J.
THE RECEPTOR FOR 2,3,7,8-TETRACHLORODIBENZO-P-DIOXIN:
SIMILARITIES AND
DISSIMILARITIES WITH STEROID HORMONE RECEPTORS
Lorenz Poellinger, Johan Lund, Mikael Gillner and Jan- Äke Gustafsson
Department of Medical Nutrition, Karolinska Institute, Huddinge University Hospital F69, 141 86 Huddinge, Sweden.
Introduction The receptor protein for 2,3,7,8-tetrachlorodibenzo-p-dioxin
(TCDD), a
putative gene regulatory protein involved in the induction of specific forms of cytochrome Ρ-Ί50, seems to share many characteristics with steroid hormone receptors. The scope of the present review is to overview and compare the present knowledge of the TCDD receptor to that of the steroid hormone receptors. Topics for this comparison include current models of gene regulation, physicochemical characteristics of the receptor proteins, ligand binding specificities and receptor interaction with DNA.
Background Steroid hormones seem to regulate the expression of specific genes by their interaction via specific intracellular recognition sites, i. e. soluble receptor proteins. In analogy to this endocrine model of gene regulation, several lines of evidence indicate that intracellular, soluble receptor proteins are essential mediators of the biological responses produced by certain xenobiotics, i.e. halogenated or non-halogenated polycyclic aromatic hydrocarbons
(1, 2). TCDD is one of the most potent
agonists known today, both for these receptor-mediated biological responses and for receptor binding itself (2, 3). The chlorinated dibenzodioxins are formed as unwanted contaminants during the synthesis of halogenated phenols. TCDD may accidentally be formed during the manufacture of 2,4,5-trichlorophenol which is, in turn, used to synthesize the
Molecular Mechanism of Steroid Hormone Action © 1985 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
756 herbicide 2,H,5-trichlorophenoxyacetic acid (2,4,5-T) and similar compounds (if). Furthermore, it appears that various polychlorinated
dibenzo-
dioxins, including TCDD, are formed as unwanted products during incomplete combustion of organic chlorinated compounds (5). TCDD also seems to be a remarkably persistent and metabolically inert compound (10) having a half-life of more than 10 years in soil (11) and, furthermore, exhibiting high biological availability after ingestion of TCDD-contaminated soil by rats and guinea pigs (12). However, some metabolic alteration or biological degradation of TCDD has recently been reported to occur _in vivo in animals (10).
Investigations with laboratory animals have shown that TCDD and structurally related compounds, e.g. chlorinated or brominated dibenzo-p-dioxins, dibenzofurans or biphenyls, produce a similar characteristic pattern of toxic responses (2, 6, 7). TCDD was shown to be the most toxic compound of these congeners thus far examined and, furthermore, appears to be one of the most potent toxic and teratogenic synthetic low-molecular compounds known (2, if, 8, 9). Thus TCDD serves as a prototype for these toxic, structurally related halogenated aromatic hydrocarbons. Several toxic lesions produced by halogenated aromatic hydrocarbons in the mouse, such as thymic involution, cleft palate formation in fetuses, teratogenesis, hepatic porphyria and epidermal hyperplasia and hyperkeratosis appear to be mediated by the TCDD receptor (12, 14, 15). Furthermore, the binding affinities of a large number of these compounds for the TCDD receptor correspond well with the rank order of their toxic potencies (6). Many of these quite characteristic lesions are reported to be relatively species-specific and to occur in a limited number of species (if, 16). In most species, however, administration of a single lethal dose of TCDD leads to the same pattern of a prolonged "wasting" syndrome including loss of adipose tissue and general debilitation of the animal leading to death within a few weeks (2, 17). This extreme acute lethality of TCDD suggests that TCDD is probably affecting some fundamental biological process within mammalian cells. A very striking and consistent feature of TCDD-toxicity is a depletion of lymphoid tissues in general and the thymus in particular (18), an effect which closely resembles the effect of glucocorticoids on the same tissues. It has also been reported that the induction of tyrosine
757 aminotransferase by dexamethasone can be inhibited by 3~methylcholanthrene and benzo(a)pyrene (19) - two well established ligands of the TCDD receptor ( 2 0 - 2 Ό . However, glucocorticoids do not compete with [3H]TCDD for TCDD receptor binding sites (20, 25-27), nor does TCDD compete for the glucocorticoid receptor binding sites (17, 23). Furthermore, adrenalectomized
rats respond to TCDD with thymic involution (28) and no endocrine
manipulation tested appears to have any effect on [3H]TCDD receptor binding in the rat liver
(29).
Several endocrine effects have been described following exposure to halogenated aromatic hydrocarbons, e.g. lowered plasma concentrations of progesterone (30, 31), corticosteroids
(32) and thyroxine (33), distur-
bances of the estrous cycle (30, 31)) and impaired reproduction
(30, 35).
One particularly striking and often studied biochemical effect produced by TCDD and related compounds is their potency to induce specific isozymes of cytochrome P-i450 and the associated monooxygenase activity aryl hydrocarbon hydroxylase (AHH) (1, 3 6 )
together with several non-monooxygenase
activities, e.g. UDP-glucuronosyltransferase, DT-diaphorase and ornithine decarboxylase (1). For chlorinated dibenzo-j?-dioxin congeners, there exists a good correlation between their binding affinities for the TCDD receptor and their potencies to induce AHH activity in vivo (20). There also seems to exist a
good correlation between the potency of these
compounds to induce AHH activity and their toxic potency (2, 37). TCDD induced keratinization of a mouse teratoma cell line has been used as one in vitro model of toxicity (37). However, many TCDD receptor containing tissues Jji vivo and cells _in vitro respond to TCDD with the induction of AHH activity but display no evidence of a toxic response (16, 3 8 ) .
A
genetic model, where the TCDD receptor appears essential but not sufficient for the expression of toxicity has been proposed (15). In this model, two genetic loci are conceived: the Ah and hr loci, which determine the presence of the TCDD receptor and the expression of receptor mediated toxicity, respectively
(15).
758 Gene Regulation by Steroid Hormones and TCDD - Level of Regulation
The synthesis of a wide variety of proteins has been demonstrated to be under hormonal control (39). For several of the genes encoding these proteins, the hormonal control of the observed alteration in gene expression has been attributed to the level of transcription, more specifically to an increased rate of transcription. This concept is, to a large extent, based on experiments where molecular cDNA probes were isolated from hormonally induced specific mRNAs and the radioactive cDNAs then used to quantitate specific mRNA levels, especially the kinetics of the induction process (40-42). The rapid hormonal induction of mRNA and the insensitivity of this response to inhibitors of protein synthesis have been taken as indications of a primary hormonal effect. A quantitative and temporal relationship between hormone-receptor complex formation, nuclear translocation and RNA induction have been taken as further support for this concept (40, 43). Also, sequences in the 5' flanking regions of hormonally regulated genes have been demonstrated to be required for the hormone responsiveness of these genes (44-55). As to the molecular mechanisms responsible for the hormone-receptor induced alteration in the transcription of certain genes, little is known. However, recent data from experiments where a glucocorticoid response element from murine mammary tumor virus (MMTV) has been inserted near originally hormone insensitive genes thereby rendering these genes hormonally controlled following transfection into glucocorticoid receptor containing cells (56, 57), may shed new light on this process and will be discussed in some detail later.
It should be pointed out that an increased rate of transcription after hormone administration is not the only mechanism proposed for the hormonal regulation of gene expression. Effects of steroids on the stability of mRNA molecules (40, 58, 59) as well as on protein-processing (60) have been proposed as additional mechanisms by which steroids may modulate gene expression. Several studies have demonstrated that administration of TCDD or TCDD-like inducers leads to a large increase in translatable mRNA's encoding the TCDD induced cytochrome P-450 isozyme(s) (61-63). It has also been shown
759 by _in vitro nuclear transcription studies that this process reflects an increased rate of transcription of the specific cytochrome P-450 gene(s) (6H-66) rather than an effect on mRNA stability - another plausible level of regulation of gene expression (67; c.f. above). Nevertheless, the latter mechanism cannot be completely ruled out in view of the limited amount of data available. In cultured cells, it has been shown that treatment with TCDD results in a large increase in the rate of transcription of specific cytochrome P-450 encoding RNA within 30 min (66). A quantitative and temporal relationship between the nuclear accumulation of the TCDD-receptor complex and the increase in synthesis of mRNA encoding a specific form of cytochrome P-M50 has also been demonstrated (68). Full accumulation of mRNA also occured in the presence of cycloheximide (69). Using variant hepatoma cells with specific cytochrome P—i)50 induction-responsive as well as induction-resistant phenotypes, it has also been shown that the presence of a functional TCDD receptor constitutes an essential component in mediating selective stimulation of the rate of cytochrome P-450 transcription (66, 69). The rapidity of this induction is similar to that observed with glucocorticoid activation of transcription of mammary tumour virus (70). No specific data are available on the effect of TCDD on cytochrome P-450 processing.
Current Models for the Mechanism of Action of Soluble Receptor Proteins
It is today widely accepted that specific intracellular recognition sites are involved in gene regulation by steroid hormones and that all steroid hormones act via a similar scheme (71. 72). This model was first proposed by Gorski et al. (73) and Jensen et al. ( 7 Ό
and involves a) the uptake of
the hormone into the cell; b ) the subsequent noncovalent binding of the steroid hormone to specific, saturable and soluble receptor proteins; c) an increased affinity of the hormone-receptor complex for the cell nucleus induced by the receptoi—ligand interaction itself. In this model, the nucleus is believed to be the primary site of action and, furthermore, cytoplasmic receptors are postulated to exist either occupied or non-occupied by a steroid, whereas nuclear receptors are postulated to exist only when occupied by a hormone. Recently, however, it has become clear that
760 several issues in this model, are somewhat controversial. Among such issues are e.g. a) the question concerning the intracellular distribution of steroid receptors in target tissues in the presence or absence of hormone (75-79); and b) the nature of the putative nuclear "acceptor" site of occupied steroid receptors (72, 79). Recent reports have indicated that, in fact, unoccupied steroid receptors may exist in a state of equilibrium between the cytoplasmic and nuclear compartment and that this equilibrium may be shifted in favor of the cytoplasm by manipulations such as tissue homogenization and subcellular fractionation (75, 76, 80, 81). Two independent studies using either immunohistochemical techniques (i.e. immunocytochemical staining using a monoclonal antibody against the estrogen receptor) (77) or cytochalasin Β induced enucleation to obtain cytoplast and nucleoplast fractions from an estrogen responsive cell line (78) supported the notion that unoccupied steroid receptors predominantly reside within the cell nucleus. Based on these studies it was suggested that the classical "two-step" model for steroid hormone action requires some modification in so far as the steroid induced increased affinity of steroid receptor for DNA should be regarded as an intranuclear event, rather than as a step whereby cytoplasmic receptors are rendered capable of interacting with nuclear structures leading to a cytoplasmic - nuclear translocation.
It has been proposed by several authors that the unoccupied steroid receptor form with negligible affinity for nuclei, DNA or other polyanionic resins may represent an oligomer of several steroid or nonsteroid binding entities. Not until after dissociation of this oligomer into a monomeric steroid binding form (for physico-chemical characteristics, cf. below), does the receptor exhibit a high affinity for nuclei or polyanions (82-81). This model, however, is based on observations _in vitro and it remains to be proven whether it is valid for the situation in whole cells.
The nature of putative intranuclear "acceptor" sites for steroid hormone receptors has been the subject of intensive research efforts over the past decade (72, 85). Recently, however, reports that steroid receptors bind to specific DNA sequences and thereby enhance transcription of specific clusters of regulated genes (50, 52, 51, 86-98) have provided an attrac-
761 tive model to explain the extreme selectivity in protein induction by steroid hormones. This mechanistic model is particularly interesting in view of its analogy to the regulation of procaryotic genes by specific proteins, e.g. the lac repressor or the catabolite gene activator protein of Escherichia coli. Furthermore, certain features of procaryotic gene regulatory proteins - i.e. requirement of the ligand for DNA-binding and separateness of ligand- and DNA-binding sites - are shared by steroid hormone receptors (cf. below).
In analogy to the "two-step" model proposed for the mechanism of action of steroid hormones, an accumulation of TCDD-receptor complexes in the cell nucleus following occupation of cytosolic receptor sites has been reported by several authors (25-27, 99, 100). Furthermore, it has been suggested that transcription of TCDD-regulated genes requires nuclear localization of the TCDD-receptor complex (66, 68, 69). As is the case with the model for the mechanism of action of steroid hormones (cf. above), questions have been raised whether unoccupied TCDD receptors solely reside in the target cell cytoplasm as proposed in the "two-step" model of action (1, 2) or whether both unoccupied and occupied TCDD receptors reside within the nuclear compartment but in two affinity states for nuclear "acceptor" sites (101). In similarity to experiments carried out with genes regulated by steroid hormones, the identification of cis-acting regulatory elements within or near the specific cytochrome P-M50 gene(s) should help to elucidate the nature of possible intranuclear target sites for occupied TCDD receptors.
Physicochemical Properties of Eucaryotic Soluble Receptor Proteins Hydrodynamic Properties and Molecular Weights. A comparison of available data on soluble receptors concerning even such basic characteristics as size and hydrodynamic properties is severely hampered by the great differences in experimental conditions used by different investigators. In addition, although a model for the structure (s) of different soluble receptor forms extracted from mammalian tissues is beginning to evolve (102), virtually nothing is known about the
762 native form(s) of soluble receptors. Taking these limitations into consideration, it becomes necessary to define the basis for the selection of data for the comparison of receptors. In Table I we have selected data from the literature regarding the monomeric forms of soluble receptor proteins, preferentially from studies on purified preparations. Reports where inadequate precautions against proteolysis were taken, leading to registration of anomalously small receptor sizes, have been avoided.
