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English Pages 1078 [1080] Year 1986
Chemistry and Biology of Pteridines 1986 Pteridines and Folic Acid Derivatives
Chemistry and Biology ofPteridines 1986 Pteridines and Folic Acid Derivatives Proceedings of the Eighth International Symposium on Pteridines and Folic Acid Derivatives Chemical, Biological and Clinical Aspects Montreal, Canada, June 15-20,1986 Editors B. A. Cooper • V M.Whitehead
w G DE
Walter de Gruyter • Berlin • New York 1986
Editors
Professor V Michael Whitehead Hematology Service Montreal Children's Hospital 2300 Tupper Street Montreal, Québec H3H 183 Canada
Professor Bernard A. Cooper Division of Hematology and Medical Oncology Royal Victoria Hospital 687, Avenue des Pins Ouest Montréal, Québec H3A 1A1 Canada
Library of Congress Cataloging in Publication Data International Symposium on Pteridines and Folic Acid Derivatives: Chemical, Biological, and Clinical Aspects (8th : 1986 : Montréal, Québec) Chemistry and biology of pteridines, 1986. Includes bibliographies and indexes. 1. Pteridines-Congresses. 2. Folic acid-Derivatives-Congresses. I. Cooper, B. A. (Bernard A.), 1928- . II. Whitehead, V M. (V Michael), 1934III. Title. [DNLM: 1. Folic Acid-analogs & derivativescongresses. 2. Pteridines-congresses. W3 IN922J 8th 1986c / QU 188 1616 1986c] QP801.P69I585 1986 612'.399 86-19888 ISBN 0-89925-271-0
CIP-Kurztitelaufnahme
der Deutschen
Bibliothek
Chemistry and biology of pteridines . . . : pteridines and folic acid derivatives ; proceedings of the . . . Internai. Symposium on Pteridines and Folic Acid Derivatives, Chem., Biolog. and Clin. Aspects. - Berlin ; New York : de Gruyter Bd. 5, Kongressname: Internat. Symposium on Chemistry and Biology of Pteridines NE: International Symposium on Pteridines and Folic Acid Derivatives, Chemical, Biological and Clinical Aspects; International Symposium on Chemistry and Biology of Pteridines 8.1986. Montreal, Canada, June 15-20. 1986. -1986. ISBN 3-11-010771-6
Copyright © 1986 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 nor translated into a machine language without written permission from the publisher. Printing: Gerike G m b H , Berlin. - Binding: D. Mikolai, Berlin. - Printed in Germany.
PREFACE These proceedings are based on the scientific presentations made at the 8th International Symposium: Pteridines and Folic Acid Derivatives, held in Montreal, Canada, June 15-20, 1986.
In
designing this symposium, the organizers perpetuated many features of earlier meetings, including plenary session format, state-of-the-art lectures, the F. Gowland Hopkins Lecture and emphasis on poster presentations.
An innovation of the program
was the introduction of plenary poster discussion sessions in which a knowledgeable scientist stimulated discussion on a collection of posters after they had been on view for some time.
These proved lively and instructive and were
well-attended.
Chairmen of sessions were invited to provide
brief summaries of the areas addressed.
These form part of
these proceedings.
A welcoming reception was held at the McCord Museum and a symposium banquet at Heléne de Champlain restaurant.
The latter
-
coincided with the all-nations finale of the Montreal Festival of Fireworks, which added some excitement to the evening.
We thank Prof. Hamish Woods, organiser of the 7th International Symposium, for advice, details of planning and process, including a mailing list and for a generous donation to start our activities.
We thank other generous donors listed under
acknowledgments and members of the Advisory Committee, the Folate Club of Montreal, the Social Committee and the staff at the McGill Conference Centre, in particular Charlotte
VI
Benabdullah, Jean Lenzi and Joan Gross, for contributing to the success of the symposium.
We thank Prof. Adrien Albert for
preparing a brief history of the pteridine symposia included in these proceedings. Finally, we thank the participants in the symposium whose productive research and enthusiasm to exchange knowledge made this meeting the success it was.
Bernard A. Cooper Montreal, June 1986
V. Michael Whitehead
ACKNOWLEDGMENTS
The Committee gratefully acknowledges contributions from the following sponsors: Air Canada Bristol-Meyers Company, New York, U.S.A. Burroughs Wellcome Co., North Carolina, U.S.A. 7th International Pteridine Symposium, The University of Strathclyde, Scotland Lederle Laboratories, New York, U.S.A. Lederle Laboratories, Ontario, Canada McGill University - Montreal Children's Hospital Research Institute Medical Research Council of Canada, Government of Canada Moravek Biochemicals, Inc., California, U.S.A. National Health and Welfare, Government of Canada National Cancer Institute, National Institute of Health, Maryland, U.S.A. Medical Liaison Service, Sandoz Canada Inc., Quebec, Canada Warner Lambert Co., Michigan, U.S.A.
CONTENTS
How it all Began: A Brief History of the Pteridine Symposia A. Albert
1
The Gowland Hopkins Lecture: The Mechanisms of Action of Folate and Pterin Requiring Enzymes S.J. Benkovic, L.J. Slieker, S.C. Daubner, L.F. Courtney, T.A. Dix, S.O. Pember, L.M. Bloom, C.A. Fierke, R.J. Mayer, J.-T. Chen, K. Taira
13
SECTION A: CHEMISTRY OF PTERINS AND FOLATES
Side-Chain Chemistry of Pteridines W. Pfleiderer, V. Kang, R. Soyka, W. Hutzenlaub, M. Wiesenfeldt, W. Leskopf
31
A General Method for the Synthesis of 10-Substituted-10-Deaza Folate Analogues M.G. Nair, T.R. Toghiyani, B. Ramamurthy, R.L. Kisliuk, Y. Gaumont
45
Synthesis and Properties 'of Pyrimidodiazepines as Ring-Strained Probes of Pterin Utilizing Enzymes S.W. Bailey, D.C. Pike, J.E. Ayling
51
Summary: Pterin and Folate Chemistry E. Taylor A Facile Method for Preparing
55 2,4-Diamino-5,8-Dideazapterins
J.B. Hynes, A. Pathak, C.H. Panos, C.C. Okeke
57
Synthesis of 5,10-Dideaza-5,6,7,8-Tetrahydrofolic Acid (DDATHF) and Analogs E.C. Taylor, G.S.K. Wong, S.R. Fletcher, P.J. Harrington, G.P. Beardsley, C.J. Shih
61
Synthetic Routes to Methotrexate- and Folic Acid-Polyglutamates of High Chemical and Enantiomeric Purity M. Przybylski, R. Renkel, P. Fonrobert
65
X In Vivo and In Vitro Evaluations of 5-[4-(Substituted Aryl)-1Piperazinyl]-6-Alkyl-2,4-Pyrimidinediamines as Antitumor Agents L.M. Werbel, J. Hung, J.A. Besserer, T.J. Boritzki, W.R. Leopold, D.W. Fry
The Electrochemical
Oxidation of Tetrahydropterin
Derivatives
S. Kwee
A Practical
69
73
Synthesis of (6R)- and
(6^)-5,6,7,8-Tetrahydrobiopterins
S. Matsuura, T. Sugimoto, S. Murata
77
Chemical Synthesis and Properties of Quinonoid
(6Rj-Dihydrobiopterin
S. Matsuura, S. Murata, T. Sugimoto
81
Pyrazine-Ring Conformations of Tetrahydropterins and QuinonoidDihydropterins J.E. Gready
85
Hydrogénation of Silylated Pterins in Benzene Solution P.H. Boyle, M.F. Kelly
N(5)-A1kylation of Polyacetylated
91
5,6,7,8-Tetrahydroneopterins
S. Antoulas, M. Viscontini
Oxidations Photosensitized by Pterins and
95
Diaminopteridines
M. Aubailly, R. Santus
99
Structure of the Riboflavin Synthase/Lumazine Synthase Complex. Arrangement and Chain Folding of Subunits in the Icosahedral Capsid R. Ladenstein, H.D. Bartunik, M. Schneider, R. Huber, K. Schott, A. Bacher
Use of C18 Silica Cartridges to Purify and Characterize
103
Pterins
K.B. Jacobson, J. Ferre
107
Synthesis and Structure-Activity Relationships of Tetrahydrobiopterin Cofactor Analogues E.C. Bigham, G.K. Smith, J.F. Reinhard, Jr
111
XI Synthesis, Purification and Properties of a New Class of Pteridine Derivatives J. Ferre, J.J. Yim, W. Pfleiderer, K.B. Jacobson
115
Summary: Chemistry of Pterins J.B. Hynes
121
S E C T I O N B: B I O S Y N T H E S I S A N D B I O C H E M I S T R Y OF
PTERINS
Biosynthesis of Tetrahydrobiopterin and Related Compounds in Drosophila melanogaster G.M. Brown, J.P. Primus, A.C. Switchenko
125
Tetrahydrobiopterin Biosynthesis in Man H.-C. Curtius, S. Takikawa, A. Niederwieser
The Biosynthesis of Tetrahydrobiopterin
in the Bovine Adrenal
141
Medulla
G.K. Smith, D.S. Duch, C.A. Nichol
The Biosynthesis of Tetrahydrobiopterin
151
in Rat Brain
S. Milstien, S. Kaufman
169
Summary: Biosynthesis of Tetrahydrobiopterin G.M. Brown
183
The Metabolic Role of Tetrahydrobiopterin S. Kaufman
185
Spectroscopic Studies on Tyrosine 3-Monooxygenase from Bovine Adrenal Medulla: A Blue Iron Protein J. Haavik, K.K. Andersson, L. Petersson, T. Flatmark
201
Queuine-Lacking tNRAs in Relation to the Grade of Malignancy of Specific Tumors, Possible Role of Pteridines W. Kersten, E. Zubrod, B. Emmerich, P. Maubach
205
XII Pteridine Synthesis During Interaction of Interleukin 2 with T Lymphocytes - Modulator Function in IL-2 Signal Transmission I. Ziegler, J. Ellwart, U. Schwulera
209
SECTION C: BIOLOGY OF PTERINS
Dopamine Neurons in Culture: A Model System for Examination of Neuronal Biopterin Metabolism G. Kapatos, L.A. Chiodo
215
Role of the Pituitary in the Regulation of Tetrahydrobiopterin synthesis in the Non-Neuronal Tissues
Bio-
D.S. Duch, S.W. Bowers, C.A. Nichol
219
Distribution of GTP Cyclohydrolase-1, Neopterin, and Biopterin in the Human Brain T. Nagatsu, M. Sawada, M. Akino, M. Masada, T. Sugimoto, S. Matsuura
Enzymatic Synthesis of
223
6,7-Dimethyl-8-Ribityllumazine
A. Bacher, G. Neuberger, R. Volk
227
A Model for Hyperphenylal aninaemia Due to Tetrahydrobiopterin
Deficiency
R.G.H. Cotton
231
The Effect of Biopterin and its Reduced Derivatives on Cultured Human Lymphocytes S. Webber, D.L. Jaye
235
Developmental Aspects of Biopterin Metabolism in Human J.L. Dhondt, J.M. Hayte, G. Forzy, M. Delcroix, J.P. Farriaux, C. Largil 1 iere
Screening for Biopterin Defects Among Hyperphenylalaninemic Report of a Canadian Program After 3 Years
239
Patients:
F. Mohyuddin, C.A. Rupar, M.C. Evers
Need for Therapy i_n utero of Fetuses with Tetrahydrobiopterin
243
Deficiency
Y. Sawada, H. Shintaku, I. Suyama, G. Isshiki, Y. Hase, Y. Okano, H. Yamamoto, T. Tsuruhara, T. Oura
247
XIII P t e r i d i n e Metabolism in P a t i e n t s S u f f e r i n g from Amyotrophic Lateral S c l e r o s i s H.-J. Z e i t l e r ,
B. Andondonskaja-Renz, G. Küther, A. S t r u p p l e r
U r i n a r y Neopterin in Cocaine-Abusing
251
Individuals
R.W. Guynn, K. B i e h l , D.K. M e r r i l l , K.J. Krajewski Features of Neopterin Determination in C l i n i c a l
257
Use
E.R. Werner, D. Fuchs, A. Hausen, G. Reibnegger, H. Wächter, J . F . K . Huber . 263 Diurnal V a r i a t i o n in U r i n a r y P t e r i n E x c r e t i o n in Man A.E. Pheasant
267
The R e l a t i o n s h i p between P t e r i d i n e s and Colour Dimorphism in the Scorpion F l y M. Tsusue, M. Nakagoshi
271
P t e r i d i n e B i o s y n t h e s i s and M a n i f e s t a t i o n of Pigment Phenotypes in Normal and N e o p l a s t i c C e l l s of G o l d f i s h in V i t r o M. Masada, J . Matsumoto, M. Akino
275
L i g h t Depending Regulations of P t e r i d i n e s in the Retina G. C r e m e r - B a r t e l s , K. Krause D i f f e r e n c e s in the Regulation of T e t r a h y d r o b i o p t e r i n B i o s y n t h e s i s Neuronal C e l l s in Culture
279 in
J.H. Woolf, C.A. N i c h o l , D.S. Duch
283
NADPH- and NADH-Specific D i h y d r o p t e r i d i n e Reductase in Teratocarcinoma C e l l s i n C u l t u r e : E f f e c t of Nerve Growth Factor Treatment of the C e l l s on the Enzyme A c t i v i t i e s N. N a k a n i s h i , K. Ozawa, S. Yamada, K. A k i b a , N. Sato
287
R e v e r s i b i l i t y of ot-Diketo Reductase A c t i v i t y by S e p i a p t e r i n Reductase S. Katoh, T. Sueoka, S. Yamada
291
Non-Enzymatic S y n t h e s i s of " D r o s o p t e r i n s " from D i h y d r o p t e r i n and 2-Amino4 - 0 x o - 6 - A c e t y l - 3 H , 9H-7,8-Dihydropyrimido [ 4 , 5 b ] [1 ,4]Diazepine D.R. Paton, G.M. Brown
295
XIV BH4 B i o s y n t h e s i s : ^H-NMR Evidence f o r the P y r u v o y l - T e t r a h y d r o p t e r i n Synthase C a t a l y z e d Formation of 6 - P y r u v o y l - T e t r a h y d r o p t e r i n from Dihydroneopterin Triphosphate S . G h i s l a , S. Takikawa, P. S t e i n e r s t a u c h , T. H a s l e r , H.-C. C u r t i u s
299
C a t a b o l i s m of T e t r a h y d r o b i o p t e r i n in Man A. N i e d e r w i e s e r , A. M a t a s o v i c , T. K ü s t e r , W. Staudenmann, W. P f l e i d e r e r , S. S c h e i b e n r e i t e r Pteridine Biosynthesis
in Human Amniocytes and C h o r i o n i c
Villi
J. F e r r e , E.W. N a y l o r
309
The Role of the Kidney in B i o p t e r i n
Metabolism
J . - L . Dhondt, J.M. Hayte, C. N o e l , M. Dracon, G. L e l i e v r e , A. Tacquet Tetrahydrobiopterin-Producing and Man
305
Enzyme A c t i v i t i e s
315
in L i v e r of Animals
T. H a s l e r , A. N i e d e r w i e s e r
319
E f f e c t of 3-Hydroxykynurenine on GTP C y c l o h y d r o l a s e A c t i v i t y and on the P t e r i d i n e P a t t e r n i n D r o s o p h i l a melanogaster F . J . S i l v a , J . L . Mensua
323
T e t r a h y d r o b i o p t e r i n Metabolism in Normal B r a i n , S e n i l e Dementia o f the Alzheimer Type and Down's Syndrome J.M. Anderson, C.G.B. Hamon, R.A. Armstrong, J . A . B l a i r Summary: B i o l o g y of
327
Pteridines
M.A. Parniak
331
B i o s y n t h e s i s of P t e r i d i n e s and Metabolism of Aromatic Amino A c i d s D r o s o p h i l a melanogaster
in
Y. B e l , J . F e r r e The I n h i b i t i o n of tRNA T r a n s g l y c o s y l a s e s M e t a b o l i c Control of Gene E x p r e s s i o n
335 by P t e r i d i n e s as a Mean f o r
H. K e r s t e n , H.J. A s c h h o f f , P. Böhm, E. Zubrod
339
Modulation of Dopamine S y n t h e s i s by Nerve Terminal A u t o r e c e p t o r s : A Role for Tetrahydrobiopterin? M.P. Galloway, R.A. Levine
347
XV A Monoclonal Antibody Reacting with All Three Aromatic Amino Acid Hydroxylases R.G.H. Cotton, I.G. Jennings, R. Kuskinsky, C.W. Chow, E. Haan, W.J. McAdam, C. Bell, F. Morgan, H. Nakata, A.C. Cuello
Alterations in Cofactor-Dependent Activity of Phenylalanine as a Function of pH
351
Hydroxylase
M.A. Parniak, S. Kaufman
355
Interaction of a Monoclonal Antibody with Rat Liver Hydroxylase
Phenylalanine
M.A. Parniak, I.G. Jennings, R.G.H. Cotton
The Effect of Dietary Iron on the Activity of Rat Liver Hydroxylase
359
Phenylalanine
M.D. Davis, S. Kaufman
363
Strict Requirement of F e 2 + for Tryptophan 5-Monooxygenase from Mouse Mastocytoma, P-815 H. Hasegawa, A. Ichiyama
369
Tetrahydrobiopterin and the Regulation of Catecholamine Synthesis in Bovine Adrenal Medullary Chromaffin Cells R.A. Levine, K.L. Keiner
373
Cofactor Activity of Tetrahydropterins for Tyrosine Hydroxylation in PC12 Pheochromocytoma Cells D.S. Duch, J.F. Reinhard, M.P. Edelstein, J.Y. Chao, C.A. Nichol
Summary.: Pterin-Dependent Biological
377
Reactions
R.A. Levine
Tetrahydrobiopterin Deficiency. Analysis from an International
381
Survey
J.L. Dhondt
385
Cofactor Specificity of 6,6-Disubstituted Tetrahydropterins, and their Potential in the Treatment of Neurological Disorders J.E. Ayling, S.W. Bailey, S.B. Dillard
Normal Concentrations of Tetrahydrobiopterin in the Cerebrospinal of Patients with Dihydropteridine Reductase Deficiency K. Hyland, I. Smith, D.W. Howells
391
Fluid 395
XVI Prenatal Diagnosis of Tetrahydrobiopterin Deficiency A. Niederwieser, H. Shintaku, T. Hasler, H.-C. C u r t i u s , H. Lehmann, D. Leupold, 0. Guardamagna, A. Ponzone, H. Schmidt
399
Defective Biopterin Biosynthesis in a Chinese Infant C.R. S c r i v e r , C.L. Clow, P. Kaplan, G.V. Watters, C. Laberge, F. Mohyuddin, S. M i l s t i e n
403
Correlation of Dihydropterine Reductase Cross Reacting Material with Non-Responsiveness to a Tetrahydrobiopterin Load R.G.H. Cotton, I.G. Jennings, G. Bracco, A. Ponzone, 0. Guardamagna
407
Neopterin and Dihydroneopterins in Serum of Controls and Patients with Various Diseases. Circadian Rhythm of Neopterin. Influence of C o r t i s o l ? H. Rokos, H. F r i s i u s , R. Kunze
411
Neopterin Content and GTP-Cyclohydrolase A c t i v i t y of Blood C e l l s of Controls and Patients P o s i t i v e for LAV/HTLV-III Antibodies K. Rokos, R. Kunze, W. Lange, M.A. Koch
415
Neopterin in Bone Marrow Transplant Monitoring: An Improvement in i t s Use for GVHD Diagnosis P. Mura, A. P i r i o u , D. R e i s s , F. Guilhot, E. Benz-Lemoine, J. Tanzer
419
Importance of Neopterin Determination in I n d i v i d u a l s at Risk for AIDS D. Fuchs, A. Hausen, G. Reibnegger, E.R. Werner, H. Wächter, H.G. Blecha, H. Roessler, B. Unterweger, H. Hinterhuber, P. Hengster, T. Schulz, M.P. D i e r i c h , D. Renner
427
Biochemical Aspects of Pteridines During Interaction Between Activated T-Lymphocytes and Monocytes/Macrophages in Patients B. Andondonskaja-Renz, H.J. Z e i t l e r
431
Summary: Pterins and Human I l l n e s s D. Fuchs, H. Wächter
443
XVII
S E C T I O N D: F O L A T E S AND P T E R I N S
IN M A M M A L I A N
TISSUES
F o l a t e s in T i s s u e s and C e l l s . S u p p o r t for a " T w o - T i e r " H y p o t h e s i s R e g u l a t i o n of O n e - C a r b o n M e t a b o l i s m
of
C.L. K r u m d i e c k , I. Eto
447
E l e v a t i o n in the Rate of C e l l u l a r F o l a t e C a t a b o l i s m in the Rat
in M i d - P r e g n a n c y
J.M. S c o t t , E. W i l s o n , D.G. Weir
467
T h e Red B l o o d Cell as a S t o r a g e Site for Folic
Acid
S.E. S t e i n b e r g
471
in B l o o d F o l l o w i n g Low Dose
M e t h o t r e x a t e a n d B i o p t e r i n Levels A d m i n i s t r a t i o n for P s o r i a s i s
R.J. L e e m i n g , R.M. C o n l o n , A. P o l l o c k , J. Kumari
Summary: Folates
475
in T i s s u e and Cells
D.G. P r i e s t
479
F o l a t e R e s c u e of N 2 0 - I n d u c e d
Inhibition
in M u r i n e
Lymphocytes
J.G. H i l t o n , B.A. C o o p e r , W. Lapp
F o l a t e A b s o r p t i o n and M e t a b o l i s m
481
in Alcohol
Fed Rats
J.M. N o r o n h a , V. Kesavan
C h r o n i c a n d A c u t e Effects of Ethanol E x c r e t i o n of F o l a t e in Rats
485
on Renal
Clearance and Urinary
K.E. M c M a r t i n , B.H. E i s e n g a , T . D . C o l l i n s , L. B a i r n s f a t h e r
489
E f f e c t of C h r o n i c A n t i c o n v u l s a n t T r e a t m e n t on F o l a t e C o n c e n t r a t i o n s the Rat
in
G.F. Carl
Alcohol
495
Induced Methyl
G r o u p W a s t a g e as a P o s s i b l e C a u s e of Fatty
A . M . M o l l o y , J.M. S c o t t , D.G. W e i r
Folate Catabolism D. A l - H a d d a d , A.E.
in the S y r i a n G o l d e n
Liver 505
Hamster
P h e a s a n t , J.A. B l a i r , C . G . B . H a m o n
509
XVIII The Level o f F o l a t e C a t a b o l i s m i n Normal Human P o p u l a t i o n s , t h a t the C u r r e n t Level o f RDA f o r F o l a t e i s E x c e s s i v e
Suggesting
J . M . M c P a r t l i n , D.G. W e i r , G. C o u r t n e y , H. M c N u l t y , J . M . S c o t t
M i c r o d e t e r m i n a t i o n of F o l a t e Monoglutamates i n Serum by L i q u i d Chromatography w i t h E l e c t r o c h e m i c a l D e t e c t i o n
513
High-Performance
K. I w a i , K. I n o u e , M. Kohashi
Folate Status in P s y c h i a t r i c mitter Metabolites T. B o t t i g l i e r i , E.H. R e y n o l d s
517
Patients:
R e l a t i o n s h i p w i t h CSF N e u r o t r a n s -
M. L a u n d y , M.W.P. C a r n e y , T . K . N . C h a r y , B . K .
Toone, 523
F o l a t e , T h i a m i n e and V i t a m i n B12 L e v e l s
in Outpatient
Epileptics
M . I . Botez
E f f e c t of A s p i r i n Liver Bioassay
527
I n g e s t i o n on F o l a t e B i o a v a i l a b i l i t y
E v a l u a t e d by Rat
K. Hoppner, B. Lampi
531
B r u s h B o r d e r P t e r o y l p o l y g l u t a m a t e H y d r o l a s e i n P i g Jejunum C . J . C h a n d l e r , T . T . Y . Wang, C.H. H a l s t e d
539
Use o f C I - 9 2 0 i n the C h a r a c t e r i z a t i o n o f the M e t h o t r e x a t e D e f e c t in a R e s i s t a n t Human Leukemic CCRF-CEM C e l l L i n e
Transport
G. J a n s e n , J . H . S c h o r n a g e l , G. R i j k s e n , J . de G i e r
543
The E f f e c t o f O x i d a t i v e S t r e s s on M e t h o t r e x a t e (MTX) T r a n s p o r t by Rat Hepatocytes M . S . Rhee, A. P u p o n s , Z. Nimec, J . G a l i v a n
F o l a t e T r a n s p o r t by P i g
Intestinal
547
Brush Border
Vesicles
A.M. R e i s e n a u e r
Depressed Folate Transfer Across D e f i c i e n c y i n the Rat
551
the Mammary Gland Secondary to
Iron
D . L . O ' C o n n o r , M.F. P i c c i a n o , A . R . Sherman, S . L . B ü r g e r t
S t u d i e s on the Mechanism o f F o l a t e T r a n s p o r t D.W. H o m e
in I s o l a t e d
555
Hepatocytes 559
XIX A n a l y s i s of the pH and Na+ Dependence of I n t e s t i n a l Folate Transport I . H . Rosenberg, J. Zimmermann, J. Selhub
563
I n t e s t i n a l Transport of Folate. Characterization of the Transport Events at the Brush Border and the Basolateral Membranes H.M. S a i d , W.B. Strum
567
The Synthesis of Some Novel Probes of Folate Transport and Binding R.J. Kempton, L.A. Sams, K.M. Harpring, A.G. Smith, F. Kohrs, E. Price, J.H. Freisheim
571
P h o t o a f f i n i t y Probes of Dihydrofolate Reductase and of the Membrane C a r r i e r f o r Folate Analogues E.M. Price, P.L. Smith, J.H. Freisheim
575
The Use of Biosynthetic Radioactive Folylpolyglutamates to Study I n t e s t i n a l Digestion and Absorption of Folate B. D a r c y - V r i l I o n , J. Selhub, I.H. Rosenberg
579
Selective I n h i b i t i o n of Bacterial Carboxypeptidase G and Pancreatic Conjugase by 2-Mercaptomethylglutaric Acid T . I . Kalman, V.K. Nayak, A.R.V. Reddy
583
Summary: Folate Absorption and Transport I.H. Rosenberg
587
Studies on Glycine-N-Methyltransferase C. Wagner, R.J. Cook Folate Binding Protein from Pediococcus Cerevisiae S t r a i n s Active Transport Systems for Folates
593 Possessing
F. Mandelbaum-Shavit
597
Immobilized Folate Binding Protein from Cow's Milk Used for Quantitation of Folate S . I . Hansen, E. Nextf, J. Holm
603
Characterization of Rabbit Antibodies Against the Folate Binding Protein from Cow's Milk M. Hoier-Madsen, S . I . Hansen, J. Holm
607
XX SECTION E: ENZYMOLOGY OF FOLATES 1. Thymidylate Synthase
Genetic and Chemical Studies on Thymidylate Synthase F. Maley, F.K. Chu, D.K. West, G.F. Maley
613
Active Site Probes of Thymidylate Synthetase A.D. Broom, I.Y. Vang
631
Resonance-Raman Spectroscopic Identification of the Transient Intermediates Formed in the Native Ternary Complex with Thymidylate Synthase A.L. Fitzhugh, S. Kaufman, S. Fodor, T.G. Spiro
639
The Reversal of the Cytotoxicity of Folate-Based Thymidylate Inhibitors in Cultures LI210 Cells
Synthase
A.L. Jackman, A.H. Calvert, R.G. Moran
Thymidylate Synthase Activity in the Tapeworm, Hymenolepis
645
diminuta
J. Ciesla, Z. Zielinski, W. Rode, B. Machnicka
651
Identification of Poly G Bound to Thymidylate Synthase J. Thorndike, R.L. Kisliuk
Methotrexate Derivates of Deoxyuridylate Showing Inhibitory for Thymidylate Synthetase from Lactobaci11 us casei
655
Properties
S. Webber, R. Nazarbaghi, J.M. Whiteley
Comparison of Thymidylate Synthase Isolated from Mouse Normal Tumour Tissues
659
and
Z. Zielinski, J. Ciesla, B. Kedzierska, W. Rode
663
Thymidylate Synthase Interaction with Analogues of dUMP and 5-Fluorid2'-Deoxyuridine-5'-Phosphate with Modified Phosphate Groups W. Rode, B. Kedzierska, T. Kulikowski, D. Shugar
667
An In Vitro System for Studies on Inhibition of the Thymidylate Cycle H. Rebandel , Y. Gaumont, R.L. Kisliuk
671
XXI N ^ O - P r o p a r g y l - 5 , 8 - D i d e a z a f o l i c A c i d Polyglutamates as I n h i b i t o r s o f Thymidylate Synthase and t h e i r I n t r a c e l l u l a r Formation E. S i k o r a , A . L . Jackman, D.R. Newell, K.R. Harrap, A.H. C a l v e r t , T.R. J o n e s , K. Pawelczak, B. R z e s z o t a r s k a S e q u e n t i a l CMF i n M e t a s t a t i c B r e a s t Cancer: An Attempt to E f f e c t i v e n e s s by Means of Biochemical Modulation
675
Increase
P. Pronzato, L. Repetto, D. Amoroso, A. A r d i z z o n i , G. B e r t e l l i , P.F. Conte, V. Fusco, M. G u l i s a n o , R. Rosso
681
Model S t u d i e s of Thymidylate Synthase Reaction P . F . C . Van der M e i j , E. H i l h o r s t , T . B . R . A . Chen, E.R. de Waard, U.K. P a n d i t Synergistic
687
I n t e r a c t i o n Between F o l i n i c A c i d and the F 1 u o r o p y r i m i d i n e s
K. Keyomarsi, R.G. Moran
2. M e t h i o n i n e Methionine
691
Biosynthesis
Biosynthesis
R.G. Matthews, D.A. J e n c k s , V. F r a s c a , K.D. Matthews Impaired Formylation and Uptake of T e t r a h y d r o f o l a t e by Rat Small F o l l o w i n g Cobalamin I n a c t i v a t i o n
697 Gut
J . P e r r y , R. Deacon, M. Lumb, I . Chanarin Heterogeneity i n F u n c t i o n a l Methionine Synthase
709 Deficiency
D. W a t k i n s , D . S . R o s e n b l a t t Summary: Methionine
Biosynthesis
E.L.R. Stokstad
3. F o l y l
713
Polyglutamate
Folylpoly-y-glutamate
717
Synthetase Synthetase
B. Shane
719
C y t o t o x i c E f f e c t s and I n h i b i t i o n of F o l y l p o l y g l u t a m a t e Synthetase by F o l a t e Analogs C o n t a i n i n g 2 , Omega-Diaminoalkanoic A c i d s J . J . McGuire, J . R . P i p e r
729
XXII An Upstream Gene R e g u l a t e s the E x p r e s s i o n o f F o l y l p o l y g l u t a m a t e Synthetase-Dihydrofolate Synthetase in Escherichia coli A. B o g n a r , C. O s b o r n e , B. Shane
733
Occurence and S y n t h e s i s of P t e r o y l - | f - g l u t a m y l - t f - g l u t a m y l - p o l y - o t glutamates in E s c h e r i c h i a c o l i R. F e r o n e , M. H a n l o n , S . S i n g e r , D. Hunt
Summary: F o l y l p o l y g l u t a m a t e
737
Synthesis
E. C o s s i n s
741
The M e t a b o l i s m of
Pteroylpolyglutamates
R.L. K i s l i u k
Dihydropteroyl
743
Hexaglutamate and T4 Phage B a s e p l a t e Assembly
B. S z e w c z y k , K. S z e w c z y k , L . M . K o z l o f f
757
E f f e c t s o f P o l y g l u t a m y l a t i o n on F o l a t e C o f a c t o r and A n t i f o l a t e A c t i v i t y i n the T h y m i d y l a t e S y n t h a s e C y c l e o f P e r m e a b i 1 i z e d M u r i n e Leukemia L 1210 C e l l s T.I.