As shown in Table I, the labeled glucocorticoid receptor, either in pure form or in crude cytosolic preparations, sediments as a 3.4 -3.7 S entity in hypertonic sucrose gradients (103, 104). During gel filtration, the glucocorticoid receptor displays a Stoke's radius of 5.6-6.0 nm (103. 104). This would imply an apparent molecular weight in the range of 85,000 to 96,000, a frictional ratio of 1.74-1.90 and an axial ratio of 15-20. These data appear to be confirmed by SDS-PAGE of either purified receptor preparations (103, 105, 106) or photoaffinity-labeled receptor in crude cytosol (107-109), where the molecular weights estimated range between 87,000 and 94,000.
In the case of the estrogen receptor, the monomeric form of the receptor sediments as a 4.2 S entity in hypertonic sucrose gradients (110, 111). If the incubation with ligand is performed at 20~37°C it appears that the -4 S estrogen receptor forms a homodimer that sediments as a -5 S entity (110). The Stoke's radius estimated for the monomeric form of the estrogen receptor ranges from 4.4 to 6.4 nm (110, 111) giving apparent molecular weights of 76,000 to 114,000. From these data it is possible to calculate frictional ratios of 1.45-1.84 and axial ratios of 8-20. By SDS-PAGE of the purified estrogen receptor its molecular weight was estimated to 70,000
(111) .
Available evidence indicates that the progesterone receptor in chick oviduct (112-114) exists in the form of two subunits, A and B, whereas the progesterone receptor in rabbit uterus seems to exist as a hormone binding unit of one and the same size, not excluding, however, the possible existence of two subunits of equal size. The A subunit from chick oviduct sediments as a 3 . 6 S entity and has a Stoke's radius of 4.6 nm whereas the
763 Β subunit sediments as a 4.2 S entity and has a Stoke's radius of 6.3 nm (112). From these data, apparent molecular weights of 71,000 and 114,000 were calculated for the A and Β subunits, respectively (112). It is also possible to calculate frictional and axial ratios of 1.54 and 10 for the A subunit and 1.81 and 15-20 for the Β subunit. Due to the general availabilty of a photoaffinity label for the progesterone receptor, R 5020, extensive data is available on molecular weights as determined by SDS-PAGE of the photoaffinity labelled receptor. These studies indicate that the A subunit has a molecular weight of 79,000-80,000 and the Β subunit a molecular weight of 108,000-109,000 (113, 114). The rabbit progesterone receptor seems to have a molecular weight of 70,000 as determined by SDS-PAGE of a purified uterine receptor preparation (115).
The androgen receptor purified from rat ventral prostate sediments at 4.5 S in hypertonic sucrose gradients and displays a Stoke's radius of 4.8 nm (116). These data suggest an apparent molecular weight of 83,000, a frictional ratio of 1.41 and an axial ratio of 6-8. SDS-PAGE of the purified androgen receptor indicated a molecular weight of 86,000 (116). The same value was obtained when using a photoaffinity label for the androgen receptor in the rat ventral prostate (117).
The vitamin D receptor, purified from chick intestine (118), has been reported to sediment as a 3.3 S entity in hypertonic sucrose gradients and a molecular weight of 68,000 was calculated from gel filtration experiments (118). From these data one may calculate a Stoke's radius of 4.9 nm, a frictional ratio of 1.67 and an axial ratio of 12-15. SDS-PAGE of the purified vitamin D receptor yielded a molecular weight of 55,000 (118). Recently, higher molecular weights of 91,000 to 1 1 0,000 (1 19-121 ) have been reported for the vitamin D receptor, a fact that the authors attribute to their precautions against proteolysis.
The data summarized above indicate that the monomeric forms of steroid hormone receptors, during conditions minimizing proteolysis, exist as components with sedimentation coefficients of 3-3 to 5.0 S, Stoke's radii of 4.4 to 6.4, frictional ratios of 1.41 to 1.90, axial ratios of 6 to 20 and molecular weights in the range of 60,000 to 120,000. The frictional
764
ο t. ο.
ιη ο
«Η ω κ
οο I t—
to •ρ
ι—I 10 ·* χ
> ω ω
to
ο. ε ο
C.1
κ! Ε-*
ι. 3 Ο 00 1 α» ω s, ο ο
Ο Ξ I 3 a) .-t
I s >1 rH c Λ to .,Η Ε e 3 Φ a:
CO α> •p ο ο •C ο.
φ
4 to α. ω .c Ρ CO
CO rH rH ω ο CO υ e Ε-
ο Ι cc •ρ
to I rH to 3 S rH >> tu t. ι-Η Ο φ -Ρ α) ttj 3 CO s OS 3 ο -P Ο Λ CO to Σ α. — cc
h
765
ao CO af
in τ
CM
1—
CO 1—
-
σ>
in
r—
CM
κ
r— CM
ο CO ι σ> t-
Φ
>
co CM I— CO C\J
ο
ο
oo
in in
CO
I
1
Ο •Ο
60 ο tΌ C η)
CO c ο Ή
CO
Φ
a\
I co ο
c
ί-
in Τ-
in
Τ
]
1
CM
\o
Ι
Ο •ρ α
in
Φ
•Ρ rH ΙΟ
Φ Ι.
ο rH
ο
Τ
CM
1
1
1
t--
1
1— J Ο
1
•
in ι
ι
I
1
in 00
CM 1
cr\
CO UD
CT*
cr\ r-
1
1
1
I
1
CO =T
CT» J
co
LT>
1
in ΓΙ ο
1
I
m
ο Ζ
1 •rH > Ο < CQ ρ
Ο Ο
•rH 3 £ TD
ο
tO φ >H
01
φ >H rH CO !-,
•Ρ to •Η 3 JD Sa φ tO •Ρ DC 3
4-> C φ >
l-t
to
Φ
j->
to ρ to •Ρ Ο tO i . cc a.
cc
H
ο ζ
i.
•P c φ
>
•Ρ Λ ce
Ί to φ 4-) φ c -ρ •rH (0 •ρ 0) Ο ο •rH s- •C α Ο
CE Q
ο ζ
Ο
φ Ο c • rH •ΓΗ •C •ρ J*
Ο
ία
ί. ο. χ
Sο Ρ ο. φ ο φ ί-
«—
1
10
φ
CC
1
ω
•
ί. ο .ρ ο. φ ο φ
Ο ζ
ί.
•Α
•rH Ο
ο •rH Ρ ίο ο ο ο 3 ΓΗ 60 κ
ω
> φ ί* to Φ 3 > Ο • rH Σ fH
CC E-H
ι—l •Ρ to ce
CE
ο *
to
Φ
φ
•
vjD
,—
CM -—
Ο.
φ Ο
φ ία α
ΙΗ
I— CO
—'
Μ CC C0
X
i.
Ν CO
(C —
m tr.
CO •
r—
Ο
ίο
C\J
II
CC
6"· to ίο •Ρ ο. φ ο φ L Q
C 'rH e
to •Ρ >
κ
CC
a
ί.·. -
Ο
Ρ ο. φ ο φ ί.
Σ
ί.
C Ο •rH 4J
VH ο
φ a
CO
£
»
L Ο -Ρ
Ο tH \
to
φ
£
•Ρ 60
C •H 6 3
to to tfl to·· ο •Η Ρ to
Φ
c u ο • rH >
•a Φ
to rH 3 Ο
r—i
3
Φ
Ρ to rH Ο ία.
01 01
φ
60 C •rH CO
Φ
C
CL
ΓΟ
=r
2
•ο
•Ρ
a •
Ϊ— CM
Λ
60 C
£-
ς-Η Φ
£
• rH ρ to 3 Β
>,
Ο
•ο φ Ρ to -Η
3
Ο
r—i
tO Ο
Ο
*
s=
CO
to c ο •Ρ Ή
CO
Ό Ο
C0
£
Ρ
3
•Ο ΙΟ 3
ιΗ tO C 60
•rH ίο
φ
£_
£
Ρ φ Ό
C
4-
•Ρ
t-
C0
φ CL Ο. to
J-> ο C
ο •σ Φ
01 Φ
£
ί-
766 and axial ratios for these proteins imply a rather assymetric configuration and this is interesting in the light of reports suggesting that certain DNA binding proteins display similar assymetry (122). These authors speculate that this characteristic may explain the ability of these relatively low-molecular weight proteins to protect comparatively long DNA sequences in DNA foot-printing experiments.
Table I also presents comparative data on the physicochemical characteristics of the TCDD receptor.
Data from our own laboratory indicate
that the TCDD receptor in the rat sediments as a 4.4-4.5 S entity in hypertonic sucrose gradients, that it has a Stoke's radius of 6.1-6.6 nm, a frictional ratio of 1.73-1.79, an axial ratio of 12-15 and an apparent molecular weight of 111,000-136,000 (23, 123). The TCDD-receptor in the mouse has been estimated to sediment in the 5.7 to 7.5 S range in hypertonic sucrose gradients (21, 25, 68). Furthermore, Stoke's radii ranging from 6.0 to 7.5 nm have been described (ibid), and the apparent molecular weight has been estimated to be between 196,000 and 245,000 (21, 68). From these data a frictional ratio of 1.40-1.67 and an axial ratio of 6-15 may be calculated. However, in a recent study using identical experimental conditions for the rat and mouse TCDD receptor we were unable to detect any physico-chemical differences between the two receptors (23).
In summary, the hydrodynamic properties and molecular weights described for the different steroid hormone receptors show both similarities and dissimilarities; it is clear that the corresponding parameters estimated for
the TCDD-receptor fall within this range of variation and that the
TCDD receptor does not display any particular hydrodynamic property distinguishing it from the steroid hormone receptors.
Charge
DEAE-cellulose chromatography and isoelectric focusing are methods often utilized to assess differences in charge of proteins. Isoelectric focusing may be carried out in density gradients in columns, or more conveniently in flat-bed Polyacrylamide gels (IFPAG). IFPAG-analysis requires considerably shorter separation times (2 h) than isoelectric focusing in
767 columns, thus receptor p r o t e o l y s i s and ligand d i s s o c i a t i o n may be minimized. I n the f o l l o w i n g we have t h e r e f o r e , when p o s s i b l e , quoted data obtained from IFPAG.
IFPAG-analyses have revealed apparent i s o l e c t r i c p o i n t s ( p l ) f o r the g l u c o c o r t i c o i d receptor of 5 to 6 and 6.1-6.2 from human lymphocyte cytosol
(124) and r a t l i v e r cytosol
(125), r e s p e c t i v e l y . Similar
pi-values
( 5 . 9 - 6 . 4 ) have been reported f o r the estrogen receptor both in human mammary tumor cytosol
(126) and in r a t l i v e r cytosol
(125). These data (pi
- 6 . 4 ) were confirmed by i s o e l e c t r i c focusing in columns of a pure receptor preparation from c a l f
uterus ( 1 2 8 ) . A pi of 6.2 has been reported f o r the
progestin receptor from r a t uterus as well as human breast carcinoma cytosol
(129).
When the androgen receptor from r a t p r o s t a t i c cytosol was analyzed by i s o e l e c t r i c focusing in sucrose density gradients the non-DNA-binding form of the non-activated ( c . f . below) receptor focused at a pH of 5.8, whereas the DNA-binding form of the receptor focused at a pH of 6.5 ( 1 3 0 ) . Chromat o f o c u s i n g , a r e c e n t l y developed method f o r protein separation based on d i f f e r e n c e s in charge, has been used t o estimate the pi of the vitamin D receptor t o 6.0-6.2 ( 1 3 1 ) .
In the case of the TCDD receptor the apparent pi as determined by IFPAG i s 6.0 in human lymphocyte c y t o s o l (132) and 6.2 in r a t l i v e r c y t o s o l
(133)·
At pH 7.2, the TCDD receptor from r a t l i v e r cytosol was reported t o e l u t e from DEAE-cellulose at 0.2-0.3 Μ NaCl ( 2 3 ) . DEAE- c e l l u l o s e chromatography at pH 7.4 has also been e x p l o i t e d t o separate the DNA-binding form
of the
r a t l i v e r g l u c o c o r t i c o i d r e c e p t o r , e l u t i n g at 0.06 Μ potassium phosphate, from the non-DNA-binding form, e l u t i n g at 0.24 Μ at a pH of 7.4 ( 1 3 4 ) .
In summary, s t e r o i d hormone receptor proteins seem t o have i s o e l e c t r i c points around 6. The same i s the case with the n a t i v e TCDD-receptor. Limited
p r o t e o l y s i s (135) i s o f t e n used t o improve the r e s o l u t i o n of
soluble receptor preparations during IFPAG a n a l y s i s . This treatment a f f e c t s the apparent pi of some receptor proteins ( 1 3 5 ) . I f
subjected t o
l i m i t e d p r o t e o l y s i s , the apparent pi i s increased f o r the estrogen
768 receptor of mammary tumours (126), is unaffected for the estrogen receptor from rat (127), and is decreased for the glucocorticoid (125) and TCDD receptor (133) from rat liver. It may be speculated that these differences are due to the loss of peptides with differing charges from different receptors. Both the TCDD and glucocorticoid receptors elute from DEAEcellulose around a salt concentration of 0.2 Μ (23, 131).
Ligand Binding Specificity
Most of the information on the specificity of binding of steroid hormones to their receptor proteins has been derived from competitive binding experiments. In such experiments the affinity of an unlabeled competitor is estimated from its ability to displace a radiolabeled ligand for the receptor. The capacity of an agonist to elicit a biological response is not always directly correlated to its receptor affinity,
since distribu-
tion factors, such as absorption, metabolism and plasma protein binding, determine the concentration of unmetabolized agonist available for receptor binding (136). It is thought that long-term retention of the agonist at the receptor sites, due to a low dissociation rate, is required for a sustained biological response (136)
From studies of substituent effects on the binding of adrenocortical hormones binding to the glucocorticoid receptor, it appears as the 3 20-oxo groups, and the 11-
and 21-hydroxyl
and
groups are essential for
binding (137-139). Schmit and Rousseau (110) have studied fifteen glucocorticoid receptor ligands and concluded that the basic structure of ring A for high receptor affinity is 1 α,2ß-half-chair. Furthermore, it was concluded that the Β and C rings are semirigid chairs, and that their conformation is not much affected by substituents. On the other hand, the receptor binding affinity may be affected by substituents in these two rings (112). The shape of the D-ring is critically dependent on the nature of the substituents. A 17-hydroxyl group reduces whereas a 17-methyl group increases the affinity for the receptor (111). Furthermore, these sub-
769 s t i t u e n t s influence the o r i e n t a t i o n of the pregnane side ohain. However, the p a r t i c u l a r conformation of the s i d e chain required f o r high a f f i n i t y binding has not yet been established
(142).