Kaiman
763
Summary: P t e r o y l p o l y g l u t a m a t e
metabolism
R . E . Mackenzie
4. D i h y d r o f o l a t e
Recent Advances
767
Reductase
in the Study of D i h y d r o f o l a t e
Reductase
R . L . B l a k l e y , J . R . Appleman
The 2 . 8 8 S t r u c t u r e o f a Type I I
769
P l a s m i d Encoded D i h y d r o f o l a t e
D.A. M a t t h e w s , S . L . S m i t h , D . P . B a c c a n a r i , J . J . B u r c h a l l , S . J . J. Kraut
Mutations B.I.
i n the Human D i h y d r o f o l a t e
Reductase Oatley, 789
Reductase
S c h w e i t z e r , S . S r i m a t k a n d a d a , S . K . Dube, J . R . B e r t i n o
T h e o r e t i c a l S t u d i e s o f the S t r u c t u r e , C o n f o r m a t i o n a l p e r t i e s of A n t i c a n c e r F o l a t e I n h i b i t o r s W.J. Welsh, V. Cody
and E l e c t r o n i c
793
Pro799
XXIII B i n d i n g of I n h i b i t o r s w i t h S p i n - L a b e l e d S i d e C h a i n s to Reductase (DHFR) from S e v e r a l S p e c i e s
Dihydrofolate
R . L . B l a k l e y , R . L . K u l i n s k i , J . R . Appleman, J . R . P i p e r
803
A f f i n i t y L a b e l i n g o f D i h y d r o f o l a t e Reductase w i t h an I o d o a c e t y l Analogue of Methotrexate
Lysine
T . J . Del camp, A. R o s o w s k y , P . L . S m i t h , J . E . W r i g h t , J . H . F r e i s h e i m
Escherichia coli
807
D i h y d r o f o l a t e Reductase I s o l a t e d as a F o l a t e Complex
S . S . Joyner, D.P. Baccanari
811
D i h y d r o f o l a t e Reductase from Soybean
Seedlings
S . Ratnam, T . J . Delcamp, J . H . F r e i s h e i m
Use o f A n t i b o d i e s as S t r u c t u r a l and E n z y m e - L i g a n d Complexes
815
Probes o f D i h y d r o f o l a t e
Reductases
M. Ratnam, T . J . Delcamp, J . H . F r e i s h e i m
819
C o o p e r a t i v i t y i n I n h i b i t o r B i n d i n g to N e i s s e r i a f o l a t e Reductase
gonorrhoeae
Dihydro-
R.L. T a n s i k , D.P. Baccanari
823
pH S t u d i e s o f the R e a c t i o n C a t a l y z e d by D i h y d r o f o l a t e Reductase from E. c o l i J . F . M o r r i s o n , S . R . Stone
827
E f f e c t s o f pH on R e a c t i o n s C a t a l y z e d by D i h y d r o f o l a t e Reductase from Chicken L i v e r J . F . M o r r i s o n , S . R . Stone
Unconjugated D i h y d r o p t e r i n S u b s t r a t e s Reductase
831
f o r Bovine L i v e r
Dihydrofolate
G.K. S m i t h , S . D . B a n k s , E . C . Bigham, C . A . N i c h o l
Enzymatic C h a r a c t e r i z a t i o n o f Recombinant Human R e d u c t a s e Produced i n coli D. S t u b e r , H. B u j a r d , E. H o c h u l i , H.P. K o c h e r , E . K . W e i b e l , F. W i n k l e r , R . L . Then
835
Dihydrofolate I . Kompis, K. Talmadge,
L e v e l s o f F o l a t e s and M e t h o t r e x a t e P o l y g l u t a m a t e F o r m a t i o n i n Hamster Ovary C e l l s L a c k i n g D i h y d r o f o l a t e Reductase P. Joannon, H. G o l d b e r g , V.M. Whitehead, D . S . R o s e n b l a t t , M . J . D. B e a u l i e u
839
Chinese Vuchich, 843
XXIV Methotrexate in Adjuvant
Arthritis
J . G a l i v a n , M.C. Rehder, S . Kerwar
847
Computer G r a p h i c M o d e l i n g i n Drug D e s i g n : C o n f o r m a t i o n a l A c t i v e - S i t e M o d e l i n g of L i p o p h i l i c D i a m i n o p y r i m i d i n e s
Analysis
and
V. Cody
851
E f f e c t o f A n t i f o l a t e s 1 0 - M e t h y l - and on a Human B r e a s t Cancer C e l l L i n e
1O-Ethyl-10-Deaza-Aminopterin
F. M a n d e l b a u m - S h a v i t
855
B i o c h e m i c a l and C y t o t o x i c E f f e c t s of the E r y t h r o - and T h r e o - I s o m e r s Gamma-Fluoro-Methotrexate
of
J . J . M c G u i r e , J . G a l i v a n , J . K . Coward
5. Other F o l a t e
861
Enzymes
C i - T e t r a h y d r o f o l a t e - S y n t h a s e , a M u l t i f u n c t i o n a l Enzyme I n v o l v e d P u r i n e M e t a b o l i s m , and i t s R e l a t e d M o n o f u n c t i o n a l Enzymes
in
K.W. Shannon, T . R . W h i t e h e a d , C. S t ä b e n , J . C . R a b i n o w i t z
The I n t e r a c t i o n o f T e t r a h y d r o p t e r o y l p o l y g l u t a m a t e s Hydrofolate Synthetase
with
865
1O-Formyltetra-
V. S c h i r c h , B. S t r o n g , G. J o s h i , R. L u r a , T. D e n n i s
Summary: F o l a t e s
887
in C 1 Metabolism
V. S c h i r c h
891
Chemical A s p e c t s o f D i m e t h y l g l y c i n e Dehydrogenase and Dehydrogenase
Sarcosine
R . J . C o o k , P . G e t t i n s , C. Wagner
Folate Normalizes
E l e v a t e d PRPP L e v e l s of F o l a t e - D e f i c i e n t
893
HL-60
Cells
J . G h i t i s , C. S c h r e i b e r , S . Waxman S t e r e o c h e m i s t r y o f H y d r i d e T r a n s f e r to NADP + by M e t h y l e n e f o l a t e Dehydrogenase from P i g L i v e r J . Green, R.G. Matthews, R . E . MacKenzie
897
Tetrahydro901
XXV The Effects of Thyroxine Status on Hepatic Levels of tetrahydrofolic Acid: NADP Oxidoreductase
10-Formyl-
J.M. Keating, H. Choe, E.L.R. Stokstad
905
Interaction of Homocysteine with Methionine
Synthetase
G.P. Lewis
909
Minor Form of Human Hepatic Betaine: Homocysteine
S-Methyltransferase
W.E. Skiba, M.S. Wells, J.H. Mangum, W.M. Awad
913
Studies of Cobalamin-Dependent Methionine Synthase from Escherichia coli B V. Frasca, W.R. Dunham, R.H. Sands, B.S. Riazzi , R.G. Matthews
Inhibition of Methylenetetrahydrofolate
Reductase by Adenosyl
917
Methionine
D.A. Jencks, R.G. Matthews
921
Regulation of Folate Homeostasis C. Osborne, K. Lowe, B. Shane, D.J. Cichowicz, D. Sussman, G. Milman
An Endogenous Inhibitor of Neurospora Folylpolyglutamate
925
Synthetase
E.A. Cossins, P.Y. Chan
929
Folylpolyglutamate Hydrolase from Beef Liver P.J. Vickers, R. Di Cecco, Z.B. Pristupa, K.G. Scrimgeour
933
Use of Mammalian Cell Transformation to Isolate Genomic Sequences Encoding Human Fo.lyl polygl utamate Synthetase (FPGS) and Dihydrofolate Reductase (DHFR) S.M. Taylor, N. Davidson, R.G.Moran
937
SECTION F: METHOTREXATE AND OTHER ANTI-FOLATES
Antifolates: Expanding Horizons in 1986 B.A. Chabner, C.J. Allegra, J. Baram ..
945
XXVI Deaza D e r i v a t i v e s of T e t r a h y d r o f o l i c A c i d . A New C l a s s of F o l a t e Antimetabolite G.P. B e a r d s l e y , E.C. T a y l o r , G.B. G r i n d e y , R.G. Moran S t r u c t u r e A c t i v i t y R e l a t i o n s h i p s of Novel T r i a z i n e
953
Antifolates
C. D i a s - S e l a s s i e , Y.C. Zheng, H. Zhu, C. Hansch, T. Khwaja, J.H. F r e i s h e i m , T . J . Delcamp
959
The E f f e c t of 7-Hydroxymethotrexate on the Antitumor A c t i v i t y and Host T o x i c i t y of Methotrexate In Vivo P.A. Newton, R.A. F i n c h , T . L . Avery
953
Summary: The B i o l o g y of A n t i f o l a t e s J. Gallivan C r y s t a l S t r u c t u r e of Methotrexate and i t s Conformational with Related S t r u c t u r e s
967 Comparison
P.A. S u t t o n , V. Cody E f f e c t o f Methotrexate on Reduced F o l a t e s and Thymidylate During Growth of L1210 C e l l s
969 Synthesis
D.G. P r i e s t , V. Kesavan, M.T.Doig D i h y d r o f o l a t e Reductase from Human Osteosarcoma C e l l s R e s i s t a n t Methotrexate
973 to
J . K . S a t o , T . J . De-Frank
977
Evidence f o r D i r e c t I n h i b i t i o n of M e t a b o l i c Pathways as a Mechanism of A c t i o n of Methotrexate C . J . A l l e g r a , J . Baram, B.A. Chabner I n h i b i t i o n of D i h y d r o f o l a t e Reductase and Thymidylate Synthase by Methotrexate Polyglutamate Analogues L a c k i n g " I n t e r n a l " « - C a r b o x y l
981
Groups
A. Rosowsky, R.A. F o r s c h , M.M. Wick, J.H. F r e i s h e i m , P.V. Danenberg, T . I . Kalman
985
The A n t i f o l a t e A c t i v i t y o f Poly-jf-Glutamyl D e r i v a t i v e s of Methotrexate, 10-Deazaaminopterin and 1 0 - E t h y l - 1 0 Deazaaminopterin R . L . K i s l i u k , Y. Gaumont, P. Kumar, M.G. N a i r , B.T. Kaufman
989
XXVII P o l y g l u t a m a t i o n of the Thymidylate Synthase I n h i b i t o r , N ^ O - P r o p a r g y l 5 , 8 - D i d e a z a f o l i c A c i d (CB 3 7 1 7 ) , in Organs of E h r l i c h A s c i t e s Carcinoma-Bearing Mice M. Manteuffel-Cymborowska, B. Kaminska, B. G r z e l a k o w s k a - S z t a b e r t
5 , 8 - D i d e a z a f o l a t e s as S u b s t r a t e s f o r F o l y p o l y - # - G l u t a m a t e from Pig L i v e r
Synthetase
J . B . Hynes, D.J. C i c h o w i c z , B. Shane 5 - S u b s t i t u t e d - 5 - D e a z a Analogues of C l a s s i c a l
993
997 Antifolates
J . R . P i p e r , G.S. McCaleb, J . A . Montgomery, F.M. S i r o t n a k
1001
A z i d o - S u b s t i t u t e d A n t i f o l a t e Drugs: S y n t h e s i s , S t r u c t u r e , and A c t i v i t y P.K. B r y a n t , K.P. Wong, J . C o l b y , C.H. Schwalbe, M.F.G. R . J . G r i f f i n , E.A. B l i s s Summary: Novel
Stevens, 1005
Antifolates
R. Jackson
1009
AUTHOR INDEX
1011
SUBJECT INDEX
1017
L I S T OF PARTICIPANTS
1033
HOW IT ALL BEGAN: A BRIEF HISTORY OF THE PTERIDINE SYMPOSIA
Adrien Albert Chemistry (Science), the Australian National University, Canberra, Act 2601, Australia
Introduction Who could have seen that, from their modest beginning in Paris little more than thirty years ago, the Pteridine Symposia would grow into such a well-established series, steadily expanding in interests and attendance?
It was in 1951, I remember, that I paid my first visit to Professor Michel Polonovski's Department of Biological Chemistry in Paris.
It was in the Faculty of Medicine, just off the east
end of the Boulevard de Saint Germain.
I had recently been
appointed to the Chair of Medical Chemistry in the newly-formed Australian National University.
However that federal
institution was only at the stage of drawing plans for the buildings.
Meanwhile, they funded me to form an Australian
research group in London, in the Wellcome Research Institution.
When we met, Polonovski and I eagerly exchanged details of our researches in pteridine chemistry, a subject not widely practised at that time, but one that fired both of us with enthusiasm.
As we spoke of it, we began to wish for an
Occasion, where all who were interested in pteridine-based science could meet to exchange information and stimulate one
Chemistry and Biology of Pteridines 1986 © 1986 Walter d e Gruyter & Co., Berlin • New York - Printed in Germany
2
another.
Polonovski thought that, provided its orbit was
confined to Western Europe, he could just about stretch some funds to bring it off!
Later he wrote to Des Brown and myself
in London: 'Le sujet du symposium sera: Etudes sur les ptérines: répartition, constitution, analyse, synthèse, propriétés physicochimiques, ptérines naturelles, action physiologique et pharmacodynamique'.
The First Symposium And so it happened that, September 28-30 1952, the First Symposium on the Chemistry and Biology of Pteridines took place in the Paris Medical Faculty, in drizzly overcast autumn weather.
The meeting attracted 18 listeners.
Our lectures were
published only individually, as papers.
Talks were given by Polonovski and his collaborators (R.-G. Busnel and M. Pesson), by W. Jacobson of the Strangeways Research Laboratory in Cambridge, by F. Korte of the Chemisches Staats Institut in Hamburg, by F. Egami from Nagoya University (he was visiting his old University in Strasbourg at the time), and by D.J. Brown and myself.
Polonovski's group spoke of their
experiences with Isay's general synthetic method, of the necessity for modifications of it to get reproducible high yields, and of some mystifying by-products obtained when preparing 4,5-diaminopyrimidines, those necessary starting materials.
Korte spoke of the naturally-occurring pteridines
whose constitutions he and R. Tschesche were beginning to
unravel.
Egami acquainted us w i t h the surprising amount of work
done in Japan on the paper-chromatographic isolation of pteridines from silkworms and fish.
Jacobson struck a clinical
note by identifying the stage of human mitosis inhibited by methotrexate, a folic acid analog recently introduced for treating leukemia in children.
I drew attention to the huge and
unprecedented electronic gradient existing in the highly n-deficient (my newly-coined word!) pteridine nucleus.
Brown
and I told how we practised the study of mono-substituted pteridines as an essential first step in assessing how this 'electron-thirst' could be attenuated, stepwise, by inserting electron-releasing substituents
(such as -NH2 or =0).
This
strategy revealed the rules governing solubility and stability in the whole pteridine series.
Photo 1, taken by Prof. Egami at the time, shows (in the back row, left to right): Drs. Jacobson, Busnel, Korte, Brown and (a little to the fore) Prof. Polonovski; also (in the front row) Madame Polonovski, myself, and Madame Busnel.
Our hosts' kind hospitality provided us with some memorable meals.
But, one lunchtime, w i t h a merry twinkle in his eye,
Michel conducted us to a typical Left-Bank establishment: la Grenouille'.
'Roger
This, as y o u may have guessed, served only one
kind of dish, one whose amphibian delicacy drew varied comments.
4
Photo 1
The Second Symposium Back in England, Jacobson and I, greatly stimulated by the Paris meeting, began to wish for a larger one, with enough funding for us to be able to invite American colleagues.
When approached,
the Ciba Foundation readily agreed to our suggestion. Accordingly, the Second Pteridine Symposium took place in the Foundation's London premises in Portland Place (March 22-26, 1954).
Spring had arrived early that year, and the dull,
war-scarred Squares of London sprang to life around drifts of golden daffodils blooming under pink-flowering Prunus trees.
5
This provided a welcoming note for the Symposium's American visitors, and it turned out to be a good omen for our Meeting.
There were 29 participants: Dr. Ruth Bellairs, F. Bergel, D.J. Brown, R.-G. Busnel, Marie Coates, H.O.J. Collier, J. Colsky, Donna Cosulich, J. Druey, Gertrude Elion, H.S. Forrest, R.H. Girdwood, A. Haddow, G.H. Hitchings, Dorris Hutchison, G.W. Kidder, F. Korte, S.F. Mason, R.H. Nimmo-Smith, M. Polonovski, E.C. Taylor, G.M. Timmis, R. Tschesche, M. Webb, F.J. Wolf, H.C.S. Wood, D.D. Woods, as well as the two Chairmen: Dr. Jacobson and myself.
I recall opening that meeting with the thought that, sixty-five years earlier, Frederick Gowland Hopkins had isolated the first pteridine from Nature, in fact from a butterfly (1).
At the
time of this Second Symposium, the only naturally-occurring pteridine known to be essential for human metabolism was folic acid, and the program gave it due prominence in clinical, biochemical, and medical contributions.
The Ciba Foundation set
a splendid example in accelerated publication of the Proceedings which came out in the same year (2).
Photo 2 shows Dr. G.E.W. Wolstenholme (Director of the Foundation) flanked by G.M. Timmis (left), who had just told us about his new, nitroso-group-participating reaction for the unambiguous synthesis of insecurely-assigned pteridines, and (on the right) by H.O.J. Collier, who had been discussing the possibilities of pteridines in chemotherapy, a topic being developed (after some remarkable molecular simplifications) into a series
6
Photo 2
of much-used diaminopyrimidine drugs by G.H. Hitchings seen (left) with D.D. Woods in Photo 3.
Photo 4 shows M. Polonovski
(right) with F. Bergel and Photo 5 presents E.C. Taylor (right) with Donna Cosulich.
Sad to tell, Michel Polonovski lost his
life in a motoring accident shortly after this London meeting.
I recall reading a paper to that Symposium: Some Unresolved Problems in Pteridine Chemistry.
I'm happy to add that, thanks
to the stimulus of the meeting, I had solved these problems before the next Pteridine Symposium.
They turned out to have a
single solution: unexpected nucleophilic addition across a
Photo 3
highly susceptible double-bond.
Further studies of this
phenomenon kept me and my colleagues busy for many a year.
Of
these addition reactions, the most remarkable (and unexpected) was covalent hydration which, as we went on to show, affects not only pteridines but many other families of nitrogen heterocycles.
The Third Symposium Rather a long interval elapsed between this and the Third Pteridine Symposium which took place, September 1962, in Germany
Photo 4
(in Stuttgart's Technische Hochschule).
It had been arranged by
Wolfgang Pfleiderer who chaired it jointly with E.C. Taylor of Princeton. days.
There were 52 participants and it lasted for four
A historical note was struck by the invited presence of
two real pioneers of the structural chemistry of naturally-occurring pteridines: C. Schopf and R. Purrmann. Hopkins did not know the structure of the substances that he had isolated from butterflies.
The subject was not resumed until
1924 when Clemens Schopf came to study in Heinrich Wieland's Department in Munich.
They coined the name 'pterin' in 1925,
but the underlying structure remained unknown until 1940 when
Photo 5
Robert Purrmann, in the same Department, showed that xanthopterin, isoxanthopterin and leucopterin were simple derivatives of pyrimido[4,5-b]pyrazine, a known ring-system to which Wieland gave the name 'pteridine' in 1941.
Photo 6, taken from the Proceedings (3), shows us participants at this Third Symposium.
The Meeting indicated several new
lines of interest, particularly the study of biopterin whose great importance in human metabolism was beginning to be realized.
10
Photo 6
Subsequent Symposia
The Fourth Pteridine Symposium took place in 1969, in an attractive pearling village named Toba, reached from Nagoya. Our Japanese hosts had taken over a complete air-conditioned hotel for our meeting which was held in comfort, in spite of the humid external weather at the height of Japan's 'rainy season'. I speak of July 21-25.
The meeting was chaired by Prof. K.
Nakanishi and attracted about 100 'pteridinologists' (as we were beginning to call ourselves) from 7 countries. papers (4).
We presented 45
This meeting coincided with Man's first landing on
the moon, an exciting and memorable coincidence.
11
Prof. Wolfgang Pfleiderer was again host to a Pteridine Symposium when he arranged the Fifth in Konstanz (Germany), exposing us to the contemporary and colorful architecture of the new University on the shores of the Bodensee.
This took place
from the 14th to the 18th of April in 1975, in delightful Spring weather.
Seventy-one papers were read (5) to an audience of
about 150.
The Sixth Pteridine Symposium was held (September 25-28, 1978) in the Scrips Clinic and Research Foundation at La Jolla, that delightful beach resort lying just outside San Diego in the USA, near the border with Mexico.
It was attended by 230
pteridinologists who presented a total of 140 papers and posters (6).
The meetings had by now grown to a size that demanded not
an organizer so much as an organizing committee: Drs. J.J. Burchall, G.M. Brown, F.M. Huennekens, R.L. Kisliuk, S. Kaufman, J. Montgomery, T. Shiota, and J.M. Whiteley.
The Seventh Pteridine Symposium (7), so fresh in our minds, went off brilliantly during September 21-24 (1982) in St. Andrews, Scotland.
It hosted 274 participants from 24 countries, and
reflected great credit on Prof. Hamish Woods who arranged it.
The present Eighth Pteridine Symposium, in Montreal, is carrying on the established tradition.
These gatherings bring together
pteridine workers from many diverse scientific disciplines, from physical and organic chemistry, biochemistry, general biology, microbiology, and clinical medicine.
Their aim is to generate,
in enthusiasm and harmony, a cross-fertilization of ideas and
12
mutual stimulation. successful.
In this, they seem to have been very
They have provided refreshing insight into
long-standing problems and they have constantly suggested new pathways for exploration.
Long may they continue!
References 1.
Hopkins, F.G. 1889. Nature (London) 40, 335.
2.
1954. In: Chemistry and Biology of Pteridines, a Ciba Foundation Symposium. (G.E.W. Wolstenholme and M.P. Cameron, eds.). London, Churchill.
3.
1964. In: Chemistry and Biology of Pteridines. (W. Pfleiderer and E.C. Taylor, eds.). Oxford, Pergamon Press.
4.
1970. In: Chemistry and Biology of Pteridines. (K. Iwai, M. Akino, M. Goto, and Y. Iwanami, eds.). Tokyo, International Academic Printing Co. Ltd.
5.
1975. In: Chemistry and Biology of Pteridines. (W. Pfleiderer, ed.). Berlin and New York, de Gruyter.
6.
1979. In: Chemistry and Biology of Pteridines. (R.L. Kisliuk and G.M. Brown, eds.). Amsterdam, Elsevier/North-Holland.
7.
1983. In: Chemistry and Biology of Pteridines. (J.A. Blair, ed.). Berlin and New York, de Gruyter.
THE MECHANISM OF ACTION OF FOLATE AND PTERIN REQUIRING ENZYMES
S.J. Benkovic, L.J. Slieker, S.C. Daubner, L.F. Courtney, T.A. Dix, S.O. Pember, L.M. Bloom, C.A. Fierke, R.J. Mayer, J.-T. Chen, and K. Taira Department of Chemistry, The Pennsylvania State University, University Park, Pennsylvania 16802
Introduction I am honored to follow in Dr. Frank Huenneken's footsteps and to present the Gowland Hopkins Lecture.
The previous volume in this
series began with a brief forward describing the achievements of Professor Hopkins, particularly his interest in pterin chemistry. I will attempt to highlight the advances achieved in the elucidation of the mechanism of action of enzymes that utilize tetrahydropterin or tetrahydrofolate cofactors since the Seventh International Symposium.
This will not be an exhaustive review and
will be biased towards studies conducted in my laboratory.
I am
indebted to Dr. Young whose exemplary state of the art lecture at the last Symposium provided me with a detailed frame of reference ( 1 )
•
Tetrahydrofolate Requiring Enzymes The bridged 5,10-CH2-H4folate is an active shuttle of one-carbon units at the formaldehyde level of oxidation.
A key to under-
standing the mechanism of action of enzymes that process 5,10-CH2H4folate was provided by the stereospecific chemical synthesis of (6R, 11R) -and (6R, U S ) - 5 ,10-CH2
[ 1 l-^-H, 2 H] H 4 folate and the deter-
mination of the absolute stereochemistry of the two epimers at C-ll by proton nuclear Overhauser enhancement relative to C7-H (2) . These NMR measurements in conjunction with others suggest that 5,10-CH2-H4folate adopts the saucer-shaped conformation shown for 1 (3) .
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
14
Hs !
COOH I CsH4CONHCHCHjCHJCOOH
H,N
The
1
correlation
epimers of the
of
the
stereochemical
formed
in e n z y m i c
latter's
absolute
stereochemical
ant mechanistic
implications.
A case
is the o n e
in p o i n t
thymidylate numerous enzymic
synthetase.
experiments process
supported by is n o w
studies
stereospecific
(4).
its C-ll
3
respectively
epimer
course
transfer
reaction has been both model
A reasonable alternate
stereochemical
conversion
and
H]TMP
This
involving
strengthened by
folate
carbon unit
involving
itself
assignments
to t h o s e
processes has permitted
of
the
and of
(S)
attend-
by
the subject
compounds
as w e l l
hypothetical substrates
information and
the
catalyzed
of as
and
inhibitors, from
[11-^h,H4-
H.
M
HN 1
o
H H
H
1
S
(1)
E
NHR
(2)
S
the
(R)-methyl[methyl-^H,2H,
(5).
VV u
the
pathway
derived
(6R,1IS)-5,1O-methylene
to t h e
for
elucidation
15 H RN H H,folate
NH.
H'
(3) TMP
H,
The first step in (eq.l) presumes the antiperiplanar opening of the imidazolidine ring (the lone pair of electrons on N-5 is almost antiperiplanar to the breaking C11-N10 bond). tional restraints of the fused
Since the conforma-
imidazolidine-tetrahydropyrazine
ring system preclude inversion at N5, a syn elimination would seem to be impossible.
The resulting N-iminium cation must then have
the Z configuration, as shown.
Nucleophilic attack by enzyme-
bound dUMP (eq.2) on Cll can then occur from the s_i face to give the ternary complex followed by elimination to give enzyme-bound 5-CH2-dUMP and ^ f o l a t e . The depicted conformation of the bound complex is based on l^F NMR studies performed on the abortive, stable ternary complex, FdUMP5,1O-methylenetetrahydrofolate-thymidylate native and denatured states (6,7).
synthetase, in both its
These measurements confirmed
the fluor ine and C6—H of the nucleotide to be in equatorial positions in the native enzyme complex, and the Enz-S and CII-CH2 bridge moieties to be in a trans-diaxial conformation.
Indirect
measurement of Jjjp values between C5-F and C11-2H suggested that the C5-F bond (and presumably the C5-H bond of the native species) was neither syn nor anti to the C11-N5 bond.
Thus, whatever the
conformation of the ternary complex, the enzyme must induce a conformation change prior to elimination. The formation of the methyl group has been postulated to occur through the transfer of C6-H as a hydride equivalent to the exocyclic C5-methylene of the uracil ring.
This results in oxidation
of the tetrahydropterin ring in a single two-electron step as opposed to the usual pathway for pterin oxidation through the quinonoid form in either one or two electron steps (8).
The place-
ment of the two rings in a stacked conformation within the thymidylate synthetase active site poises them for e~ transfer.
A
16 two-step 1 e~/H- radical sequence invoking the redox properties of the pterin is shown (eq.3).
This mechanism can satisfy the
observed stereochemistry provided rotational effects within the radical pair are slow relative to complete reduction.
The stereo-
chemical evidence by itself does not preclude the hydride transfer process. Our apparent understanding of the thymidylate synthetase reaction notwithstanding, the participation of 5,10-CH2~H4folate in the conversion of uridine to ribothymidine in tRNA catalyzed by the ribothymidyl synthase from S_;_ faecalis takes an unexpected course (9).
Experiments with the purified enzyme demonstrated that the
methyl group is derived from the methylene unit but that FADH2 serves as the reducing agent and not H4folate.
The hydroxymethyl-
transferases found in bacteriophages are additional examples of enzymes that utilize 5,10-CH2~H4folate, transferring the onecarbon unit as a hydroxymethyl group to form pyrimidine nucleosides' -monophosphates (4).
Whether all these reactions proceed at
least as far as a common putative exocyclic methylene intermediate and then diverge is not known. The H4folate also acts as a source of one-carbon units in reactions catalyzed by a group of enzymes referred to as methionine synthases.
There are two different classes of synthase enzymes:
those that utilize cobalamin as a prosthtetic group and those that do not (10).
Both enzymes are often found in microorganisms such
as E^ coli; mammalian tissues contain only the cobalamin-dependent form.
Both classes of synthases catalyze the transfer of a methyl
group from S-CHj-t^folate to homocysteine to form methionine. the case of the
In
coli cobalamin-dependent methionine synthase
there is now direct stereochemical data to add to other evidence that this reaction involves an intermediate methylcobalamin
(eg.4).
17 H 200 times) the
steady-state turnover rate, V^, is not affected.
In terms of the
dissociation equilibrium constant the effect is 140 fold shown).
Note, however, that k o f f
dissociation of ^ f o l a t e
(data not
( H 4 F ) — t h e rate constant for
from E--is > 300
in constrast to 1.4
s _ 1 observed for wild-type, and parallels the weak binding of 7,8-H2folate. trolling.
Thus product dissociation is no longer rate con-
Secondly, the deuterium isotope effect on Vm is 3.0,
25 in constrast to the (V)D of 1.1 for wild-type (30).
Thus the
similar turnover rates observed for the two enzymes in the steadystate measurement are coincidental with hydride transfer largely rate-limiting for the mutant enzyme. Table I. Comparison of Kinetic Parameters for Wild-type and Gly-54
K
Ma (yM)
Va (s- )
Wild-type
0. 5
12
Gly-54
140
14
a
k 0 ff (H 4 F) b (s-1)
1
1. 4
300
3. 0
Conditions: 50 mM Mes, 25 mM Tris, 25 mM ethanolamine, 100 mM NaCl, (MTEN buffer) pH 5.5, 25°C, 100 yM NADPH, enzyme and H 2 F according to K M and V values,
b Conditions: MTEN buffer, pH 7.0, 25°C. c
Kinetic deuterium isotope effect with NADPD, under same conditions as (a).
It is doubtful that the function of the Gly-54 mutant enzyme was seriously impaired by a change in conformation.
Point mutations
in general are accomodated by very minor readjustments of the protein structure and that "space" created by introducing smaller amino acids can be occupied by water molecules (31,32).
Exper-
imental evidence for the Gly-54 enzyme supports this generalization since the on and off rates for NADPH binding, the rates of DHFR coformer interconversion and their relative concentrations are in good agreement with wild-type values (33). The effect of the Leu-54 -»• Gly mutation then is both to decrease the binding interaction and to make chemical catalysis less efficient.
The primary effect of removing the isobutyl side chain
is a 140-fold, or 2.9 kcai_/mol, decrease in the free energy change obtained upon binding substrate.
However, the interaction in the
transition state for the chemical step between Leu-54 and substrate must also be important despite the remoteness of the
26 residue from the reaction center.
The difference in the rate of
hydride transfer due to the mutation is 32-fold from 450 s~l to 14 s _ 1 .
The transition state may be destablilized either by
misalignment relative to the NADPH, or by loss of a hydrophobic interaction which preferentially stabilizes the developing H4folate product.
In terms of observed free energy changes, at
saturating f^folate levels, the Leu-54 residue stabilizes the transition state for hydride transfer ca. 35-fold (AAG = 2.1 kca]_/ mol) relative to the ternary complexes.
At subsaturating H2folate
levels, one would observe both the 2.9 k c a i/mol of binding energy and 2.1 k c a i/mol of transition state stabilization.
Thus the total
stabilization by Leu-54 of the transition state for hydride transfer is ca. 5000 fold (AAG = 5.0 k c a i/mol) relative to free enzyme, assuming both mutant and wild-type have identical free energies.
With respect to methotrexate binding, K D is increased
by 300-fold or A k c a i/mol of 2.9.
It remains to be seen whether
the magnitude of these effects are general or unique to this mutation.
Acknowledgment This work was supported in part by grants to S.J. Benkovic from the National Science Foundation #DMB-8316425 A02 and the National Institutes of Health #GM24129.
References 1.
Young, D.W. 1983. (J.A. Blair, ed.).
In: Chemistry and Biology of Pteridines W. deGruyter Berlin, p. 321.
2.
Slieker, L.J. , S.J. Benkovic. 333.
3.
Poe, M., L.M. Jackman, S.J. Benkovic. 5527 .
4.
Santi, D.V., P.V. Danenberg. 1985. In: Folates and Pterins (R.L. Blakley and S.J. Benkovic, eds.). Wiley Interscience New York, Vol I. Chap. 9.
1984.
J. Am. Chem. Soc. 106, 1979.
Biochemistry 18,
27 5.
Tatum, C., J. Vederas, E. Schleicher, S.J. Benkovic, H. Floss. 1977. J. Chem. Soc. Com. Coramun., 218.
6.
Bryd, R.A., W.H. Dawson, P.D. Ellis, R.B. Dunlap. Am. Chem. Soc. 100, 7478.
7.
James, T.L., A.L. Pogolotti, K.H. Ivanetich, Y. Wataya, S.S.H. Lam, D.V. Santi. 1976. Biochem. Biophys. Res. Commun. 72, 404 .
8.
Pfleiderer, W. 1985. In: Folates and Pterins (R.L. Blakley and S.J. Benkovic, eds.). Wiley Interscience, Vol II, Chap. 2.
9.
Deik, A.S., D.P. Nagle, Jr., J.C. Rabinowitz. Chem. 255, 4387.
1978.
1980.
J.
J. Biol.
10.
Matthews, R.A. 1985. In: Folates and Pterins (R.L. Blakley and S.J. Benkovic, eds.). Wiley Interscience, Vol I, Chap. 13.
11.
Zydowsky, T.M., L.F. Courtney, V. Frasca, K. Kobayashi, H. Shimizu, L.-D. Yuen, R.G. Matthews, S.J. Benkovic, H.G. Floss. 1986. J. Am. Chem. Soc. 108, 3152.
12.
Smith, G.K., P.A. Benkovic, S.J. Benkovic. istry 20, 4034.
13.
Daubner, S.C., M. Young, R.D. Sammons, L.F. Courtney, S.J. Benkovic. 1986. Biochemistry ,25, 2951.
14.
Daubner, S.C., S.J. Benkovic. 4990.
15.
Daubner, S.C., J.L. Schrimsher, F.J. Schendel, M. Young, S. Henikoff, D. Patterson, J.A. Stubbe, S.J. Benkovic. 1985. Biochemistry 24, 7059.
16.
Lazarus, R.A., R.F. Dietrich, D.E. Wallick, S.J. Benkovic. 1981. Biochemistry 20, 6834.
17.
Lazarus, R.A., S.J. Benkovic, S. Kaufman. Chem. 258, 10960.
18.
Dix, T.A., G.E. Bollag, P. Domanico, S.J. Benkovic. Biochemistry 2_4, 2955.
19.
Wallick, D.E., L.M. Bloom, B.J. Gaffney, S.J. Benkovic. Biochemistry ¿3, 1295.
20.
Marota, J.J., R. Shiman.
21.
Bloom, L.M., B.J. Gaffney, S.J. Benkovic: (in press).
22.
Pember, S., J.J. Villafranca, S.J. Benkovic: (in press).
1984.
1985.
1981.
Biochem-
Cancer Research 45,
1983.
J. Biol. 1985. 1984.
Biochemistry _23, 1303. Biochemistry. Biochemistry.
28
23.
Storm, C.B., S. Kaufman. Coraraun. 3J2, 788.
1968.
Biochem. Biophys. Res.
24.
Dix, T.A., S.J. Benkovic.
25.
Shiman, R.: (personal communication).
26.
White, R.E., M.J. Coon.
27.
Bolin, J.T., D.J. Filman, D.A. Matthews, R.C. Hamlin, J. Kraut. 1982. J. Biol. Chem. 257, 13650.
28.
Filman, D.J., J.T. Bolin, D.A. Matthews, J. Kraut. J. Biol. Chem. 257, 13663.
29.
Stone, S.R., J.F. Morrison.
30.
Chen, J.-T.: (unpublished results).
31.