In a study of the thermodynamics of binding of 29 c o r t i c o s t e r o i d s to the r a t hepatoma c e l l g l u c o c o r t i c o i d r e c e p t o r , Wolff et a l . (143) found that the changes in both enthalpy and entropy of binding decreased as the temperature was increased, which i n d i c a t e s that the s t e r o i d receptor binding mainly i s of hydrophobic nature.
A phenolic r i n g seems t o be a common f e a t u r e of both estrogens and a n t i estrogens, e . g . d i e t h y l s t i l b e s t r o l and tamoxifen, r e s p e c t i v e l y . HShnel et a l . (144) have suggested that the phenolic 3-hydroxyl group of
estrogens
i s of greater importance f o r binding than the 17-hydroxyl group, although both are required f o r h i g h - a f f i n i t y binding of the estrogen r e c e p t o r . Certain t r i p h e n y l e t h y l e n e d e r i v a t i v e s hydroxylated in two of the rings have higher a f f i n i t y f o r the estrogen receptor than e s t r a d i o l , but i t
is
not e n t i r e l y c l e a r how the hydroxyl groups of these ligands can be superimposed on the hydroxyl groups of e s t r a d i o l t o depict common binding f o r these hydroxyl groups on the estrogen receptor
sites
(145).
Duax et a l . (146) have found that the progestin receptor i s able t o bind a number of s t e r o i d s with s i g n i f i c a n t structural v a r i a t i o n s in the B-, C-and D-rings. The only s t r u c t u r a l f e a t u r e that was common t o a l l s t e r o i d s with a f f i n i t y f o r the progestin receptor was the 3 - o x ° -
configuration a l -
though not a l l s t e r o i d s with t h i s structure bind t o the receptor with a high a f f i n i t y . Several of the S-oxo-A^-steroids with high a f f i n i t y f o r the progestin receptor a l s o had the 1 β, 2a-inverted half chair conformation (146). These f i n d i n g s l e d Duax e t . a l . to propose that high binding a f f i n i t y f o r the progestin receptor i s due t o a t i g h t binding of
the
inverted Α - r i n g t o the binding s i t e .
A r e l a t i v e f l a t n e s s of the Α - r i n g , as in 5a-reduced or
Δ^-structures,
seems t o be required f o r high binding a f f i n i t y f o r the androgen receptor (147). A 17$-hydroxyl group a l s o seems necessary f o r high a f f i n i t y b i n ding, whereas structures with a 17a-hydroxy group are unable t o bind t o
770 the receptor (117). A 3~oxo group increases binding affinity, but is not necessary (1 -48, 119). 19-Nortestosterone binds with higher affinity than testosterone, a 17a-methyl group does not decrease binding affinity, and a 7a-methyl group further increases the binding affinity (147). Introduction of a 3,9,11-triene structure resulted in an increased binding affinity indicating that binding increases with increasing flatness of the steroid nucleus (150).
A problem in studies of the mineralocorticoid receptor has been the possible coexistence of mineralocorticoid and glucocorticoid receptors in mineralocorticoid target cells, since most ligands binding to one of these receptors also bind to the other receptor, albeit not with the same affinity (151). Because of this problem we have chosen not to discuss the properties of the mineralocorticoid receptor in this review. Fortunately, the
problem of insufficient specificity of mineralocorticoid receptor
ligands has recently been diminished by the synthesis of specific glucocorticoids, such as RU 26988, which do not interact with the mineralocorticoid receptor or corticosteroid-binding globulin and which may therefore be used to block the glucocorticoid receptor binding sites (152).
The Β ring of the steroid nucleus is opened in the vitamin D secosteroids. In these, the 1a- and 25ß-hydroxyl groups are reported to be the most important substituents for high affinity binding to the vitamin D receptor (153, 154). The binding is also reported to be sensitive to modifications in the A ring and the side chain (154).
The TCDD receptor binds TCDD with a high binding affinity (Kd = 0.3 χ 10~9 Μ in mouse liver cytosol) (20). The TCDD receptor preferentially binds compounds known to induce microsomal AHH. These compounds are polycyclic aromatic hydrocarbons, e. g. 6-naphthoflavone, 3-methylcholanthrene, benzo(a)pyrene, and chlorinated hydrocarbons, e.g. dioxins, dibenzofurans, and biphenyls (2). From studies of the binding of halogenated dibenzodioxins to the TCDD receptor it has become clear that at least 3 and preferentially 4 halogens in positions 2, 3. 7 and 8 are required for high binding affinity. The dioxin nucleus is not essential for binding since some other molecules, e. g. anthracene and biphenylene substituted with 4
Figure 1. Plots of molecules with the van der Waals radii of the atoms included. TCDD (2,3,7,8-tetrachloro-p-dibenzodioxin), top (A), and side view (C), and budesonide (11g,21-dihydroxy-16a,17a[(22R)-propylmethylenedioxyJ-pregna-1,4-diene~3,20-dione) top (B) and side view CD).
772 chlorines at similar positions as in TCDD, also bind to the receptor with high affinity (6). Biphenyls chlorinated at similar positions as in TCDD binds to the TCDD receptor with a lower affinity than the corresponding dioxins (155). Planarity, or the ability to attain planarity, may therefore be a prerequisite for binding.
It has been noted that these chlori-
nated ligands fit into a 3 χ 10 Ä rectangle where the centers of the chlorine atoms are situated in its corners. As pointed out (2), this concept does not account for the binding of unhalogenated ligands, like ß-naphthoflavone, to the receptor. We have instead attempted to visualize the true three-dimensional space occupied by some receptor ligands. Therefore the molecular structures of these compounds were studied with a vector display driven by a VAX 11/750 computer running an interactive program using crystallographic data as inputs. All potent receptor ligands studied could be fitted into a rectangle of 6.8 χ 13.7 Ä, when the van der Waals radii of their atoms were included (156).
The affinity of TCDD for the TCDD receptor corresponds to that of steroid hormones for their receptors. To compare a high affinity ligand for the glucocorticoid receptor with TCDD, we have used the method described above to plot the (22R)-epimer of Budesonide (157), and TCDD (158) in two projections (Fig 1). Budesonide can be regarded as an analogue of triamcinolone acetonide, where the 9a-fluorine is replaced by a hydrogen, and the two methyl groups of the acetal are replaced by a hydrogen and a propyl group. It is evident that Budesonide fits quite well into the 6.8 χ 13.7 X rectangle. On the other hand, it can be seen that the overall thickness of the Budesonide molecule is considerably greater than that of TCDD (3.1* X). The reason for this difference is that Budesonide is, due to its partially saturated structure, like other steroids, pleated, whereas TCDD due to its aromatic structure is planar. Since all known ligands of the TCDD-receptor are very lipophilic, it is probable that the main driving force for binding is of hydrophobic nature, as in the case of the glucocorticoid receptor
(113).
It is interesting that the requirement for binding of chlorinated ligands to the TCDD-receptor is such that the chlorine atoms should be separated by certain distances, whereas the intervening structure is of less impor-
773 t a n c e , as long as i t i s planar or may a t t a i n a planar conformation.
This
s t r u c t u r a l requirement resembles t h a t f o r l i g a n d binding t o t h e e s t r o g e n r e c e p t o r where hydroxyl groups s e p a r a t e d by c e r t a i n d i s t a n c e s seem t o be r e q u i r e d f o r b i n d i n g , whereas t h e i n t e r v e n i n g s t r u c t u r e appears l e s s c r i t i c a l . Furthermore i t i s i n t e r e s t i n g t h a t p l a n a r i t y of ligands f a v o r s TCDD r e c e p t o r binding as i s a l s o t h e case with androgen r e c e p t o r b i n d i n g . S t e r o i d r e c e p t o r s e x h i b i t some c r o s s - s p e c i f i c i t y with regard t o l i g a n d b i n d i n g , e s p e c i a l l y in case of t h e g l u c o c o r t i c o i d and m i n e r a l o c o r t i c o i d r e c e p t o r s . On t h e o t h e r hand, no s t e r o i d has yet been shown t o bind t o t h e TCDD-receptor.
DNA-Binding P r o p e r t i e s of Soluble Receptor P r o t e i n s The i n t e r a c t i o n of s t e r o i d hormones and t h e i r r e c e p t o r p r o t e i n s with the c e l l nucleus of t a r g e t t i s s u e s i s a presumed e s s e n t i a l s t e p in t h e mechanism by which t h e s e hormones modulate n u c l e a r e v e n t s such as gene e x p r e s s i o n (72). Nuclear s t e r o i d r e c e p t o r s may o f t e n be e x t r a c t e d from nuclei with 0 . 3 - 0 . 6 Μ KCl or NaCl (73, 159, 160). The c e n t r a l i s s u e about t h e accumulation of s o l u b l e r e c e p t o r s in t h e nucleus i s what d e f i n e s a p u t a t i v e n u c l e a r a c c e p t o r and/or b i o l o g i c a l e f f e c t o r s i t e f o r t h e s e p r o t e i n s . Among t h e p o t e n t i a l s i t e s , DNA has been suggested t o be of prime importance (72, 161). The "nuclear t r a n s f e r " phenomenon of s t e r o i d hormone r e c e p t o r s - in i t s e l f a c o n t r o v e r s i a l i s s u e , c f . above - i s u s u a l l y mimicked _in v i t r o by t h e a d d i t i o n of hormone t o c y t o s o l , followed by " r e c e p t o r a c t i v a t i o n " . This i s a poorly understood process in which t h e r e c e p t o r i s rendered competent t o bind t o i s o l a t e d n u c l e i or v a r i o u s n u c l e a r t a r g e t elements f o l l o w i n g c e r t a i n m a n i p u l a t i o n s , such as prolonged s t o r a g e , d i l u t i o n , gel permeation chromatography, warming, exposure t o s a l t s or p r e c i p i t a t i o n by ammonium s u l f a t e (71), 160, 162-165). This process may involve a conformational change of t h e s t e r o i d - r e c e p t o r complex, r e s u l t i n g in t h e exposure of p o s i t i v e l y charged r e g i o n s on t h e s u r f a c e of t h e molecule (166). A f t e r " a c t i v a t i o n " , t h e s t e r o i d - r e c e p t o r complex d i s p l a y s an increased a f f i n i t y f o r both n a t u r a l and s y n t h e t i c polyanions i n c l u d i n g chromatin (128,
774 167-169), nuoleosomes (170), purified DNA (166, 171-173), DNA-cellulose (171-177), RNA (178-180, phospho-cellulose (177, 181), heparin-agarose (111, 131), ATP-Sepharose (182, 183), carboxy-metyl(CM)-Sephadex (166, 184), sulfopropyl(SP)-Sephadex (166) and glass beads (166, 185). However, the overall K d of the steroid receptor interaction with bulk DNA sequences has been estimated to only -10-11 Μ (186). Clearly, the DNA-binding property of steroid receptors seems to be physiologically significant. Yamamoto et al. (187) examined the differences in binding to DNA-cellulose of the glucocorticoid receptor from two mutant phenotypes of glucocorticoid-resistant S 49 mouse lymphoma cells in which the receptor appeared to be normal with respect to hormone-binding. One class of cells exhibited decreased nuclear binding (nt~) whereas the other showed increased nuclear binding (nt*) of the mutant receptor complexes. The different nuclear binding properties of these receptors correlated well with their respective affinities for DNA-cellulose. A mutation affecting the polynucleotide binding domain of the receptor resulting in a glucocorticoid-resistant phenotype was suggested. The polynucleotidebinding domain was thus shown to be distinct and separated from the hormone-binding domain. All studies on receptors associated with the nti-phenotype have revealed a molecular weight of the mutant glucocorticoid receptor of approximately 40,000 rather than 94,000 M r characteristic of the wild-type receptor (109, 188, 189). Interestingly, α-chymotrypsin or trypsin cleavage of the 94,000 M r rat liver glucocorticoid receptor leads to the formation of a 39,000 M r fragment that retains both steroid- and DNA-binding activities (106, 190); like the nt* receptor, this fragment binds with increased affinity to bulk DNA sequences (109, 187, 189). Accordingly, there seems to exist a third, non-steroid- and non-DNA-binding domain of the glucocorticoid receptor important for its biological activity (189, 191-193). Polyclonal antibodies raised against highly purified glucocorticoid receptor (194) have been used to detect and characterize this domain, which was shown to carry the main antigenic determinants (191). Further-
775 more, 40,000 M r mutants of the glucocorticoid receptor as well as 40,000 M r proteolytic fragments of wild-type glucocorticoid receptors lack this major immunoreactive region (194-196).
Limited proteolysis has also been used for the characterization of the progestin (198-203). estrogen (200, 204-208), androgen (209) and putative mineralocorticoid (200) receptors. Based on these findings and on studies performed on the glucocorticoid receptor, it has been proposed that all steroid hormone receptors may have the same basic structure (193): three protein domains separated by protease-sensitive regions.
It has been demonstrated that most classes of steroid hormone receptors (glucocorticoid, estrogen, progesterone and androgen receptors) have to undergo the losely defined process called "activation"
(cf. above) in
order to acquire affinity for polyanionic resins such as DNA-cellulose (160, 162, 165). Several molecular mechanisms leading to steroid receptor "activation" have been proposed: a) dimerization of receptor subunits (110, 176); b) limited proteolysis of "unactivated" receptor (204-206); c) conformational changes of the receptor molecule (138, 166, 210, 211); and d) the dissociation of receptor oligomers into constitutive subunits (82-84, 211). There has been some controversy regarding the existence of an "activation" process for vitamin D
receptors, in part due to reports
that both unoccupied (120, 212) as well as occupied (118, 212-214) vitamin D receptors readily interact with DNA-cellulose. Recently, however, it has been shown, by means of "mixing" experiments, that unoccupied vitamin D receptors exhibit a lower affinity for DNA than occupied receptors (120). The ionic strengths required to dissociate steroid hormone receptors from DNA-cellulose closely resemble those required to extract them from nuclear binding sites (i.e. -0.1-0.5 Μ KCl or NaCl).
The concept that DNA may be an important component of genomic binding sites for steroid-receptor complexes is further strengthened by recent studies demonstrating selective binding of glucocorticoid and progesterone receptors to specific cloned portions of hormonally regulated genes (52, 54, 86-98). Several types of experiments have demonstrated that at least some of the cloned DNA-fragments that interact selectively with steroid
776 receptors _in vitro (89, 96) are capable of mediating hormonal responsiveness in vivo (46, 47, 50, 89, 97) leading to the formulation of the concept that these specific binding regions - subsequent to interaction with the receptor protein - might function as hormone- and receptor-dependent transcriptional enhancers (57).
It has been reported that less than
10?
of protein-bound
[3H]TCDD
as-
sociates with DNA-cellulose without any preceding manipulations known to lead to "activation" of steroid receptors for
30
min at
25~37°C
ceptor complexes
>50?
(123).
However, upon incubation
and/or gel permeation chromatography of TCDD-reof the specific
[3H]TCDD
binding in rat liver
cytosol was retained on DNA-cellulose (R. Hannah, J. Lund, L. Poellinger, M. Gillner, J.-Ä. Gustafsson, unpublished). DNA-binding of the TCDD-receptor required the presence of ligand, and limited proteolysis of the receptor by trypsin or α-chymotrypsin abolished the DNA-binding
(123;
Hannah et al., unpublished), in analogy to studies performed on the glucocorticoid receptor
(190).
The DNA-binding form of the TCDD receptor
has, however, not yet been characterized. Furthermore, there is no consensus as to the nature of genomic target sites for the TCDD-receptor complexes (2, 68), and it remains to be established if the nuclear form of the TCDD receptor (of. above) interacts with cloned portions of genes regulated by TCDD. There is also a paucity of data concerning the nature of the primary biochemical response to the "nuclear transfer" phenomenon of TCDD receptor-complexes. Clearly, further studies are needed in this field before any conclusions can be drawn about analogies between steroid receptors and the TCDD receptor as DNA-binding and gene-regulatory proteins .
Concluding Remarks
Apparently the steroid hormone receptors and the TCDD receptor share certain characteristics with regard to size, charge and DNA-binding. It is also thought that these soluble receptor proteins regulate the expression of certain genes in a similar fashion. However, to evaluate common features with regard to this receptor-mediated regulation of gene ex-
777 p r e s s i o n , f u r t h e r work i s c l e a r l y needed on t h e i n t e r a c t i o n of b o t h t h e TCDD r e c e p t o r and s t e r o i d hormone r e c e p t o r s w i t h r e g u l a t o r y e l e m e n t s of c o n t r o l l e d g e n e s . Such s t u d i e s have been performed w i t h t h e g l u c o c o r t i c o i d and p r o g e s t e r o n e r e c e p t o r s (52,
86-98).
I n view of t h e many s i m i l a r i t i e s between t h e t h e TCDD r e c e p t o r and t h e s t e r o i d hormone r e c e p t o r s , i t i s t e m p t i n g t o s p e c u l a t e t h a t t h e s t r u c t u r a l genes f o r a l l t h e s e r e c e p t o r p r o t e i n s have e v o l v e d from a common a n c e s t r a l gene by gene d u p l i c a t i o n and s u b s e q u e n t d i v e r g e n t e v o l u t i o n . Based on DNA sequence homology such a c o n c e p t has been proposed f o r c e r t a i n s u b u n i t s of an o l i g o m e r i c s t e r o i d b i n d i n g p r o t e i n , t h e p r o s t a t i c s t e r o i d
binding
p r o t e i n (PSP) ( 2 1 8 ) . C e r t a i n s u b u n i t s of PSP have been shown t o have amino a c i d homologies w i t h a n o t h e r s t e r o i d b i n d i n g p r o t e i n , r a b b i t
uteroglobin
(219) and a common a n c e s t o r f o r t h e s e p r o t e i n s has been s u g g e s t e d
I n o r d e r t o t e s t t h e v a l i d i t y of s p e c u l a t i o n s r e g a r d i n g
(219).
evolutionary
r e l a t i o n s h i p s between s o l u b l e r e c e p t o r p r o t e i n s , t h e a v a i l a b i l i t y of a cDNA-probe c o r r e s p o n d i n g t o a p o r t i o n of t h e r a t g l u c o c o r t i c o i d r e c e p t o r coding s e q u e n c e s h o u l d p r o v e e x t r e m e l y h e l p f u l ( 2 2 0 ) . Using t h i s cDNA probe i t should be p o s s i b e t o o b t a i n t h e gene f o r t h e g l u c o c o r t i c o i d r e c e p t o r and p e r h a p s a l s o , by d e c r e a s i n g t h e h y b r i d i z a t i o n s t r i n g e n c y , o b t a i n the genes f o r o t h e r s o l u b l e r e c e p t o r
to
proteins.
Acknowledgements
T h i s work was s u p p o r t e d by g r a n t s from t h e Swedish Cancer S o c i e t y and t h e Swedish C o u n c i l f o r P l a n n i n g and C o o r d i n a t i o n of R e s e a r c h . Dr. C. Camb i l l a u (CRMC2-CNRS Campus Luminy - Case 91 3, 1 3288 M a r s e i l l e ,
Cedex,
F r a n c e ) i s g r a t e f u l l y acknowledged f o r p e r f o r m i n g t h e computer s u p p o r t e d p l o t t i n g of t h e m o l e c u l e s i n F i g .
1.
778 REFERENCES
1.
N e b e r t , D.W., E i s e n , H . J . , N e g i s h i , Μ., Lang, Μ.Α., Hjelmeland, Okey, A . B . : Ann. Rev. Pharmacol. T o x i c o l . 21_, 431-462 ( 1981 ) .
2.
Poland, Α . , Knutson, J . C . : Ann. Rev. Pharmacol. T o x i c o l . 22, 517- 554 (1982).
3.
Kimbrough, R.D., e d . : Halogenated Biphenyls, Terphenyls, Naphthal e n e s , Dibenzodioxins and R e l a t e d Products, 406 p p . , E l s e v i e r - N o r t h H o l l a n d , Amsterdam 1980.
4.
Kimbrough, R.D. : CRC C r i t . Rev. T o x i c o l . 2j_ 445-489
5.
Hay, Α . : Nature 289, 351-352 ( 1 9 8 1 ) .
6.
Poland, Α . , G r e e n l e e , W.F., Kende, A.S. : Ann. Ν. Y. Acad. S e i . 214-230 (1979) .
7.
Goldstein, J.A.
8.
H a r r i s , M.W., Moore, J . Α . , Vos, J . G . , Gupta, B.N. : Environ. Health P e r s p e c t . 5, 101-109 ( 1 9 7 3 ) .
9.
McConnel, E . E . , Moore, J . Α . , Haseman, J . K . , H a r r i s , M.W.: T o x i c o l . A p p l . Pharmacol. 44, 335*356 ( 1 9 7 8 ) .
10.
N e a l , R . A . , Olson, J . R . , Gasiewicz, T . A . , G e i g e r , L . E . : Metab. Rev. 1_3. 355-385 ( 1 9 8 2 ) .
11.
DiDomenico, Α . , S i l a n o , V . , V i v i a n o , G., Zapponi, G . : Environ. S a f e t y 4, 339-345 ( 1 9 8 0 ) .
12.
McConnel, E . E . , L u c i e r , G.W., Rumbaugh, R.C., A l b r o , P.W., Harvan, D . J . , Hass, J . R . , H a r r i s , M.W.: S c i e n c e 223, 1077-1079 ( 1 9 8 4 ) .
13.
Jones, K.G., Sweeney, G.D.: T o x i c o l . (1980).
14.
Poland, Α . , G l o v e r , E. : Mol. Pharmacol. Π ,
86-94 ( 1980).
15.
Knutson, J . C . ,
(1982).
16.
Schwetz, B . A . , N o r r i s , J.M., Sparschu, G . L . , Rowe, V . K . , Gehring, P . J . , Emerson, J . L . , G e r b i g , C.G.: Environ. Health Persp. 5, 87" 99 ( 1 9 7 3 ) .
17.
N e a l , R . A . , B e a t t y , P.W., G a s i e w i c z , T . A . : Ann. N . Y . Acad. S e i . 204-21 3 ( 1 9 7 9 ) .
18.
Vos, J . G . , F a i t h , R . E . , L u s t e r , M . I .
19.
Gayda, D . P . , P a r i z a ;
I n : R e f . 3, pp.
L.M.,
(1974).
320,
151-190.
Drug.
Ecotoxicol.
Appl. Pharmacol 53, 42-49
Poland, Α . : C e l l 30, 225-234
I n : R e f . 3, pp. 241-266.
M.W.: Carcinogenesis 4, 1131-1131
(1983).
320,
779 20.
Poland, Α., Glover, Ε., Kende, A.S. : J. Biol. Chem. 251, 4936-4946 (1976).
21.
Hannah, R.R., Nebert, D.W., Eisen, H.J. : J. Biol. Chem. 256, 4584-4590 (1981).
22.
Okey, A.B., Vella, L.M.: Eur. J. Biochem. 127, 39-17 (1982).
23.
Poellinger, L., Lund, J., Gillner, Μ., Hansson. L.-A., Gustafsson, J.-K.: J. Biol. Chem. 258, 13535-13542 (1983).
24.
Okey, A.B., Dub£, A.W., Vella, L.M.: Cancer Res. 44, 1426-1432 (1984).
25.
Okey, A.B., Bondy, G.P., Mason. M.E., Kahl, G.F., Eisen, H.J., Nebert, D.W.: J. Biol. Chem. 254, 11636-11648 (1979).
26.
Lund, J., Kurl, R.N., Poellinger, L., Gustafsson, J.-8.: Biochim. Biophys. Acta 716, 16-23 (1982).
27.
Poellinger, L., Kurl, R., Lund, J., Gillner, Μ. Carlstedt-Duke, J., Högberg, Β., Gustafsson, J.-Ä.: Biochim. Biophys. Acta 714, 516-523 (1982).
28.
van Logten, M.J., Gupta, B.N., McConnel, E.E., Moore, J.Α.: Toxicology 15, 135-144 (1980).
29.
Carlstedt-Duke, J.: Cancer Res. 39, 4653-4656 (1979).
30.
Jonsson, H.T., Keil, J.Ε., Gaddy, R.G., Loadholt, C.B., Hennigar, G.R., Wal der, Ε.Μ.: Arch. Environ. Contain. Toxicol. 3, 479-490 (1976).
31.
Barsotti, D.A., Abrahamson, L.J., Allen, J.R.: Bull. Environ. Contam. Toxicol. 21, 463-469 (1979).
32.
Balk, J.L., Piper, W.N.: Biochem. Pharmacol. 33, 2531-2534 (1984).
33.
Batomsky, C.H.: Endocrinology 101, 292-296 (1977).
34.
Kociba, R.J., Keeler, P.A., Park, C.N., Gehring, P.J. : Toxicol. Appl. Pharmacol. 35, 553"574 (1976).
35.
Murray, F.J., Smith, F.A., Nitschke, K.D., Humiston, C.G., Kociba, R.J., Schwetz, B.A.: Toxicol. Appl. Pharmacol. 5£, 241-252 (1979).
36.
Conney, A.H. : Cancer Res. 42, 4875-4917 ( 1982).
37.
Knutson, J.C., Poland, Α.: Cell 22, 27~36 (1980).
38.
Knutson, (1980). J.C., Poland, Α.: Toxicol. Appl. Pharmacol. 54, 377-383
780 39.
Dahlberg, Ε., Gustafsson, J.Ä. In: Progress in Drug Research Vol. 29, in press.
HO.
McKnight, G.S., Palmiter, R.D.: J. Biol. Chem. 254, 9050-9058 (1979).
41.
Palmiter, R.D., Moore, P.B., Mulvihill, E.R.: Cell 8, 557-572 (1976).
42.
Hynes, N.E., Groner, B., Sippel, Α., Jeep, S., Wurtz, T., Nguyen Huu, M.C., Giesecke, K., Schütz, G.: Biochemistry J_8, 616-624 (1978).
43.
Mulvihill, E.R., Palmiter, R.D.: J. Biol. Chem. 255, 2085*2091 (1980).
44.
Ucker, D.S., Ross, S.R., Yamamoto, K.R.: Cell 27, 257-266 (1981).
45.
Yamamoto, K.R., Chandler, V.L., Ross, S.R., Ucker, D.S., Ring, J.C., Feinstein, S.R.: Cold Spring Harbor Symp. Quant. Biol. 45, 687-697. (1981).
46.
Lee, F., Mulligan, R., Berg, P., Ringold, G.: Nature 294, 228-232 (1981).
47.
Huang, A.L., Ostrowski, M.C., Berard, D., Hager, G.L.: Cell 27, 245-255, (1981).
48.
Renkawitz, R., Binetruy, B., Cuzin, F.: Nature 295, 257-259 (1982).
49.
Fasel, Ν. , Pearson, Κ., Buetti, Ε., Diggelman, Η.: Embo J. (1982).
50.
Chandler, V.L., Maler, B.A., Yamamoto, K.R.: Cell 33, 489-499 (1983).