Howell, E.E., J.E. Villafranca, M.S. Warren, S.J. Octley, J. Kraut. 1986. Science 231, 1123.
32.
Chothia, C., A.M. Lesk.
33.
Cayley, P.J., S.M.J. Dunn, R.W. King. 20, 874.
Biochemistry 2±,
1985.
1980.
Ann. Rev. Bioch. 49, 315.
1984.
1985.
5839.
1982.
Biochemistry 23, 2753.
J. Mol. Biol. 182, 151. 1981.
Biochemistry
SECTION A CHEMISTRY OF PTERINS AND FOLATES
SIDE-CHAIN
CHEMISTRY
W.
Pfleiderer,
W.
Leskopf
OF
PTERIDINES
Y. K a n g ,
R. S o y k a , W. H u t z e n l a u b ,
Fakultät für C h e m i e , U n i v e r s i t ä t Konstanz U n i v e r s i t ä t s s t r a ß e 10, D - 7 7 5 0 K o n s t a n z / W .
M.
Wiesenfeldt,
Germany
Introduction Ever
since
structure
1940 w h e n of
the
R.
three
Purrmann naturally
(1-3)
xanthopterin,
isoxanthopterin , and
the
nucleus
pteridine
system dines
and
start able
a large
pterins
either
from
to f o r m
vey
of
the m o s t
done
and
Tschesche chain
bear
not
and
Glaser
that
to g i v e
in r e a s o n a b l e
approach
in t h e i r
the
directly
Goto
on t r e a t m e n t noticed
with
P^S^g.
chain
Another
on N a ? S ? 0 4 - t r e a t m e n t
of
are
the
sur-
fact
that
dealing
with
has
been
naturally their
in-
condensation
that
brominated
the C - 6 and
and
(6) a p p l i e d the
side-chain
D-erythro-neopterin
Chemistry and Biology of Reridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
side-
oxidized
I'-keto
an a n n e l a t e d of
py-
chain-1ransformation .
by c o n v e r t i n g into
an by
functional
most
1'-hydroxy
example
or
in 6 - p o s i t i o n
and Sakurai
synthesis
dibenzoyloxy-2'-oxobutyl)-side
since
through
be
pteri-
A close
chemistry
1958 a l r e a d y can
ring
surprising
various
a subsequent
in
to
approaches
is c o n c e r t e d
system
the Even
corresponding
urothion
the
side-chain
showed
yields.
that
derivative
pteridine.
little
side-chains.
(4)
pyrazine
ring
of
very
through
routes
derivative
this
in 6 - a c e t o n y l i s o x a n t h o p t e r i n
respectively
was
at
achieved
(5)
showed
pyrimidine
indicates
a carbon
indirectly
and
chemical pigments
two m a j o r
annelated
reactions
but
carbon
is u s u a l l y
The
the c o r r e s p o n d i n g
literature
nucleus,
pterins
synthetic
substitued the
modifications
in m o d i f y i n g
step
to
leucopterin
developed.
pyrazine
displacement
at the
troduction
1 ogs
substituted
common
occurring
been
the
butterfly
of a p y r a z i n e [ 2 , 3 - d ] p y r i m i d i n e ri ng
versatile
a suitably
pteridine
nucleophilic groups
have
annelation
the
of
on c o n d e n s a t i o n
appropriately rimidine
consists
number
elucidated
occurring
a
ana-
similar
6 - ( 3 ' ,4 1 thieno-ring modification (7)
lead-
32 ing
to a m i x t u r e
of 6 - s u b s t i t u t e d
involving
displacement,
reactions
respectively
pterins
and
7 ,8-dihydropterins
isomerization , reduction, of
various
N
H
hydroxy
groups
and
oxidation
(Fig.
H
1).
H
Na,SA
OH C - CH2 - CHjOH H
NEOPTERIN HN A .N
N
Intraly
and
(8,9)
sing
intermolecular
7 ,8-dihydrobiopterin at
since
thetic
varying nature
pathway
from
tetrahydrobiopterin
redox-reactions (8) a n d
pH. T h e s e
uses
have
are
however
transformations
guanosine-5 '-triphosphate (10-12)
also
been
tetrahydrobiopterin
results
analogous
H
^0H N'
HjNA , N
1
Fig.
with
OH •C - C - CHÎOH
HN'
(Fig.
not
found
respectivetoo
in the
(GTP)
to
surpri-
biosyn5,6,7,8-
2). OH OH HN
hnAt-Nx
A
XN>
H,N
A , N"
~N' H
X
H H
PHOSPHATEELIMINATING ENZYME
"
H H C-C-CHj
C-C-CH3 H H,N
N.^C-C-CH,0®3
HN
H,N A
A H
Fig. 2
H
H H
OH OH
33 The
side-chain
also
very
in 5 , 6 , 7 , 8 - t e t r a h y d r o b i o p t e r i n - 5 ' - t r i p h o s p h a t e
sensitive
reactions
giving
rise
7,8-dihydropterin change
takes
(14)
0
hydrolysis,
to the f o r m a t i o n
derivatives
place
a c i d at e l e v a t e d deri vati ve
towards
of v a r i o u s
(13). A m o r e
if D - n e o p t e r i n
temperatures (Fig.
oxidation, and
6-substituted
severe
structural
is t r e a t e d w i t h
forming
is
elimination
polyphosphorous
a pyrrolo [ 1 ,2-f]pteridine
3).
OH OH
0
900
hnVvu-^
HJI'VV'
|
M
1
W^H-^U*
W
n
n
D - NEOPTERIN
Fig. In a n a l o g y
to t r a n s f o r m a t i o n s
thro-biopterin to f o r m
has been
3
in the n u c l e o s i d e
treated with
in a s t e r e o s p e c i f i c
intermediary
ring
0
opening
N
HN' I I W ' V N r
H
cyclic
and acyl
H
' ' 0H 0H
CH,
*
acyloxonium-ion migration
o
/I OCOCH,
(15)
°
—
|
led to followed
H
I I n I t l V v i
°
NH
|
H
- c -CHS C CH,
4
via
nucleophilic
N
|
Ac
^H H
, ..o h
t H
H-Nli HjN n X - N 0 0®0
Fig.
by
derived
4).
" 3 — OCOCH,
lH
6-(L-threo-1'-acet-
have b e e n
(Fig.
?
N
IT
chloride
6-(L-threo-2 -acetoxy-1 ' -
treatment
amino-2'-hydroxy propyl)-pterin , which must an
L-ery-
1
reaction
chloropropyl)-pterin . Ammonia
chemistry
2-acetoxy-isobutyryl
A N 'H2h h n ^ - N ^ C - C - CH3
nhjj-4 ^ ^ N J LN }
H
OCOCHj
34 Addition cribed could
reactions
only
to u n s a t u r a t e d
incidentally.
be c o n v e r t e d
phenyl-ethyl) chiral
of c o m p o u n d s
reactivity
of
potential.
Other
found
such
type
interesting
and 6-keto
(17)
derivatives
studies
n
Y
C H j 0 H
H
des-
to
the
(Fig.
KMnOt/OHe
AcOH/HjO
SO,
80
Oj
have
syntherecent7,7-
6-carboxal-
5).
NO REACTION
OR HjO,
02-
-
new
of 6 - s u b s t i t u t e d
corresponding
3
1
regarding
a high
reactions
respectively
A S
t
been
at the
known
possessing
processes
0 H N ^ y V H ,
h n A
are
side-chain
in the a u t o x i d a t i o n
dialkyl-7 ,8-dihydropterins dehyde
also
stereochemistry
further
tic
ly b e e n
of u n k n o w n
( 1 6 ) , b u t no
the
have
6-(1 ' , 2 1 - d i h y d r o x y - 2
to t h e c o r r e s p o n d i n g
derivative
centres
side-chains
2 ,4-Diamino-6-styry1pteridine-8-oxide
H,N
XH,
•N^CH,
HN
Fig.
Results In o r d e r carbons simple and
to g a i n
reactions
benzyl
1960
that
the
information
position been
Henseke
to
treatment
the with
corresponding
can
7-bromomethyl
showing
and
Acid the
formation
about
7 of
out
and Muller
pyridine
nitrone.
phenylhydrazone
6 and
carried
1,7-dimethyl1umazine
ne-7-carboxaldehyde from
basic
at
have
groups.
in h i g h y i e l d quent
some
side-chains
have
methyl, already
brominated
derivative,
reactivity
pteridine
to m o d i f y (18)
be
the
the
ethyl, shown
in a c e t i c
which
on
normal (Fig.
led
carbonyl
6).
to
acid
subse-
p - n i t r o s o d i m e thy 1 a n i 1 i n e
hydrolysis
of
nucleus
formed
1-methyl 1umazi-
reactivity
as
seen
35
0
0
0
Fig. There
is a l s o
the
possibility
trimethyl1umazine and very
easily
oxaldehyde, inert
under
ly b a s i c
acid
medium,
the
of w h i c h
conditions
to
7-dibromomethyl
hydrolysis.
however,
gave
Reaction rise
tion with
could
formaldehyde
be g e n e r a t e d (Fig.
Fig.
7
directly
into
1,3,7the
6-
hydrolysed
1,3-dimethyl1umazine-6-carbfunction with the
by a c i d
7).
1,3,6- and
the 6 - i s o m e r
to t h e
thy11umazine-7-carbaldoxime , from which 7-carboxaldehyde
the
on b r o m i n a t i o n
derivatives,
acidic
whereas
towards
of c o n v e r t i n g
respectively
7-dibromomethyl
6
turned
o u t to
hydroxylamine
formation
of
in
be weak-
1,3-dime-
1,3-dime thy11umazinecatalysed
transoxima-
36 Analogously
the e x p e c t e d
1 ,3-dimethyllumazine hydrolysis. the
Whereas
dibromobenzoyl
l e d the
protic
higher
reactivity
was o b s e r v e d in
the case
derivative
work-up
of
of
could
of
the
reactivities
diamino-7-ethy1pteridine ferences drolysis whereas
in
showing
be i s o l a t e d
(Fig.
Fig. A comparison
also
always
latter
of
7 - (1 , 1 - d i b r o m o e t h y 1 ) - p t e r i d i n e
in c r y s t a l l i n e
to the
form
isolation
of
2 , 4 - d i a m i n o - 7 - b e n z y l - and
reveals
allows
7-benzyl-
subsequent
8
straightforward example
and
8).
bromination
the
as a s t a b l e
Fig.
9
in
dif-
and i m m e d i a t e
hy-
the former
isolation
2,4-
structural
the o b v i o u s
to 2 , 4 - d i a m i n o - 7 - b e n z o y l p t e r i d i n e the
t h e 6 - and
7-benzyl-1 ,3-dimethyl1umazine
the 6 - s i o m e r
6 - b e n z o y l - 1 , 3 - d i m e t h y l 1umazine
of
on b r o m i n a t i o n
of the
intermediate
case,
2,4-diamino(Fig.
9).
37 Direct
oxidations
different stituents. to
the
ah
alkyl
to
the
using
chemical The
benzyl
corresponding
oxy1ic
(Fig.
be
6- and
by
oxidative
the a - c a r b o n y l formation
of
illustrate and
nicely
derivatives
further
with
also
7-alkyl
oxidized
7-benzoyl
underlies
scission
permanganate
the
can
activation
in a C - C acid
of
groups 6- and
substituent
additional
finally
potassium
behaviour
in
high
sub-
yields
respectively , but t r a n s f o r m a t i o n due
function
the
the
aralkyl
resulting
corresponding
carb-
10).
CH,
KMnO T« j Levitt^ M • and Unden fr i end * S. J. Biol. 1964, 239, 2910.
Chem.,
3. Ichiyama, A., Nakamura, S., Nishizuka, Y. and Hayaishi, 0. J. Biol. Chem., 1970, 245, 1699. 4. Curtius, H.-Ch., Niederwieser, A., Viscontini, M., Otten, A., Schaub, J., Scheibenreiter, S. and Schmidt, H. Clin. Chim. Acta, 1979, 93, 251. 5. Narabayashi, H., Kondo, T., Nagatsu, T., Sugimoto, T. and Matsuura, S. Proc. Japan Acad., Ser.B, 1982, 58, 283. 6. Matsuura, S., Sugimoto, T., Murata, S., Sugawara, Y. and Iwasaki, H. J. Biochem., 1985, 98, 1341. 7. Matsuura, S., Murata, S. and Sugimoto, T. Chem. 735. 8. Matsuura, S., Murata, S. and Sugimoto, T. 1985, 23, 3115. 9. Bieri, J. H. and Viscontini, M. Helv. 1926 .
Lett.,
1984,
Heterocycles,
Chim. Acta,
1979, 60,
10. mp. 252-255 °C (dec); [a ] D 2 2 +49.63* (c = 0.524, 0.1 M HCl); pK, 1.25, 4.69, and 10.84; UV X «.ai/nm (log c ) at Hi -1.0: 262 (4.19); at pH 3.2: 264 (4.08), 300 (2.65); at pH 7.5: 260 (3.68),300 (9250); at pH 13.0: 289 (3.90);iH NMR (D 2 0) 1.25 (3H, d, J - 7.1 Hz, CHa ) , 3.60 (1H, dd, J - 14.7 and 9.0 Hz, C(7)H a x), 3.69 (1H, dd, J - 5.8 and 5.8 Hz, C(l')H), 3.73 (1H, dd, J - 14.7 and 3.4 Hz, C(7)H e q), 3.80 (1H, ddd, J - 9.0, 5.8, and 3.4 Hz, C(6)H), 3.94 (1H, dq, J - 5.8 and 7.1 Hz, C(2')H). Anal. Calcd for C 9 H i 5 N 5 0 3 • H 2 S 0 t : C, 31.86; H, 5.30; N, 20.64. Found: C, 31.62; H, 5.00; N, 20.34. 11. Oka, K., Kato, T., Sugimoto, T., Matsuura, S. and Nagatsu, T. Biochem. Biophys. Acta, 1981, 661. 12. Matsuura, S., Murata, S., Sugimoto, T., Sawada, M. and Nagatsu, T. Chem. Express, 1986, in press.
CHEMICAL SYNTHESIS AND PROPERTIES OF QUINONOID (6R)-DIHYDROBIOPTERIN
Sadao Matsuura, Shizuaki Murata, and Takashi Sugimoto Department of Chemistry, College of General Education, University, Chikusa-ku, Nagoya 464, Japan
Nagoya
Introduction Quinonoid (6R)-dihydrobiopterin catabolite
of
the enzymatic hydroxylation of living
cells,
has been assumed to
together
aromatic
amino
speculated
from
the
dimethyl analogue (1,2). thesis
and
(1).
This
In
the
recycling
ows the major responsibility
supply of the cofactor.
is such an important compound, only
acids.
with the reduction of 7,8-dihydrobiopterin by
dihydrofolate reductase, stationary
the
the catabolite (X) in turn becomes the substrate
of dihydropterin reductase to reproduce 2 system,
be
(6R)-5,6,7,8-tetrahydrobiopterin cofactor (2) in
properties
(6R)-dihydrobiopterin
the
but yet it has been
a
compound
studies on and the 6-methyl or 6,7We describe here
of
(JJ
for
Quinonoid dihydrobiopterin
hitherto and
the
the
chemical
syn-
uncharacterized quinonoid 6-methyl
and
6,7-dimethyl
analogues (7^,8).
Synthesis To
a
solution
of (6R)-tetrahydrobiopterin (2) dihydrochloride
(3) (1.26 g, 4.0 mmol) and 10% KI (64 n 1, ml),
30%
H202
( 400
ii 1,
4.0
mmol)
0.04 mmol) in HjO (10 was added at 0 • C under
stirring.
After 18 min the precipitate was collected by filtra-
tion
washed
and
with
H2O
and tetrahydrofuran to give 0.61 g
(55%) of quinonoid dihydrobiopterin (X) hydrochloride
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
as
ivory
82
needles (4)* By sin analogous wayf quinonoid 6-methyldihydropterin (7) hydrochlride (70%) and quinonoid 6,7-dimethyldihydropterin (8) hydrogen sulfate (10%) were obtained from the corresponding 5 t 6,7, 8-tetrahydropterins(5 ) . Chemical Properties The IR spectra (KBr) of the onium salts all exhibited a band at 1740-1750 cm - 1 which can be utilized as a diagnosis for the quinonoid dihydropterin structure. Although they decomposed quickly in solutions, the crystalline salts could be stored without significant decomposition at -10 *C for several months.
0 0 " S 0 Z OH
a
0
H
5
H
Scheme 1. The Transformation Paths of Quinonid (6R)-Dihydrobiopterin (¿). 0
0
7
H
8
H
83 The
quinonoid
(6J?)-dihydrobiopterin
(1_) followed several reac-
tion paths to give (6R)-tetrahydrobiopterin 7,8-dihydrobiopterin
(4),
in Scheme 1 and Table 1.
(2),
biopterin (3),
and/or 7,8-dihydropterin In a pH 6-7 phosphate
(5) as shown
buffer,
4
was
formed as the major product. The isomerization occured under almost
all the reaction conditions examined,
enhanced much by proton and phosphate ions basic
solution,
a
retro
3-4 ,
2 and
formed in equal decleased
on
In
a
more
aldol-type reaction to split off the
side chain predominatly occured giving pH
though the rate was (2a).
were the
(6).
major products.
quantities
and
their
Alternatively at Since 2
yields
and 3 were
relative
lowering the substrate concentration,
likely that a disproportionation of isomerization, produced 2 and
in
to
4
it is most
competition
to
the
3.
Table 1. Relative yields (X) of the decomposition products from quinonoid (6J?)-dihydrobiopterin (!).•> tetrahydrobiopterin(2)
pH 1.0
19
1 .0 •> ' 3.0C
7,8-dihydrobiopterin(3) biopterin(4) 22
6
7,8-dihydropterin(5)
44 9
none
85
none
41
45
10
none
6.0
8
10
66
16
11.0
3
4
18
75
HC1.
10 mM in 30 mM potassium phosphate buffer. c ' 100 mM in H 2 0 .
b
> 1 mM in 0.1M
All of these decompositions were well prevented by NaHS03, which
i formed a metastable adduct (6) across the C n - N s
with double
bond to exhibit a characteristic UV spectrum (7). Heating (5 with a large excess of NaHS03 yielded 2 and an unidentified (8) in nearly equal amounts.
compound
The adduct can be a model compound
for the primary adduct of the cofactor (2.) to O2 during the
en-
84 zyamtic hydroxylation. NADPH to
A nonenzymatic addition of hydrogen from
proceeded stereospecifically giving exclusively 2.
Quinonoid 6-methyl- (X) and analogous
isomerization
6,7-dimethyldihydropterin
into
(8)
the 7,8-dihydro isomers;
displayed a small extent disproportionation
into
did
T_ also
6-methylpterin
and its tetrahydro derivative in a pH 3-4 aqueous solution
(5).
References and Notes (1) a) Kaufman, S. J. Biol. S.J. Biol.
Chem.,
Chem.,
1964, 239,
1961, 236, 804; b) Kaufman,
332.
(2) a) Archer, M. C. and Scrimgeour, K. G. Can.
J.
Biochem.,
1970, 48, 278; b) Lazarus, R. A., DeBrosse, C.W., and Benkovic, S. J. J. Am.
Chem.
Soc.,
1982, 104, 6871.
(3) Matsuura, S., Murata, S. and Sugimoto, T. Chem.
Lett.,
1984, 26, 4003. (4) For the NMR spectrum, see: Matsuura, S., Murata, S. and Sugimoto, T.
Tetrahedron
Lett.,
1986, 27, 585.
(5) Matsuura, S., Sugimoto, T. and Murata, S. Tetrahedron
Lett.,
1985, 26, 4003. (6) iHNMR in D 2 0 : 7.03 ppm (1H, t, J = 3 Hz) and 4.17 (2H, d, J = 3 Hz). (7) A m a x at pH 3.0: 220 and 280 nm; HPLC retention time on a Partisil SCX-10
(4.5 x 250 mm) column eluted by 30 mM
ammonium phosphate, pH 3.0, containing 3 mM NaHSOs at 2.0 ml/min: 1.73 min. (8) X max at pH 3.0: 220 and 276 nm; HPLC under the same conditions as Ref.(7):
1.53 min.
PYRAZINE-RING CONFORMATIONS OF TETRAHYDROPTERINS AND QUINONOID-DIHYDROPTERINS
J. E. Gready Department of Biochemistry, University of Sydney, Sydney N.S.W. 2006, Australia
Introduction We have previously reported theoretical geometries at the SCF/STO-3G level for the neutral and ionised forms of tetrahydropterin and some quinonoid-dihydropterin tautomers
(1-3).
For the
tetrahydropterins these structures are in agreement with experimental x-ray
(4) and recent nmr (5) results in predicting a pyr-
azine-ring conformation distorted from a half-chair form such that only one ring atom
(C6) is significantly out-of-plane.
It
has been suggested that the flattened ring structure is due to the vinylogous-amide resonance which links the pyrazine and pyrimidine rings via the
C 4(04)C4aC8aN8(H8) group of atoms
However, as our related theoretical studies
(2,5).
(1-3,6) had indicated
that the presence and nature of the other ring in these pteridine derivatives influenced a number of structural and other chemical properties by complex
Ti-delocalisation
effects, we decided to
complement further investigation of this conformational behaviour with studies on tetrahydropyrazine and tetrahydropteridine.
In
this paper we have identified all possible pyrazine-ring conformers for H4pyrazine, H4pteridine and H4pterin at a higher theoretical level
(SCF/3-21G), and, for comparison purposes, those for
p-quinonoid-dihydropterin at the SCF/STO-3G level.
Methods and Results The conformer search and geometry calculations were performed with the GAUSSIAN-80 and GAUSSIAN-82 programs as reported previously (1,7).
As defined schematically in Figure 1 three stable half-
chair forms of H4pyrazine, two flattened conformers
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
(C6 out-of-
86
Figure 1. Structures for the three half-chair forms of H4pyrazine (a,b,c = H-C 1,2&3), and the two flattened conformers for H4pterin (d,e 5 1C6 S 2C6) and p-q-dihydropterin (f,g ï 1C7 &2C7). U, D and P denote whether the H5, C6, C7 and H8 atoms (or H4pyrazine equivalents) are up, down or within the general molecular plane.
Figure 2. ST0-3G geometries for the two conformers of p-q-dihydropterin shown in Figure 1. The angle sums around N8 are shown in brackets.
plane) for both H4pteridine and H4pterin, and two flattened conformers
(C7 out-of-plane) of p-q-dihydropterin were identified.
In Figures 2 and 3 the corresponding geometries are reported, including, in Figure 3, geometries for the tetrahydro forms in which the pyrazine-ring heavy-atom structure has been restricted to be planar.
These planar forms have been studied in order to
isolate "intrinsic" differences in ring-bond lengths, especially for C - N bonds, which we have previously shown
(7,8) depend on
the overall molecular topology and atom connectivity of these TT-W-bicyclic systems, from local conformational effects. In
87
Figure 3. 3-21G geometries for the planar (a), H-C 1,2,&3 (b,c,d) forms of H4pyrazine, and the planar and flattened conformers for H4pteridine (e,g,h) and H4pterin (f,i,j). The sum of the angles around the N5 and N8 atoms (and H4pyrazine equivalents) for the non-planar forms are shown in brackets.
T a b l e 1 the d e v i a t i o n s are s u m m a r i s e d .
(in 8) of the ring atoms
D e t a i l e d d i s c u s s i o n of the
from
planarity
conformational
88 a ,b
Table 1. Deviations(in 8) of Atoms from the Molecular Plane. H8 N8 H7 H7' H6 C7 H61 H5 C6 N5
0.35 1.43 0.03 -0.35 -1.43 -0.03 0.01 -0.36 0.07 -0.63 0.37 1.44 0.11 -0.37 -1.44 -0.11 -0.07 0.63 H-C 2 H-C 3 -0.04 0.30 0.24 1.30 -0.10 -0.51 -1.57 -0.29 -0.12 0.58
H4pyrazine H-C 1 -0.01 0.36
2C6
0.25 -0.22 -1.27 0.19 0.01 -0.01 0.03 -0.73 0.54 1.60 0.36 -0.14 -1.19 0.33 0.01 0.00
1C6
0.01 0.18 0.60
2C6
0.09 -0.74 0.70
H4pteridine 1C6
H4pterin
0.00 0.05 0.,49 1.56
p-q-H2pterin 1C7
0.04
2C7
0.07
1.67 0.43 -0.10 -1.14 0..35 0.03 0.07 1.75 0..62 0.03 -0.98 0..58 0.03 0.05
0..07 1.11 -0.,45 -0.57 -1.65 -0..36 0..05 -0.26 0..11 1.16 -0..40 -0.52 -1.60 -0..33 0..02 0.98
a Defined1 by C4a,C8a and the pyrimidine ring, or C1,C2 and the mid-point of H1&H2 for H4pyrazine. b Equivalent atom labelling for H4pyrazine as in Fig. 1.
energetics and H-H interactions will be given elsewhere:
here we
merely report that the SCF/3-21G energies for the non-planar conformers of H4pyrazine, H4pteridine and H4pterin are all approximately the same with the planar forms 7-9 kcal/mole less stable.
Discussion and Conclusions Focussing attention particularly on the C8a-N8 and C4a-N5 bond lengths as well as the angle sums around N8 and N5 as a measure of N-atom planarity we observe that: 1. The "intrinsic" tendency for a shorter bond length (la greater IT -electron délocalisation) for the C8a-N8 bond than for the C4a-N5 bond is present in the planar forms of both H4pteridine and (to an increased extent) H4pterin.
The C8a-N8 bonds, in
particular, are much shorter than for planar H4pyrazine. 2. For non-planar H4pteridine and H4pterin a possible four halfchair forms predicted on the basis of the H4pyrazine results have "collapsed" into only two forms in which the N8 environment is effectively planar and only the C6 heavy-atom is significantly out of the molecular plane.
This flattened ring
structure is thus not specifically due to the presence of the vinylogous-amide group in H4pterin.
N8 is more planar in these
89 3-21G geometries than in the previously reported
(1,3) ST0-3G
ones because of the improved representation of w-delocalisation effects by the larger basis set (6,7). 3. In agreement with earlier findings (1,3) the structures for the two non-planar conformers of p-q-dihydropterin are effectively non-aromatic, exhibiting little if any shortening of the C8a-N8 bond and no tendency towards planarity of N8.
The fact
that C7 is the heavy atom out-of-plane may be rationalised by assuming some residual TT -délocalisation preference for keeping N5 planar (and hence keeping the C4a-N5 double bond in plane) rather than N8. We conclude that the conformational complexity in these systems may be explained in terms of two competing energetic factors, H-H steric repulsions and stabilising délocalisation effects.
ir-electron inter-ring
The importance of this latter factor
m
imposing a flattened pyrazine-ring structure on H4pterin should apply also to most of the natural tetrahydrofolate cofactors.
Acknowledgement This research was supported by grants from NH&MRC and the Sydney Cancer Research Fund, and computing time from TAFENET(Sydney).
References 1. Gready, J. E.
1984. J.Mol.Struct.: THEOCHEM 109, 231.
2. Gready, J. E.
1985. J.Comput.Chem. 6, 377.
3. Gready, J. E.
1985. J.Am.Chem.Soc. 107, 6689.
4. Prewo, R., J. H. Bieri, S. N. Ganguly, M. Viscontini. Helv.Chim.Acta 6^5, 1094 and references therein. 5. Williams, T. C. and C. B. Storm. Int.J.Quant.Chem.
1982.
1985. Biochem. 24, 458.
6. Gready,
J. E.:
(in press)
7. Gready,
J. E. 1985.
J-Mol.Struct.: THEOCHEM 124, 1.
8. Gready,
J. E. 1984.
J.Comput.Chem. 5, 411.
HYDROGENATION OF SILYLATED PTERINS IN BENZENE SOLUTION
P.H. Boyle, M.J.Kelly University Chemical Laboratory, Trinity College, Dublin 2, Ireland
Introduction Reduction of the pyrazine ring of pteridines has been achieved using a variety of reducing agents, and the reaction is of great importance because it is in their reduced forms that naturally occurring pteridines such as folic acid or biopterin are biologically active. Because of the highly insoluble nature of most pteridines, catalytic reduction with hydrogen has usually had to be carried out in highly polar solvents such as aqueous acid or trifluoroacetic acid. This, however, has precluded the use of modern chiral hydrogénation catalysts, which are mostly used in organic solvents. We therefore investigated the hydrogénation of some model pteridine compounds in benzene solution by solubilising them as their trimethylsilyl derivatives. As well as achieving their reduction in organic solution, we also observed a novel de-silylation reaction of silylated pteridines, arising from their interaction in benzene solution with a soluble ligandcoordinated rhodium catalyst.
Results When a suspension of 6,7-dimethylpterin (_1) in benzene at room temperature was stirred in an atmosphere of hydrogen with a platinum catalyst, no absorption of hydrogen occurred. Neither was any reaction observed when a solution of its di-trimethylsilyl derivative (2) in dry benzene was stirred under hydrogen with the same catalyst. However, if benzene saturated with water was added slowly to this latter reaction mixture, absorption of hydrogen began immediately (see scheme 1), and a good yield of 6, 7-dimethy 1-5, 6 , 7, 8-tetrahydropterin (_3) separated
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
92 from
solution.
This
product was identical
with the
obtained by hydrogénation of 6,7-dimethylpterin oxide
in
spectrum groups
trifluoroacetic
acid solution
product
(1),over platinum,
(1),
and
its
p.m.r.
showed a cis disposition of the 6- and 7- methyl (2,3).
OSi (CH 3 ) 3
V r
N
Si (CH 3'3
Pt/H2
Pt/H2
HN H2N 1
9
CgHg+ H2O
H
/CH3 13)
N
H
N x
-
^ CH,
(Scheme 1
It
appears that
catalytic reduction of the pyrazine ring in
is inhibited by the adjacent bulky 4-trimethylsiloxy that
the
this
interfering group
derivative, would
group,
role of water in promoting hydrogénation is to by selective hydrolysis.
(2) and
remove
The monosilyl
6,7-dimethy1-2-trimethyIsilylamino-4-pteridinone,
thus be the species actually undergoing reduction.
Evidence
supporting
this idea was obtained
monosilylated compound, pteridinone
(i_) ,
by
preparing
the
3,6,7-trimethyl-2-trimethylsilylamino-4-
and hydrogenating it over a platinum catalyst.
Absorption of hydrogen occurred immediately without the necessity for the addition of any water
(equation 1).
93
C H
3 N ^ Y
N
Y
C H 3
R / H 2 i n
H N - ^ N ^ N ^ C H , I
C
C H
r
3 N ^ V N > Z h
6H6
3
K
Si (CH 3 )3 14) (Equation 1)
An
unusual
hydrogenate
reaction was discovered when an attempt was made
to
the
solution
in
No absorption
of
disilylated. pterin
(2^ in benzene
presence of the soluble catalyst Rh(DIOP)Cl. hydrogen
occurred.
conditions,
Instead,
6,7-dimethylpterin
even under rigorously
anhydrous
(jj was slowly precipitated from
solution in almost quantitative yield
(equation 2).
OSi (CH 3 ) 3
0
-CH3
R h l D l O P ) CI ^
H N ' ^ N ^
0
"
C6H6
12)
11) (Equation 2)
Control
experiments
occurred well
showed
that
in the complete absence
as
in
the
this
de-silylation
of water,
presence of hydrogen,
reaction
in the absence
of
Rh(DIOP)Cl.
The
reaction was markedly faster if thiophene was first added to
the
catalyst
catalyst solution. ution
with
silylation
contrary silylated
in benzene with thiophene alone,
free DIOP.
These results suggest that
is not caused by water hydrolysis,
the catalyst reaction),
with
De-silylation did not occur in benzene sol-
without catalyst,
benzene
as well as
the
as
use
[Rh (COD)DIOP] + C10 4 ~
and with
(since
the
the de-
by chloride
perchlorate catalyst
or by free DIOP in the catalyst.
also
gives
and
the catalyst,
from the
They suggest on the
that the reaction is caused by interaction between pterin
or in
and furthermore,
the
that the
94 catalyst
is
most
thiophene). transfer
A
active mechanism
in its is
monomeric
proposed
in
form
(effect
scheme
of an "unactivated" hydrogen atom from a
2
silyl
methyl
group to the rhodium atom of the soluble catalyst.
H-CH2
cr R/h ^ g V S i ( C H )
3 2
S
n^VnYCH3 3
HNVr
CH3 +
DIOP \ / Rh
H N ^ N ^ N ^ C H 1
Si (CH 3 ) 3
S = Solvent
/ \
S
CI
Scheme 2
ABBREVIATIONS DIOP
=
2,3-0-isopropylidene-2,3-dihydroxy-1,4-bis(diphenylphosphino)butane
COD
=
1,5-cyclooctadiene
REFERENCES 1.
Viscontini, M. and J. Bieri. 1972. Helv.Chim.Acta
2.
Armarego, W.L.F. and H. Schou. 1977. J. Chem. Soc., Perkin Trans. 1, 2529
3.
Weber, R. and M. Viscontini. 1976. Helv.Chim.Acta
of
showing
55,21
59,2379
N(5)-ALKYLATION OF POLYACEIYLATED 5,6,7,8-TETRAHYDROPTERINS
S. Antoulas Zentrale Forschungseinheiten, F. Hoffmann-La Roche Inc. CH - 4002 Basle M. Viscontini Organisch Chemisches Institut, Universitaet Zuerich-Irchel CH - 8057 Zuerich
Introduction The diastereomeric mixture of 6 a - and 6 P -tetraacetyl-tetrahydro-D-neopterin (D-l)^
gave
under
hexaacetylated
drastic
derivatives
acetylation
a mixture
of
conditions 6a-
besides
N,2-N,8-heptaacetyl-5-ethyl-5,6,7,8-tetrahydro-D-neopterin 0
H
A JL
OAcOAc -CH 2 0Ac
"
*=20' p>,ridin
penta-
and
and 6 p -1'-0,2 1 -0,3'-0,4-0,2(D-2) (Scheme X).
OAc ^ OAcOAc ^ N y f - C -CH 2 0AC
1 1/2 h reflux
A A
Ac-N^N t^VH ! ' H Ac Ac 6(a+p)-D-2
HN-^-N-^N^TH 1 u H Ac H 6{a + p)-D-1
"
Scheme 1 The 1
structure
of
the (3 -diastereoisomer
6 p-D-2 has been established by
H-NMR, MS and X-ray diffraction analysis [1].
Mechanistic Considerations Ethanol, which was used during work up, can be excluded as a possible source of alkylation. In a control experiment using C^J^CD no deuterium incorporation was observed.
The terms and are used according to IUPAC rules for the nomenclature of steroids as proposed by M. Viscontini [2].
Chemistry and Biology of Reridines 1986 © 1986 VVaiter de Gruyter & Co., Berlin • New York - Printed in Germany
96 A careful examination of the reaction mixture (before and after work up) by 2) TLC revealed, that oxidised products were formed as well As a result of these observations, two reaction mechanisms, based on the property of reduced pterins to act as hydride donors [3], are proposed. Proposed rrechanism 1
H
e-
TIT ¥ N^R
1nr
^
y
0—C-OI® I 1
XiT
- H
Ac
Ac
Ac
•2 H®
-H20
CH,
Ox. Pterin H®
E»
Red. Pterin
0 Ç* nÀ^NV^-R ( AC>7 N
(Ac)2N^N
N
CHjCO
iH3 AcO *CH
H H
(AcljN
jnrr
Red. Pterin
Ox. H® Pterin
Ac
^
Scheme 2 Intermolecular redox reaction with participation of the amide function of the pyrimidine ring
2)
All reactions were carried out under nitrogen, oxidation by air can therefore be excluded.
97 Proposed mechanism 2
• H® - CH3COOH
CH,
CH3
H-FVoAC
IT
®Ç VOAc -N^-^OAc
OAc H
Ox. Pterin Red. Pterin
J
-N' Ac
CH 3 CO®
ÇH3
tr H-C*
Red. Pterin
-Ox. hPPtecki
C,H, 2n5
X»T 1
Ac
Ac
6 ( a •*• P l - D - 2
Scheme 3 Intermolecular redox reaction with participation of the side chain of the octaacetyl-tetrahydro-D-neopterin
The intramolecular ringformation depicted in Scheme 3 is arbitrarily shewn with participation of the acetyl group at C(3'). A participation of the acetyl groups at C(2*) or C(l') cannot be excluded.
98 Control Experiments and Conclusions Acetyl-tetrahydropterin, which does not possess a side chain, undergoes no alkylation under the same acetylation conditions. Therefore irechanism 1 would appear unlikely for the ethylation of D-l. Preliminary experiments dealing with the behaviour of (6 a + P )-triacetyltetrahydro-L-biopterin under drastic acetylation conditions indicate, according to masspectroscopic analyses, that a 5-ethyl-hexaacetyl-derivate of tetrahydro-L-biopterin is formed. These findings are compatible with a mechanism 2 like reaction, in which acetyl group C(2') or C(l') is participating in the manner indicated in Scheme 3. Further experiments are necessary for a definite elucidation of this reaction mechanism.
Acknowledgement s The authors wish to thank Prof. Dr. H.J. Hansen and Drs. M. Schmid and R. Schmid for helpful discussions, Drs. G. Englert and W. Arnold for the NMR spectra, Dr. W. Vetter and Mr. W. Meister for MS measurements and F. Hoffmann-La Roche Inc. (Basle) for financial support.
References [1] S. Antoulas, R. Prewo, J. Bieri & M. Viscontini, Helv. Chim. Acta 69, 210 (1986) [2] S.N. Ganguly & M. Viscontini, Helv. Chim. Acta 67, 166 (1984) M. Viscontini. 1985. In: Biological and Clinical Aspects of Pteridines (W. Wachter, H.Ch. Curtius, W. Pfleiderer, eds.). Walter de Gruyter & Co., Berlin, New York, p. 57 [3] F. Stierli, J. Bieri & M. Viscontini, Chimia 38, 429 (1984)
OXIDATIONS PHOTOSENSITIZED BY PTERINS AND DIAMINOPTERIDINES
M. Aubailly, R. Santus Laboratoire de Physico-Chimie de l'Adaptation Biologique U.A. CNRS n° 481, Muséum National d'Histoire Naturelle 43, rue Cuvier, 75231, Paris Cédex, France.
Introduct ion In
some
animals, pterins are concentrated in areas
light (skin, tegument) or in gland).
This
to
led us to investigate the photochemical properties
of these derivatives. diated in
exposed
light sensitive organs (eye, pineal
Some time ago,
we showed that, when irra-
its first absorption band,
2-amino-4-pteridinone
sensitize the oxidation of amino acids and purine bases,
can
via the
usual type I and type II mechanisms (1). The aim of this paper is to
present both new data and a comparative study of pterins
their analogs, the 2,4-diaminopteridine derivatives
and
(R-DAP).
Results 1)
oxidations by the triplet excited state (Type I photosensiti-
zat ion ) . According to this mechanism, between
there is a direct electron transfer
the substrate and the sensitizer in its triplet
excited
state
(2). In a first time, the characteristics of the triplet 3 * state ( P ) must be studied. This has been done using laser flash spectroscopy (the experimental set-up and method for the determi-
nation
of
described DAP),
a
the triplet state characteristics have ( 1 )J .
already
2,4-Diamino-6-pteridinecarboxaldehyde
(6-CH0-
methotrexate photoproduct (3) was chosen as a model
2,4-diaminopteridine
derivative.
Fig.l
shows
the
absorption
spectrum of the triplet state observed 0.2
the
flash.
laser
substrate
been
cation
laser flash.
The
pteridine
radical MeTRP'
The lifetime of the
+
anion are
after the
observed 16 ys after
the
state is
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
P"
ys and
triplet
radical
of
transient
reduced
as
100
Fig. 1 Transient
absorption
measured 16
0.2 ps (
spectra
— ) and-
ys(-o- ) after the laser
flash ( 353 nm excitation)
0.10 .
(6-CHO-DAP) = 1.5 10
M
(1-Me-Tryptophan) = 5 10 pH = 7 (10~
2
M phosphate
argon saturated
0l05
400
500 M nm )
M buffer)
solution.
600
compared with the absence of oxidizable substrate. This data provides
evidence for the type I
experiments
have
characteristics
photosensitized
oxidation.
enabled us to obtain results of Table of
the pterin triplet state (1) are
Such
1.
The
given
for
comparison. Table 1 : Triplet State Characteristics of 6-CHO-DAP and Pterin T 1.5
= triplet state lifetime (ground state concentration = -4 x 10 M), $ = triplet state production quantum yield.
= X
6-CHO-DAP
Max
(nm)
:
e
Max
(M
X
cm
1
)
: T t (ys)
:
415
:
11 000
:
3.4
: 0 60
pterin
:
550
:
2 000
:
2.3
: 0 23
(pH = 9.2)
:
350
:
4 700
(pH = 7)
101 2)
Oxidations involving singlet oxygen (Type II
photosensitiza-
tion ) . In
this mechanism the oxidant is singlet oxygen "^C^ .
duced
by
energy transfer between ground state
It is pro-
oxygen
and
the
sensitizer in its triplet excited state (2). Histidine is readily oxidized shown
by
^0-,- Using this amino acid as a 1
that
substrate
pterins and 2,4-diaminopteridines can give
they are U.V.
irradiated.
we have
1
This is a common feature of
when unconju-
gated pteridines only (Table.2). Methotrexate and triamterene are not photosensitizers. Table
2.
Photooxidation
Presence
of
Pterins
Sensitizers. saturated
or
Irradiation
solutions,
Quantum
Yield
of
Histidine
2,4-Diaminopteridines wavelength 10
PH
2
\ = 366 nm,
M
phosphate
in
the
(R-DAP)
as
oxygen buffer
(Histidine) = 5 10~ 4 M. 6-CHO
6-COOH
6-CH 2 OH 6,7di-i-Pr methotrexate:triamterene
DAP
DAP
DAP
DAP
0 .050
0.035
0.019
0 .035
1 OI O S-
O
V)
o >-.| í/) 00
o m
cu > o>
M UJ CD O — O i t < 1— oo Lü < I— _i < o. O Lü z Z o 1 O h- z Lü c OC 1 O X «t LÜ s : a: * o 00 z hz: •z. t « Lü — hz o C¿
«3 u 23 o
Oc CO (O O) •r- ^ S- +J +J c O l-H u CL E a. 00 a> c o co c •o a ra cu q- s- c o 4-> E m o J- X O ai
CSJ
IT)
- L U X hO O. a: JJ • f a >- -w >-1 O l X HE"-» » • M ( O O l « O S -M vo Z a » e t o
•» +
L T ) O O
o i r > ro
+
« s vo *—
o r » +
w
+
i / ) O) t. +
c
< / l a > L.
ut o > l O
•
00 C M
•w
O ID 00 C M V —
o C M
m r-.
L T > L f ) m
o
CD
o a>
C M O C M
—
C
C M
•
O z HC M «— Zz < —" X cc OL U l / > h> •C L . Z >—« 1 Û C OL k J hco a. z 1 M
» 4) un U-—• o O« C i / i z o> c a. a > oi — t. 1 Û£ OL U E ' O 3 L U hz a. « O i— • M C < 9 t - ¿Z a i -m 1 / 1 o » a > i o X c • r -< —o T3 O J • < - .o a. i - i - i a > o i lA •m . e a. r r— o. a. oc L O 0) 4 » o ( / I r a »— o -O o N. c e n o O. z
o r > » o
O Oí
o < x > < N J C M
o C M
1 / 1
a J Î.
L f > c r .
c
en
C M
< T >
en
•
o 00
o\
,—
V I 0)
r s . C M
+
c o m o m
• M < / > «/» T J f T J < O — C» — p W. O . Û O O o Cl c c 3 o o < / > s Z
o
O r-.
00 i T )
« o E E < T J o> z l i .
m E E r o a» z u. « 4 -« O + • M C
en ifí
Q. o • f + J c v i 4 > < / > c« — u .O 0) o Q. C 3 O oo E
>—
^ ' — N E • — >• — 3 Z" O Q- " O Q£ X a > O E » E a » r3 C E • r -i —\ " O" O en 0) O Q. Z —'
438 fluoresceins by V i s c o n t i n i et a l . (_1£,
). In Comamonas s p . , L-monapterin was r e -
ported to be a cofactor involved in the oxygen-dependent hydroxylation of phenylalanine (J_2). Although Gene M. Brown reported an enzyme-dependent epimerization of dihydroneopterin triphosphate to dihydromonapterin triphosphate in E. c o l i ("D-erythro-dihydroneopterin triphosphate 2 ' - e p i m e r a s e " ) , the biochemical
func-
tion of L-monapterin in E. c o l i remained unknown (J_3). D-erythro-Neopterin, L-monapterin and L-monapterin 2 ' 3 ' - c y c l i c phosphate were i d e n t i f i e d in S e r r a t i a indica as products from GTP; however, an pteridine triphosphate from the enzymatic reaction of i s o l a t e d S. indica GTP-CH, which was also found, was reported to be different from D-erythro-dihydroneopterin triphosphate ( U K
and the question
a r i s e s as to whether i t could be L-dihydromonapterin triphosphate. The reduced form of L-monapterin was only found to be active as a cofactor of phenylalanine hydroxylase in rat l i v e r (14). In human or animal c e l l s , however, we know almost nothing about the biosynthesis and the biochemical role of the L-threo-neopterin
(L-monapterin).
In our i n v e s t i g a t i o n s on human blood c e l l s and body f l u i d s , we have demonstrated the simultaneous occurence of neopterin and monapterin as well as t h e i r nearly constant r a t i o in the p a r t i c u l a r compartment investigated (see Table 2 ) . Analogous f i n d i n g s were obtained in patients s u f f e r i n g from malignant diseases (tumor, leukemias): a l t e r a t i o n s in neopterin were accompanied in most cases by analogous a l t e r a t i o n s in the monapterin l e v e l s before and during treatment with c y t o s t a t i c s and/or a n t i b i o t i c s
(15-18).
Proglicem, which affects the b e t a - c e l l s in the human pancreas and induces hyperglykemia, caused a s i g n i f i c a n t decrease in both pterins in the peripheral
leuko-
cyte f r a c t i o n , the plasma and the urine (19). The c h a r a c t e r i s t i c l e v e l s and r a t i o s of neopterin and monapterin in human c e l l s and body f l u i d s ( i n healthy adults) are summarized in Table 2. The important f i n d i n g s are as f o l l o w s : - Neopterin and monapterin seem to have nearly constant r a t i o s in a l l
compart-
ments ; - Neopterin was found in higher concentrations than monapterin in a l l the cases investigated; - The lowest concentration of monapterin in r e l a t i o n to neopterin was observed in the urine (N/M, approx. 10). In other body f l u i d s (plasma, CSF) and in the peripheral erythrocytes, the r a t i o (N/M) was about 6. In c o n t r a s t , c e l l s which probably have a marked pterin metabolism (eg. bone marrow, peripheral
lympho-
cytes and granulocytes) demonstrated r e l a t i v e l y high concentrations of monapterin (N/M, approximately 3).
439
Table Z .
PTERIDINES
IN HUMAN CELLS AND BODY
FLUIDS.
R p - H P L C a n a l y s i s of i o d i n e - o x i d i z e d (pH = t ) and d e p r o t e inized s a m p l e s (fluorescence d e t e c t i o n , e x c / e m = 3 6 0 / 4 6 0 nm). For details see "Methods and M a t e r i a l s " . NEOPTERIN (TOTAL)
MONAPTERIN (TOTAL)
RATIO V«I
ERYTHROCYTES, peripheral b l o o d (ng/ml e r y t h r o c y t e s )
2.4
0.4
6.0
RED C E L L S , bone m a r r o w (ng/ml red cells)
4.6
1.1
4.2
WHITE CELLS, peripheral blood (Lymphocytes, 51%, Monocytes, 51, Granulocytes, 40«, Others, 4%)
296
48
6.0
«
WHITE C E L L S , bone m a r r o w
620
154
4.0
LYMPHOCYTES, peripheral blood
o
1228
393
3.0
THROMBOCYTES, peripheral blood
E
37
8
4.6
315
92
3.4
>.
a
GRANULOCYTES, peripheral blood PLASMA (ng/ml
plasma)
2.8
0.4
7.0
C E R E B R O S P I N A L FLUID (pg/mg l y o p h i l i z e d CSF) *'
543
93
6.0
URINE (nmol/mmol
311
32
10.0
creatinine)
•) ' 1 mg l y o p h i l i z e d
A C S F — 100 mg cerebrospinal
fluid
(n*27).
In freshly prepared peripheral cell fractions (erythrocytes, white cell fraction) obtained from two blood donors, reduced forms of neopterin and monapterin were not detectable. The highest concentrations of reduced neopterin and monapterin were observed in the CSF of healthy individuals (see Table 3). Table
3.
REDUCED
PTERIDINES
IN
BIOLOGICAL
MATERIALS.
The v a l u e s a r e the d i f f e r e n c e s b e t w e e n the r p - H P L C a n a l y s i s of a c i d i o d i n e - o x i d i z e d s a m p l e s (total a m o u n t of p t e r i d i n e s ) a n d of n o n - o x i d i z e d s a m p l e s ( o x i d i z e d p o r t i o n of p t e r i d i n e s ) . For d e t a i l s see " M e t h o d s a n d M a t e r i a l s " . NEOPTERIN (REDUCED)
MONAPTERIN (REDUCED) %
ERYTHROCYTES , peripheral blood WHITE CELLS, peri phera1 blood PLASMA CEREBROSPINAL URINE
FLUID
...
...
...
54
54
88
86
57
70
440 Our r e s u l t s lead us to the following questions: i ) I s there a "D-erythro-dihydroneopterin triphosphate 2'-epimerase" in human c e l l s , as we suggested some years ago (V7> J8.) > and/or i i ) I s there a further GTP cyclohydrolase, the a c t i v i t y of which leads to phosphorylated dihydromonapterin (triphosphate ? , 2 ' 3 ' - c y c l i c phosphate ?) ?
Acknowledgement We are indebted to the Deutsche Forschungsgemeinschaft for f i n a n c i a l
support.
References 1. Z e i t l e r , H . - J . , B. Andondonskaja-Renz. 1986. In: Methods in Enzymology (S.P. Colowick, N.O. Kaplan, F. Chytil and D.B. McCormick, e d s . ) . Academic Press, Orlando, p. 273. 2. Z e i t l e r , H . - J . , B. Andondonskaja-Renz, G. KUther, A. Struppler. 1986. I n : Chemistry and Biology of P t e r i d i n e s ; Pteridines and F o l i c Acid Derivatives (B.A. Cooper and M. Whitehead, e d s . ) . De Gruyter, Berlin-New York, in press. 3. Huber, Ch., J.R. Batchelor, D. Fuchs, A. Hausen, A. Lang, D. Niederwieser, G. Reibnegger, P. Swetly, J. Troppmair, H. Wächter. 1984. J. Exp. Med. J 6 0 , 310. 4. Takigawa, S . , H.-Ch. C u r t i u s , U. Redweik, S. G h i s l a . 1986. Biochem. Biophys. Res. Commun. 134, 646. 5. Sh intaku, H., H.-Ch. C u r t i u s , A. Niederwieser. 1986. 5th International Workshop on Biochemical and C l i n i c a l Aspects of P t e r i d i n e s . S t . Christoph, Arlberg, A u s t r i a . 6. Fuchs, D., A. Hausen, H. Lutz, G. Reibnegger, E.R. Werner, H. Wächter. 1985. In: Biochemical and C l i n i c a l Aspects of Pteridines (H. Wächter, H.-Ch. Curt i u s and W. P f l e i d e r e r , e d s . ) . De Gruyter, Berlin-New York, p. 287. 7. Stea, B., R.M. Halpern, B.C. Halpern, R.A. Smith. 1981. C l i n . Chim. Acta JM3, 231. 8. Wächter, H., A. Hausen, K. Grassmayr. 1979. Hoppe-Seyler's Z. Phys. Chem. 360, 1957. 9. Dhondt, J . L . , J.M. Hayte, C. Noel. 1985. In: Biochemical and C l i n i c a l Aspects of Pteridines (H. Wächter, H.-Ch. Curtius and W. P f l e i d e r e r , e d s . ) . De Gruyter, Berlin-New York, p. 419. 10. V i s c o n t i n i , M., M. Pouteau-Thouvenot, R. BUhler-Moor, M. Schroeder. 1964. Helv. Chim. Acta 47, 1948. 11. V i s c o n t i n i , M., R. Provenzale. 1968. Helv. Chim. Acta 5J_, 1495. 12. Guroff, G., C.A. Strenkowski. 1966. J. B i o l . Chem. 241_, 2220.
441 13. Brown, G.M., J. Yim, Y. Suzuki, M.C. Heine, F. Foor. 1975. In: Chemistry and Biology of Pteridines (W. P f l e i d e r e r , ed.). De Gruyter, Berlin-New York, p. 219. 14. Iwai, K., M. Kobashi. 1975. I n : Chemistry and Biology of Pteridines (W. P f l e i d e r e r , e d . ) . De Gruyter, Berlin-New York, p. 341. 15. Andondonskaja-Renz, B . , H.-J. Z e i t l e r . 1984. I n : Biochemical and C l i n i c a l Aspects of Pteridines (W. P f l e i d e r e r , H. Wächter and H.-Ch. C u r t i u s , e d s . ) . De Gruyter, Berlin-New York, p. 295. 16. Andondonskaja-Renz, B . , H.-J. Z e i t l e r . 1985. In: Biochemical and C l i n i c a l Aspects of Pteridines (H. Wächter, H.-Ch. Curtius and W. P f l e i d e r e r , e d s . ) . De Gruyter, Berlin-New York, p. 559. 17. Z e i t l e r , H . - J . , B. Andondonskaja-Renz. 1984. In: Biochemical and C l i n i c a l Aspects of Pteridines (W. P f l e i d e r e r , H. Wächter and H.-Ch. C u r t i u s , e d s . ) . De Gruyter, Berlin-New York, p. 313. 18. Z e i t l e r , H . - J . , B. Andondonskaja-Renz. 1986. In: Cancer Detection and Prevention (The International Society for Preventive Oncology) (H.E. Nieburgs, e d . ) . A.R. L i s s , New York ( i n p r e s s ) . 19. Z e i t l e r , H . - J . , B. Andondonskaja-Renz. 1985. Unpublished data. 20. Oyer, P.E., S.W. Jamieson, E.B. Stinson. 1982. Heart t r a n s p l a n t . U
285.
SUMMARY PTERINS AND HUMAN ILLNESS
D. Fuchs, H. Wachter Institute for Medical Chemistry and Biochemistry University of A-6020 Innsbruck, Austria One of the major recent advances in the field of pterin gation
has
been
the
investi-
recognition that pterins are produced and
excreted during immune responses particularly associated with the activation of the cell-mediated The
observation
immunity.
that this activation of the cellular immune sy-
stem is paralleled strictly by e.g. elevated production pterin
both
in
of
neo-
vitro and in vivo has a number of useful impli-
cations in clinical chemistry. The physiological conditions
lea-
ding to neopterin production have been partly explored. Activated T-lymphocytes secrete interferon-gamma that to
induces
macrophages
produce neopterin by GTP cyclohydrolase via dihydroneopterin-
triphosphate. Whether this reduced or oxidized neopterin plays role
a
in cell-mediated immunity still remains a matter of contro-
versy and speculation. The studies were performed mainly by HPLC with tection
based
on
fluorescence
out preceding oxidative step. This procedure does dihydro-
and
de-
direct measurement of urinary neopterin with-
tetrahydroneopterin.
not
determine
Similarly the application of
radioimmunoassay for neopterin in serum is usally conducted without
oxidation
steps.
However,
techniques
involving oxidation
steps of dihydro- and tetrahydroneopterin appear to produce
com-
parable clinical results to those without such steps. In
this chapter, the diagnostic potential of neopterin assays is
illuminated on a few presented more,
the
examples
of
diseases.
Further-
dependence of reduced and oxidized forms of neopterin
in healthy subjects and in patients with diseases involving activation
of
the
cellular immune system are studied. In this con-
text, the concomitantly measured activity of and
GTP
cyclohydrolase
intracellular levels of GTP in macrophages and T-lymphocytes
appear to be of interest as this study possibly
contributes
in-
formation on the physiological role of neopterin production. Two
further reports focus on some of the most prominent clinical
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
444 applications of the neopterin assay, the monitoring of the clinical
status
of patients having received a bone marrow transplant
and the condition of individuals infected with human
immunodefi-
ciency virus. Finally,
the
content and excretion patterns of other pteridines
besides neopterin in immune competent cells was reversed
investigated
by
phase HPLC subsequent to iodine oxidation with particu-
lar emphasis to micro techniques.
SECTION D FOLATES AND PTERINS IN MAMMALIAN TISSUES
FOLATES IN TISSUES AND CELLS. SUPPORT FOR A "TWO-TIER" HYPOTHESIS OF REGULATION OF ONE-CARBON METABOLISM.
Carlos L. Krumdieck and Isao Eto Department of Nutrition Sciences, University of Alabama at Birmingham, Birmingham, AL 35294
Introduction In 1946 Pfiffner et al (1) and Angier et al (2) published in Science the first reports demonstrating the existence of polyglutamyl peptide derivatives of folic acid.
Two years later, the
exact configuration of the peptide chain was determined by comparison to synthetic isomeric peptides (3).
The year of 1986
marks, therefore, the fortieth anniversary of the discovery of the poly-y-glutamates of folic acid.
I will take this occasion to
focus my remarks on these, the true naturally occurring folates in tissues and cells. For many years, we (4-6) and others (7-10) have investigated the hypothesis that changes in the length of the polyglutamyl chain serve as an element of regulation of one-carbon metabolism.
The
strongest evidence supporting this view comes from in vitro work by a number of investigators demonstrating that the kinetic parameters for folyl polyglutamate substrates and inhibitors (516), and even the mechanisms of catalysis of folate-requiring enzymes (8) are, in most cases, dramatically altered by changes in the length of the polyglutamyl chain.
In addition, it has been
shown that pteroyl-polyglutamates are preferentially "channeled" through two multifunctional proteins of folate metabolism (17,18) and possibly also between enzymes involved in de novo purine biosynthesis (19).
Since channeling is thought to be kinetically
advantageous, the one-carbon flux through these reactions could be modulated by altering the chain length of the polyglutamates.
A
mechanism for the regulation of the activity of folate-requiring enzymes based on covalent modification of their cofactors (and/or inhibitors) by addition or deletion of Y-glutamyl residues (5) seems, therefore, a likely possibility.
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
448 The in vitro demonstration that the catalytic efficiency of folate-dependent enzymes is affected by the chain length of the cofactors is a necessary, but insufficient, condition to validate the regulation hypothesis.
It is necessary also to demonstrate
that changes in the chain length distribution of the folates occur in vivo in response to alterations in the steady state of onecarbon metabolism.
Considerable difficulty has been encountered
to demonstrate this, primarily because of limitations of the analytical methods.
I will briefly review some recent advances in
methodology, and new evidence supporting the regulation hypothesis, and offer in the end a possible explanation for why the folate-requiring enzyme systems, which respond to classical regulatory mechanisms, would have to be subjected to yet another, seemingly redundant, regulatory system.
Analytical methods No single method has yet been devised that is applicable to the determination of all known naturally occurring pteroyl mono and polyglutamates (20,21).
Some remarkably successful efforts
combining ion exchange chromatography, gel permeation and differential microbiological assays before and after conjugase treatment, resulted in the quantitation and chain length determination of many of the one-carbon substituted and unsubstituted, reduced and oxidized, folates of a limited number of biological samples (20).
These methods are however so laborious and time consuming
and so subject to the drawbacks of microbiological assays, that they have been essentially abandoned
in favor of simpler, though
often less informative, procedures. Most, if not all, modern methodologies resort to analytical approaches that limit the complexity of the family of natural folates.
The most often used approach has been to cleave the C 9 -
N^g bond converting the folyl polyglutamates (PteGlu n ) to a far simpler homologous series of p-aminobenzoyl polyglutamates (pABGlu n ) easily resolved and identified by co-chromatography with authentic synthetic markers.
The drawbacks of earlier oxidative
and reductive cleavage procedures (20), which failed to cleave several of the naturally occurring folates, partially degraded the
449
pABGlu n , and introduced errors in quantitation due to the presence of uncleaved [31,5',7,9(n)-^H] folates contaminating fractions presumed to contain only 3',5' labeled pABGlu n , were recognized by Maruyama et al (22) and by Lewis and Rowe (23). Newer cleavage procedures (24-28) have resolved the above difficulties by combining oxidative and reductive treatments and by increasing the sensitivity of the pABGlun quantitation methods by forming azo dyes (24) or by post-column fluorescamine derivation (27).
This eliminated the need for radiolabeling the folates of
the sample and permitted the analysis of "endogenous" patterns. Although much valuable knowledge has been gained by the application of Cg-N^o cleavage procedures, it is obvious that this approach sacrifices all information relative to the one-carbon substituents.
In an effort to recover some of this information,
we have taken advantage of the different susceptibility to oxidative cleavage of the various reduced, one-carbon substituted and unsubstituted folates to develop a "differential cleavage" procedure that permits the quantitation and determination of chain length of three pools of the folates (29-32).
Pool 1 contains
dihydro and tetrahydro pteroyl polyglutamates
(H2PteGlun,
H 4 PteGlu n ) plus 5,10-methylene-tetrahydro folates (5,IO-CH2-H4PteGlun); pool 2 is made up solely of 5-methyl-tetrahydro folates (S-CHj-H^-PteGlUjj), and pool 3 includes all reduced folates with substituents at the formyl oxidation level: 5,10-methenyl- (5,10CH=H 4 -PteGlu n ), 5 and 10 formyl- (5 and 10-CHO-H4-PteGlun) and 5formimino-tetrahydro folates (5-CH=NH-H4~PteGlun).
Conditions
that selectively cleave the folates of pool 1, of pools 1 + 2 , and of all three pools 1 + 2 + 3 ,
have been found.
The pABGlu n , after
formation of their azo-dye derivatives (Azo-pABGlun) by the Bratton-Marshall procedure (24) are pre-purified on a polyacrylamide column, concentrated by the use of a disposable octadecylsilane column and separated by reversed phase HPLC (33).
An
important refinement of this methodology has been the synthesis of two internal standards, Azo-p-aminobenzoyl-a-glutamyl-Y-glutamylglutamic acid and Azo-p-aminobenzoyl-a-glutamylglutamic acid, which have the same molar extinction coefficient as the AzopABGlun derived from natural folylpolyglutamates, and are readily separated from them by the HPLC column.
Inclusion of these
450 compounds improves the quantitation and facilitates the identification of sample-derived Azo-pABGlun (33). The most promising new methodology is that introduced by Priest et al (34,35) in 1980. Their method is based on the formation of a ternary complex between 5,10-CH2"H4-PteGlun, thymidylate synthase (T.S.) and radiolabeled 5-fluoro-2-deoxy[3H]uridylate ([3H]FdUMP). The use of the enzyme T.S. as a reagent which very selectively and efficiently extracts and incorporates the 5,10-CH2"H4PteGlun of a sample into a radioactively labeled, high molecular weight, covalently linked stable complex, is central to the success of this method. Its sensitivity is extremely high and limited only by the specific radioactivity of the [ 3 H]FdUMP used. The negative charge of the ternary complex increases by one with each successive ^-glutamyl residue. This gives the complexes of the various polyglutamates different electrophoretic mobilities which are a linear function of the number of glutamyl residues. If the experimenter is not interested in determining the length of the polyglutamyl chain, the complexes can be purified free of excess [ 3 H]FdUMP by gel permeation and the concentration of 5,10-CH2"H4PteGlun be determined by radioactivity counting. To quantitate and determine the chain length of other 1-C substituted and unsubstituted pools, Priest and his collaborators have developed enzymatic procedures that convert specific folate pools to 5,10-CH2"H4-PteGlun. Figure 1 summarizes the principles employed. In most cases a complexation step with non-radioactive FdUMP, designed to remove the endogenous pool of 5,10-CH2"H4PteGlun, is inserted prior to conversion of the pool to be quantitated into the T.S.-reactive 5,10-CH2"H4PteGlun. The direct estimation of H4PteGlun is obtained by the inclusion of formaldehyde (35) as shown in Figure 1. Adding formaldehyde to the nonradioactive complexation mixture removes both endogenous 5,10-CH2~ H4"PteGlun and H4"PteGlun, setting the stage for the determination of 5-CH3-H4"Pte-Glun after its methylene reductase-mediated oxidation to 5,10-CH2"H4-PteGlun in the presence of menadione (36). Dihydrofolates and fully oxidized PteGlun can be independently determined by converting them to H4"PteGlun with dihydrofolic reductase. At low reductase levels H2~PteGlun, the preferred substrate, is quantitatively converted to H4~PteGlun with little
451
Ternary Complex Assay: Principle * FdUMP T.S. Non-radioactive complexation removes: X=H 4 X=5,10-CH2 - H < X=5,10-CH 2 - H 4 *
Tissue folates: X
H C H 0
[ 3 H] FdUMP
V/
>/
y/
s/
V/
N/
Thymidylate Synthase (T.S.)
V/
V/
V
s/
s/
Y
X/
V
V
s/
s/
IO-CHO de-acylase
1 DHFR
H CHO
methylene H 4 reductase * menadione
enzyme RADIOACTIVE ternary complex with X -
5-CH3-H
5,10-CH 2 -H 4
Separation of X - Pte Glu „
4
10-CH0-H,
H2
|DHFR
H j and PteGlu n
Electrophoresis
DetectionQuantitation
Fluorography - Densitometry
Figure 1 (For explanation see text) reduction of PteGlu n .
With high levels of dihydrofolic reductase
the fully oxidized PteGlu n also undergo reduction to H4~PteGlu n and can be quantitatively recovered (37,38).
10-formyl-tetra-
hydrofolates are determined by converting them first to H4"PteGlu n by the use of 10-formyl-tetrahydrofolate deacylase and then to the desired 5,10-CH2-H 4 -PteGlu n by formaldehyde treatment (39).
At
present, no procedures are available for quantitating separately the 5-formyl, 5-formimino and 5,10-methenyl tetrahydrofolate pools.
Because of their recent introduction, these methods have
not yet been extensively applied to the study of natural folates. There is every reason to expect, however, that they will soon become the methods of choice.
452 In-vivo changes in the chain length of the pteroylpoly-Y-glutamates in response to alterations in the steady-state of one-carbon metabolism. There can be little doubt that the requirements for one-carbon transfer reactions must differ, within the same species, from organ to organ. If changes in polyglutamyl chain length are involved in the regulation of these reactions, different patterns of chain length distribution ought to be found in different organs. Using our differential cleavage procedure, we have studied the chain length patterns of total folates in the major organs of the rat and in the liver, kidney, testicle and brain of the Japanese quail. The results are summarized in Table 1. It is clear that pronounced differences do exist confirming and expanding earlier reports (20). The ratio of percent of folates with six and seven glutamyl residues to folates with five residues has been arbitrarily chosen to highlight the differences observed. The spleen and lungs have a predominance of hexa and hepta glutamates with significant amounts of octa detected in both organs. The small intestine presented a unique pattern with a very high proportion of monoglutamates not found in any other organ. These did not come from degraded dietary folates since fasting did not modify the pattern. They may well represent biliary monoglutamates undergoing reabsorption in the entero-hepatic cycle (40,41). It is also very unlikely that this high proportion of monoglutamates is an artifact of degradation by intestinal conjugases. The first step of our procedure inactivates the conjugases instantly by homogenization in 0.1N HC1. Significant organ to organ differences were also seen in the quail. Interspecies differences do exist together with some striking similarities as seen, for example, comparing the testicle folate patterns of the rats and birds. If these differing patterns reflect different one-carbon fluxes through the reactions that compete in the animal organism for the folates of the cell, mainly those involving 5-CH3"H4-PteGlun for the regeneration of S-adenosyl-methionine on the one hand, and 10CH0-H4-PteGlun and 5,10-CH2-H4PteGlun for purine nucleotide and thymidylate synthesis on the other, it should be possible to
453 •o
0) •P
r(0 c td Oi M 0
+ O
o
CO
rH •rH m 3 O'
00
•O c IB 4J (0 u >M 0
co 0) •p (4
e
IB +J 3 rH O" >1 rH 0 0. .H >1
(0
in rH rH
in rn
r~ CN
ro 00 CN CM
cm rCM rH
ai «—t -U-—. 1« IIIS •p f—t 3. 0 o •— MH
-l -U c 0 u
ra
-o ai MH
•
5) ± S.D.
m a i n t a i n p r o t e c t i v e l e v e l s of drug.