51.
Hynes, N., van Ooyen, J.J., Kennedy, N. t Herrlich, P., Ponta, Η., Groner, B.: Proc. Natl. Acad. Sei. USA 80, 3637*3641 (1983).
52.
Renkawitz, R., Schuetz, G., von der Ahe, D., Beato, M.: Cell 37, 503-510 (1984).
53.
Majors, J., Varmus, H.E.: Proc. Natl. Acad. Sei. USA 80, 5066-5870 (1983).
54.
Karin, M., Haslinger, Α., Holtgreve, Η., Richards, R.I., Krauter, P., Westphal, H., Beato, M.: Nature 308, 513-519 (1984).
55.
Dean, D.C., Knoll, B.J., Risen, M.E., 0'Malley, B.W.: Nature 305, 551-554 (1983).
56.
Ringold, G.M., Dobson, D.E., Grove, J.R., Hall, C.V., Lee, F., Vannice, J.L.: Ree. Prog. Horm. Res. 39, 387-424 (1983).
3-7
781 57.
Yamamoto, K.R. In: Steroid Hormone Receptors: Structure and Function. Nobel Symposium 57 (H. Eriksson, J.-Ä. Gustafsson, eds.), Elsevier, Amsterdam 1983.
58.
Wiskocil, R., Bensky, P., Dower, W., Goldberger, R.F., Gordon, J.L., Deely, R.G.: Proc. Natl. Acad. Sei. USA 77, U147H-U478 ( 1980).
59.
Brock, M.L., Shapiro, D.J.: Cell 34, 207-214 (1983).
60.
Firestone, G.L., Payvar, F., Yamamoto, K.R.: Nature 300, 221-225 (1982).
61.
Bresnick, Ε., Brosseau, Μ., Levin, W., Reik, L., Ryan, D.E., Thomas, P.: Proc. Natl. Acad. Sei. USA 78, 4083-4087 (1981).
62.
Pickett, C.B., Telakowski-Hopkins, C.A., Donokue, A.M., Lu, A.Y.H.: Biochem. Biophys. Res. Commun. 104, 611-619 (1982).
63.
Morville, A.L., Thomas, P., Levin, W., Reik, L., Ryan, D.E., Raphael, C., Adesnik, M.: J. Biol. Chem. 258, 3901-3906 (1983).
64.
Tukey, R.H., Nebert, D.W., Negishi, M.: J. Biol. Chem. 256, 69696974 (1981).
65.
Gonzales, F.J., Tukey, R.H., Nebert, D.W.: Mol. Pharmacol. 26, 117-121 (1984).
66.
Israel, D.I., Whitlock, J.P., Jr.: J. Biol. Chem. 259, 5400-5402 (1984).
67.
Darnell, J.E.: Nature 297, 365"371
68.
Tukey, R.H., Hannah, R.R., Negishi, M., Nebert, D.W., Eisen, H.J.: Cell 31, 275-284 ( 1982) .
69.
Israel, D.I., Whitlock, J.P., Jr.: J. Biol. Chem. 258, 10390-10394 (1983).
70.
Ucker, D.S., Yamamoto, K.R.: J. Biol. Chem. 259, 7416-7420 ( 1984).
71.
Gorski, J., Gannon, F.: Ann. Rev. Physiol. 38, 425-450 (1976).
72.
Yamamoto, K.R., Alberts, B.M.: Ann. Rev. Biochem. 45, 722-746 (1976).
73.
Gorski, J., Toft, D., Shyamala, G., Smith, D., Notides, Α.: Ree. Prog. Horm. Res. 24, 45-80 (1968).
74.
Jensen, E.V., Suzuki, Τ. Kawashima, Τ., Stumpf, W.E., Jungblut, P.W., DeSombre, E.R.: Proc. Natl. Acad. Sei. USA 59., 632-638 (1968).
75.
Sheridan, P.J., Buchanan, J.M., Anselmo, V.C., Martin, P.M.: Nature 282, 579-582 (1979).
(1982).
782 76.
Martin,
77.
K i n g , W . J . , Greene, G . L . : Nature 307, 745-747
78.
Welshons, W.V., (1984).
79.
G o r s k i , J . , Welshons, W., S a k a i , D . : Mol. C e l l . 1 1-1 5 ( 1 9 8 4 ) .
80.
W a l t e r s , M.R., Hunziker, W., Norman, A.W.: J . B i o l . Chem. 255, 6799-6805 ( 1 9 8 0 ) .
81.
W a l t e r s , M.R., Hunziker, W., Norman, A.W.: Biochem. Biophys. Commun. 98, 990-996 ( 1 9 8 1 ) .
82.
Raaka, B.M., Samuels; H . H . : J . B i o l . Chem. 258, 417-425
83.
V e d e c k i s , W . V . : B i o c h e m i s t r y 22, 1983-1989
84.
Sherman, M.R., Moran, M.C., Tuazon, F . B . , S t e v e n s , Y . - W . : J . Chem. 258, 10366-10377 ( 1 9 8 3 ) .
85.
T h r a l l , C . L . , W e b s t e r , R . A . , S p e i s b e r g , T . C . I n : The C e l l (H. Busch , e d . ) , 461-529, Academic, New York 1978.
86.
P a y v a r , F . , Wränge, Ö, C a r l s t e d t - D u k e , J . , O k r e t , S . , G u s t a f s s o n , J . - S . , Yamamoto, K . R . : P r o c . N a t l . Acad. S e i . USA 74_, 6628-6632
(1982).
P.M., Sheridan,
P . J . : J . S t e r o i d . Biochem. 1_6, 215-229
(1984).
Lieberman, M.E., G o r s k i , J . : Nature 307,
747-749
Endocrinol.
36,
Res.
(1983).
(1983). Biol
Nucleus,
(1981).
87.
Mulvihill, (1982).
E . R . , LePennec, J . - P . ,
Chambon, P . :
C e l l 28,
88.
Compton, J . G . , S c h r ä d e r , W . T . , O ' M a l l e y , Res. Commun. 1_05, 96-104 ( 1982).
89.
P a y v a r , F . , F i r e s t o n e , G . L . , Ross, S . R . , Chandler, V . L . , Wränge, Ö C a r l s t e d t - D u k e , J . , G u s t a f s s o n , J . - Ä . , Yamamoto, K . R . : J . C e l l . Biochem. _1_9. 241-247 ( 1982).
90.
Govindan, M . V . , S p i e s s , E . , M a j o r s , J . : 79, 5157-5161 ( 1 9 8 2 ) .
91.
P f a h l , Μ.: C e l l 3J_, 475-482 ( 1982).
92.
G e i s s e , S . , S c h e i d e r e i t , C . , Westphal, H.M., Hynes, N . E . , B e a t o , M.: EMBO J . 1_j_ 161 3—1619 ( 1 9 8 2 ) .
93.
Compton, J . G . , S c h r ä d e r , W . T . , O ' M a l l e y , S e i . USA 80, 16-20 ( 1983) .
94.
B a i l l y , Α . , A t g e r , M., A t g e r , P . , Cerbon, M . - A . , A l i z o n M., Vu Hai Μ . Τ . , L o g e a t , F . , Milgrom, Ε . : J . B i o l . Chem. 258, 10384-10389 (1983).
B.W.: Biochem.
621-632
Biophys.
P r o c . N a t l . Acad. S e i . USA
B.W.: P r o c . N a t l .
Groner,
Acad.
783 95.
Scheidereit, C., Geisse, S., Westphal, H.M., Beato, M.: Nature 304, 7H9-752 (1983).
96.
Payvar, F., DeFranco, D., Firestone, G., Edgar, Β., Wränge, Ö, Okret, S., Gustafsson, J.-JL, Yamamoto, K.R.: Cell 35, 381-392 (1983).
97.
Pfahl, M., McGinnis, D., Hendricks, Μ., Groner, Β., Hynes, Ν.Ε.: Science 222, 1311-1343 (1983).
98.
Scheidereit, C., Beato, .M.: Proc. Natl. Acad. Sei. USA 8l_, 3029" 3033 (1981).
99.
Greenlee, W.F., Poland, Α.: J. Biol. Chem. 251, 9814-9821 (1979).
100. Okey, A.B., Bondy, G.P., Mason, M.E., Nebert, D.W., Foster-Gibson, C.J., Muncan, J., Dufresne, M.J.: J. Biol. Chem. 255, 11115-11422 (1980). 101. Whitlock, J.P., Jr., Galeazzi, D.R.: J. Biol. Chem. 259, 980-985 (1984). 102. Sherman, M.R., Stevens, J.: Ann. Rev. Physiol. 46, 83"105 (1984). 103. Wränge, Ö., Carlstedt-Duke, J., Gustafsson, J.-Ä.: J. Biol. Chem. 251, 9284-9290 (1979). 104. Stevens, J., Stevens, Y.-W., Rosenthal, R.L.: Cancer Res. 39, 4939-4948 (1979). 105. Govindan, M.V., Sekeris, C.E.: Eur. J. Biochem. 89, 95"104 (1978). 106. Wränge, Ö., Okret, S. Radojcic, Μ., Carlstedt-Duke, J., Gustafsson, J.-Ä.: J. Biol. Chem. 259, 4531-1541 (1984). 107. Nordeen, S.K., Lan, N.C., Showers, M.O., Baxter, J.D. : J. Biol. Chem. 256, 10503-10508 (1981). 108. Simons, S.S., Schleenbaker, R.E., Eisen, H.J.: J. Biol. Chem. 258, 2229-2238 (1983). 109. Gehring, U., Hotz, Α.: Biochemistry 22_j_ 4013-4018 ( 1983). 110. Notides, A.C., Nielsen, S.: J. Biol. Chem. 249, 1866-1873 (1974). 111. Sica, V., Bresciani, F.: Biochemistry 1_8, 2369-2378 ( 1979). 112. Schräder, W.T., 0'Malley, B.W.: Cancer Res. 38, 4199-4203 (1978). 113- Dure, I.V., L.S., Schräder, W.T., 0'Malley, B.W.: Nature 283, 784-786 (1980). 111. Gronemeyer, Η. , Harry, P., Chambon, P.: FEBS Lett. |_56, 287"292 (1983).
784 115. Lamb, D.J., Holmes, S.D., Smith, R.G., Bullock, D.W.: Biochem. Biophys. Res. Commun. 1_08, 1 131-1 135 (1982). 116. Chang, C.H., Rowley, D.R., Tindall, D.J.: Biochemistry 22, 61706175 (1983). 117. Chang, C.H., Lobl, T.J., Rowley, D.R., Tindall, D.J.: Biochemistry 23, 2527-2533 ( 19814). 118. Pike, J.W., Haussler, M.R. : Proc. Natl. Acad. Sei. USA 76^ 5489 (1979).
5485-
119. Bishop, J.E., Hunziker, W., Norman, A.W.: Biochem. Biophys. Res. Commun. _[2£, ilio-l45 ( 1982). 120. Hunziker, W., Walters, M.R., Bishop, J.E., Norman, A.W.: J. Biol. Chem. 258, 8642-8648 (1983). 121. Kaetzel, D.M., Fu, Ι.Ϊ., Christiansen, M.P., Kaetzel, C.S., Soares, J.H., Lambert, P.W.: Biochim. Biophys. Acta 797, 312- 319 (1984). 122. Biecker, J.J., Roeder, R.G.: J. Biol. Chem. 259, 6158-6164
(1984).
123. Carlstedt-Duke, J., Harnemo, U.-B., Högberg, Β., Gustafsson, J.-Ä.: Biochim. Biophys. Acta 672, 131-141 (1981). 124. Hansson, L.-A., Gustafsson, S.A., Carlstedt-Duke, J., Garton, G, Högberg, Β., Gustafsson, J.-Ä.: J. Steroid. Biochem. J_4, 757-764 (1981). 125. Wränge, Ö.: Biochim. Biophys. Acta. 582, 346-357
(1982).
126. Wränge, Ö., Nordenskjöld, Β., Gustafsson, J.-iL: Anal. Biochem. 85^, 461-475 (1978). 127. Wränge, Ö., Norstedt, G., Gustafsson, J.-Ä.: Endocrinology 106, 1455-1462 (1980). 128. Molinari, A.M., Medici, N., Moncharmont, B., Puca, G.A.: Proc. Natl. Acad. Sei. USA 74, 4886-4890 (1977). 129. Wränge, Ö., Humla, S., Ramberg, I., Gustafsson, S.A., Skoog, L., Nordenskjöld, Β., Gustafsson, J.-Α.: J. Steroid Biochem. J_4, 141148 (1981). 1 3 0 . Mainwaring, W. P., Irving, R. : Biochem. J. 1_34, 1 13-127 ( 1973). 131. Simpson, R.U., DeLuca, H.F. : Proc. Natl. Acad. Sei. USA 79, 16-20 (1982). 132. Carlstedt-Duke, J., Kurl, R., Poellinger, L., Gillner, Μ., Hansson, L.-A, ToftgSrd, R., Högberg, Β., Gustafsson, J . - L In: Chlorinated Dioxins and Related Compounds: Impact on the Environment., 355-365, (0. Hutzinger, ed.), Pergamon Press, Oxford 1982.