E v e n at these h i g h d o s e s , t h e e f f e c t s of
c a r b a m a z e p i n e a n d v a l p r o a t e a r e fairly small. a r e d i s t r i b u t i o n of folate a p p e a r s to o c c u r . i n c r e a s e a s liver levels d e c r e a s e m e n t the p a t t e r n r e v e r s e s .
(Fig. 4).
With chronic valproate
treatment
Initially brain and plasma But a f t e r s e v e r a l w e e k s of
levels treat-
498
11.010.0-
7 =-0.617 p a.
Liver
ï ' T - H
0.6-
0.4. 0.302-
c
o o
7 =-0.454 (NS)
Brain
0.1-
—I
1—
0 06 0.06-
t"T
0.040.030.02-
7=+0.077 (NS)
Plasma
0.01-
-I
1
1
1
1
1
0
1
2
3
4
6
1 6
Weeks of Chronic Phénobarbital Treatment
Figure 2. The effect of chronic phénobarbital treatment on folate concentrations. Dose of phénobarbital was 50 mg/kg. For details see Fig. 1. Folate concentration in liver declined significantly with time of chronic treatment. No significant effects were observed with respect to folate concentrations in brain or plasma. Each point represents the mean (n 5) ± S.D.
Carbamazepine does not seem to cause a folate depletion in any tissue of the rat.
Indeed, the only significant effects of chronic carbamazepine treatment
are the late increases in folate concentration in liver and plasma (Fig. 5).
Discussion There is no consistent pattern of changes in folate concentrations with chronic treatment using different anticonvulsants.
This suggests that the effect of
499
Uvar Folata • -0.682 p«0.06
Brain Folata > = 0.275 INSI
oja»»-
Plasma Folata TV, = 0.666 p< 0.06
Weeks of Treatment with Primidone
Figure 3. The effect of chronic primidone treatment on folate concentrations. Primidone was maintained in homogeneous suspension in water with constant stirring and administered at a dose of 100 mg/kg every 12 hours. Control animals were given water. Rats were sacrificed and folates determined as described in Methods. Means from all treatment groups are significantly different (p 6) ± S.D.
lowering the folate concentration is not a component of the anticonvulsant activity of antiepileptic drugs as some have suggested (15).
Indeed the time
course for the effects on folate concentrations indicates that, where significant effects are found, the effects are slow and gradual when compared to the anticonvulsant effect of the drugs.
In brain, where one would expect to first
observe effects on folate concentrations, if such effects were involved in the
500
W e e k s of Treatment with Valproate F i g u r e 4. T h e e f f e c t of c h r o n i c v a l p r o a t e t r e a t m e n t o n folate c o n c e n t r a t i o n s . V a l p r o i c a c i d w a s d i s s o l v e d in w a t e r at 250 m g / m l b y a d j u s t i n g t h e p H to 7.2 w i t h NaOH. T h i s s o l u t i o n w a s a d m i n i s t e r e d to r a t s e v e r y 8 h o u r s at a dose of 300 m g / k g as d e s c r i b e d in M e t h o d s . T h e c o n t r o l s o l u t i o n w a s 0.96 M N a C l . Rats w e r e s a c r i f i c e d a n d f o l a t e s w e r e d e t e r m i n e d as d e s c r i b e d i n M e t h o d s . Each point r e p r e s e n t s t h e m e a n ± S.D. of 6 - 1 0 a n i m a l s . * Indicates significant difference f r o m c o n t r o l (p
C C
.
D
7
k3
>
D
Equation (1) Equation (2)
where the letters represent: "A"
- non hydrolyzed folate polyglutamate in the lumen
"B"
- hydrolyzed folate polyglutamate (1), or PteGlu (2) in the lumen
"C"
- folate in the intestinal tissue
"D"
- folate transported into the blood
k1, k2, and k3 are the rate constants for these reactions. The rate constants estimated by fitting the experimental data to the theoretical equations are reported in table 2.
Table 2:
Rate Constants Estimated for Equations (1) and (2) equation (2)
equation (1) mean ± SD
1
k1
0.108 ± 0.008 min."
k2
0.046 ± 0.006 min." 1
0.048 ± 0.004 min." 1
k3
0.421 ± 0.044 min." 1
0.189 ± 0.040 min." 1
- -
The fit of the experimental data to the theoretical equations was good in both cases, as shown by the residual sum of square and by the s.d. found for the parameters.
In the case of folate polyglutamates (equation 1),
the rate of hydrolysis (k1) was twice as high as the rate of luminal disappearance of hydrolysis products (k2).
The values for k2, corresponding
to intestinal transport of monoglutamyl folate, were similar in equations (1) and (2).
The higher value for k3 of equation (1), compared to equation
(2), corresponding to blood transport, may reflect delay in the release of absorbed folic acid from the enterocyte.
582 Conclusions We report a simple and convenient method to obtain biosynthetic, purified, radiolabeled folylpolyglutamates.
These polyglutamates can be used as a
tool to study digestion, absorption, and metabolism of natural folate. Data on intestinal absorption are consistent with a model which assumes that hydrolysis to monoglutamyl derivatives precedes transport into the intestine.
Further work is needed to establish the exact location of this
intestinal hydrolysis and the origin of the operating pteroylpolyglutamate hydrolase.
References 1.
Butterworth, C.E., R. Santini and W.B. Frommeyer. 1963. The pteroyl polyglutamate components of American diets as determined by chromatographic fractionation. J.Clin.Invest. 42, 1929-1939
2.
Rose, R.C., A.M. Hoyumpa, Jr., R.H. Allen, H.M. Middleton, L.M. Henderson and I.H. Rosenberg. 1984. Transport and metabolism of water-soluble vitamins in intestine and kidney. Fed Proc, 43 (9), 2423-2429
3.
Selhub, J., 0. Ahmad and I.H. Rosenberg. 1980. Preparation and use of affinity columns with bovine milk folate-binding protein (FBP) covalently linked to sepharose 4B. Methods Enzymol., 66, 686-690
4.
Elsenhans, B., J. Selhub and I.H. Rosenberg, 1980. Assay of folylpolyglutamate hydrolase using pteroyl-labeled substrates and selective short term bacterial uptake for product determination. Methods Enzymol., 66, 663-666
5.
Selhub, J., G.M. Powell, and I.H. Rosenberg, 1984. Intestinal transport of 5-methyltetrahydrofolate. Am J. Physiol., G515-G520
SELECTIVE INHIBITION OF BACTERIAL CARBOXYPEPTIDASE G AND PANCREATIC CONJUGASE BY 2-MERCAPTOMETHYLGLUTARIC ACID
T.I. Kaiman, V.K. Nayak and A.R.V. Reddy Departments of Medicinal Chemistry and Biochemical Pharmacology State University of New York, Buffalo, New York 14260
Introduction The activity of H^folate cofactors and the therapeutic utility of a variety of cytotoxic antifolates may depend on the extent of their polyglutamylation
(1,2).
The biosynthesis and degradation
of the poly-y-glutamate chain is catalyzed by folylpolyglutamate synthetase
(FPGS) and conjugases
22.12), respectively
(2).
(y-glutamyl hydrolases, EC 3.4.
Intracellular regulation of the poly-
glutamate chain length may involve both elongation and cleavage (2,3) by FPGS and conjugases, respectively
(see Fig. 1), but the
role of cellular conjugases in this process has remained elusive. For an effective regulatory function, a likely enzyme candidate with the required hydrolytic activity is a non-lysosomal cytopla smic carboxypeptidase catalyzing the stepwise degradation of a folate polyglutamate chain.
It was of interest, therefore, to
develop selective inhibitors of carboxypeptidases specific for the cleavage of terminal glutamic acid residues.
Such inhibitors may
be useful in the identification and isolation of cytoplasmic conjugases as well as in the study of the metabolism and function of folate and antifolate polyglutamates.
ATP
GLU
+
FPGS
X-H^PTEGLU,
ADP
+
P
X-H^PTEGLU,
N
+
1
(¡¿I CONJUGASE
Figure 1.
Folate Polyglutamate Metabolism.
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
584
Results Our approach to the design of inhibitors of C-terminal glutamate specific carboxypeptidases was analogous to that of Ondetti et al. (4) in obtaining selective inhibitors of carboxypeptidase A and B, which, in turn, was based on the work of Byers and Wolfenden (5). The rationale is outlined in Fig. 2, using carboxypeptidase G (6)
FN7YMFS
/CARBOXYPEPTIDASE A /CARBOXYPEPTIDASE B \ /CARBOXYPEPTIDASE G \
S - C H 2 - C H - coo Figure 2.
Rationale for the Design of Carboxypeptidase Inhibitors.
as the model target enzyme.
Specificity of binding of the inhi-
bitor molecule is provided by the "C-terminal" carboxy group and the carboxyethyl side chain attached to the a-carbon, whereas the presence of the sulfur in the proximity of the active site Znatom provides for the necessary strength of binding for potent inhibitory activity.
The simplest molecule incorporating these
desired structural features is 2-mercaptomethylglutaric acid (MMGA) with the configuration corresponding to L-glutamate (see Fig. 2). The synthesis of D,L-MMGA was accomplished in 3 steps as outlined in Fig. 3.
Michael addition of thiobenzoic acid to 2-methylene-
glutaric acid obtained by acid hydrolysis of 2,4-dicyano-l-butene resulted in a thiolester intermediate, which was aminolyzed to get
585 the desired product in 52% overall yield.
No attempt was made to
resolve the racemic mixture. CN (CH2)2 C=CH 2 CN
H+
COOH
COOH
(CH2)2 OCH2 COOH
PHCOSH ( C H 2 ) 2 ^ HC-CH2-S-CO-Ph COOH
COOH RNH 2
(CH2)2 CH-CH2-SH COOH DA-MHGA
Fig. 3. Scheme for the Synthesis of 2-Mercaptomethylglutaric Acid (MMGA). MMGA was found to be a potent inhibitor of carboxypeptidase G^ (6).
Using folate as substrate and following its conversion to -7 (6), a K^-value of 2.3 x 10 M
pteroate spectrophotometrically was obtained.
In contrast, MMGA was a relatively weak inhibitor -4 of carboxypeptidase A (K. = 1.0 x 10 M) and carboxypeptidase B 1 -4 M) , using hippuryl-L-phenylalanine and hippurvl(K^ = 1.9 x 10 L-arginine as substrates, respectively.
The results are summar-
ized in Table 1. Table 1. Comparison of the Inhibition of Carboxypeptidases by MMGA. Enzyme
(MMGA), pM
Carboxypeptidase A
100
Carboxypeptidase B
190
Carboxypeptidase G^
0. 23
The predicted importance of the SH-group of MMGA for its inhibitory activity against carboxypeptidase G-^ was confirmed by replacement of the -CH 2 SH with a -CH^ group: 2-methylglutaric acid showed no detectable inhibitory activity at a 10,000-fold higher concentration
(3 mM) than that required for 50% inhibition (IC^Q)
by MMGA. A partially purified conjugase preparation from chicken pancreas, assayed at pH 7.2, was found to be strongly inhibited by MMGA. The hexaglutamate derivative of methotrexate
H-NP^-lO-CH^-PteGlUg)
was used as substrate and the formation of the diglutamate endproduct was quantitated by reversed phase HPLC. 6
Using 4.3 x 10
M substrate, an IC50-value of 9.3 x 10~ M was obtained for MMGA.
586
In contrast, no inhibition by 2 x 10 ^ M MMGA of partially purified lysosomal hog kidney conjugase
(7) was observed at pH 4.7.
Conclusions The results demonstrate that selective inhibition of glutamyl carboxypeptidases and yglutamyl hydrolases can be achieved.
A
prototype inhibitor, 2-mercaptomethylglutaric acid, was designed and proved to be effective in selectively interferring with the activities of these enzymes.
This type of enzyme inhibitors can
serve as useful biochemical tools and may also have potential therapeutic applications..
Acknowledgement This work was supported by grant CA 3 5212 awarded by the National Cancer Institute.
References 1.
Goldman, I.D., ed. 1985. Proceedings of the Second Workshop on Folyl and Antifolyl Polyglutamates. Praeger, New York.
2.
McGuire, J.J. and J.K. Coward. 1984. In: Folates and Pterins, Vol. 1 (R.L. Blakely and S.J. Benkovic, eds.). Wiley, New York. pp. 135-190.
3.
Whitehead, V.M. and D.S. Rosenblatt. 1985. Proc. Amer. Assoc. Cancer Res. 26, 232.
4.
Ondetti, M.A., M.E. Condon, J. Reid, E.F. Sabo, H.S. Cheung and D.W. Cushman. 1979. Biochemistry 1427.
5.
Byers, L.D. and R. Wolfenden.
6.
McCullough, J.L., B.A. Chabner and J.R. Bertino. J. Biol. Chem. 2^6, 7207.
7.
Brody, T., J.E. Watson and E.L.R. Stokstad. Biochemistry 2_1, 276 .
1973. Biochemistry 12, 2070.
1982.
1971.
SUMMARY FOLATE ABSORPTION AND TRANSPORT
I.H.
Rosenberg
Clinical
N u t r i t i o n Research
Chicago,
Illinois
transport
at this meeting
progress
Symposium.
to
review
s o r p t i o n and rent work
They project
tumor c e l l s , conceptual transport
Since
of
study:
out o f ,
approaches
1969
predominant
1)
enzymes
intestinal
we
involved
have
forms
to
known
of
in m e m b r a n e
that
in the d i e t ,
of folate
polyglutamyl
w e r e hydrolyzed
is the form which
polyglutamate
the variability
kidney, and
binding
and
is
in the
Only recently h a s the isolation and
ferent s p e c i e s explained
re-
uptake
folates,
circulation.
pteroyl
these
translocation.
folate
intestinal
cur-
technical
specific
and m o n o g l u t a m y
tion of
ab-
dietary
c e l l s as well as in
isolation
of
on three in
to
will
Many of
involved
2 ) the mechanism
7th
I
c o l l e c t i o n of
and h e p a t o c y t e s and 3 ) the evolving
proteins
the
in folate transport.
in this v o l u m e ) by focusing
folate d i g e s t i o n ; even
reflect
the current s t a t e of our u n d e r s t a n d i n g
elsewhere
areas
and
absorption
approaches
(presentations will be cited by authors.
polyglutamyl into,
events
some promising
t r a n s p o r t , based on this exciting
are published lated
on the intestinal
in the s t a t e of k n o w l e d g e since
the study of the molecular attempt
Chicago,
of f o l a t e a c r o s s m a m m a l i a n cell m e m b r a n e s
the substantial Pteridine
of
60637
The paper presented and
C e n t e r , University
intestine
released
into
from
in earlier
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
the
characteriza-
hydrolases seen
the
dif-
studies.
588 Following long
their
report
predicted
in human two
brush border
intestine,
distinct
border,
situated
from
ideally
into
human for
studies
in pig
two
important
as a model
for
from
intestinal
and chick.
PPH's have been purified
to
dietary
folate hydrolysis using
Olson,
Selhub,
lack
an
intrinsic
and Rosenberg
PPH from rat
intestine,
showed
to be the single
this
no evidence of
previously
releasing
in contrast
to
are exopeptidases. neutral
Selhub
by
gestion and
reduced
purified
identifiable
the brush
border
enzyme
enzymes
were
purified
system employing
by
use
These Selhub
immobilized
and Malec's milk
perform
for
group,
and
in the rat
with
as
enzyme
is
a
an
first
and
man
exhibited in-
Darcy-Vri11 on, casei
to
obtain
study of folate po1yg1utamates
affinity
folate binding
by
cytosolic
significantly
L.
"natural"
thus
in pig
zinc.
of
which
monkey)
This enzyme
the rat
pH optima which
dif-
and
the
this
of
absorption,
The study
monog1utamate
Interestingly,
the
by
enzyme.
fo1y1po1yg1utamates
absorption.
promise
PPH and
by
intes-
species from
characterized
pteroyl
reported
The
enzymes.
interaction of the enzyme with
and Rosenberg
biosynthetic
readily
and acidic
PPH from pig
the human and pig
brush border
further
which
this meeting
insights:
secreted
brush
intracellular
(guinea pig, dog,
a second brush border
endopeptidase,
fluenced
the other
in which
isolate
hydrolysis
The only other
appear
both
and
to
the (PPH)
in the
human studies of folate
fer
which
po1yg1utamate
recent
the true species differences the rat,
one
The d e s c r i p t i o n at
and
product,
intestine,
the enterocyte,
hydrolase
proceeded
Wang, and Halsted of a brush border
tine emphasized
identified
pteroylpo1yg1utamate
less c e r t a i n function.
Chandler,
which
C h a r l e s H a l s t e d ' s group
enzymes
precedes uptake with
in Science years ago
diwere
chromatography
proteins.
These
589 should and
help
to establish whether
biochemical
polyglutamates folates.
are
facilitated
fully
and their
greatly
and
similar
to
probes for
as
for
transport
so
and
the
m a m m a l i a n cells. testine
is
acid
the
membrane
controlled
transport
membrane
with similar
affinities for
methotrexate
(in contrast
subsequent
lumenal
reduced
isolation,
intestinal
to transport
folate
important
and
function
is now
uptake
studies
across
that
and
in 1970,
other
this
the folate uptake
into
structure-specific folates
tumor
been
cell
first
represents at
and
lines)
reported
least
three
elucidated
low-outside vs higher and
per-
single
vesicles when pH g r a d i e n t s
ionization
in-
Using
unreduced
surface which have
and
in
this
ionic gradients.
This pH dependence,
A pH gradient, in
compounds
m e m b r a n e s which
to b a c t e r i a and some
studies with membrane
in 1) changes
Some
may become
vesicles was saturable,
laboratory
rigidly controlled.
of
pH and
pH dependent.
p h e n o m e n a at the
carboxypeptidase
with and d i f f e r e n c e s from
demonstrated
brush border
results
of
The newest approach
John B l a i r ' s
Kalman,
in hydrolase enzymes
process
similarities
mit a n a l y s i s of
and strikingly
by
be
PPH's.
the
technique, we previously
hydrolysis
reported
u t i l i z e s v e s i c l e s from brush border
under
biosynthetic of
PPH.
location,
folyl-
Such s t u d i e s will
inhibitors of
pancreatic
study of
and other
clear,
reduced
that
location and species v a r i a t i o n
becoming
from
such
with selective
the further
to
physiological
unreduced
to compare rates
S-mercaptomethylglutaric
intestinal
If the
synthetic
applicable
by work
Reddy
insights from
interrelationship.
which also h a v e activity
of
of
We should now be able
and transport
Nayakj
studies
the
diffusibi1ity
by were
inside of
the
590 transported
species;
(substrate/carrier transport. of folate
2)
affinity);
vesicles
3) c h a n g e s
from
A n n Reisenauer
pig
to
and
transport
unidirectional
transport. other
vesicles
cesium and other
sistent with acids.
to
monovalent affect
the model
Studies
influx
examine
across
Na"
requirement
cations
i.e.
could
the K™ of
of folate uptake.
d a t a from
brush
vesicles from rat
new data sheds
light on
process
enterocytes
from
a
structure which
for
in
and Strum
for
the
intestine. specific,
appears
inconamino
to
the
non-
time,
exciting
saturable be
are
presented
first This
in
Na*.
a K"1" ionophore,
component
and,
folate
guanidium
of Na"* and glucose or
saturable
membranes
jejunal
observed
substitute
Said
dis-
studies
rat
lithium,
a role for monovalent c a t i o n s
border
be
transport, a finding
of cotransport
with
between
the sodium e f f e c t s of -
the
isolated
in v e s i c l e s with v a l i n o m y c i n ,
membrane
pH-dependent
reported
most consistent with
basolateral
border
This relationship
w a s not specific,
Further, Na4" did not
brush
study
transport
Z i m m e r m a n and Selhub
In these studies
preparations
this technique for jejunal
Km
coupled
in m a m m a l i a n cells and tissues will
using
border
folate-H"*
saturable,
to vesicles.
Rosenberg,
brush
transport
c h a r a c t e r i s t i c s of
cussed below. measuring
the of
used
demonstrate
of folate comparing
extent of folate binding binding
in
Three p a p e r s here employed transport.
transport
changes
exit
shared by
all
fo1ates.
The paper Utrecht cells and
by
Schornagel,
shifts our
Rijksen,
attention
emphasizes
methotrexate-resistant
that cells
de
to other, the to
lack
Gier,
and
Jansen
non epithelial of
cross
the antitumor
from
mammalial
resistance
antibiotic
of
CI-920
591 is further contrast
evidence for to
the situation
system e x p l a i n s
Donald H o m e
reported
a
affinity with
system.
Km
Pupons, in
transport
of
the
system
system which
low
affinity
important
reducing
agents.
us that folate bioavailability which
polyglutamyl
measures
folate
shown
demonstrated
liver
to
be a weak
that
study.
Rhee,
that
insight
methotrexate
is impaired by
f u n c t i o n of binding
transport.
most
Selhub, that
and proposed
Emmanouel,
in renal
an
By
Using
work
or carrier Hjelle,
intact
rat yeast
to
acid.
folic
by Zimmerman and
transfer
in
et
Burgert by
mam-
this
in folate
Caroni
provided
and
kidney
and c o n v e r s i o n of
session
proteins
p r o t e i n of rat
a monkey
reminded
deficiency.
new
transport
by
this assay
in vitro
e n d o c y t o s i s as the mechanism
f o 1 a t e - p r o t e i n complex.
by
superior
iron
exciting
the folate binding
is involved
and Lampi
system of folate
addressed
the
is
inhibitor
the
tubule
system
O'Connor, Picciano, Sherman,
the complex
into milk
judged
uptake.
In my opinion,
evidence
this
methodological
Hoppner
c a n be
availability
al , is .not inhibitory.
mary gland
to
is impaired by o x i d a t i o n stress which c a n be avoided
use of natural
Aspirin,
In
is the higher
significance of
studies of h e p a t o c y t e m o n o l a y e r s by showing
bioassay
as
range deserves further an
5-methyl
and folic acid appeared
is pH-dependent
The physiological
and Nimaec provided
in
transport
in isolated hepatocytes.
tetrahydrofolate
in the millimolar
transport the
in tumor cells,
best.
studies
transport
this tissue 5-methyl
of reduced
in intestine where a single
the f i n d i n g s
tetrahydrofolate
share
the carrier
of
proximal folates
translocation of
kidney cell
line
the
in which
592 the folate the
transport
cell,
Kamen
"receptor"
-
and
specificities
returned
testine as well. transport,
novel
contrast
on binding
attention
bind
reductase
to
(DHFR)
folate transport and Rosenberg hibitors be able
to
To study approaches
amined
system
the other
this by synthesizing
in which for
growing
and thus
tissues.
Price,
novel
the
initiate research.
an exciting
in-
participate
in
that
Such drugs
dihydrofolate -
specific Selhub,
three DHFR T h u s one
transport Sams,
in-
should system.
Harpring,
Smith and Fresheim
ex-
photoaffinity
labeling
reagents
Price et al reported
exciting
new
the probe
biology of
new phase
in
data
labeled a ¿»6K p r o t e i n which carrier
the tools
the molecular
in
using
system. even
intestine
Zimmerman,
Fresheim,
by Price,
to Ann
protein
the structure
line of L1210 which
and
pig
inhibit
folate transport.
the transport
that
similar
realization
absent from a mutant cell It appears
kidney
intestine. in
of for
isolation are being employed.
inhibitors as probes of
one by Kempton,
contender
Both
were
the
this conclusively
intestinal
and Kohrs and
a strong
to
inhibitors of
demonstrated
L1210 cells
to
in m a m m a l i a n
based upon methotrexate. on
which
these p r o t e i n s which
the
are also
to use DHFR
Smith,
evidence
folates.
transport
the active center
inhibit
Two reports,
and
other
to the function of the binding
approaches are based upon which
of
specificities in
the folate content
provided
endocytosis
transport
Reisenauer's paper
is regulated by
Capdevila
mediated
studies showed binding
system
to probe these this
protein, lacks the
which
lively
events
proteins
area
was
transport
the molecular
transport
is
of
will
folate
STUDIES
ON
GLYCINE
Wagner*+
Conrad
N-METHYLTRANSFERASE
and R o b e r t
Cook+
J.
VA M e d i c a l Center* and D e p a r t m e n t of B i o c h e m i s t r y + , Vanderbilt U n i v e r s i t y S c h o o l of M e d i c i n e , N a s h v i l l e , T e n n e s s e e , 3 7 2 3 2
Introduction Sarcosine in
is p r o d u c e d
liver
demethylation chondria 1)
methyltransferase accounting
for
from rabbit
(Fig.
1).
direct This
latter
(GNMT;
1.5%
of
protein
5-CHg-H^PteGlUg size
We
which
believe
soluble
an
Fig.
glycine GNMT
allosteric
in
the
nine
levels
the in
"methyl
the
diet
r e g a r d i n g the properties
trap" (3).
in We
the GNMT
of
GNMT
adjusting report
as
bound
of
to
here
to
reaction synthe-
b u t to m o d u -
S-adenosyl-homobe
important
decreased
further
of G N M T a n d i n h i b i t i o n
the
is n o t
( A d o M e t ) to
complementing
cytosol
(1).
a role would
Such
abundant
liver
as F B P - C I I
N-
but not c o v a l e n t l y ,
late the r a t i o of S - a d e n o s y l m e t h i o n i n e liver.
Fig.
by g l y c i n e
has no k n o w n m e t a b o l i c f u n c t i o n ,
in t h e
mito-
7,
identified
inhibitor
role
in the
(reaction
cysteine
(AdoHcy)
1)
choline
oxidative
is e x t r e m e l y
protein
designated
of
the
is c a t a l y z e d
tightly,
the m e t a b o l i c
sarcosine, which
4,
by
GNMT was recently
previously is
that
of
EC 2 . 1 . 1 . 2 0 ) . the
formed
(reaction reaction
a n d 0.73» f r o m r a t .
binding
in the t u r n o v e r
is
methylation
isolated from rat liver c o n t a i n s (2).
It
of d i m e t h y l g l y c i n e
or by the
in the c y t o s o l .
folate
as an i n t e r m e d i a t e
mitochondria
in
methio-
information
by v a r i o u s
folates.
Results Kinetic measurements rate cine.
radioactive
carried out using
T h e pH o p t i m u m of G N M T is a b o u t 9.0 a n d w h e n m e a s u r e d at
this
contrast
obtained
to
values
is 1 . 9 7
from
purified
mM a n d f o r A d o M e t
the
data
obtained
of
0.13
mM
and
by
Ogawa
30 uM
for
AdoMet
sepagly-
glycine
produced
an H P L C m e t h o d to and
p H , the K m f o r in
were
sarcosine
is 78
and
Fujioka
glycine
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
uM. and
This (4)
is who
AdoMet
594
MITOCHONDRIA
CYTOSOL
CHOLINE
©I a ©|
BETAINE-ALDEHYDE BETAINE _
U HOMOCYSTEINE
^{•»METHIONINE
DIMETHYLGLYCINE ^UH^PteGius AdoMet
Ado Hey
•SARCOSINE- •-SARCOSINE
GLYCINE
UHiPteGlus r^SJO-CHj-H^PteGluj^
®
GLYCINE
®\
SERINE
Fig.
1.
Choline
respectively for AdoMet pH
9.0
Hill
turnover
at pH 7 . 4 .
They
plot was
no
evidence
of G N M T
tion
25.7
and w a s
positive
also
observed
positive
cooperativity
for
this.
The
n
value
obtained
at
from
a
1.03. a c t i v i t y was
l o w e d by 5 - C H 3 - H 4 P t e G l u 6 and
liver
at b o t h pH 7.4 a n d 8 . 8 w h e r e a s o u r r e s u l t s c a r r i e d o u t
showed
Inhibition 6.8
in t h e
greatest
and 5 - C H 3 - H 4 P t e G l u 3
pM, r e s p e c t i v e l y .
The
complete
at 2 4 ° .
in 15 m i n
cooperativity
with
for AdoMet
S-CHj-H^PteGlug
w i t h Kj v a l u e s
inhibition
when
required
There
was
measured
fol-
of
4.9,
preincuba-
no e v i d e n c e
in t h e
for
presence
of
5-CH3-H4PteGlu5.
Binding
of r a d i o a c t i v e
unlabeled length
folate
and
important
the
ligands 5-methyl
factors
specificity.
3 6 ( S)5-CH3-H^ [ H]PteGlu5
in
(Table group
binding,
1). on
the
indicating
Both
was
competed
for
polyglutamate
reduced
pterin
a high
degree
ring of
by
chain were
binding
595 Table
1.
of 6 ( S ) 5 - C H 3 - H 4 [ 3 H ] P t e G l u g
Inhibition
Binding
to
Glycine
N-Methyltransferase
Inhibitor
Concentration
Y-GIU-Y-GIU-Y-GIu
1
0 1
1
0
10 100
0
5-CH,-H.PteG1u, 4
1
binding
reaction
and 0 . 0 1 6 the
was
obtained
animals
The
binding
of
studied
using
and
their uM,
tetramer. AdoMet
Human
as
of
8 22 50
1 10 100
1 3 25
out
0.01 by
M
using
HPLC
previously aj[.
from
for
This
is
of
at pH 7 . 0
enzyme for
with
(80%
15 m i n
at
6(S)5-CH,-
GNMT
preparation
[ 3 H ] P t e G l u as
fully
(2).
in t h e Only
consistant
compounds
nanomolar and
one
with
polyglutamates
of t h e s e
5-CH3-H4PteGlug
respectively.
ug
a crude
injected
the f l u o r e s c e n c e
concentration
3
2-mercaptoethanol.
the
of
range.
lack
ligand of
to
GNMT
at pH 2 . 5 The
5-CH3-H4PteGlu3
mole
was
to
dissociawere
0.56
bound
per
cooperativity
for
substrate.
liver GNMT has also been p u r i f i e d
appears Mr
4
1 10 100
two 5 - m e t h y l t e t r a h y d r o f o l a t e
constants 1.6
of
purified
by Wagner £ t
was tion
carried
100
uM 6 ( S ) 5 - C H 3 - H 4 [ H ] P t e G l u g
presence
from
was
0
3
H4[JH]PteG1u5
measure
0
10
PteGlu,
described
0 0
1
J
in
0
10 100
PteGlu,
25"
0
0 0
1
PteGlu,
pure)
Inhibition
1
1
The
%
10 100
5-HCO-H.PteGlu-i
J
(yM)
to c o n s i s t 34,000
of f o u r ,
daltons
each
presumably similar
to
approximately identical, rat
liver
100 f o l d .
subunits GNMT
with
(1,4).
It an The
596 partially
purified
about
same extent
the
purified
rat
human
enzyme
enzyme
is
inhibited
as the r a t e n z y m e . crossreacts
with
by 5 - C H 3 - H 4 P t e G l U g
Antiserum
the
prepared
partially
purified
to
to the
human
enzyme.
Acknowledgement This
work
Veterans to
was
supported
Administration
acknowledge
the
B r i g g s and W a r a p o r n Krumdieck, PteGlUg,
by and
the by
excellent
Medical
NIH
Grant
technical
Decha-Umphai.
We
Research
and
of
We
are
assistance
of
William
also w i s h
to t h a n k
U n i v e r s i t y of A l a b a m a f o r the g e n e r o u s
PteGlUg
Service
IAM15289.
Dr.
g i f t of
the
plesed T.
Carlos
synthetic
PteGlug.
References 1.
Cook,
R.J.
2.
Wagner,
and
Wagner,
C.
(1984)
Proc.
Natl.
Acad.
Sci.
8J,,
3631-3634. C.,
Biophys.
Briggs,
Res.
J.M.
Comm.
W.T.
127,
and W e i r ,
and
Cook,
R.J.
(1985)
Biochem.
746-752.
3.
Scott,
D.G.
4.
O g a w a , H. and F u j i o k a , M . ( 1 9 8 2 ) J. B i o l . C h e m . 2 5 7 ,
(1981)
Lancet
2,
337-340. 3447-3452.
FOLATE BINDING PROTEIN FROM PEDIOCOCCUS CEREVISIAE STRAINS POSSESSING ACTIVE TRANSPORT SYSTEMS FOR FOLATES
Frederika
Mandelbaum-Shavit
D e p a r t m e n t of B a c t e r i o l o g y , Jerusalem, I s r a e l
Hebrew U n i v e r s i t y - H a d a s s a h
Medical
School,
Introduction
We h a v e
shown
previously
cerevisiae/PteGlu,
that
a
s h a r e d by t h e r e d u c e d d e r i v a t i v e s , (MTX),
Pediococcus
p o s s e s s e s an a c t i v e
whereas t h e p a r e n t
cerevisae
a s w e l l a s by t h e a n a l o g ,
their
methyltetrahydrofolate independent indicated
process,
0°C and
P.
the reduced
methotrexate (1,2).
at
only
P.
(PteGlu),
folates
substrates
accumulated
mutant,
system f o r f o l a t e
C e l l s of b o t h s t r a i n s a l s o e x h i b i t e d an a b i l i t y t o p a r t i a l l y a c c u m u l a t e respective
strain
transport
cerevisiae/PteGlu
accumulated
5-
( S - C H j - H ^ P t e G l u ) by a s p e c i f i c and e n e r g y ( g l u c o s e ) not i n h i b i t e d
p r e s e n c e of a f o l a t e
by i o d o a c e t a t e ( 3 ) .
The
latter
data
binder.
B i n d i n g of f o l a t e s by s p e c i f i c b i n d i n g p r o t e i n s p r e s e n t i n many b i o l o g i c a l s o u r c e s h a s been s t u d i e d r e f . 4).
extensively
Membrane-associated
underwent,
as
well,
during the
last
f o l a t e binding protein
detailed
investigation
decade ( f o r r e v i e w from L a c t o b a c i l l u s
which
resulted
in
see casei its
c h a r a c t e r i z a t i o n and p u r i f i c a t i o n ( 5 , 6 ) . The p u r p o s e of t h e p r e s e n t work was t o f u r t h e r e l u c i d a t e f o l a t e b i n d e r a s a component of t h e a c t i v e t r a n s p o r t s y s t e m . strains
varying in t h e i r
transport
properties
made i t more f e a s i b l e t o s t u d y b i n d i n g v s
t h e r o l e of Using
for various f o l a t e
the
bacterial
derivatives
transport.
Results
K i n e t i c s of B i n d i n g of F o l a t e s and t h e E f f e c t of pH S t u d i e s of b i n d i n g of P t e G l u and S-CHg-H^PteGlu by P. c e r e v i s i a e / P t e G l u
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
were
598 performed with energy depleted cells incubated at 5°C. Determination of the time course of binding of PteGlu by 10 9 cells at an external concentration of 10 for 35 min.
juM revealed a maximum binding upon incubation
Binding of S-CH^-H^PteGlu by the same number of cells incubated
at a concentration of 5 jjM achieved steady state within 25 min (not shown). The results depicted in Figs. 1 and 2 show that binding of PteGlu and 5-CHgH^PteGlu follow saturation kinetics and double reciprocal plots of the data (insets) provide affinity constants for this process.
The affinity of the
binder for PteGlu and S-CHg-H^PteGlu is optimal at pH 6.0 and decreases at more alkaline or acidic pH values.
The Kj values for binding of PteGlu (inset
Fig. 1) at pH 6.0, 6.5 and 7.5 were 1.6, 1.9 and 2.7 pH 5.5 the K d was 2.3 jiM (not shown). pH 6.0, 6.5 and 7.0 were 0.9, 1.2 and K d was 1.9 juM (not shown). be 0.28 nmol / 10 cells.
9
The
juM respectively and at
K d values for
5-CH3-H4PteGlu
at
2.4 ,uM respectively, and at pH 5.5 the
The maximal
binding of PteGlu was calculated to
cells, whereas that of 5-CH 3 -H 4 PteGlu was 0.71 nmol / 10 9
The affinity constants for binding of S-CHg-H^PteGlu by P. cerevisiae,
parent strain, determined at pH 6.0 and 7.0 were 0.1 and 0.3 (not shown).
jiM respectively
These cells were unable to bind PteGlu even upon exposure to a
concentration of 50 ^M for 60 min.
Fig. 1
Fig. 2
Figure 1. Binding of folate vs concentration. [2- 14 C] Fol ic acid, potassium salt, sp. act. 52.4 mCi/mmol was purified and quantitated as described previously (2). Growth of bacteria and binding assays: the cells were grown in a Folic Acid Casei Medium, product of Difco, supplemented with folate or folinate 0.4 nM, harvested during the late exponential growth phase and washed with saline. Glucose-depleted cells were obtained by incubation in saline supplemented with 20 mM potassium phosphate buffer, pH 6.5, for 2 hr at 30°C. The cells were collected by centrifugation, washed once in the above solution and suspended (10 cells equivalent to 1 mg dry weight) in 0.95 ml of potassium phosphate buffer 50 mM at the indicated pH. The labelled compound was added in 50 >il and the mixtures were incubated for 35 min at 5°C. The binding was terminated by filtration through membrane filters, 2 washes with
599 i c e - cold s a l i n e and further processed a s described previously (2). Symbols: binding a t pH 6.0 ( • ) ; pH 6.5 (0); pH 7.5 (A). F i g u r e 2. B i n d i n g of 5 - C H 3 - H ^ P t e G 1 u v s c o n c e n t r a t i o n . 5-[1^C] methyltetrahydrofolic acid sp. a c t . 58.3 mCi / mmol. The experimental d e t a i l s were a s f o r F i g . 1, e x c e p t f o r i n c u b a t i o n time which was 25 min. Symbols: binding a t pH 6.0 ( • ) ; pH 6.5 ( 0 ) ; pH 7.0 (A). Binding of F o l a t e s by a Mutant S t r a i n Posessing impaired Transport System for Folates. A mutant s t r a i n of P. c e r e v i s i a e , P. cerevisiae/MTXr, i s o l a t e d by s e l e c t i o n of c e l l s growing in increasing concentrations of MTX exhibited e l e v a t e d a c t i v i t y of d i h y d r o f o l a t e r e d u c t a s e and impaired t r a n s p o r t f o r t h i s a n a l o g and f o r f o l a t e (7).
The r e s u l t s summarized in T a b l e 1 show t h a t the Kd
values
o b t a i n e d f o r binding of v a r i o u s f o l a t e s c o r r e l a t e with t h e i r a p p a r e n t Km values. Table
1.
Kinetics
of
Binding and T r a n s p o r t
of
Various
Folates
in P.
cerevisiae/MTXr and P. c e r e v i s i a e / P t e G l u . P. cerevisiae/MTXr
P. cerevisiae/PteGlu
Km (uM)
Kd (uM)
Km (uM)
Kd (uM)
10.0 a
4.9
6.6a
1.6
5-CH3-H4PteGlu
0.9
0.5
1.2
0.9
MTX
5.0
3.9
0.5
0.2
Compound PteGlu
o For d e t e r m i n a t i o n of t h e K d v a l u e s f o r b i n d i n g of [ H] MTX, t h e P. cerevisiae/MTXr c e l l s were incubated at a concentration range of 1 - 10 uM and P. c e r e v i s i a e / P t e G l u c e l l s a t 0.1 - 1.0 uM f o r 30 min. Other e x p e r i m e n t a l d e t a i l s were a s f o r F i g . 1. a Previously published data (3.7). Binding of Methotrexate and Folate by Plasma Membranes from Pediococcus c e r e v i s a e / PteGlu and Pediococcus c e r e v i s a e / MTXr. The Kj v a l u e s f o r binding of MTX by membranes a r e e s s e n t i a l l y the same a s those obtained with i n t a c t c e l l s .
Thus the a f f i n i t y of the binder for MTX i s
about 20-fold lower in P. cerevisiae/MTXr than that of P. ( T a b l e 1, T a b l e 2).
cerevisiae/PteGlu
S i m i l a r l y , the Kd v a l u e s f o r PteGlu binding by i n t a c t
c e l l s or membranes a r e 3 - f o l d higher in P. c e r e v i s i a e / M T X r a s compared to those of P. c e r e v i s i a e / P t e G l u . Table 2.
Binding of MTX and PteGlu by Membrane Preparations. P. cerevisiae/PteGlu
Compound
Kd (uM)
P. cerevisiae/MTXr Kd (uM)
PteGlu
1.5
4.7
MTX
0.2
3.8
600 Plasma membranes were obtained from lysozyme treated cells by a modification of the method described for Streptococcus cremoris (8): increasing the amount of lysozyme to 1 mg / mg cells (dry weight) and duration of treatment at 30°C to 3 hr instead of 30 min. The binding mixture in 1 ml contained 1 mg membrane protein determined by the method of Lowry (9) in 50 uM potassium phosphate buffer, pH 6.0.
Discussion
Data presented in this study demonstrate that the ability of P. cerevisiae strains to accumulate various folate derivatives is reflected by binding properties of the folate binder.
Thus P. cerevisiae, unable to accumulate
folate could not bind this derivative and an MTX -resistant mutant with impaired transport for MTX due to a 10-fold higher Km value than that of the susceptible strain exhibited an almost
20-fold higher K^ value.
Low binding
affinity for folate has also been reported in an MTX resistant subline of L. casei (10). The affinity of the folate binder for various folates changes with increasing or decreasing pH values in a pattern which correlates with the pH profiles obtained in transport studies of these compounds (2,7). Changes in Kj values with changing pH were also reported in studies of folate binding by L. casei cells (11). In conclusion, the membrane associated folate-binding protein appears to be a crucial component of the active transport system.
Acknowledgment
This research was supported in part by a grant from the Schonbrunn Fund.
References 1.
Mandelbaum-Shavit, F. and N. Grossowicz. 1970. Transport of folinate and related compounds in Pediococcus cerevisiae. J. Baceriol. 104 1-7.
601 2.
M a n d e l b a u m - S h a v i t , F. and N. Grossowicz. 1973. Carrier-mediated transport of folate in a mutant of Pediococcus cerevisae. J. Bacteriol. 114, 485 - 490.
3.
Mandel baum-Shavit, F. and N. Grossowicz. mutant with altered transport of folates.
4.
Wagner, C. 1982. C e l l u l a r f o l a t e binding significance. Ann. Rev. Nutr. 2_, 229 - 248.
5.
Henderson, G.B., E.M. Z e v e l y , and F.M.Huennekens. 1976. Folate transport in Lactobacillus cosei: Solubilization and general properties of the binding protein. Biochem. Biophys. Res. Commun. 68, 712 - 717.
6.
Henderson, G.B., E.M. Z e v e l y , and F.M. Huennekens. 1977. and properties of a membrane-associated folate-binding Lactobacillus cosei. J. Biol. Chem. '252, 3760 - 3765.
7.
M a n d e l b a u m - S h a v i t , F. 1976. Resistance of Pediococcus c e r e v i s a e to amethopterin as a consequence of changes in enzymatic activity and cell permeability. II. P e r m e a b i l i t y changes to amethopterin and other folates in the drug-resistant mutant. Biochim. Biophys. Acta 428, 674 -
1975. Pediococcus cerevisiae J. Bacteriol. 123, 400 - 406. proteins;
function
and
Purification protein from
682.
8.
Otto, R., R.L. L a g e v e e n , H. V e l d k a m p , and W.N. Konings. 1982. Lactate efflux-induced electrical potential in membrane vesicles of Streptococcus cremoris. J. Bacteriol. 149, 733 - 738.
9.
Lowry, O.H., N.J. Rosebrough.A.J. Farr, and R.J. R a n d a l l . 1951. Protein measurements with the Folin phenol reagent. J. Biol Chem. 193, 265 275.
10.
Ananthanarayanan, M., J.M. Kojima and G.B. Henderson. 1984. Structural and functional properties of the folate transport protein from a methotrexate-resistant s u b l i n e of L a c t o b a c i l l u s casei. J. B a c t e r i o l . 158, 202 - 207.
11.
Henderson, G.B. and S. Potuznik. 1982. I r r e v e r s i b l e inhibition of folate transport in Lactobacillus casei by covalent modification of the binding protein with carbodiimide-activated folate. Arch. Biochem. Biophys. 216, 27 - 33.
IMMOBILIZED FOLATE BINDING PROTEIN FROM COW'S MILK USED FOR QUANTITATION OF FOLATE
S.I. Hansen, E. Nex0 Department of Clinical Chemistry, Central Hospital Hiller0d DK-3400 Hiller0d, Denmark J. Holm Department of Clinical Chemistry, Central Hospital Nyk0bing F. DK-4800 Nyk0bing Falster, Denmark
Introduction The purpose of this study was to immobilize the pure folate binding protein (FBP) from cow's milk (1), compare the binding properties of the complex with those of soluble FBP, and use the immobilized FBP for routine determination of erythrocyte folate.
Materials and methods Pure FBP from cow's milk (1) was coupled to microcellulose activais ted with benzoquinone (2) and Dynospheres activated with toluenesulfonylchloride essentially as previously described (3). Binding 125 3 studies were performed with H- and I-labeled folate. Immobilized FBP was incubated with folate for 1 h (25°C, Tris 0.17 M, Triton X-100 1g/1, pH 7.4) prior to centrifugation (3000 g, 4°C, 30 min). Studies with soluble FBP was performed by equilibrium dialysis or charcoal precipitation (4).
Results and Discussion Binding characteristics for FBP insolubilized to cellulose and Dynospheres are compared with those of soluble FBP in table 1. The most important change upon immobilization is the decrease in the apparent affinity constant.
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
604 Table 1 F o l a t e B i n d i n g P r o p e r t i e s of I m m o b i l i z e d a n d S o l u b l e F B P
Solid phase
Cellulose
Y i e l d of c o u p l i n g
%
S t e a d y state for folate b i n d i n g 25°C, p H 7.4
min.
Dynospheres
none
10
10
-
45
60
30 +
D i s s o c i a t i o n of ^ H - f o l a t e a f t e r 1 h a t zero c o n c e n t r a t i o n , 25°C. pH 7 r
pH
- 9
Fraction
3.5
Non specific binding
folate
%
0.1
0.1
0.1 +
>0.8
>0.9
>0 .9 +
-
5+
0
Me
R=H
A; I R = H1
R = cyclopropyl
X. 1 R = cyclopropyl )
Fig. 3 : Generation of A* from DAUM derivatives in acidic media
At reflux temperature (CH^CN/HOAc; ca 80°C) A" could be reduced by either Hantzsch ester (5) or 5,6-dihydrophenanthridine 7 (Fig. 4).
(6) to the thymine derivative
689
O^N^NHMe J. ® •
7o R = H 7b R = 0
O^N^NHMe Me RR EtOOC^YxOOEt
5o R =H 5b R = D
Me^JpMe Fig. 4 : Reduction of A" to 6-ajninothymine derivatives Study of DAUM derivative 4b was expected to throw light on the nature of the reduction step. During the reduction of A1 (R= cyclopropyl), opening of the cyclopropyl ring would imply a radical mechanism involving a SET process, as shown in Fig. 5 ( a - > b - » b ' -»9 ). However, reduction of A' (R= cyclopropyl) by Hantzsch ester (5) and 5,6-dihydrophenanthridine (6) in CH^CN/HOAc at roomtemperature resulted, in both cases, in the formation of "thymine" derivative 8 and not the ring-opened product 9. These results indicate a hydride type mechanism, although operation of a radical mechanism in which intermediate b is quenched by a hydrogen radical, in preference to ring-opening, cannot be excluded at this stage. o
Y
Yr™" O^N^NH, I Me b
O^N^NHj Me b'
0
V
O^-N^nh. J- ©
-
0
Y
!
I Me
N' O^N Me 9
Fig. 5 : Reduction of A' via a radical or hydride type mechanism In view of the observed reduction of intermediate A" by 5,6-dihydrophenanthridine, the folate model 11 was synthesized and examined for its ability to transfer both the methylene group and the hydride equivalent to aminouracil 10•
690 Mi
H
•
0 4-N
-C-Glu
J
11
11
Me
-To Fig. 6 : Chemical modelling of the thymidylate synthase reaction Reaction of 10 with 11 resulted in a mixture in which thymine derivative 7a was identified. Finally, it was also shown that 1_0 reacted with S^O-CH^-H^folate (12) to give spectroscopically identifiable amounts of 7a.
Conclusions The results show that the chemical modelling of the thymidylate synthase reaction, involving both the carbon-transfer and the reduction step has been achieved. Biomimetic studies aimed in particular at the mechanistic details of the reduction step are in progress. Acknowledgements This work was carried out in part under the auspices of the Stichting Scheikundig Onderzoek in Nederland (SON) with the financial support of the Netherlands Organization for Fundamental Research (ZWO).
References 1. Santi,D.V. and P.V. Danenberg.1984.In: Folates and Pterins, Vol.1 (R.L. Blakley and S.J. Benkovic, eds),Wiley, New York, pp 345-398 2. Slieker,L.J. and S.J. Benkovic.1984. J.Am.Chem.Soc. 106, 1833 3. Van der Meij.P.F.C, R.D. Lohmann, E.R. de Waard, T.B.R.A. Chen and U.K. Pandit.1985. J.Chem.Soc,Chem.Comm., 1229
SYNERGISTIC INTERACTION BETWEEN POLINIC ACID AND THE FLUOROPYRIMIDINES
KJiandan Keyomarsi and Richard G. Moran Department of Biochemistry, School of Medicine, University of Southern California, Los Angeles, California 90033, and Children's Hospital of Los Angeles, Division of Hematology-Oncology 4650 Sunset Boulevard, Los Angeles, California 90054
INTRODUCTION The fluorinated pyrimidines have been used extensively in the treatment of certain types of cancer since they were first synthesized in 1957 (1). Exposure to 5-FU or FUdR results in inhibition of the growth of cell lines derived from both solid tumors and leukemias (2) . The effects of the fluoropyrimidines against tumor cells in culture and the related chemotherapeutic activity of 5-FU and FUdR in vivo have been ascribed to three major mechanisms: a) metabolism to FdUMP, which is a potent suicide inhibitor of thymidylate synthase (TS) (3) , b) incorporation of the ribonucleotide triphosphate of 5-FU into some species of RNA (4) , and (c) incorporation into DNA (5) . The inhibition of TS by FdUMP involves the formation of a ternary complex in which the enzyme is covalently linked to the nucleotide substrate which is, in turn, covalently bound to the folate cofactor, 5,10-methylene tetrahydrofolate (5,10-CH2H4PteGlu) (3). In the absence of the cofactor, FdUMP forms a weak binary complex with TS (Kd = 10 "*M) , where as the presence of 5,10-CH_H.PteGlu results in a covalent -9 ternary complex in which FdUMP is bound much more tightly (Kd = 1 0 -12
10 M). Fran this it follows that intracellular levels of reduced folate cofactors could be a critical determinant of the cytotoxic effects of 5-FU and FUdR. In this study, we show a synergism between folinic acid and fluoropyrimidines in leukemic cells.
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
692 RESULTS The growth inhibitory and cytotoxic effects of fluoropyrimidines on leukemic cells of mouse and human origin in the presence of folinic acid were studied (6). Exposure of exponentially growing mouse L1210 cells to low concentrations of FUdR resulted in an initial inhibition of the growth of these cells (Figure 1) . Subsequent recovery of the growh rate of growth of these cells after 12 hours approached that of control cultures, in spite of the continued presence of drug. On the other hand when folinic acid was added to the cultures at the sams time as FUdR, the initial growth inhibition was maintained.
The growth inhibitory effects of 5-FU were 1.5- to 2.1- fold
more potent in the presence of folinic acid while the potency of FUdR was increased by 2.4- to 4.5- fold in the cell lines studied. Furthermore, L1210 cells that were exposed to folinic acid and concentrations of 5-FU or FUdR that were individually noncytotoxic resulted in a 98% to 99.9% cell kill.
Time
hours
Figure 1 Inhibition of growth of L1210 cells by FUdR and folinic acid. Triplicate suspension cultures (20 ml were exposed to PBS (0) , 10
M
folinic acid (•) , 3.2 x 10~10M FUdR (D), or 10-5M folinic acid and 3.2x10 ^ M FUdR ( • ) . Aliquots of each culture were removed at the indicated times and the culture density of each was determined electronically.
Variation among replicates was less than the size of the
symbols. The ordinate expresses the culture density relative to the culture 4 density at time zero (2.5x10 cells/ml).
693
DISCUSSION The most likely mechanism for the synergism between high concentrations of folinate and the fluoropyrimidines is the stabilization of catalytically inactive complexes between TS, FdUMP, and 5,1O-CH^H^PteGlu. Daneriberg and his colleagues (7) have reported that mainrialian TS follows an ordered sequential reaction mechanism with dUMP binding first (Fig. 2) and that formation of a ternary complex with FdUMP and cofactor follows the same sequence of addition of reactants to the enzyme. This order of addition of reactants furnishes an explanation of the folinate induced synergism. S-CHO-H4PtaQlu • FdUMP
I
dCMP^^^dUMPTS I UOP'
5.10-CH2-H,Pt»Glu
' TS.FdUMPMM^» T8.FdUMP.5.10-CHi-HJ 4 DTT 4.30 100 + Met synthase 10.7-7.6 , +catalose 3.55 0
0
2
4
6
8 10 12 TIME (min)
14
16
18
20
22
Figure 2. Characterization of the thiol oxidase activity associated with partially purified methionine synthase from pig liver. The enzyme used for these studies had a specific activity of 0.05 pmoles min~l mg~l, and had been purified by ammonium sulfate fractionation and chromatography on DEAE cellulose and hydroxylapatite (BioRad HTP). Thiol oxidase activity was measured in an oxygen electrode at 37°C. Reactions were measured in solutions containing 25 mM dithiothreitol in 50 mM potassium phosphate buffer, pH 7.2. confirming the oxidation state of the inactive enzyme.
Activation
of the enzyme using the R/F/NADPH reducing system and AdoMet leads to the absorbance changes expected for conversion of cob(II)alamin to methylcobalamin, as previously reported by Fujii and Huennekens (13) and to the disappearance of the cob(II)alamin EPR spectrum. [The copper associated with the enzyme preparation is EPR silent, and can only be visualized as C u + + after denaturation of the enzyme in the presence of mersalyl, urea and EDTA.] Activation of the enzyme is generally postulated
to proceed by
reduction of the enzyme-bound cobalamin to the cob(I)alamin oxidation state with trapping of this species by methylation with AdoMet.
The unliganded cob(II)alamin/cob(I)alamin couple has a redox
potential at pH 7 of -0.61 V vs the standard hydrogen electrode and the potential is -0.50 V at pH 2, where cob(II)alamin exists
704 in the b a s e - o f f c o n f o r m a t i o n due to p r o t o n a t i o n of the d i m e t h y l benzimidazole substituent
(21).
It is p o s s i b l e that the m e t h i o -
nine s y n t h a s e a p o e n z y m e s i g n i f i c a n t l y a l t e r s the redox
potential
of the enzyme b o u n d c o b ( I I ) a l a m i n , b u t c o b ( I ) a l a m i n is n e v e r observed during reductive activation.
We m u s t t h e n e x p l a i n h o w
s y s t e m s like R / F / N A D P H or d i t h i o t h r e i t o l , w i t h redox p o t e n t i a l s the range from - 0 . 3 8 to - 0 . 2 0 V , are able to a c c o m p l i s h of c o b a l a m i n .
in
reduction
It is not c l e a r that m e t h y l a t i o n by A d o M e t can p r o -
v i d e m u c h d r i v i n g force for the r e a c t i o n , since the weak bond in the s u l f o n i u m will be r e p l a c e d by a weak
S-methyl
carbon-cobalt
bond o n the e n z y m e . I think we need to a d d r e s s s e r i o u s l y the p o s s i b i l i t y
that
c o b ( I I ) a l a m i n reacts w i t h A d o M e t by h o m o l y t i c m e t h y l t r a n s f e r , that the r e d u c i n g s y s t e m is r e q u i r e d for the s u b s e q u e n t of A d o H C y , as s h o w n by e q u a t i o n
[4] and
I
+
S
CH-?-cobalamin +
le~ +
/\ Spectroelectrochemical
reduction
[5]
CH3 cob( I I ) a l a m i n + J5
and
•+ S
[4]
S
[5]
/\
t i t r a t i o n s s h o u l d e s t a b l i s h the n u m b e r of
e l e c t r o n s a c t u a l l y r e q u i r e d for a c t i v a t i o n and the p o t e n t i a l at w h i c h they are
approximate
delivered.
A final m e c h a n i s t i c q u e s t i o n c u r r e n t l y of g r e a t interest to m a n y of the p a r t i c i p a n t s
in this S y m p o s i u m c o n c e r n s the m e c h a n i s m of
i n a c t i v a t i o n of m e t h i o n i n e s y n t h a s e by N 2 O , and its ramifications.
Early i n v e s t i g a t i o n s
physiological
(22-24) n o t e d the
development
of m e g a l o b l a s t i c a n e m i a in p a t i e n t s w h o had b e e n e x p o s e d to N2O for p r o l o n g e d p e r i o d s , and the n e u r o l o g i c a l s y m p t o m s of
pernicious
a n e m i a in d e n t i s t s and o t h e r s s u b j e c t e d to c h r o n i c e x p o s u r e N2O.
to
T h e s e s y m p t o m s were c o r r e l a t e d w i t h i n a c t i v a t i o n of m e t h i o -
nine s y n t h a s e in a n i m a l s e x p o s e d to N2O (25-27).
Model
studies
have s u g g e s t e d that c o b ( I ) a l a m i n , a p r o p o s e d i n t e r m e d i a t e m e t h y l t r a n s f e r by m e t h i o n i n e s y n t h a s e , reacts w i t h N2O to e q u a t i o n
[6]
(28,29).
in
according
705 cob(I)alamin + N2O + cob(III)alamin + N2 + H2O
[6]
We began by establishing that methionine synthase from either _E. col i or pig liver can be inactivated by N2O _i_n vitro [Frasca e_t al., this volume].
Inactivation occurs only during turnover and
requires ~3900 turnovers per inactivation event.
Since the
products of equation [6] are inocuous, it was not clear why the reaction of N2O with methionine synthase should result in the irreversible inactivation of the enzyme.
Our studies suggest that
methionine synthase-mediated cleavage of N2O proceeds according to equation [7]. cob(I)alamin + N2O •* cob(II)alamin + N2 + OH.
[7]
We postulate that the generation of hydroxyl radical at the active site is responsible for the irreversible loss of activity, and for the observed partial loss of the cobalamin prosthetic group. Indeed, Kondo and his colleagues (27) reported the accumulation of unidentified cobalamin analogues following exposure of rats to N 2 0. Since N2O remains the anesthetic of choice for many surgical procedures, we need to consider the implications of these findings for patient management following long term exposure to the gas. O'Sullivan and colleagues have already shown that prior administration of 5-HCO-H4folate prevents the development of bone marrow abnormalities on prolonged exposure to N2O (24).
The possibility
remains however, that the cobalamin pools in the body become deficient in methyl cobalamin, and that significant levels of cobalamin analogues accumulate, as in the studies by Kondo e_t a_l on rats exposed to N2O (27). It is clear that nitrous oxide is proving to be an important research tool for exploring folate metabolism _i_n vitro and _i_n vivo. One may note particularly the elegant demonstration by Scott and his colleagues that chronic administration of N2O to monkeys results in development of the neurological symptoms characteristic of pernicious anemia and that dietary supplementation with methionine prevents the development of these symptoms (30).
Rosenblatt
706 and his c o l l e a g u e s
(20) h a v e used N2O to a s s e s s the a c t i v i t y of
m e t h i o n i n e s y n t h a s e inside f i b r o b l a s t s , since t u r n o v e r is for i n a c t i v a t i o n by N 2 O .
required
We a n t i c i p a t e a c o n t i n u e d i n t e r e s t
the use of N2O as a p r o b e of folate m e t a b o l i s m , and
continued
e l u c i d a t i o n of the c o m p l e x m e t a b o l i c s e q u e l l a e of m e t h i o n i n e thase
in syn-
inactivation.
Acknowledgements R e s e a r c h in the a u t h o r s ' l a b o r a t o r y w a s f u n d e d by the N a t i o n a l I n s t i t u t e s of H e a l t h G r a n t
GM24908.
References 1.
D a u b n e r , S . C . , R.G. M a t t h e w s .
2.
C l a r k , J . E . , L.G. L j u n g d a h l . 10845.
3.
K u t z b a c h , C., E.L.R. S t o k s t a d . 250, 459.
4.
M a t t h e w s , R . G . , M.A. V a n o n i , J . F . H a i n f e l d , J . W a l l . J . B i o l . C h e m . 259, 11647.
5.
S u m n e r , J . , D.A. J e n c k s , S. K h a n i , R.G. M a t t h e w s . J . B i o l . C h e m . 261, 7697.
6.
Mudd, S . H . , B.W. U h l e n d o r f , J . M . F r e e m a n , J . D . F i n k e l s t e i n , V.E. S h i h . 1972. Biochem.Biophys.Res.Comm. 46, 905.
7.
Erbe, R.W.
8.
R o s e n b l a t t , D . S . , B.A. Cooper. 1979. In: Folic A c i d in N e u r o l o g y , P s y c h i a t r y and Internal M e d i c i n e (M.I. B o t e z and E.H. R e y n o l d s , eds.). R a v e n P r e s s , N . Y . , p. 385.
9.
N a r i s a w a , K. 1979. In: F o l i c A c i d in N e u r o l o g y , P s y c h i a t r y and I n t e r n a l M e d i c i n e (M.I. Botez and E.H. R e y n o l d s , e d s . ) . R a v e n P r e s s , N . Y . , p. 391.
1975.
1982.
J.Biol.Chem.
1984.
N.Engl.J.Med.
J.Biol.Chem.
1971.
257,
140.
259,
Biochim.Biophys.Acta 1984.
1986.
293, 753, 807.
10.
L e v i t t , M., P.F. N i x o n , J. P i n c u s , J . R . Bertino. J . C l i n . I n v e s t . 50, 1301.
11.
M a t t h e w s , R . G . , S. Kaufman.
12.
T a y l o r , R.T. 1982. In: B12, V o l u m e 2 (D. D o l p h i n , W i l e y - I n t e r s c i e n c e , N . Y . , p. 307.
ed.)
13.
Fujii, K . , F.M. H u e n n e k e n s .
Aspects
1980.
1979.
J.Biol.Chem.
In:
1970. 255,
Biochemical
6014.
707 of N u t r i t i o n (K. Y a g i , ed. ) J a p a n S c i e n t i f i c S o c i e t i e s T o k y o , p. 173.
Press,
14.
M a t t h e w s , R.G. 1984. In: F o l a t e s and P t e r i n s , Vol. _1, (R.L. B l a k l e y and S.J. B e n k o v i c , eds.) J o h n W i l e y , N.Y. , p. 497.
15.
Z y d o w s k y , T . M . , L.F. C o u r t n e y , V. F r a s c a , K. K o b a y a s h i , H. S h i m u z u , L.-D. Yuen, R.G. M a t t h e w s , S.J. B e n k o v i c , H.G. Floss. 1986. J . A m . C h e m . S o c . 108, in p r e s s .
16.
T a y l o r , R . T . , H. W e i s s b a c h . 123, 109.
1968.
Arch.Biochem.Biophys.
17.
F u j i i , K . , F.M. H u e n n e k e n s .
1974.
J.Biol.Chem.
18.
U t l e y , C . S . , P.D; M a r c e l l , R.H. A l l e n , A . C . A n t o n y , J.F. Kolhouse. 1985. J . B i o l . C h e m . 260, 13656.
19.
S c h u h , S . , D.S. R o s e n b l a t t , B.A. C o o p e r , M . - L . S c h r o e d e r , A.J. B i s h o p , L.E. S e a r g e a n t , J.C. H a w o r t h . 1984. N e w . E n g l . J . M e d . 310, 686.
20.
R o s e n b l a t t , D . S . , B.A. C o o p e r , A . P o t t i e r , H. L u e - S h i n g , Mat iaszuk, K. G r a u e r . 1984. J. CI in. Invest. 2149.
21.
L e x a , D. and S a v e a n t , J.M. 1976.
22.
L a s s e n , H . C . A . , E. H e n r i c k s o n , F. N e u k i r c h , H.S. 1956. L a n c e t j., 527.
23.
A m e s s , J . A . L . , G . M . R e e s , J.F. B u r m a n , D.G. D.L. M o l l i n . 1978. L a n c e t i_i, 339.
24.
O ' S u l l i v a n , H., F. J e n n i n g s , K. -Ward, S. M c C a n n , J . M . D.G. W e i r . 1981. A n e s t h e s i o l o g y ^ 5 , 645.
25.
D e a c o n , R . , J. P e r r y , M. Lumb, I. C h a n a r i n , B. M i n t y , M.J. H a l s e y , J.F. Nun. 1978. Lancet 1023.
26.
K o b l i n , D . D . , J . E . W a t s o n , J . E . D e a d y , E.L.R. S t o k s t a d , Eger. 1981. A n e s t h e s i o l o g y 54, 318.
27.
K o n d o , H . , M . L . O s b o r n e , J . F . K o l h o u s e , M.J. B i n d e r , P o d e l l , C.S. U t l e y , R.S. A b r a m s , R.H. A l l e n . 1981. J. Clin. Invest. 6J_, 1270.
28.
B a n k s , R . G . S . , H e n d e r s o n , R . J . , P r a t t , J.M. J . C h e m . S o c . (A), 2886.
29.
B l a c k b u r n , R., M. K y a w , A.J. S w a l l o w . F a r a d a y T r a n s . 7_3, 250.
30.
S c o t t , J . M . , J.J. Dinn, P. W i l s o n , D.G. W e i r , 1981. i, 334.
J.Am.Chem.Soc.
1977.
249,
6745.
N.
9j3, 2652. Kristensen.
Nancekievi11, Scott,
E.I.
E.R.
1968. J.Chem.Soc. Lancet
IMPAIRED FORMYLATION AND UPTAKE OF TETRAHYDROFOLATE BY RAT SMALL GUT FOLLOWING COBALAMIN INACTIVATION
Janet Perry, Rosemary Deacon, M. Lumb and I. Chanarin Medical Research Council, Clinical Research Centre, Northwick Park Hospital, Harrow, Middlesex, U.K.
Introduction
During absorption reduced folate analogues are converted into methyltetrahydrofolate in the enterocyte.
In the case of tetrahydrofolate(H4PteGlu) there is
addition of a formate(CHO-) group which is further reduced to methyl (1). It has been suggested that the role of cobalamin is to make formate units available and that methionine is an important source of such formate units (2). Nitrous oxide (N2O) oxidizes and inactivates cob[I]alamin, the cofactor in the methionine synthetase reaction.
Many of the effects are reversed when formyltetrahydro-
folate is supplied (3). The defect is also reversed when methionine and some of its metabolic products are given with H4PteGlu (4).
Small gut segments in
vitro are able to formylate tetrahydrofolate and hence provide an opportunity for measuring the formylation step directly in control and cobalamin-inactivated (N20-exposed) animals. In view of uncertainty about the presence of methionine synthetase in small gut (5,6), this enzyme was assayed in small gut segments.
Methods
Animals:
Male Sprague-Dawley rats, 80-100g, were used.
Test animals breathed
N20:02 (1:1) in a chamber in which CO2 and humidity were controlled, with free access to commercial rat diet and water.
Preparation of everted gut sacs:
Control animals breathed air.
These were prepared according to Wilson &
Wiseman (7). The test compounds (16umols), together with 2pCi
[2- 1 4 C]H4PteGlu
and 1% ascorbate, pH 6.1 were added to the mucosal fluid, the flasks flushed with 02:C02 (95:5) for 3 minutes and incubated for one hour at 37°.
The
serosal fluid was then drained from the gut sac and retained, and the gut sac,
Chemistry and Biology of Pteridines 1986 © 1986 Walter d e Gruyter & Co., Berlin • New York - Printed in Germany
710
washed with saline, was homogenized in 0.1M potassium phosphate buffer pH 5.7 containing 0.2% ascorbate.