785 133. Carlstedt-Duke, J., Elfström, G., Snochowski, M., Högberg, G., Gustafsson, J.-L: Toxicol. Lett. 2, 365-373 (1978). 134. Sakaue, Y., Thompson, E.B.: Biochera. Biophys. Res. Commun. 7 7 , 533-541 (1977). 135. Wränge, Ö.: Breast Cancer Res. Treatment 3, 97-102 (1983). 136. Raynaud, J.-P., Ojasoo, T., Bouton, M.M., Philibert, D. In: Drug design, Vol. 8 (E.J. Ariens, ed.), 169-214, Academic, New York 1978. 137. Baxter, J.D., Tomkins, G.M.: Proc. Natl. Acad. Sei. U.S.A. 68, 932-937 (1971). 138. Rousseau, G.G., Baxter, J.D., Tomkins, G.M. : J. Mol. Biol. 57_, 99-115 (1972). 139. Ballard, P.I., Carter, J.P., Graham, B.S, Baxter, J.D.: J. Clin. Endocrinol. 4j_, 290 (1975). 140. Schmit, J.P., Rousseau, G.G. In: Glucocorticoid Hormone Action, (J.D. Baxter, G.G. Rousseau, eds.), 79"95, Springer, Berlin 1979. 141. Rousseau, G.G., Schmidt, J.-P.: J. Steroid Biochem. 8, 911—919 (1977). 142. Dahlberg, Ε., Thal6n, Α., Brattsand, R., Gustafsson, J.-Ä., Johansson, U., Roempke, K., Saartok, T.: Mol. Pharmacol. 25, 70-78 (1984). 143. Wolff, M.E., Baxter, J.D., Kollman, P.A., Lee, D.L., Kuntz, I.D., Bloom, E., Matulich, D.T., Morris, J.: Biochemistry 1_7, 3201-3208 (1978). 144. Hähnel, R., Twaddle, E., Ratajczak, T.: J. Steroid Biochem. 4, 21-31 (1973). 145. Pons, M., Michel, F., Crastes de Paulet, Α., Gilbert, J., Miquel, J.-F., Pr^cigoux, G., Hospital, Μ., Ojasoo, T., Raynaud, J.-P.: J. Steroid Biochem. 20, 137-145 (1984). 146. Duax, W.L., Griffin, J.F., Rohrer, D.C., Swenson, D.C., Weeks, C.M.: J. Steroid Biochem. J_5. 41-47 (1981 ). 147. Liao, S., Liang, T., Fang, S., Castaneda, E., Shao, T.-C.: J. Biol. Chem. 248, 6154-6162 (1973). 148. Dahlberg, Ε., Snochowski, Μ., Gustafsson J.-Ä.: Endocrinology 108, 1431-1440 (1981). 149. Saartok, Τ., Dahlberg, Ε., Gustafsson J.-Ä.: Endocrinology 114, 2100-2106 (1984) .
786 150. Delettr70%) of specific binding applied to the column.
Recoveries on the 30 cm TSK3000 SW columns were
consistently 87 to 93%.
Column calibration with marker
proteins suggested this component to be a very large species of >80°A.
0
20
40
60
80
0
20
40
60
βΟ
FRACTION NUMBER
Fig. 4 Separation of progestin receptor isoforms from human uterus using HPSEC. Labeled cytosolic proteins were applied to and eluted from a 30 cm TSK3000 SW column as described (29). Progestin receptors labeled with [3H]C>RG-2058 and incubated in the presence (•) and absence (•) of excess ORG2058 are presented in A. The receptor isoform pattern eluting under identical conditions using t^H]R5020 as ligand in the presence (Δ) and absence (A) of excess unlabeled steroid is presented in B. The HPSEC system was pre-calibrated with a series of pure proteins, thyroglobulin (TG), ferritin (FE), bovine serum albumin (SA) and cytochrome c (CC).
A small but distinct and reproducible secondary isoform (Fig. 4B) was demonstrable between fractions 50 and 60 with R5020, (ca. 50 A), but only represented 10 to 15% of the specifically bound radioactivity.
No free steroid radioactivity appeared
in these separations, indicating that dextran coated-charcoal clearance of the unbound ligand was complete and that no
802 discernible column-induced dissociation of steroid occurred. [3H]ORG-2058 also appeared bound specifically by two isoforms [3H]R5020
with virtually identical ratios as observed for (29).
However, with ORG-2058 as ligand, the primary receptor
isoform was observed between fractions 40 and 47 representative of a protein of ca. 70 A.
(Fig. 4A)
The smaller,
secondary receptor peak appeared between fractions 73 and 83 with O R G - 2 0 5 8 . 2058
The nonspecific binding was minimal with ORG-
when compared with that of
R5020,
similar to the density
gradient sedimentation data reported elsewhere
(29).
Clinical application of the HPSEC mode for the analysis of estrogen receptors in human tumor samples is rapidly evolving. However, quantification is essential since the levels of estrogen receptor have prognostic value in the determination of hormonal response 2,3,24,27.
At the same time, our
laboratory (e.g. 3,16) and others (24,25) have proposed that the distribution of receptor isoforms has clinical significance also.
Clearly, if HPSEC analysis proves to
provide quantitative and qualitative information on hormone receptors in human tumors, it will find wide application in the clinical laboratory due to its speed.
In this regard,
(21,28) suggested that an automated system employing high performance ion-exchange chromatography (HPIEC) could be highly useful in the determination of the profile of receptor isoforms.
The relationship of receptor isoform profiles
("fractionated receptors") to ultimate responsiveness has yet to be established (3). HIGH PERFORMANCE CHROMATOFOCUSING (HPCF) As described earlier (18,29) all chromatography was performed in cold-room at 0-4°C.
Buffers were filtered under vacuum
through Millipore 0.45 μπι HAWP filters before use.
Free
steroid or the ligand-labeled cytosols were applied to SynChropak AX-300 or AX-500 (250 χ 4.1 mm I.D.) anion-exchange
803 columns valve
( S y n C h r o m ) w i t h a n A l t e x M o d e l 210 s a m p l e
(Beckman).
112 p u m p s .
injection
Elution was carried out using Altex
T h e a b s o r p t i o n p r o f i l e of the e l u a t e w a s
a t 280 nm w i t h a H i t a c h i
100-40
w i t h a n i n - l i n e flow cell
spectrophotometer
(Beckman).
Model monitored
equipped
pH w a s m e a s u r e d
in-line
with a Pharmacia pH monitor. Two different column equilibration and elution programs u s e d d e p e n d i n g u p o n the i n i t i a l b u f f e r c o n d i t i o n s of receptor preparations.
The columns were
e q u i l i b r a t e d to the s t a r t i n g pH u p p e r limit)
initially
( s l i g h t l y a b o v e the
using a common cationic buffer.
high performance chromatofocusing
were
the
on AX-300
desired
I n the c a s e of and AX-500
c o l u m n s , w e h a v e u s e d 25 m M T r i s - H C l c o n t a i n i n g 1 m M d i t h i o t h r e i t o l a n d 20% a t 0°C
(v/v) g l y c e r o l a d j u s t e d to pH 8.1 - 8.3
(18) or a s i m i l a r p h o s p h a t e b u f f e r
chromatofocusing molybdate-stabilized
(29).
receptor
m M s o d i u m m o l y b d a t e w a s i n c l u d e d in the c o l u m n buffer.
For components,
C y t o s o l s p r e p a r e d in h o m o g e n i z a t i o n b u f f e r
were
e l u t e d w i t h a 30:70 m i x t u r e of P o l y b u f f e r s 96 a n d 74.
This
p o l y a m p h o l y t e s o l u t i o n w a s d i l u t e d 1 0 - to 2 0 - f o l d w i t h glycerol,
f i l t e r e d w i t h a 0.45 μπι f i l t e r
(Millipore)
a d j u s t e d to b e t w e e n p H 4.0 a n d 5.0 a t 0 - 4 ° C . experiments,
column equilibration buffer at 1-2 The
For
20%
and
most
1.0 m l f r a c t i o n s w e r e c o l l e c t e d a t 1.0
C o l u m n s w e r e r e g e n e r a t e d to t h e i r s t a r t i n g pH
(8.3)
ml/min. with
ml/min.
[125i]iodoestradiol-17 ß-labeled receptor complexes,
s p e c i f i c b i n d i n g c o m p o n e n t s , a n d f r e e s t e r o i d in e a c h were detected radiometrically
in a M i c r o m e d i c s 4/600
c o u n t e r or w i t h the new B e c k m a n M o d e l 170 detector.
[3H]R5020
and
non-
fraction gamma
flow-through
t 3 H ] O R G - 2 0 5 8 w e r e m e a s u r e d in M o d e l
3801 l i q u i d s c i n t i l l a t i o n c o u n t e r
(Beckman).
S o m e t i m e s the pH
of a l t e r n a t e f r a c t i o n s w a s d e t e r m i n e d a t 0 ° C u s i n g a Model
10
equilibration
Beckman
3500 pH m e t e r w i t h a c o m b i n a t i o n g l a s s e l e c t r o d e .
c o u n t i n g e f f i c i e n c y of !25;ι;0(}ίηθ a v e r a g e d 65%
in the
The
804 conventional counter, as judged by reference to independent determinations of disintegratins per minute using a Beckman 4000 two-channel gamma counter.
Tritium counting efficiency
was 35-42%. Chromatofocusing is a technique which separates proteins on the basis of their surface charge properties and uses a column which is essentially a weak ion-exchanger.
The enhanced
ability to resolve ionic species which differ in charge by as little as 0.1 pH unit provide a unique method, especially in the HPLC mode to separate and charaterize proteins. Our first experiments with estrogen receptor indicated that the AX-300 column formed a stable pH gradient with the polybuffers, and that a number of cytosolic proteins were well resolved within the gradient (18).
We were concerned that the
initial (i.e. "loading") peak may be composed of unresolved species, namely, that certain proteins would be excluded based upon size and charge properties.
However, HPCF of labeled
estrogen receptors from human uterus (Fig. 5) showed that isoforms were not eluted in the loading peak but were recovered in the gradient when the A-500 column was employed. Similar results were observed when estrogen receptors in lactating mammary gland of the rat were separated (Fig. 6).
805
Fig. 5. Separation of estrogen receptor isoforms from human uterus in the presence or absence of molybdate by HPCF. A. Cytosol was incubated with [125χ]iodoestradiol-178 in the presence or absence (·) of excess diethylstilbestrol. Activity was eluted from the AX-500 column with a mixture of Polybuffers 96 and 74 adjusted to pH 4.5. B. Cytosol was prepared in buffer containing 10 mM molybdate and incubated with [125j]iodoestradiol-17ß in the presence or absence (·) of excess diethylstilbestrol. The primary eluent was a mixture of Polybuffers 96 and 74 containing 10 mM sodi um molybdate and adjusted to pH 5.0. The secondary eluent (arrow) was Polybuffer 74 (no molybdate) adjusted to pH 3.5. Taken from (18).
806 Fig. 6. Separation of receptor isoforms by HPLC chromatofocusing on AX-300. Cytosol was prepared from 14-day lactating mammary glands and incubated with [125i]iodoestradiol-17ß as described earlier. For elution, a 30:70 mixture of Polybuffers 96 and 74, diluted 1:10 with 20% glycerol and adjusted to pH 5.0, was used. Taken from (18).
HPCF of progestin receptors was accomplished primarily on the AX-500 column as described previously
(18).
The AX-500 column
in the HPCF mode exhibited problems found with the HPIEC system, namley that radioactivity appeared just after the void volume and prior to application of the pH gradient (Fig. 7). This peak was in the exact location in which free steroid eluted in the HPLC mode (29).
Even in the presence of 10 mM molybdate, the AX-500 column appeared to strip labeled-steroid from the receptor.
However,
a second peak appeared at a pH of 5.6 - 6.1 which contained specifically bound steroid
(Fig. 7).
The results presented
with [3H]R5020 in Figure 7 were virtually identical to those observed when [ 3 H]ORG-2058 was used as ligand (29).
Thus,
based on pH, the progestin receptor isoform focused at a pi value regardless of the ligand used in contrast to the HPSEC profiles
(29).
The origin and significance of progestin receptor polymorphism remains obscure.
Although certain components may represent
distinct physiological species, proteolytic cleavage may occur with a labile receptor.
Dougherty et al. (30) identified two
8S forms of the progesterone receptor from chick oviduct. Interestingly each form contained a 90,000 molecular weight component which did not associate with progestin and either a 75,000 or 110,000 molecular weight steroid binding
species.
Various combinations of these components could give rise to considerable size heterogeneity as we observed with receptors from human uterus
(29).
807
Fig. 7. HPCF of progestin receptor isoforms in human uterus. Cytosol obtained from human uterus was incubated with [^H]R5020 in the presence (0) and absence (·) of excess unlabeled R5020. Following removal of the free steroid, the incubate was injected and eluted on an AX-500 column in a chromatofocusing mode as described earlier (29).
One advantage of HPCF is that stabilizing agents such as sodium molybdate may be included in the buffer systems. Molybdate has several useful properties, including the preservation (stabilization) of larger forms of the receptor and the ability of block receptor activation (e.g. 31).
Thus,
molybdate is a valuable tool in correlating the interrelationships between receptor isoform structure and biologic function. HIGH PERFORMANCE ION EXCHANGE CHROMATOGRAPHY (HPIEC) This is one of the most effective HPLC modes for the study of receptor isoforms (21,29).
The resolution of isoforms and
their high recovery provide an excellent means of characterizing receptors for structure/function relationships.
808 Briefly, a portion
(150-200
ul) of i n c u b a t e c l e a r e d of
l i g a n d is a p p l i e d to a n A l t e x
322
(Beckman, Berkeley,
Chromatograph equipped with either AX-300, AX-500 (SynChrom)
anion exchange columns.
phosphate
(30 m i n ) of the c o l u m n w i t h b u f f e r
f o l l o w e d by e l u t i o n w i t h a l i n e a r g r a d i e n t of (21,29).
Subsequently
r e t u r n e d to s t a r t i n g c o n d i t i o n s . n m
absorbing
spectrophotometer c o u n t e d for
filter.
was
filtered
T h e level
the e l u a t e t h r o u g h a H i t a c h i
e q u i p p e d w i t h a low v o l u m e flow
from
100-40
cell.
1 ml f r a c t i o n s of the e l u a t e w e r e c o l l e c t e d
[16α - 1 2 5 χ ] i o d o e s t r a d i o l - 1 7 ß
using a
M o d e l 170 F l o w - t h r o u g h D e t e c t o r . radioactivity
Beckman
[^HjLigands were measured
in c o l u m n f r a c t i o n s w i t h a M o d e l
liquid scintillation counter
(Beckman).
The
c o n c e n t r a t i o n w a s d e t e r m i n e d by m e a s u r i n g fractions with an in-line detector
from
the c o n d u c t i v i t y
(21), l a c t a t i n g m a m m a r y
g l a n d of the r a t a n d
c a r c i n o m a of the r a b b i t
(19).
is s h o w n in F i g u r e 8.
and AX-1000
separation
from h u m a n b r e a s t
i s o f o r m e l u t e d a t 190
p h o s p h a t e w h i l e o t h e r s w e r e o b s e r v e d a t 52 m M a n d 100 phosphate
(21).
cancer
endometrial
A representative
The m a j o r
of
Bio-Rad.
c o l u m n s in the H P I E C m o d e u s i n g h u m a n u t e r u s a n d b r e a s t
isoforms
by
3801
phosphate
W e h a v e c o m p a r e d the use of the S y n C h r o p a k A X - 5 0 0
p r o f i l e of e s t r o g e n r e c e p t o r
and
Micromedics
g a m m a c o u n t e r h a v i n g a 62% c o u n t i n g e f f i c i e n c y or the counting
of
s p e c i e s w e r e d e t e c t e d as they e m e r g e d
the c o l u m n by d i r e c t i n g Approximately
after
the c o l u m n
All buffers were
p r i o r to use w i t h a 0 . 4 5 u m M i l l i p o r e A280
was
potassium
p h o s p h a t e a t pH 7.4 w h i c h a p p r o a c h e d 500 m M 90 m i n gradient initiation
is
Each column was
e q u i l i b r a t e d p r e v i o u s l y w i t h low i o n i c s t r e n g t h A wash
or A X - 1 0 0 0
All chromatography
p e r f o r m e d in the c o l d r o o m a t 0 - 4 ° C . buffer.
unbound CA)
T h e i s o f o r m s e l u t i n g a t 100 a n d 200
cancer mM
mM mM
p h o s p h a t e h a v e b e e n o b s e r v e d in c y t o s o l s f r o m m a m m a r y g l a n d of the r a t a n d h u m a n u t e r u s c y t o s o l of e n d o m e t r i a l
(21) a l s o .
cancer
T h e i s o f o r m s in the
fo the r a b b i t e x h i b i t a 50 m M
s p e c i e s a n d 175 m M c o m p o n e n t w h e n s e p a r a t e d o n H P I E C
(19).
809
Fig. 8. HPIEC separation of ionic forms of the estrogen receptor from human breast cancer tissue on AX-1000. Cytosol was prepared and incubated in the presence (0) or absence (·) of 500-fold excess of inhibitor. Elution was performed at 1.0 ml/min using a gradient of potassium phosphate at pH 7.4. The elution of the labeled ligand alone was previously determined under identical conditions and is marked with an arrow. The recovery of radioactivity from the column was 91% for the aliquot of cytosol incubated in the absence of diethylstibestrol. A tracing of species absorbing at 280 nm is given by the continuous line. Taken from (21). Additionally, the on-line method of analysis using the Model 170 Flow-Through Detector permitted the detection of very low levels of receptor isoforms in small quantities of cytosol (10— 20 μΐ).
Figure 9A and 9B compare the manual and on-line
profiles of 6.9 fmol of total receptor-bound from human uterine tissue separated by HPIEC.
radioactivity Measurements
obtained manually are shown in panel A, with the continuous tracings presented in panel B.
An elution pattern is similar
to that for estrogen receptors in breast tissue emerged (32). Two non-specific binding components that did not intract with the column were also present in uterine cytosol.
However, the
two receptor isoforms were shown to have slightly different surface charge properties as characterized by an altered
810
elution from the phosphate gradient. The first species of receptor eluted at a phosphate concentration of 150-180 mM and was equivalent to 1.4 fmol of bound steroid (22% of total). The second isoform eluted between 225-255 mM phosphate and was equal to 5.0 fmol of receptor (78% of total). A 93% recovery was observed in this representative experiment. The presence of different ionic isoforms of the receptor in breast and uterine tissues revealed by the rapid format with HPIEC allows the comparison required of clinical studies.
Fig. 9. HPIEC separation of micro quantities of ionic isoforms of the estrogen receptor from human uterus. The curves shown are the results of receptors separated in the presence (0) or absence (·) of 200-fold excess of diethylstibestrol. Elution was performed on 10 μΐ of cytosol (10 mg/ml) equivalent to 6.9 fmol receptor at 1.0 ml/min using a gradient of potassium phosphate ( ). (A) 1 ml fractions were collected and radioactivity measured manually, or (B) radioactivity recorded continuously using in-line Model 170 Radioisotope Detector with conductivity flow cell. Total binding is indicated by (·) in A and by (—) in B, and nonspecific binding is indicated by (0) in A and by ( ·) in B. Recovery of radioactivity from the column was 93% for the total bound curve determined by counting a 10 μΐ aliquot before sample injection. Specific binding was 30 fmol receptor/mg cytosol protein determined by multi-point titration analysis. Taken from (32).
811 SUMMARY High performance liquid chromatography of steroid hormone receptors provides rapid analyses, sensitivity and high recoveries of these elusive, labile proteins.
Based upon the
demonstration that receptors exhibit polymorphism, we propose that their level of cellular organization and interrelationships are more complex than considered originally.
Some of the cellular events which may give rise
to receptor heterogeneity include proteolysis, phosphorylation and other post-translational modifications, protein-protein interactions as well as protein-nucleic acid interactions. Some isoforms may be generated due to handling artifacts while others may be the result of authentic physiologic processes. Regardless, HPLC in its various modes should be useful in future studies of receptor characterization.
Although the
biological significance of receptor polymorphism is not well understood currently, there are important biological implications which include the utility of receptor isoform profiles as new markers in the clinical setting. ACKNOWLEDGMENTS Studies from the author's laboratory have been supported in part by USPHS grants CA-19657, CA-34211, CA-32101, and CA-31946 from the National Cancer Institute and by grants from the American Cancer Society (PDT-210) and Phi Beta Psi Sorority.
The important contributions of numerous research
fellows are acknowledged, particularly those of Drs. R.D. Wiehle, G.E. Hoffmann, A. Fuchs, T.W. Hutchens, Ν.A. Shahabi and Α. van der Walt.
The author also expresses his deepest
appreciation to Ms. Dana Gibson for her assistance in the preparation of this typescript.
812
1.
McGuire, W.L., Carbone, P.P. and Vollmer, Ε.P., eds. Estrogen Receptors in Human Breast Cancer. Raven Press, New York (1975).
2.
Anonymous Cancer 46, 2759-2963 (1980).
3.
Wittliff, J.L., Cancer 53, 630-643 (1984).
4.
McGuire, W.L., Raynaud, J.P. and Baulieu, E.E., eds. Progesteroine Receptors in Normal and Neoplastic Tissues. Raven Press, New York (1975).
5.
Creasman, W.T., McCarty, K.S. Sr., Barton, T.K., and McCarty, K.S., Jr.
Obstet. Gynecol. 55, 363 (1980).
6.
Erlich, C.E., Young, P.C., Cleary, R.E. Gynecol. 141, 539-546 (1981).
Am. J. Obstet.
7.
Käuppila, Α., Kujansuu, Ε., Vihko, R. 2166 (1974).
8.
Carlson, J.A. Jr., Allegra, J.C., Day, T.G. and Wittliff, J.L. Am. J. Obstet. Gynecol. 149, 149-153 (1984).
9.
Mörtel, R., Levy, C., Wolf, J.P., Nicolas, J.C., Röbel, P. and Baulieu, E.E. Cancer Res. 41, 1140-1145 (1981).
Cancer 50, 2157-
10. Daxenbichler, G., Grill, H.J., Geir, W. , Wittliff, J.L. and Dapunt, 0. In Steroid Receptors and Hormone Dependent Neoplasia (J.L. Wittliff and 0. Dapunt, eds.) pp. 59-67, Masson Publishing USA, Inc., New York (1980). 11. Boylan, E.S. and Wittliff, J.L. (1973). 12. Gardner, D.G. and Wittliff, J.L. 2096 (1973). 13. Goral, J.E. and Wittliff, J.L. (1975).
Cancer Res. 33, 2903-2908 Biochemistry 12, 3090Biochemistry 14, 2944-2952
14. Wittliff, J.L. I_n Methods in Cancer Research (H. Busch, ed.). Vol. XI, pp. 293-354. Academic Press, New York (1975). 15. Wittliff, J.L., Mehta, R.G. and Kute, T.E. In Progesterone Receptors in Normal and Neoplastic Tissues (W.L. McGuire, E.E. Baulieu and J.P. Raynaud, eds.), pp. 39-57. Raven Press, New York (1977). 16. Wittliff, J.L., Lewko, W.M., Park, D.C., Kute, T.E., Baker, D.T. Jr. and Kane, L.N. Iji Hormones, Receptors and Breast Cancer (W.L. McGuire, ed.) pp. 325-359. Raven Press, New York (1978). 17. Wittliff, J.L., Feldhoff, P.W., Fuchs, A. and Wiehle, R.D. In Physiopathology of Endocrine Diseases and Mechanisms of Hormone Action (R. Soto, A.F. DeNicola and J.A. Blaquier, eds.), pp. 397-411. Alan R. Liss, Inc., New York (1981) .
813 18. H u t c h e n s , T . W . , W i e h l e , R . D . , S h a h a b i , N.A. a n d J.L.
J. Chromatogr.
266, 1 1 5 - 1 2 8
Wittliff,
(1983).
19. S h a h a b i , N . A . , H u t c h e n s , T . W . , W i t t l i f f , J . L . , H a i m o , S.D., Kirk, M.E. and Nisker, J.A. Iji H o r m o n e s a n d C a n c e r 2 (F. B r e s c i a n i , R . J . B . K i n g , M . E . L i p p m a n , M . Namer and J.P. Raynaud eds.), pp. 63-71. Raven Press, New Y o r k (1984). 20. W i e h l e , R . D . , H o f m a n n , G . E . , F u c h s , A . a n d W i t t l i f f , J. C h r o m a t o g r . 307, 39-51 (1984).
J.L.
21. W i e h l e , R . D . a n d W i t t l i f f , J . L .
313-
326
J. C h r o m a t o g r . 2 9 7 ,
(1984).
22. S h e r m a n , M . R . , P i c k e r i n g , L . A . , R o l l w a g e n , F . M . ,
Miller,
L.K. F e d . P r o c . 37, 1 6 7 - 1 7 2 (1978). 23. M c C a r t y , K . S . J r . , C o x , C . , S i l v a , J . S . , W o o d a r d , B . H . , Mossier, J.A., Haagensen, D.E., Barton, T.K., McCarty, K . S . S r . , a n d W e l l s , S.A. J r . C a n c e r 4 6 , 2 8 4 6 - 2 8 5 0 (1980) . 24. C l a r k , G . M . , M c G u i r e , W . L . , H u b a y , C . A . , P e a r s o n , O . H . , Marshall, J.S. N. E n g l . J. M e d . 309, 1 3 4 3 - 1 3 4 7 . 25. P o w e l l , B., G a r o l a , R . E . , C h a m n e s s , G . C . , M c G u i r e , C a n c e r R e s . 39, 1 6 7 8 - 1 6 8 2
W.L.
(1977).
26. K n i g h t , W . A . , L i v i n g s t o n , R . B . , G r e g o r y , E . J . a n d
McGuire,
W.L. C a n c e r Res. 37, 4 6 6 9 - 4 6 7 1 (1977). 27. F i s h e r , B., R e d m o n d , C . , B r o w n , Α . , W i c k e r h a m , D . L . , W o l m a r k , N., A l l e g r a , J . C . , E s c h e r , G., L i p p m a n , M . , S a v l o v , Ε., W i t t l i f f , J . L . a n d F i s h e r , E . R . e t al. J. C l i n . O n e . 1, 2 2 7 - 2 4 1 (1983). 28. W i t t l i f f , J . L . a n d W i e h l e , R . D . In: H o r m o n a l l y S e n s i t i v e T u m o r s , (V.P. H o l l a n d e r , ed.) Academic Press Inc. (1985) in p r e s s . 29. V a n d e r W a l t , A . a n d W i t t l i f f , J . L . J. C h r o m a t o g r . in p r e s s .
(1984)
30. G r e e n e , G . L . , N o l a n , C . X . , E n g l e r , J . P . a n d J e n s e n , P r o c . N a t l . A c a d . S e i . U.S. 77, 5 1 1 5 - 5 1 1 9 . 31. N i s h i g o r i , H. a n d T o f t , D . O . (1980)
Biochemistry
19,
32. B o y l e , D . M . , W i e h l e , R . D . , S h a h a b i , N.A. a n d J.L. J. C h r o m a t o g r . (1985) in p r e s s .
E.V.
77-83
Wittliff,
AUTHOR INDEX
Andreasen, P.A. Auricchio, F.
199 279
Bardin, C.W. Baulieu, E.E. Binart, N. Bodwell, J.E. Brinkman, A.O. Buchou, T.
587 31 31 637 563 31
Callison, S. Castoria, G. Catelli, M.G. Catterall, J.F. Cidlowski, J.A. Clark, J.H.
173 279 31 587 141 399
d'Arville, C. Dickerman, H.W. Dohanich, G. Dougherty, J.J.
659 505 701 299
Faber, L.E.
61
Gase, J.M. Gillner, Μ. Gorski, J. Gustafsson, J.A.
31 755 539 755
Holbrook, N.J. Horwitz, K.B.
637 659
Isohashi, F.
225
Janne, O.A. Joab, I. Jordan, V.C. Junker, K.
587 31 603 199
Kishimoto, S. Kontula, K.K. Kovacic-Milivojevic, B. Kumar, S.A.
249 587 85 505
LaPointe, M.C. Leavitt, W.W. Lieberman, Μ.Ε.
85 437 539
816
Litwack, G. Lund, J.