Portions of both samples were counted for
radioactivity to determine total uptake of [ 2 - 1 4 C ] H 4 P t e G l u .
Separation and identification of folates: This has been described elsewhere (4).
Methionine synthetase was assayed by the method of Kamely et al., (8) and protein content measured as described by Lowry et al., (9).
Expression of results: The proportion of mucosal fluid [ 2 - u C ] H 4 P t e G l u metabolized to 1-carbon-substituted folate compounds during absorption was derived from the chromatograms of gut and serosal fluid, and the radioactivity of each folate expressed as a percentage of the total mucosal [2-^CJltyPteGlu.
Statis-
tical comparison between groups were performed according to Hill and Peto (10).
Results
Methionine synthetase activity:
Considerable methionine synthetase activity was
present in whole gut which had been washed through with saline, everted and washed again. Activity was present in all but 2 of 14 specimens from air-breathing rats with assay values from 0.95 to 2.31 nmol methionine protein/hour.
formed/mg
There was no detectable methionine synthetase activity in gut
segments from N20-breathing rats regardless of the method of preparation.
Folate uptake by gut segments.
The mean folate uptake by gut sacs from control
animals was 4.39% of the amount added to the incubation fluid.
There was no
change after 24 hour N2O exposure but a significant fall to 2.51% after 7 days N2O.
The proportion of radiolabelled formylfolate formed from mucosal
[2-14C] PteGlu by control tissue was 1.06%.
This was halved to 0.56% after
24 hour N2O and fell further to 0.26% after 7 days N2O (Figure). differences were significant (p = 25
enzyme from inactivation by proteases (11), suggesting that it induces a conformational change in the protein or holds the protein in a specific conformation.
The d i v a l e n t cation require-
ment is to generate the substrate MgATP, and free ATP is a potent inhibitor of the reaction.
The proteins are monomeric and have
similar turnover numbers with their preferred folate substrates (3,4,12).
The CQtyQeijasteiiuiD and EA c q I a proteins also possess
dihydrofolate synthetase activity, while enzyme from
sa££i
>
methylene-THF (glu-2)
dihydrofolate
tetrahydrofolate
(glu-2)
»
(glu-3,4)
methylene-THP
The physiological relevance, if any, of the change in oxidation state and one carbon substitution of the pteroyl substrate as the glutamate chain is extended is not known.
Each of the indicated
steps requires the involvement of an additional enzyme viz. dihydrofolate reductase and serine hydroxymethyltransferase an additional glutamate moiety can be added.
before
The purified
£o£yn£bac££riuQi enzyme metabolizes folates to the tetraglutamate derivative, which are the types of folates that predominate io 2ÏXQ.
The LâStQfcàÇÀlllJS and IL e e l i enzymes w i l l metabolize
folates ¿q yitr.e to tetra- and triglutamate derivatives, respectively, although longer polyglutamate derivatives are observed ¿q YÀÏQ.
This apparent lack of fidelity, with the Ej.
ç o l i e n z y m e at l e a s t , is due to the p r e s e n c e of an a d d i t i o n a l enzyme in SL s s l i that converts pteroyltri-y-glutamates to long chain polyglutamate derivatives, with the additional glutamate residues added in a-linkage (14). The properties of several mammalian folylpolyglutamate synthetases have been examined (7-10).
The pig liver enzyme is the only
mammalian enzyme to have been purified to homogeneity (5) and its
722 Table 2
General Properties of Pig Liver Folylpolyglutamate Synthetase
Purification (fold) pH optimum monovalent cation divalent cation reducing agent M r (SDS gel elec) M r (Sephadex) DHF synthetase act. -1 cat (min )
40-200,000 9.4 2 0mM K + M g 2 \ Mn22 ++ DTT, ßME 62,000 66,000
NO 127
general properties, which in most regards are qualitatively identical to the properties reported for other mammalian enzymes, are listed in Table 2. The pig liver enzyme resembles the bacterial synthetases in that it is a monomeric protein present at low cellular concentrations (10-50 nM), it has a high pH optimum, and requires mono- and divalent cations for activity, although the monovalent cation requirement is met by lower concentrations. Mammalian synthetases differ from the bacterial enzymes in their absolute requirement for a reducing agent, their lack of dihydrofolate synthetase activity, and by a marked difference in folate substrate specificity (described below). The high pH optimum of folylpolyglutamate synthetases is due a high K m value for glutamate at physiological pH rather than an effect of pH on V m a x . Under physiological conditions, the glutamate concentration in mammalian tissues would not be saturating, suggesting that any modulation of cellular glutamate concentrations would be expected to modulate the rate of folylpolyglutamate synthesis.
723
Table 3
Kinetic Constants of Hog Liver Folylpolyglutamate Synthetase
Substrate H4PteGlu H 4 PteGlu 2 H 4 PteGlu 3 H 4 PteGlu 4 H 4 PteGlu 5 H 4 PteGlu 6 H 4 PteGlu ? HjPteGlu H 2 PteGlU 2
V "
M
7.7 3.4 1.1 2.0 2.7
5.0 2.6
>
K
i("M>
v
max(rel)
100
45
102
8.8
62
11
4.5
14 34 47
1.6
17 5 2000
1
2,5-di ami nopentanoate
2.5
3.2
2,4-diami nobutanoate
5.7
330
2,3-diami nopropanoate
17
glutamate (MTX)
Rat Liver
K
50
nM
R= K562
FPGS Inhibition
1
2,5-di ami nopentanoate 2,4-di ami nobutanoate 2,3-di ami nopropanoate
showed the pentanoate length gives maximum FPGS inhibition.
3.8 200 >1000
The analogs were
relatively weak inhibitors of human leukemia cell growth (Table 2). cytotoxic, the pentanoate MTX itself.
The most
derivative, was 70 to 100-fold less cytotoxic than
However, a CCRF-CEM subline resistant to MTX (250-fold) via defec-
tive MTX transport was only 5-fold cross-resistant to the pentanoate
analog.
This result suggested that this analog might use a pathway of uptake different from that of MTX.
Transport of the pentanoate analog was examined by characterizing its inhibi3 tion of [ H]MTX transport. In these studies, 20 uM pentanoate analog 3 affected neither the initial velocity of transport of 2 nM [ H]MTX by CCRF3 CEM cells nor the plateau level of [ H]MTX at 30 min. Thus, the pentanoate analog either uses a pathway separate from the reduced folate/MTX or uses this transporter with a very low affinity.
transporter
731 Table 2. Cytotoxic e f f e c t s on K562 and CCRF-CEM human leukemia cell
lines
of
2, u-diaminoalkanoic acid analogs of MTX Cell
Inhibitor
line
4-NH 2 -10-CH 3 -Pte-R
EC
R= K562
CCRF-CEM
An analog of f o l i c
50 IIM
2 , 5 - d i ami nopentanoate
1.7
2,4-di ami nobutanoa te
2.3
2,3-diami nopropanoate
3.0
glutamate (MTX)
0.0175
2 , 5 - d i ami nopentanoate
0.74
glutamate (MTX)
0.011
acid,
10-CH 3 -Pte-(2,5-diaminopentanoate)
was also
synthe-
sized.
This compound was a weaker FPGS i n h i b i t o r
than the corresponding MTX
analog
(K^ s >100
state
inhibition
(Kis
pM).
= 7 nM).
reduced d e r i v a t i v e s folates
as
Reduction The
paralleled
substrates.
Thus,
to
the
potency
dihydro
increased
of
inhibition
by
the
the r e l a t i v e
affinities
of
the
the
structural
specificity
of
the
oxidized
FPGS and
corresponding FPGS
for
the
pteridine moiety i s not altered by the s u b s t i t u t i o n of 2,5-diaminopentanoate. These studies indicate that i n h i b i t i o n of FPGS by those compounds i s for the 2,5-diaminopentanoate d e r i v a t i v e . unaltered by t h i s
substitution.
greatest
S p e c i f i c i t y for the pteridine seems
Provided the poor transport
characteristics
of t h i s i n h i b i t o r can be overcome, these studies may allow the design and synt h e s i s of s p e c i f i c FPGS i n h i b i t o r s which may be useful agents.
732 Acknowledgement
This work was supported by ACS Grant CH-288 and CA25236 from the NCI.
JJM i s
a Scholar of the Leukemia Society of America.
References
1.
McBurney, M.W. and Whitmore, G.F. 1974. I s o l a t i o n and Biochemical Charact e r i z a t i o n of Folate D e f i c i e n t Mutants of Chinese Hamster C e l l s . Cell 2: 173-182.
2.
Cichowicz, D., Cook, J . , George, S. and Shane, B. 1985. I n : Proceedings of the Second Workshop on Folyl and A n t i f o l y l Polyglutamates. Hog L i v e r Folylpolyglutamate Synthetase: Substrate S p e c i f i c i t y and Regulation. (Ed. 1.0. Goldman) pp 7-13. Praeger, NY.
3.
Piper, J . R . , McCaleb, G.S., Montgomery, J . A . , Schmid, F.A., and Sirotnak, F.M. 1985. Syntheses and Evaluation as A n t i f o l a t e s of MTX Analogues Derived from 2,0mega-diaminoalkanoic a c i d s . J.Med. Chem. 28: 1016-1025.
AN UPSTREAM GENE REGULATES THE EXPRESSION OF FOLYLPOLYGLUTAMATE SYNTHETASE-DIHYDROFOLATE SYNTHETASE JN ESCHERICHIA COLI
Andrew L. Bognar Department of Microbiology, University of Toronto, Toronto, Ontario, Canada M5S 1A8 Charles Osborne, Barry Shane Department of Nutritional Sciences, University of California, Berkeley, Berkeley, California 94720
Introduction We have recently reported the isolation and cloning of the gene for folylpolyglutamate synthetase-dihydrofolate syntnetase (folC) from Escherichia coli (1).
The folC gene was localized on a 1.5 kb Pvu
I fragment which could complement the methionine auxotrophy of the FPGS-
mutant, SF4 (2).
The smallest DNA fragment whicn also
resulted in amplified expression of the FPGS enzyme when cloned into high copy number plasmids was a 3.5 kb Sst II fragment.
In
this report we describe studies of the expression of FPGS/DHFS activity in plasmids containing the cloned folC gene and snow that an intact upstream gene is required for the high expression of tne enzyme from high copy number plasmids.
Results We have cloned the folC gene by selecting for transformants of plasmids containing E. coli sequences which complement the SF4 mutation.
In the process of subcloning the folC gene, some trans-
formants were found which could complement the SF4 mutant but nad less than wild type levels of FPGS activity in a mutant background. A lOkb Hind III fragment cloned in pKC7 (pH2al, Table I) produces amplified enzyme activity while its suoclone cut with Eco RI (pHE2a4) had only wild type activity.
A 3.5 kb Sst II fragment
was the smallest subclone of the Hind III fragment which gave amp-
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
734 lified enzyme activity when cloned into high copy number plasmids Subclones in which insert DNA was cut at a Kpn I
(pAC3, p2S2-4).
(pAC5R) or PvU I site (p2P2-7) had low activity.
These same sub-
cloned fragments placed downstream from a promoter from the vector, such as the lac promoter (pAC5) of the lambda P T promoter
(p2P2-7)
produced highly amplified enzyme levels in transformants.
These
results initially suggested that the promoter of the folC gene was being deleted by removal of the sequences upstream of these restriction sites. Table 1
FPGS Activities of Transformants of Various Plasmids
Strain
Plasmid
Vector
Site of Deletion
Relative Activity
W1485
-
-
-
1
SF4
-
-
-
0 .09 .
SF4
pH2al
pKC 7
SF4
pHE2a4
pKC7
SF4
pAC3
pUC 8
SF4
pAC5R
pUC8
Kpn I
SF4
a
pUC9
Kpn I
pAC5
-
Eco RI -
SF4
p2S2-4
b
pHE2
SF4
p2P2-7 b
pHE2
Pvu I
SF4
p2P2-7 b
pHE2
Pvu I
a
-
46 1.
.4
71 0 .67 . 15 60 0 .
154
(30°) , 4 (30°) (42°)
The folC gene is downstream from the lac promoter of pUC9 in the proper orientation for transcription.
k These plasmids have the folC gene downstream of the lambda PLi promoter controlled by a temperature sensitive repressor. The DNA sequence of 2.5 kb of E. coli DNA containing the folC gene has been determined.
The Eco RI, Pvu I and Kpn I sites map up-
stream of the coding sequence of the folC gene, as expected (Figure 1).
These sites are not located in a non coding region
but within the coding sequence of an upstream open reading frame. This open reading frame is 912 base pairs long and predicts a protein with a molecular weight of 33,000 daltons.
The non-coding
735 region between the two genes is only 72 bp in length.
Deletion of
sequences upstream of the above restriction sites removes most of the upstream gene and causes a concomitant loss of amplified FPGS expression in transformants.
This suggests that the promoter
function being deleted from the folC gene is the promoter of the upstream gene and that the two genes are co-regulated at the level of transcription.
I
2
3
Figure 1. Physical map of the region of the folC gene showing the open reading frames for the folC gene and the upstream gene. SDS polyacrylamide gel electrophoresis was performed to determine whether the levels of FPGS activity can be correlated with the intensity of the protein bands for the products of the folC and upstream genes.
A protein band which comigrates with purified FPGS
can be seen in extracts of amplified strains, such as transformants of pAC3, but not of wild type or transformants of plasmids with the upstream gene deleted enzyme activity.
(pAC5), which do not have amplified
Initially, we were unable to see a similar in-
crease in intensity of a band corresponding to the predicted size of the upstream gene product in these soluble extracts.
However,
when proteins in the sonic pellets were run on SDS gels, a protein band of Mr 33,000 can be seen which is more intense in extracts from transformants of pAC3 but not of pAC5 or in wild type.
Discussion We have shown that deletion of an upstream gene results in greatly decreased expression of FPGS from the downstream folC gene.
This
suggests that the promoter function responsible for high expression of the folC gene is the promoter of the upstream gene and that the
736 two gene products may be expressed from a polycistronic message. Plasmids with the upstream gene deleted express low but measurable amounts of FPGS.
They are able to complement the SF4 mutation,
suggesting that some wild type enzyme is produced.
This is true
even in plasmids, such as pAC5, in which all promoters present in the vector are oriented in the direction opposite to folC transcription.
This suggests that there may be a weak promoter in the
non coding region between the two genes.
There are sequences in
this region which have homology with the consensus sequences for the -35 and -10 promoter regions.
Studies to determine whether
there is a promoter in this region are currently in progress. We have shown that the upstream gene codes for a protein product and that its expression is coregulated with that of FPGS. function of upstream gene product is unknown at present.
The Its se-
quence has no homology with any gene whose sequence has been previously studied.
It would be very interesting to determine if the
function of this gene product is related to folate metabolism.
Acknowledgement This research was supported by grant no. CA 41991 from the National Cancer Institute, Department of Health and Human Services.
References 1.
Bognar, A.L., C. Osborne, B. Shane, S.C. Singer, R. Ferone. 1985. J. Biol. Chem. 260, 5625.
2.
Ferone, R., S.C. Singer, M.H. Hanlon, S. Roland. 1983. Chemistry and Biology of Pteridines (Blair, J.A., ed.) de Gruyter, Berlin, p. 585.
In:
O C C U R R E N C E A N D S Y N T H E S I S OF a - G L U T A M A T E S IN E S C H E R I C H I A
R. F e r o n e , M .
Hanlon,
Burroughs Wellcome
D.
S.
PTEROYL-y-GLUTAMYL-y-GLUTAMYL-POLYCOLI
Singer
Company,
Research
Triangle
Park, N.C.
27709
Hunt
Department VA 22901
of C h e m i s t r y ,
University
of V i r g i n i a ,
Charlottesville,
Introduction
In m o s t mate the
cells
analysed,
conjugates,
folate
in w h i c h
cofactors
the amide
y-carboxyls
of
the glutamates
as the p o s i t i o n
of
linkage originally
only
synthetic
L. c a s e i
assays
factor")
(1).
for
PteGlu^
a-COOH
linkages
the p r e s e n c e
to p o l y g l u t a m a t e
Results
been
in t h e
chains
y-COOH bond
impure.
We
bonds was
report
Discussion
E. c o l i w a s
grown with
[7-
14
group
to be
here
y-COOH that
as a c t i v e
in
("L.
casei
have been
the
via
finding
susceptibility
although
folylpolyglutamates
a-COOH
polygluta-
of t h e
from t h e
linkages
of t h e i r
conjugases,
via
as
Assignment came
assumed
to
cleav-
preparations
the p r e s e n c e
extracted
in E. c o l i of an e n z y m e w h i c h
and
and
found
are presumed
pteroyltriglutamate
because
p r e p a r a t i o n s of
used have usually
and
then,
folylpolyglutamates
age w i t h
(1).
containing y-COOH
as an e x t r a c t e d Since
are
bonds
adds
of
from E.
linkages.
C]p-aminobenzoate
to
label
folates
then extracted
F o o et al.
(2).
and c l e a v e d to p A B G l u . . , as d e s c r i b e d by (n) 14 The C - l a b e l l e d p A B G l u , . from E. c o l i d i d n o t (n) —
co-chromatograph
with
systems
and
Control
experiments
materials
coli
glutamates
on a Biogel
effected
synthetic
P-4 column
eliminated the
pAB(y)Glu^_^
cleavage
(as a z o - d y e
the p o s s i b i l i t y or H P L C of
on
several
HPLC
derivatives). that
E.
the p A B G l u ,
Chemistry and Biology of Pteridines 1986 © 1986 Walter d e Gruyter & Co., Berlin • New York - Printed in Germany
coli the
738 cleavage and HPLC behavior of standards (y-COOH linked) were not changed when "spiked" into E. coli extracts. The pABGlu^j derived from the cleavage of E. coli folylpolyglutamates were purified by HPLC on C, 0 Nova-pak columns eluted with acetonitrile/ 1o trifluoroacetic acid. Molecular and fragment ions of methylated unknowns, as determined by tandem mass spectrometry, were consistent with the structure of a linear chain of glutamates attached to a p-aminobenzoyl group.
Chiral HPLC on a B-cycl-odex-
trin column of dansylated glutamates formed from hydrolysed E. coli-derived p A B G l u ^
showed the glutamates to be exclusively
the L-enantiomer. The y-COOH linked pABGlu^j standards and the E. coli-derived pABGlu^ n j differed in their susceptibility to digestion by the a-COOH specific enzyme, carboxypeptidase Y.
This enzyme was shown
to cleave authentic pAB-y -Glu-a-Glu., to pAB-y-Glu.,, but not to react with pAB(y)Glu 2 _ 7 .
Purified E. coli pABGlu 4 _ g were each
digested by carboxypeptidase Y to pAB(y)Glu^, in a stepwise manner.
E. coli pABGlu^ was not digested, and co-chromatographed
with pAB (y ) Glu^ .
Thus, in E. coli folylpolyglutamates, glutamates
added after the third residue are linked via a-COOH groups (see Figure 1). FIGURE 1 y-COOH LINKED FOLYLPOLYGLUTAMATES
COOH .¿H
PTERIN—CHjNIR)-^0^-CONH 1)
pABGlu. r Glu
(n>l)
(n> 1)
aciug a-COOH linkage
740 References 1.
Krumdieck., C.L., Tamura, T., Eto, I. 1983. In: Vitamins and Hormones. Vol. 40, Academic Press, Inc., New York, p. 45.
2.
Foo, S.K., Cichowicz, D.J., Shane, B. 1980. 107, 109.
3.
Bognar, A.L., Osborned, C., Shane, B., Singer, S.C., Ferone, R. 1985. J. Biol. Chem. 260, 5625.
Anal. Biochem.
SUMMARY FOLYLPOLYGLUTAMATE SYNTHESIS Edwin A. Cossins Department of Botany, University of Alberta, Canada, T6G 2E9
Since the Symposia held
in La Jolla
(1978) and St. Andrews (1982) the
subject of folylpolyglutamate synthesis has been actively pursued of
in a number
In this regard, there has been noteable progress in studies
laboratories.
of folylpolyglutamate therefore concentrated
synthetase
(FPGS).
on recent and
The presentations
in Session 14
innovative work on this key enzyme of
folate metabolism. The 'state of the art' lecture was delivered the
general
characteristics
by Barry Shane who reviewed
of the bacterial,
fungal and manmalian
synthetases. The complete purification of the bacterial and porcine liver enzymes has allowed detailed study of the physical and catalytic properties of these proteins.
More recently, Shane's group has
sequenced the FPGS gene of E. coli. physiological
role of FPGS
suggested that cellular
Dr. Shane also considered
in the generation of native
folates. It was
Folylpolyglutamate
synthesis
affinities of FPGS for folate
in manmalian tissues
process and FPGS displays a decreased activity with substrates.
the
folate pools and the distribution of polyglutamates
tend to reflect the substrate specificities and substrates.
successfully cloned and
is a slow
longer chain polyglutamate
The lecture also included new data on the inhibition of FPGS by
pteryol-ornithine
derivatives. Replacement of glutamate by ornithine in folate
or antifolates resulted in marked inhibition of FPGS activity. Inhibition of human cell FPGS activity was the subject of the paper by J.J. McGuire and J.R. Piper. Compounds of special interest in this work were folate and antifolate analogs in which glutamate was diaminoalkanoic
acids.
replaced by various
2, omega-
Enzyme activity was strongly inhibited as the analog
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
742
side chain was lengthened to the pentanoate derivative. These compounds were however less cytotoxic to human leukemia cells than methotrexate. data presented
Fran the
it is clear that these compounds have potential as specific
inhibitors of polyglutamate synthesis. The paper by Bognar et al reported FPGS activity.
Methods were described for cloning the fol C
determining its sequence.
An open reading
upstream of the FPGS gene protein.
new work on the expression of 12. coli gene and for
frame of 910 base pairs occurs
and this region encodes for a membrane-associated
Evidence was presented that the expression of both genes was
coregulated. The
last paper
of Session 14 was
given by Dr. R. Ferone.
In an
investigation with Hunt, Hanlon and Singer the polyglutamates of E. coli were shown to contain glutamyl noieties, linked via first three glutamates
are
linked by
a- and y-carboxyl bonds. The
Y-carboxyl bonds whereas additional
glutamates are linked via their a-carboxyl groups.
Cell-freee
extracts of E.
coli were shown to contain an enzyme that produced such a-carboxyl products in vitro.
This activity was separated frcm FPGS-dihydrofolate synthetase by gel
filtration. It was concluded
that
folylpolyglutamate formation in E. coli
involved two distinct glutamyl conjugation reactions.
THE METABOLISM OF PTEROYLPOLYGLUTAMATES
Roy L. Kisliuk Department of Biochemistry and Pharmacology, Tufts University, Boston, Massachusetts 02111
Introduction The most thoroughly documented early study suggesting the existence of polyglutamyl derivatives of folate was that of Ratner, Blanchard and Green (1) who, in 1946, described the isolation of a p-aminobenzoic acid derivative from yeast which contained 10-11 glutamic acid residues. These authors included an addendum which states "Some time after this manuscript was submitted for publication, the structure of folic acid was published (2). It appears that an essential part of the folic acid molecule is analogous to the PAB peptide described here. There remains to be determined, therefore, whether a functional relationship exists between the PAB peptide of yeast and the various conjugates of folic acid." That such a functional relationship does indeed exist has been amply documented and reviewed (3-10). We here briefly review selected areas of folate polyglutamate metabolism under active study including: intestinal absorption, biosynthesis, biodégradation, metabolic chain length alterations, interactions with folate enzymes and enzymeenzyme interactions. We also discuss methanopterin, an unusual folate-like coenzyme involved in methane formation. Intestinal Absorption Decisive studies in this area were made possible by the development of the solid phase synthesis of model folate polyglutamates (11). Intestinal absorption depends on the hydrolysis of dietary polyglutamates which takes place at the mucosal border (12-14). A zinc-requiring exopeptidase has been isolated from the brush border membrane of human intestinal cells (15). This enzyme differs
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
744 from an intracellular hydrolase isolated from the same tissue. Although mucosal cells can convert folate to 5-methyltetrahydrofolate, the main blood form of folate, reduction, methylation and presumably polyglutamylation are not required to transport folate across the villus tip cells (16,17). It is usually assumed that dietary folates are poly-gamma-glutamyl forms but it has recently been reported that E. coli contains folate polyglutamates in which the first three Glu residues are linked through their gamma-carboxyl groups but additional Glu residues are alpha-linked (18) . In addition, the enzyme folate oligoglutamate transpeptidase has been described in rat liver extracts which catalyses the exchange of the terminal Glu residue with methionine, glutamine or glycine (19). Perhaps further studies will reveal that dietary folates contain unusual peptide chains. Biosynthesis Most biological systems convert folates to polyglutamate forms (10). The action of a single enzyme, folylpolyglutamate synthetase, is thought to account for this synthesis in most instances. However, in Neurospora crassa at least two enzymes are involved (20) . One converts H 4 PteGlu 1 to H 4 PteGlu 2 and a second enzyme converts H.PteGlu_ to H.PteGlu,. A third activity found in mitochondria, 4 Z 4 b catalyses the conversion of H 4 PteGlu 2 to H4PteGlu3- E. coli contains two enzymes for folylpolyglutamate synthesis. One is the combined folylpolyglutamate synthetase-dihydropteroate synthetase which can catalyse the synthesis of derivatives containing three gamma-linked Glu residues. The gene for this enzyme has been cloned (21). A second enzyme catalyses the further addition of alpha-linked Glu residues (181• The substrate specificities for many folylpolyglutamate synthetases have been summarized (5,6,10). More recently studies with hog liver (22), mouse liver (23), beef liver (24) and human liver (25) have been carried out. These enzymes all have a broad specificity with respect to the pteridine moiety of folates and folate analogs but they require a free amide carboxyl group on the Glu residue of the folate or antifolate for activity. 5-Methyltetrahydrofolate is generally a poor substrate. The length of the polyglutamate chain synthesized often depends on the substrate offered.
745 DL-threo-4-Fluoroglutamic acid is a chain terminating inhibitor of rat liver folylpolyglutamate synthetase (26) . A methotrexate derivative containing fluorglutamic acid proved to be a potent inhibitor of dihydrofolate reductase but was not converted to polyglutamate forms by H35 hepatoma cells and was considerably less toxic than methotrexate (27) . These results suggest that polyglutamylation is an important component of the cytotoxic effect of methotrexate. Biodégradation It is usually assumed that gamma-Glu-hydrolases commonly found in animal tissues are involved in the biodégradation of folylpolyglutamates but this has not been definitively established (10). In most instances activity is located in the lysosomes (28) . Specificity for folylpolyglutamates is not generally observed (10) but the intracellular hydrolase from human intestine requires the folate portion of the molecule (15). Recent studies on the hydrolysis of methotrexate polyglutamates in murine tissues show that activity is much lower in extracts of ascites tumors (Sarcoma 180, Ehrlich, L1210) than in extracts of liver, small intestine, bone marrow or kidney (29). The tumor cells showed highest activity when harvested during the early logarithmic phase of growth. Activity of the tumor cells grown in vitro was lower than activity found in the ascites forms. A striking instance of a metabolic role for a gamma-Glu-hydrolase is suggested by the studies on the formation of F^PteGlUg from longer chain polyglutamates in E. coli infected with T4 bacteriophage (30). H2PteGlUg is specifically needed as a structural component of the baseplate of this bacteriophage as is the gamma-Glu-hydrolase itself. Alterations in Folylpolyglutamates During Metabolism Studies on the alterations in the chain length of folylpolyglutamates under different dietary or growth conditions were recently reviewed (8). There is a shift to longer chains in Neurospora grown on a high glycine medium (31) , in Lactobacillus casei grown on a low folate medium (32), in quail liver from animals maintained
746 on a high casein diet (33) , and in rats maintained on a folate deficient diet (34). In cultured mouse hepatoma cells starved for folate for 48 hours, GlUg is the predominant folate polyglutamate as opposed to the normal distribution of equal amounts of Glu^ and GlUg (35). These shifts to longer chain lengths may bring about more efficient use of limited amounts of folate. During rat liver regeneration, GlUg and Glu^ derivatives increase at the expense of Glu^ and Glu,. forms (36) . The newly synthesized GlUg forms are predominantly 5-methyltetrahydrofolate, whereas the newly synthesized Glu^ forms are formylated derivatives. Other studies on rat liver (37) found that different H^PteGlu predominate in fractions of rat liver separated according to chain length. Among Glu,. derivatives, 5-methyltetrahydrofolate is the predominant form whereas the Glu^ derivatives are mainly H^PteGlu. These results suggest that derivatives containing different chain lengths may serve different functions and may be located in different cellular compartments. Mouse Sarcoma 18 0 cells have larger folate pools with longer Glu chains than do human Hep-2 carcinoma cells (38) . This observation provides a reasonable explanation for the greater susceptibilty of the mouse cells to 5-fluorouracil, which after conversion to 5fluorodeoxyuridylate, binds to thymidylate synthase more firmly in the presence of methylenetetrahydrofolate derivatives. Improved methods of analysis for tissue folates (39,40) and polyglutamate chain length (41,42,43)have yielded new information on the effects of inhibitors on folate metabolism. For example, methotrexate treatment leads to a decrease in the levels of 5-methyltetrahydrofolate in L1210 cells (43) and MCF-7 cells (40) . This apaprently results from accumulation of dihydrofolate polyglutamates which inhibit the reduction of methylenetetrahydrofolate. Interaction of Folylpoyglutamates with Enzymes A. Regulatory interactions: Polyglutamyl derivatives of 5-methyltetrahydrofolate are known to regulate the activity of at least three folate enzymes; cystathionine-gamma-synthase of Neurospora (44), serine hydroxymethyltransferase of pig liver (45) and glycine N-methyl transferase from rat liver (46). Cystathionine-gamma-synthase, which catalyses a reaction on the
747
on the biosynthetic pathway to homocysteine, requires 5-methyltetrahydrofolate as an allosteric activator. The Glu 7 form is much more potent than the Glu^ form. Thus the methylated coenzyme stimulates the formation of the acceptor of its methyl group and methionine is formed. The weak inhibition of serine hydroxymethyltransferase by 5-methyltetrahydrofolate (47) is enhanced by the elongation of the Glu chain. Inhibition of this enzyme leads to a decrease in the amount of serine used to supply single carbon units for purine, thymine and methionine formation and an increase in the amount of serine available for gluconeogenesis or oxidative metabolism. Glycine N-methyl transferase is a major folate binding protein in rat liver (48). It catalyses the reaction: glycine plus S-adenosylmethionine yields sarcosine plus adenosylhomocysteine. This reaction does not require a folate coenzyme, but is strongly inhibited by the Glu,- derivative of 5-methyltetrahydrofolate (46) . The glycine N-methyltransferase reaction provides a mechanism for removing excess adenosylmethionine which might arise from dietary methionine. Both products of the reaction can be converted to useful metabolites. Adenosylhomocysteine can be split and rearranged to form methionine (49), whereas sarcosine is converted to glycine and methylenetetrahydrofolate in mitochondria (50). B: Coenzyme Interactions: Only one folate enzyme is known to have a stringent requirement for a folylpolyglutamate coenzyme, the nonB^2 requiring 5-methyltetrahydrofolate-homocysteine transmethylase from E. coli (51) or B. subtiltis (52). Other folate enzymes will function with Glu^ derivatives although addition of gamma-Glu residues generally enhances affinity of cofactors for folate enzymes (8-10). One likely role for the polyglutamate chain is to aid in the channeling of folate cofactors among sequential folate enzymes. A role for folylpolyglutamate substrates in substrate channeling has been demonstrated for the two reactions involved in the conversion of formiminoglutamic acid to methenyltetrahydrofolate catalysed by fromiminoglutamate:tetrahydrofolate formiminotransferase and formiminotetrahydrofolate cyclodeaminase from pig liver (53). These enzymes are associated as a tetramer of dimers which binds four pteroylpolyglutamates per octamer. The efficiency of channeling was highest with the pentaglutamate although binding was
748
tightest with the hexaglutamate. This demonstrates that channeling has a steric requirement which can be separated from the affinity of the system for the ligand. Enzyme-Enzyme Interactions Evidence is accumulating which shows that the common conditions used for enzyme assay, in which the enzyme concentration is low relative to the substrate concentration, are a poor reflection of the situation in vivo where the situation is reversed. An example is phosphofructokinase (54) where the widely cited (55) inhibition by ATP is greatly decreased when the enzyme is studied 1) at high concentration (0.6 mg/ml), 2) in permeabilized red blood cells or 3) in the presence of polyethylene glycol which increase the local protein concentration. The authors go so far as to state that "... most kinetic data obtained with routinely diluted enzyme are not extrapolable for quantitatively meaningful regulation in vivo." This is a sobering thought for those of us who always carry out assays with dilute enzyme. High enzyme concentration favors channeling, that is the transfer of ligands from enzyme to enzyme without dispersion in the solvent. An interesting example of this type of transfer occurs between NADH and NADH linked dehydrogenases (56,57). NADH can pass directly from glyceraldehyde-3-phosphate dehydrogenase to alcohol dehydrogenase. Direct transfer occurs when the two enzymes transfer hydrogen from opposite faces (A and B) of the nicotinamide ring. Whenever the two enzymes involved are both A specific or both B specific, transfer occurs through the solvent. Consideration of the molecular basis for the transfer of NADH from one dehydrogenase to another based on the crystal structures of glyceraldehyde-3-phosphate dehydrogenase"and liver alcohol dehydrogenase enables estimation of the electrostatic potential of the enzyme surfaces likely to be involved in docking (58). The A specific dehydrogenases examined have areas of negative potential around the opening designed for the nicotimamide portion of the coenzyme. It is postulated that after the nicotinamide portion of the coenzyme transfers from one enzyme to the next, the remainder of the molecule rotates 180° at the Nj-C^' glycosidic bond before binding to the acceptor enzyme. It is noteworthy that a similar
749
180° rotation is possible in the binding site of dihydrofolate reductase in that the pteridine ring of methotrexate is rotated 180° from that of dihydrofolate about the C g - N 1 0 bond. Future studies of the relationship of folate polyglutamates with their corresponding enzymes will have to deal with the interactions between sequential enzymes as in the thoroughly documented case of the channeling interaction between formiminotransferase and cyclodeaminase mentioned above. We believe a fruitful area for such studies is to be found in the thymidylate cycle. In the animal and bacterial systems so far studied, the three enzymes of this cycle, dihydrofolate reductase, serine hydroxymethyltransferase and thymidylate synthase have not been shown to associate physically. In protozoa, however, dihydrofolate reductase and thymidylate synthase share the same peptide chain (59). The thymidylate cycle has been studied extensively because dihydrofolate reductase and thymidylate synthase are the target enzymes for widely used chemotherapeutic agents. Our attention was particularly drawn to a paper by Harvey (60), who gives a well- reasoned explanation of the antibacterial synergy observed when sulfonamides, which inhibit dihydrofolate synthesis, are combined with trimethoprim, a potent inhibitor of bacterial dihdyrofolate reductase. The essence of the argument is that when trimethoprim is present alone, it will inhibit dihydrofolate reductase until enough dihydrofolate (polyglutamate), generated by the action of thymidylate synthase, accumulates to compete effectively with trimethoprim and overwhelm the block. Reduction of the level of folate coenzyme in the cycle through the action of sulfonamides on folate biosynthesis would render the system more sensitive to trimethoprim because the amount of competing dihydrofolate coenzyme would be lowered. If two enzymes within the cycle are inhibited, antagonism is predicted because only one of the enzymes within the cycle could be rate limiting. Therefore inhibiting the other would be ineffective (61) . We felt that the interaction of the three enzymes in vivo might be more complicated so we tested the growth inhibtion of L. casei brought about by combinations of trimethoprim to inhibit dihydrofolate reductase and 5,8-dideaza-10-propargylPteGlu, a powerful inhibitor of thymidylate synthase (62-64)under conditions where thymidylate is the growth limiting metabolite. Synergistic growth inhibition
750
was obtained with this combination (65). With the Glu 2 derivative of the propargyl derivative, antagonistic, additive or synergistic effects were obtained with increasing concentration. In order to eliminate the possibility of the inhibition being influenced by the transport or metabolism of folates or inhibitors, a system was developed consisting of two enzymes of the cycle, dihydrofolate reductase and thymidylate synthase purified from extracts of L. casei (66). Formaldehyde is the source of the single carbon unit and net thymidylate synthesis is measured under steady state conditions by release of H from 5-(^H)-dUMP. Table 1 Inhibition of Thymidylate Formation by Combinations of Trimethoprim with 5,8-Dideaza-10-propargylPteGlu Derivatives Expt. 1 Cone (M) 1.6 3.3 6.6
X
X
10" 10 10" 10 10" 10
13.2
X
10" 10
X
2 1.7 3.4 6.8 13.6
PPG1 alone
TMP alone
TMP + PPG^
% Inhib.