309 755
Maeda, Y . Markaverich, B.M. Matsumoto, K. McEwen, B.S. Mendel, D.B. Μ ester, J. Migliacchio, A . Moudgil, V.K. Mulder, E. Muldoon, T . G . Munck, A . Murayama, A . Myers, J.E.
61 399 249 701 637 31 279 351 563 377 637 1 61
Nakao, M. Nishizawa, Y . Nock, B. Noma, K . Notides, A . C .
249 249 701 249 173
Pasqualini, J.R. Poellinger, L .
471 755
Radanyi, C. Reker, C.E. Renoir, J.M. Riehl, R . M . Rotondi, A .
31 85 31 733 279
Sakamoto, Y . Sasson, S. Sato, B. Schmidt, T.J. Sedlacek, S.M. Shull, J.D. Shyamala, G. Silva, C.M. Simons, S.S. Sumida, C.
225 173 249 309 659 539 413 141 111 471
Tai, Pink-K. K . T o f t , D.O.
61 733
Vedeckis, W.V.
85
Watson, C.S. Wei, L . L . Welshons, W.V. W i t t l i f f , J.L.
587 659 539 791
SUBJECT INDEX
Acceptors, microsomal Accessory proteins Acetylcholinesterase Achlya Activated receptor binding by ATP-Sepharose Chromatin DNA nuclei oligonucleotides Activation estrogen receptor glucocorticoid receptor progesterone receptor Activation, mechanism Affinity labeling Agonist-antagonist, relationship Allosteric binding mechanism Androgen action Androgen-induced proteins Androgen receptor activation cyproterone acetate binding DNA binding molybdate effects nuclear binding photoaffinity labeling polyribonucleotides binding prostate, rat RNA, binding seminal vesicles, ram Anterior pituitary estrogen receptor prolactin gene transcription protein synthesis Antheridiol Antiandrogens cyproterone acetate Antibodies estrogen receptor glucocorticoid receptor progesterone receptor
382 517 712 733 231,354 226
322,328,505,671,783 235,783 511,515 174-176,261,362,381 85,103,199,225,309,327,362,637,646 34,38,362 48,105,106,353 111,672 644 174,175,188 587,590,591 383 563-569 568-570 580-582 567,568 563,589,593 580-582 384,385,570-582 575 565-570 387,543,544 539-541,544-546,548 547 733 587 567-570 472,614 119 37,51,64,72
818 A nti estrogens binding site biological responses chemotherapy mechanism metabolism structure-activity relationship
610,612,613 471,492,495 603,604,627-629 609-613 606-608 618-623
Antiglucocorticoids Antiprogestin Aqueous two phase partitioning Aurintricarboxylic acid
113-115,682 682 199,200 359,360,365
Brain
acetylcholine acetylcholinesterase choline acetyltransferase cholinergic system dopaminergic regulation gonadal steroids localization of receptors muscarinic receptors noradrenergic regulation Breast cancer
714 712 710 710 717 706 703 708 719 659
Oa2+—calmodulin—Kinase Calpastatin cAMP cAMP-dependent kinase cDNA Choline acetyltransferase Cholinergic system Chymotrypsin Clomiphene Cortisol 21-mesylate Cyproterone a c e t a t e
288 654 389 303 590 710 706 89,91,93 603,604 113-115 567-570
Deoxycorticosterone-agarose Dephosphorylation DNA binding accessory proteins nonspecific probes DNA sequences recognition Dopaminergic regulation
305 230,289,452,453 580-582,671 517 507 509 509,524 717
819 Enclomiphene Endocrine therapy Equilibrium model Estradiol binding in mammary tumor Estradiol e f f e c t s on f e t a l tissues gene transcription histone acetylation protein synthesis receptor synthesis RNA polymerase activity
182,184 690,792,795 61,81 404
Estradiol, mechanism of action Estriol kinetics and responses Estrogen priming responses Estrogen binding endogenous inhibitor low molecular weight stabilizer
293,381,428,431,438 181,183
Estrogen-induced mammary tumors Estrogen receptor activation aggregation factor affinity labeling anterior pituitary, binding factors biological activity, actions breast cancer cooperativity cytosol form dephosphorylation dimer structure dissociation kinetics distribution DNA binding equilibrium binding fetal, new born pig uterus GH 3 hormone binding hydrophobic domain inactivation lactating mouse, rat leydig cell tumor magnesium ions, e f f e c t of mammary gland
487 539,541,544-546,549 485 485 497 485
445,484 481 399,400,402,407 255 404 174-176,256 269 379 543,544 8-26
264,471,663 792 175,180,188 543,544 289 177-179 183,185-187 189,378,539,550,552,553,555,560 174
180 472,473,477,478 551 284 23,28 280,450 404,420,427 252 25 391,413,422,423
820
microsomal monoclonal antibodies nuclear form nuclear localization nuclear receptor nuclear translocation nuclear type II sites oligonucleotide binding ontogeny phosphoamino analysis phosphorylation processing proteolized forms purification regulatory factor T47 D T47 D c o cells transformation translocation tumor biopsy type II binding sites unoccupied vero-receptor forms virgin mice Estrogen sulfates
378.380 472,473,800 390,543,544 539,550,552,553,560 437,543,544 21,25,28 401 511,515 478 291 279,285-288,293 438 7,22,23,178 176 439,450-453
Flutamide
596
Gene cloning Gene expression Gene regulation GH 3 cells estrogen receptor distribution prolactin synthesis Glucocorticoid receptor activation affinity labeling antibodies AtT-20 cells degradation dexamethasone mesylate DNA binding domain gene cloning hormone binding site, domain kinase activity kinetics leukocytes mero receptor
590 383,539-541,587 758 557,558 539,550,552,553,555,560 556
662 662,680
380.381 21
795 399,447 262,448,539,550 5 427 491,493
102,199,225,309,637,646 111
119 86
637 115,367 89,91,99,123 107 89,91,92,114 336 637,644 637 87,94,638
821
molecular weight molybdate-stabilized mutants nt mutants phosphorylation physiologic significance proteolysis proteolytic map proteolytic pathway purification pyrophosphate, e f f e c t s on rat thymus ribonuclease sensitivity RNA interaction structure subunit dissociation subunits sulfhydryl group association translocation inhibitor variants Glucose oxidation Gonadal steroids
117,119,129,132 142,639 95 95,205,212 132,309,367-371 141 86,91,639 92 92,93 134,308,318,324 238-240,646 637,638 96,98,99 97,99 637 86,88 145,150 166,648 225,226,229 132,133,205 415 706
Heterogenous receptor forms High performance chromatofocusing ion exchange liquid chromatography size exclusion Histone acetylation Hormone binding domain Hormone-dependent tumors
144 802 807 791 797,798 485 89,91,114,134 691
Immunoaffinity chromatography Immunoblotting Inhibitors of ATP binding Insulin receptors
66,76 43 359 681
Keoxifen
604
Leukocytes, human LHRH Lithium Low molecular weight inhibitor
637 386,389 214 260
Mammary gland estrogen action estrogen receptor progesterone receptor responsiveness
404,414 422,423 416 404,414,418
822
Mammary tumors Mammary tumor virus, mouse MER 25 Microsomal acceptors Minicolumn analysis Molybdate effects mRNA, testosterone-induced Muscarinic receptors
404,623-627 125-128 603,604 382 641 50,142,299,300,305,360,365,424,742 597 708
Nafoxidine Neuromodulators Neurotransmitters Non-steroid binding subunits Noradrenergic regulation Nuclear acceptor sites Nucleotides
603,604 701 701,716,723 147 719 438,577-579 199,230,351
oligonucleotide binding o-phenanthroline Oxytocin receptor
512 359,360,365 459,460,464,465
Phosphatase inhibitors Phosphatases Phosphocellulose binding Phosphorylation of estrogen receptor glucocorticoid receptor progesterone receptor Photoaffinity labeling Polyribonucleotides PPi effects Pregnancy Progesterone action Progesterone binding globulin Progesterone receptor activated form antibodies, against breast cancer cross-linking DNA binding fetal tissue immunoaffinity chromatography mammary gland monoclonal antibodies non-activated form nuclear processing ontogeny
101 101,289,304,452,453 564,565 279,285,293 132,309,367,369,370 299 66,79,111,574-577,672 646 464 439,447,498 475 34,38,69 37,55 659,671,684 49 671 475,477,479 66,76 416 37,55,61,64,72 34,38,45,46,299 666 478,483
823 phosphoamino acids phosphorylation photoaffinity labeling physiological significance purification uterus receptor form, 8S regulation by progestins steroid affinity chromatography stimulation by estradiol subcellular distribution subunits T47Do0 cells transformation Progesterone withdrawl Progestin action therapy treatment Prolactin messenger RNA synthesis Prolactin-estrogen interplay Prolactin gene transcription Proteases Protein synthesis Proteolysis Purification of estrogen receptor glucocorticoid receptor progesterone receptor Pyridoxal 5'-phosphate R 5020 RU 38486 Receptor activation adenine nucleotides, by allosteric mechanism ATP, by hormonal requirement KCl, by mechanism of nucleotides, by Receptor binding factors Receptor kinase activity Receptor recycling Receptor regulation
302 299 66,79,672 141 36-44,63,69,300,301,305 61,801 299 665 300,301,305 484,496 51 38,61,77,78,145 666
35,48 455-460 660,678,719 684,685 659,684 540 540 419 539-541 3,6,7,16,23,86,101 485 91,143,205 176 134,309,318 36-44,69,300,301,305 231,359,360,365 674,676 682,684 199,209 173,353 263 257 256,353 199,351 97,104-106 304,306,336,371 292 386,391,437,439,451
824
Receptor stabilization by molybdate Receptor subunits Ribonuclease Ribonucleic acid Rifamycin AF/103 RNA polymerase
299 38,61,77,78,145 96,99 97,100,332 359,360,365 485
Steroid affinity chromatography Steroid receptor achyla antheridiol brain, in the DNA binding fungi interaction with nucleotides isoforms kinetics mechanism of action modification non-hormone binding subunits oligonucleotide binding physicochemical properties regulation T47D C0 cells
300,301,305,318 733-754 736,737 702 123-128,236,505,671,783 733 351 791,794,806,809,810 644 759 164 55,80 512 761 386 660
Tamoxifen Testosterone, responses to Tetrachlorodibenzo-p-dioxin receptor Tfm/y mouse Translocation modulators ATP-stimulated low molecular weight Triamcinolone acetonide Trioxifene Trypsin Tungstate Tyrosine aminotransferase induction Tyrosyl receptor kinase
493,495,603-635,687,690 591 755 595 225,226 236 225 117,118 604 91,93,94 232 113-115 290
Uterine cytosol inhibitor Uterotrophic effects Uterus androgen receptor estrogen receptor fetal and new born pigs progesterone receptor
402,403,407 482,496 437-465 566,567 471,514 471,472 471
Vanadate Variants glucocorticoid receptors
452 132,133,205,211
w DE
G κ. Fotherby
s. B. Pal (Editors)
Walter de Gruyter Berlin-New York Hormones in Norma! and Abnormal Human Tissues Volume 1 1980.17 cm χ 24 cm. XIV, 658 pages with figures and tables. Hardcover. DM 145,-; approx. US $48.40 ISBN 311 0080311
Volume 2 1981.17 cm χ 24 cm. XII, 552 pages with figures and tables. Hardcover. DM 135,-; approx. US $45.00 ISBN 3110085410
Volume 3 1982.17 cm χ 24 cm. X, 297 pages with figures and tables. Hardcover. DM 150,-; approx. US $50.00 ISBN 3110086166
K. Fotherby S. B. Pal (Editors)
The Role of Drugs and Electrolytes in Hormonogenesis 1984.17 cm χ 24 cm. XII, 360 pages. Numerous illustrations. Hardcover. DM 180,-; approx. US $60.00 ISBN 311008463 5
K. Fotherby S. B. Pal (Editors)
Steroid Converting Enzymes and Diseases 1984.17 cm χ 24 cm. IX, 261 pages. Numerous illustrations. Hardcover. DM 180,-; approx. US $60.00 ISBN 3110095564
Prices are subject to change without notice
w
Walter de Gruyter Berlin-New York
DE
G K. Fotherby
Exercise Endocrinology
S. B. Pal (Editors)
1985.17 cm χ 24 cm. XII, 300 pages. Numerous illustrations. Hardcover. DM 230,-; approx. US $76.70 ISBN 311 009557 2 There has been a marked increase in the amount of interest taken in exercise physiology during the past few years. This is partly due to the higher standards demanded in most sports and the most efficient use of strength, energy and stamina required of the sports-person, which can have a significant effect on the final result. This book will be of importance to both "trained" and "untrained" subjects in helping them to understand the physiological changes which take place during exercise.
Μ. K. Agarwal (Editor)
Μ. K. Agarwal (
Editor
)
Hormone Antagonists 1982.17 cm χ 24 cm. IX, 734 pages. Numerous illustrations. Hardcover. DM 180,-; approx. US $60.00 ISBN 311 0086131
Principles of Recepterology 1983.17 cm χ 24 cm. VII, 677 pages. Numerous illustrations. Hardcover. DM 220,-; approx. US $73.30 ISBN 311009558 0
Μ. K. Agarwal M. Yoshida
Immunopharmacology of Endotoxicosis
(Editors)
Proceedings of the 5th International Conference of Immunology. Satellite Workshop. Kyoto, Japan, August 27,1983 1984.17 cm χ 24 cm. XIV, 376 pages. Numerous illustrations. Hardcover. DM 170,-; approx. US $56.70 ISBN 311 009887 3
Μ. K. Agarwal (Editor)
Adrenal Steroid Antagonism Proceedings · Satellite Workshop of the VII. International Congress of Endocrinology. Quebec, Canada, July 7,1984 1984.17 cm χ 24 cm. VIII, 399 pages. With numerous illustrations. Hardcover. DM 175,-; approx. US $58.30 ISBN 3110100908
Prices are subject to change without notice