% Inhib.
% Inhib. Cale. Obs.
1 11 21 36 PPG 2 alone
X X X X
10" 11 11
10" 10" 11 10"
11
0 4 18 34
22 22 22
23 33 43 58
22 TMP alone 10 10 10 10
*
23 24 35 48
TMP + PPG 2 10 14 28 44
14 19 19 36
Abbreviations: PPG-j^ = 5,8-dideaza-lO-propargylPteGlu-j^; PPG 2 5,8-dideaza-10-propargylPteGlu2; TMP = trimethoprim Conditions described in (66) . * TMP conc. 5 x 10 8 M. Folate cofactor added
=
H 2 PteGlu 1 at 1.3 x 10 5 M, NADPH 5 x 10
5
M
Table 1 shows data comparing the inhibition obtained with combinations of trimethoprim with PPGj^ and PPG2- With PPG 1 (Expt. 1) the combination results in antagonism wheras with PPG 2 at lower concentrations a small but reproducible synergistic effect is obtained. The concentration of PPG 2 at which this effect can be observed, 1-3 x 1 0 - 1 1 M, is about 1/100 that of the molar concen-
751 of thymidylate synthase present. The ratio of activities of dihyrofolate reductase to thymidylate synthase in the system is 4:1. The mechanism of the synergistic effect is not known but it may relate to the steady state concentrations of dihydrofolate and tetrahydrofolate. Under conditions where TMP is inhibiting1dihydrofolate reductase, the level of dihydrofolate piling up behind the block would be reduced by inhibition of thymidylate synthase. As inhibition of thymidylate synthase is increased, it becomes rate limiting and the block of dihydrofolate reductase becomes less influential. In this in vitro system, synergism is obtained at low PPG2 concentrations and antagonism at higher concentrations which is opposite to the results obtained in vivo (65). This in vitro system will allow us to study effects of polyglutamate cofactors and inhibitors as well as to compare formaldehyde versus serine plus serine hydroxymethyltransferase as sources of methylenetetrahydrofolate derivatives. It should also enable us to study potential direct interactions between the three enzymes of the cycle. Methanopterin Methanopterin derivatives which are coenzymes of one-carbon metabolism in methane bacteria (67) are not known to occur as polyglutamates. However their structure is truly unique (Figure 1) and the methods used in studies of their structure and biosynthesis aré "state of the art". In addition, they may be considered as analogs of folate polyglutamates in which the Glu chain is replaced by the two pentose units and a phosphate in diester linkage with alpha-hydroxyglutaric acid.
OH
Figure 1
Tetrahydromethanopterin (71)
COOH
752 The structure of methanopterin was elucidated using two-dimensional NMR techniques (68) , whereas that of methenyltetrahydromethanopterin confirmed the results of NMR studies with fast atom bombardment mass spectrometry (69) . The biosynthetic pathway has been stu13 14 died by the incorporation of C (70) and C (71) compoundsi Methanobacterium thermoautotrophicum, from which the methanopterin derivatives were isolated, has less than 1% the level of folate found in E. coli or B. subtilis (72). This indicates that onecarbon metabolism in this organism utilizes methanopterin cofactors in place of folates. We thought it would be of interest to test methanopterin derivatives in some standard folate test systems. Dr. G.D. Vogels of the University of Nijmegen kindly provided us with a sample of methanopterin from which we prepared the corresponding dihydro and tetrahydro derivatives. No growth promoting activity was seen for Streptococcus faecium (ATCC 8043) or Lactobacillus casei (ATCC 7469) at 100 nanograms/ml with any of the three compounds. Folate gives full growth at 1 nanogram/ml. No growth inhibition of these organisms was seen with these three compounds at 1 microgram/ml. In addition, dihydromethanopterin was neither a substrate -5 nor an M. inhibitor of L. casei dihdyrofolate reductase at 5 x 10 Tetrahydromethanopterin was not a substrate for L. casei thymidy-4 late synthase at 3 x 10 M even at 10 times the usual enzyme concentration. These results emphasize the unique character of the methane bacteria since folate derivatives are ubiquitous in other life forms as far as is known. (It should also be mentioned that a gamma-linked diglutamate derivative of 8-hydroxy, 7-demethyl, 5-deazaflavin has been isolated from methane bacteria (67).) Acknowledgement Work in the authors laboratory was supported by Grant CA 10914 from the National Cancer Institute and carried out with outstanding skill by Ms Yvette Gaumont and Dr. Henry Rebandel.
753 References 1. Ratner, S., M. Blanchard, D.E. Green. 1946. J. Biol. Chem. 164, 691. 2. Angier, R.B., J.H. Boothe, B.L. Hutchings, J.H. Mowat, J. Semb, E.L.R. Stokstad, Y. SubbaRow, C.W. Waller, D.B. Cosulich, M.J. Fahrenbach, M.E. Hultquist, E. Kuh, E. H. Northey, D.R. Seeger, J.P. Sickels, J. M. Smith, Jr. 1946. Science 103, 667. 3. Stokstad, E.L.R., J. Koch. 1967. Physiol. Rev. £7, 83. 4. Baugh, C.M. , C.L. Krumdieck. 1971 Ann. N.Y." Acad. Sei. 186, 7. 5. Mc Guire, J.J., J. R. Bertino. 1981. Mol. Cell. Biochem. 3£, 19. 6. Cichowicz, D.J., S.K. Foo, B. Shane. 1981. Mol. Cell. Biochem. 39., 209. 7. Kisliuk, R.L. 1981. Mol. Cell. Biochem. ¿9, 331. 8. Kisliuk, R.L. 1984. In: Folate Antagonists as Therapeutic Agents (F.M. Sirotnak, J.J. Burchall, W.D. Ensminger and J.A. Montgomery, eds.) Academic Press, p. 1. Vol. 1. 9. Goldman, I.D. (ed.). 1985 Proceedings of the Second Workshop on Folyl and Antifolyl Polyglutamates, Praeger. 10. McGuire, J.J., J.K. Coward. 1984. In Folates and Pterins, Vol. 1. (R.L. Blakley and S.J. Benkovic, eds.) Wiley, p. 136. 11. Krumdieck, C.L., C.M. Baugh. 1969. Biochemistry 8, 1568. 12. Halsted, C.H. 1979. Am. J. Clin. Nutr. 32,
846.
13. Selhub, J., G.J. Dhar, I.H. Rosenberg. 198 3. Pharmacol. Ther. 20, 397. 14. Elsenhans, B., 0. Ahmad, I.H. Rosenberg. 1984. J. Biol. Chem. 259, 6364. 15. Wang, T.T.Y., C.J. Chandler, C.H. Halsted. 1986. Fed. Proc. £5, 479. 16. Selhub, J., H. Brin, N. Grossowicz. 1973. Eur J. Biochem. 3J3, 433. 17. Selhub, J., G.M. Powell, I.H. Rosenberg. 1984. Am J. Physiol. 246,G515. 18. Hanion, M.R., R. Ferone, S. Singer, D. Hunt. 1986. Fed. Proc. £5, 1542. 19. Brody, T., E.L.R. Stokstad. 1982. J. Bio-. Chem. 257, 14271. 20. Cossins, E.A., P.Y. Chan. 1984. Phytochemistry 23, 965.
754 21. Bognar, A.L., C. Osborne, B. Shane, S.C. Singer, R. Ferone. 1985. J. Biol. Chem. 260, 5625. 22. Cichowicz, D., J. Cook, S. George, B. Shane. 1985. In: Second Workshop on Folyl and Antifolyl Polyglutamates, (I.D. Goldman, ed.) Praeger, p.7. 23. Moran, R.G., P.D. Coleman, A. Rosowsky, R.A. Forsch, K.K. Chan. Mol. Pharmacol. 156. 24. Schoo, M.M.J., Z.B. Pristupa, P.J. Vickers, K.G.Scrimgeour. 1985. Cancer Research. 45, 3034. 25.
Waxman, D.J., L. Clarke. 1986. Proc. Am Assoc Cancer Res. 27, 255.
26. McGuire, J.J., J.K. Coward. 1985. J. Biol. Chem. 260,6747. 27. Galivan, J., J. Inglese, J.J. McGuire, Z. Nimec, J.K. Coward. 1985. Proc. Natl. Acad Sei. USA 82^, 2598. 28. Priest, D.G., C.D. Veronee, M. Mangum, J.M. Bednarek, M.T. Doig. 1982. Mol. Cell. Biochem. 4_3, 81. 29. Samuels, L.L., Goutas, L.J. D.G. Priest, J.R. Piper, F.M. Sirotnak. 1986. Cancer Research £6, 2230. 30. Kozloff, L.M. 1985. In: Folyl and Antifolyl Polyglutamates (I.D. Goldman, ed. ) Praeger, p. 22. 31. Chan, P.Y., E.A. Cossins. 1980. Arch. Biochem. Biophys. 200, 346. 32. Shane, B., A.L. Bognar, R.D. Goldfarb, J.H. LeBowitz. 1983. J. Bact. 153,316. 33. Thompson, R.W., J. Leichter, P.E. Cornwall, C.L. Krumdieck. 1977. Am. J. Clin. Nutr. 30, 1583. 34. Cassady, I.A., M.M. Budge, M.J. Healy, P.F. Nixon. 1980. Biochem Biophys Acta. 633, 258. 35. Priest, D.G., Doig, M., Mangum, M. 1983. Biochem. Biophys. Acta. 756, 253. 36. Eto, I., C.L. Krumdieck. 1982. Life Sciences 30, 183. 37. Brody, T., J.E. Watson, E.L.R. Stokstad. 1982. Biochemistry 21, 276. 38. Yin, M.B., S.F. Zakrzewsky, M.T. Hakala. 1983. Mol Pharmacol. 23, 190. 39. Wilson, S.D., D.W. H o m e . 1986. Arch. Biochem. Biophys. 244, 248. 40. Allegra, C.J., R.L. Fine, J.C. Drake, B. Chabner. 1986. J. Biol. Chem. 261, 6478.
755
41. Eto, I., C.L. Krumdieck. 1981. Anal. Biochem. 115, 133. 42. Priest, D.G., K.K. Happel, M. Mangum, J. M. Bednarek, M.T. Doig, C.M. Baugh. 1981. Anal. Biochem. 115, 163. 43. Doig, M.T., J.R. Peters, P. Sur, M. Dang, D.G. Priest. 1985. J. Biochem. Biophys. Met. H), 287. 44. Selhub, J., W. Sakami, M. Flavin. 1971. Proc. Natl. Acad. Sci. USA 312. 45. Matthews, R.G., J. Ross, C.M. Baugh, J.D. Cook, L. Davis. 1982. Biochemistry 21,1230. 46. Wagner, C., W.T. Briggs, R.J. Cook. 1985. Biochem. Biophys. Research. Commun. 127, 746. 47. Schirch, L., M. Ropp. 1967. Biochemistry 6, 253. 48. Cook, R.J., C Wagner. 1984. Proc. Natl. Acad. Sci. USA. 81, 3631. 49. Backlund, P.S. Jr., C.P. Chang, R.A. Smith. 1982. J. Biol. Chem. 257, 4196. 50. Wittwer, A.J., C. Wagner. 1981. J. Biol. Chem. 256, 4109. 51. Guest, J.R., S. Friedman, M.A. Foster, D.D. Woods. 1964. Biochem. J. 92^, 497. 52. Salem, A.R., J.R. Patterson, M.A. Foster. 1972. Biochem. J. 126, 993. 53. Pacquin, J. C.M. Baugh, R.E. Mackenzie. 1985. J. Biol. Chem. 260,14925. 54. Bosca, L., J.J. Aragon, A. Sols. 1985. J. Biol. Chem. 260, 2100. 55. Orten, J.M., Neuhaus, O.W. 1982. Human Biochemistry, C.V. Mosby, p. 229. 56. Srivastava, D.K., S.A. Bernhard. 1985. Biochemistry, 24, 623. 57. Srivastava, D.K., S.A. Bernhard. 1986. In: Current Topics in Cellular Regulation and Metabolism (B.L. Horecker and E.R. Stadtman, eds.) Academic Press (in press). 58. Srivastava, D.K., S.A. Bernhard, R. Langridge, J.A. McLarin. 1985. Biochemistry, 24, 629. 59. Ferone, R., S. Roland. 1980. Proc. Natl. Acad. Sci. USA 77, 5802. 60. Harvey, R.J. 1982. Rev Inf. Diseases, 4, 255. 61. Jackson, R.C., A.L. Jackman, A.H. Calvert. 1983. Biochem.
756 Pharmacol. 32^ 3783. 62. Jones, T.R., A.H. Calvert, A.L. Jackman, S.J. Brown, M. Jones, K.P. Harrap. 1981. Eur. J. Cancer, 17, 11. 63. Nair, M.G., D.C. Salter, R.L. Kisliuk, Y. Gaumont, G. North, F.M. Sirotnak. 1983. J. Med. Chem. 26, 605. 64. Nair, M.G. , N.T. Nanavati, I.G. Nair, R.L. Kisliuk, Y. Gaumont, M.C. Hsiao, T. Kaiman. J. Med. Chem. (in press). 65. Kisliuk, R.L., Y. Gaumont, P. Kumar, M. Coutts, M.G. Nair, N.T. Nanavati, T.I. Kaiman. 198 5. In: Second Workshop on Folyl and Antifolyl Pölyglutamates,(I.D. Goldman, ed.) Praeger, p.319. 66. Rebandel, H., Gaumont, Y., R. L. Kisliuk. (This volume). 67. Wolfe, R.S., Trends In Biocemical Sciences. 1985. 10,396. 68. Van Beelen, P., A.P.M. Stassen, J.W.G. Bosch, G.D. Vogels, W. Guijt, C.A.G. Haasnoot. 1984. Eur. J. Biochem. 138, 563. 69. Van Beelen, P., J.W. Van Neck, R.M. deCock, G.D. Vogels, W. Guijt, C.A.G. Haasnoot. 1984. Biochemistry 23^, 4448. 70. Keller, P.J., H.G. Floss, Q. Le Van, B. Schwarzkopf, A. Bacher. 1986. J. Am. Chem. Soc. 108, 344. 71. White, R.H. 1986. J. Bacteriol. 165, 215. 72. Leigh, J.A. 1983. Applied and 800.
Environmental Microbiol. 45,
ADDENDUM This paper is dedicated to the memory of Professor Warwick Sakami (1918-1986), mentor, scientist, friend.
DIHYDROPTEROYL HEXAGLUTAMATE AND T4 PHAGE BASEPLATE ASSEMBLY
Boguslaw Szewczyk*, Krystyna Szewczyk*, and Lloyd M. Kozloff Department of Microbiology and Immunology, University of California, San Francisco San Francisco, California 94143-0404
Summary and Introduction A major step in the assembly of the T4 bacteriophage tail baseplate is the addition of six wedge-like structures around a central hub (1).
The baseplate has a mass of 7.7 xlO^ Kd, it
contains 19 different proteins of known size and six molecules of dihydropteroyl hexaglutamate
(2).
The report by Maley si. al.
(3)
that carbodiimide accivated the carboxyl groups of a labeled folyl polyglutamate and lead to the formation of covalent bonds to thymidylate synthase suggested that a similar approach could identify the baseplate proteins nearest the phage folate.
Culture
media containing l^C-aminobenzoic acid (to label only the folyl polyglutamate) was inoculated with £.. coli
and the host cells
infected with a T4 mutant, unable to form complete particles. Tail substructures containing the baseplate were purified and reacted with carbodiimide.
Six labeled protein bands were found
when tnese baseplates were analyzed by PAGE, two major bands at 41.5Kd and 39Kd, and four minor bands at 82Kd, 55Kd, 31Kd and 25Kd.
The major band at 39Kd was identified using
immunoblotting
as dihydrofolate reductase, a baseplate outer wedge component. The minor 31Kd band appeared to be phage thymidylate synthase, a baseplate hub component, since its mobility on gels was the same as the enzyme.
The other 4 labeled proteins have not been
unequivocally identified.
These results support the proposal
(1,2) that the baseplate folyl polyglutamate links the outer wedges to the baseplate hub.
*
Current address: Department of Biochemistry, University of Gdansk, 80-822 Gdansk, Poland
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
758 Materials and Methods Biological methods were similar to those used before (2).
The
major phage T4 amber mutant used was defective in genes 14 and 15 (B20/N133).
[l^c]-p-aminobenzoic acid was incorporated into the
phage T4 substructure consisting of the baseplate plus the inner tail tube as described earlier (4). dihydrofolate reductase from C.
Antiserum used were:
Mathews; anti-T4
anti-T4
thymidylate
synthase from G. Maley; anti-T4 whole baseplate from P. Berget. G. Maley also furnished purified T2 thymidylate synthase.
SDS-
PAGE, protein transfer to nitrocellulose and immunoblotting were performed by standard procedures
(6,7,8).
l-ethyl-3-(dimethyla-
minopropyl) carbodiimide hydrochloride and 4-chloro-l-naphthol were from Sigma Chemical Co., St. Louis.
Horseradish peroxidase
conjugated to goat anti-rabbit immunoglobulins was from Boehringer Mannheim.
Results and Discussion coupling
Phage Baseplate Proteins ifi.
Labeled Folate ¿¡X Carbodiimide Treatment.
-p-aminobenzoic About lOmg of the
labeled phage purified substructure containing the baseplate plus the tail tube (4) was treated with 100 mg of carbodiimide for 4 hours at 25° at pH 7.0 in 0.05 M TRIS buffer.
The usual
activation at pH 4.75 was not used because at the lower pH baseplate proteins reacted with each other forming insoluble precipitates.
Coupling at pH 7.0 did not lead to any significant
differences in SDS-PAGE profiles of untreated and carbodiimidetreated material which indicated that no measurable reaction between individual substructure proteins took place.
The proteins
of the gels of the treated labeled baseplates were transferred to nitrocellulose and subjected to autoradiography.
Densitometric
analysis revealed six weak, radioactive protein bands (Fig. 1). The two bands of highest intensity corresponded to molecular sizes of approximately 41.5 Kd and 39 Kd, and there were four additional weaker bands of 82 Kd, 55 Kd, 31 Kd and 25 Kd.
759
AL.5
K
39 k
Fig. 1. Densitometer of the radioautograph nitrocellulose of the PAGE gel of 14 C-PABA labeled T4 baseplates with carbodiimide.
tracing from SDS-
Identification fli i i
M
treated
Labeled Baseplate Protein. The direct comparison of the size of a particular gene product on a gel with that of the labeled proteins eliminated some proteins but did not alone identify the folate binding proteins since
linKing of the folate compound to a protein may have slightly altered its electrophoretic mobility (M.W. of folyl polyglutamate is - 1 Kd.
Where possible, immunoblotting was used to confirm the
identification.
When the proteins of the treated labeled
baseplates separated on gel and transferred to nitrocellulose were reacted with anti-phage T4 dihydrofolate reductase serum, only one band of 39 Kd was observed (not shown).
This band corresponded to
14
the 39 Kd protein band labeled with [ C]-p-aminobenzoic acid. The molecular weight of the monomer of phage dihydrofolate reductase (called frd) is about 20 Kd (9), hence it was possible that this anti-frd reacting band is due to the coupling of two frd monomers to the folate compound.
However, when unlabeled
baseplates, not treated with carbodiimide, were similarly immunoblotted with the anti-frd serum, a band in the same position was observed, and no band corresponding to the dihydrofolate reductase monomer was seen.
The folate binding protein of 39 Kd
is then either a modified or an unmodified dimer of two dihydrofolate reductase subunits with a covalent bond between the subunits. imrounoblotting oL Baseplate proteins With other Anti-seta.
The
molecular size of thymidylate synthase (called td) monomer is about 30 Kd.
This molecular weight corresponded to the molecular
weight of the minor protein band of 31 Kd labeled with [l4C]-paminobenzoic acid.
We could not immunologically confirm that this
760 band was td, because the anti-td serum was too weak.
However,
based on the identical mobility of this labeled band and the highly purified T2 td, and the known presence of only a few thymidylate synthase molecules in the baseplate hub, it seems likely tnat this minor labeled band is td.
Efforts were made to
identify the other labeled proteins using anti-baseplate serum and bacterial extracts obtained after infection with various phage mutants.
This baseplate anti-sera has antibodies against gene
product 12 (55 Kd) and gene product 11 (23 Kd), which were potential candidates for the minor labeled bands at 55 Kd and 24 Kd.
It was found that the smallest labeled protein could not be
the baseplate gene 11 product.
When baseplate proteins were
reacted with anti-baseplate serum, the gene 11 product band was higher than that of the labeled protein of MW 24K.
Similarly the
approximately 55 Kd band could not be gP12 since this labeled band migrated somewhat faster than gP12. Baseplate Proteins .Linked ¿s. Folyl Polyalutamate.
The identifi-
cation of the proteins linked to the labeled folate, shown in Table 1, is complicated by the possibility that the 7 activated folyl carboxyl groups plus any activated protein carboxyl groups (which could react with the amino group on the pteridine ring) could bind to more than one protein.
However, one expects that
the initial crosslinking reaction for one protein would so disturb the native structure that a second crosslinking event would become unlikely, and we have favored the view that at least the two major labeled bands represent the folate compound crosslinked to a single baseplate protein. experiments
This conclusion was supported by
(not shown) indicating that there was no non-specific
linking of the folate to basic proteins of the phage structure. The 39Kd major band is clearly the product of the phage frd gene and it is possible that the labeled folate is bound both by its amino group, to possibly the asp-27 residue
(10) of the frd and by
one of its carboxyl groups to some amino group in this protein. The other major labeled band at 41.5 Kd, which is even more highly labeled than the frd band, has not been identified.
The most
likely possibility based on size is the gene 26 product which is a hub component of 41 Kd.
The gene 26 product has not been studied
761 TABLE 1 - COMPOSITION OF THE T4D BACTERIOPHAGE BASEPLATE Molecular Size Kd
Copy Number
Total Mass Kd
Linked to Folate
77 24 49 44 41 29 16
6 -3 6 6 -3
462 72 284 264 123 58 16 1279
Likely Likely No No Likely Yes
88 24 140 46 85 23 15 20
2 4 1 1 2 1 1 -1
176 96 140 46 170 23 15 20 686
Hub 1279 Wedge 686 gP9 34 gP12 55 gP48 44 gP54 36 H 2 Pteglu 6 1
1 6 24 18 6 6 6
1279 4116 816 990 264 216 6 7687
Component Central Hub
Individual Wedge
Complete Baseplate
gP29 gP28 gP27 gP5 gP26 gPtd gP51 gPIO gPll gP7 gP8 gP6 gP53 gP25 gPfrd
~2
and its ability to bind folate is not known.
?
No No No No No No No YES -
NO No No No -
For the minor bands
we have reasonable evidence that the 31 Kd band is due to folate bound to the hub thymidylate synthase.
The band at 25 Kd probably
is due to the binding of the folate to the hub gene product 28, of 24 Kd.
This gene product is a folyl polyglutamate
carboxypeptidase
(11) and would be expected to react with
activated carboxyl groups.
The identity of the final two minor
bands of about 82 Kd and 55 Kd are less certain.
The largest
could be due to the complex of the folate plus the hub gene 29 product, of 77 Kd which is a folyl polyglutamate synthetase (12) but identity of the 55 Kd band is unknown.
These experiments show
that the dihydropteroyl hexaglutamate is near or closely associated with only 6 of the 19 baseplate proteins and clearly plays a specific structural role in this virus particle by linking together two major components.
762 Acknowledgement This investigation was supported by NIH Grant AI 18370 from the National Institute of Allergy and Infectious Disease.
References 1.
Kozloff, L.M. Dubrow, Ed.).
1981. In: Bacteriophage Assembly. (M. Alan R. Liss, Pubi., New York, p. 327
2.
Kozloff, L.M. 1985. In: Proc. of the Second Workshop in Folyl and Antifolyl Polyglutamates. (I. David Goldman, Ed.). Praeger, New York, p. 22.
3.
Maley, G.F., F. Maley. Biophysics 216. 551.
4.
Kozloff, L.M., M. Lute, L.K. Crosby, N. Rao, V.A. Chapman, S.S. DeLong. 1970. J.Virol. jj_«. 726.
5.
Nakamura, K., L.M. Kozloff. 54Q, 313.
6.
Laemmli, U.K.
7.
Towbin, M., T. Stachlin, J. Gordon. Sci. U.S.A. 76. 4350.
8.
Douglas, C.G., B.F. King. 75. 333.
9.
Purohit, S., R.K. Bestwick, G.W. Lasser, C.M. Gogers, C.K. Mathews. 1981. Gene.J.Biol.Chem. 256. 9121.
1970.
1982.
Arch, Biochem. &
1978.
Nature
Biochem. Biophys.
Acta
227, 680.
1984.
197y.
Proc. Nat. Acad.
J. Immunol.
Methods
10.
Howell, E.E., J.E. Villafranca, M.S. Warren, S.V. Oatley, J. Kraut. 1986. Science. 231. 1123.
11.
Kozloff, L.M., M. Lute.
12.
Sadewasser, D.A. L.M. Kozloff. Biophy.Res.Comm. 116. 1119.
1981.
J.Virol. 1983.
40. 645.
Biochem.
EFFECTS OF POLYGLUTAMYIATTON ON FOLATE COFACTOR AND ANTTFOIATE ACTIVITY IN THE THYMIDYLATE SYNTHASE CYCLE OF PERMEABILIZED MURINE LEUKEMIA L1210 CELI£
Thomas I. Kaiman Departments of Medicinal Chemistry and Biochemical Pharmacology, State University of New York, Buffalo, NY 14260
Introduction Polyglutamylation of folate cofactors and cytotoxic folate analogues is an important metabolic process (1,2).
The essential function of the enzyme,
folylpolyglutamate synthetase, responsible for building the poly-y-glutamyl chain was demonstrated by the finding that mutant mammalian cells lacking this enzyme activity cannot survive, unless endproducts of folate requiring metabolic pathways are supplied (2,3). Explanations advanced for the vital role of polyglutamylation (1,2) include increased cellular retention of polyglutamylated folates. Another, based on work with isolated enzymes, is the strong preference of many folate dependent enzymes for the polyglutamylated forms of their folate cofactors over the corresponding monoglutamates (lower K^ and/or increased V^^).
In our laboratory, we have used permeabilized L1210 leukemia
cells to study the effects of polyglutamylation on cofactor and antifolate activity in thymidylate biosynthesis.
Results Partial permeabilization of L1210 cells using high nolecular weight dextran sulfate (5) permitted the study of the influence of polyglutamates on the thymidylate synthase cycle (TS cycle) composed of thymidylate synthase (TS), dihydrofolate reductase (DHFR) and serine hydroxymethyl transferase (SHMT), outlined in Fig. 1. With the provision of substrates and cofactors the TS cycle is fully operational.
The cycle can be initiated at any of the 3
enzymatic reactions and quantitated by measuring the tritium released from the labelled substrate in a manner described for the assay of TS activity in intact L1210 cells (6).
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
764
5-3H-dUMP
1 Thymidylate synthase 2 Dihydrofolate reductase 3 Serine hydroxymethyl
transferase
CONCENTRATION, H Fig. 1. The Thymidylate Synthase Cycle and the Permeabilized Cellular Enzyme Assay. Fig. 2. Cofactor Activities of Pteroylhexaglutamate and Pteroylglutamate (Folate) in the TS Cycle of Permeabilized L1210 Cells. A comparison of the cofactor activities of the mono- and the hexaglutamate forms of folate shown in Fig. 2 clearly indicate a marked preference of the TS cycle for the hexaglutamate. At the physiologically relevant concentration range of 1-3 iiM, maximal activity is achieved by the hexaglutamate, whereas the monoglutamate gives only negligible activity. When SHMT was excluded from the cycle by replacement of serine with formaldehyde as one-carbon source for the 5,10-CH2H4PteGlun cofactor, a similar pattern was obtained, but the difference was less pronounced, demonstrating that both SHMT and TS contribute to the observed effect. Kinetic analysis of the data showed that both the apparent K m and the apparent V ^ ^ are affected by the extra glutamate residues. The results strongly suggest that even full intracellular retention of the monoglutamates of folates would not be sufficient to support effective DNAthymine biosynthesis in L1210 cells in vivo.
765 Hie effects of the extent of polyglutamylation on the functioning of the TS cycle were also examined by varying the chain length from 1 to 7. Fig. 3 illustrates the effect of chain length on the cofactor efficiencies of pteroylglutamates expressed as the apparent V^JJ/K • The results demonstrate the superior effectiveness of the polyglutamate forms.
The differences are
most pronounced between the monoglutamate and the di- and triglutamates with the efficiencies reaching a plateau at 4 glutamate residues. eo MTX[Glun]
50
pM
V/K,
40
20
-
Y/A> j) a
7rrX////)t?}?\
Fig. 3. Chain Length Dependence of the Cofactor Efficiencies of Pteroylglutamates in the OS Cycle of L1210 Cells. Fig. 4. Chain Length Dependence of the Thymidylate Synthase Inhibitory Activity of Methotrexate Polyglutamates in Permeabilized L1210 Cells. The direct inhibition of TS by methotrexate (Mtx) and its polyglutamates was also investigated in this system. As shown in Fig. 4, the inhibitory activity of Mtx increased 60-fold by 3 additional glutamate residues, but no further increase was evident up to the heptaglutamate.
In contrast, the quinazoline
antifolate CB 3717 (7), a potent TS inhibitor, reached stoichiometric inhibition at the triglutamate level at a concentration 15-fold lower than the IC^0-value of the monoglutamate.
This represents a 3-orders of magnitude
higher potency than that shown by the polyglutamates of Mtx.
766
Conclusions This work demonstrates that permeabilized cellular assay systems are useful for the study of the effects of folate and antifolate polyglutamates on intact metabolic pathways. The study of the TS cycle of permeabilized L1210 cells revealed that polyglutamylation of folate cofactors is essential for thymidylate biosynthesis.
The results provide a functional connection between
the genetic evidence for the vital role of folylpolyglutamate synthetase and the preference of many isolated enzymes for the polyglutamylated forms of their folate cofactors.
Acknowledgement This work was supported by research grants CH-192 from the American Cancer Society and CA 35212 from the National Cancer Institute.
References 1. Goldman, I.D., B.A. Chabner and J.R. Bertino, eds. 1983. Folyl and Antifolyl Polyglutamates. Plenum, New York. 2. Goldman, I.D., ed. 1985. Proceedings of the Second Workshop on Folyl and Antifolyl Polyglutamates. Praeger, New York. 3. McBurney, M.W. and G.F. Whitmore. 1974. Cell 2, 173; 183. 4. Taylor, R.T. and M.L. Hanna. 1975. Arch. Biochem. Biophys. 171, 507. 5. Kucera, R. and H. Paulus. 1982. Arch. Biochem. Biophys. 214, 102. 6. Yalowich, J.C. and T.I. Kalman. 1985. Biochem. Pharmacol. 34, 2319. 7. Jones, T.R., A.H. Calvert, A.L. Jackman, S.J. Brown, M. Jones and K.R. Harrap. 1981. Eur. J. Cancer 17, 11.
SUMMARY R. E. MacKenzie McGill University, Department of Biochemistry, Montreal, Quebec, Canada H3G 1Y6 Pteroylpolyglutamates
are preferred substrates for many enzymes having much
lower
than
values
effects clear
of
Km
seen on V^,
the
corresponding
While this f a c t
that we have demonstrated a l l
provide,
and e s p e c i a l l y
if
they
i s well
monoglutamates, established,
the advantages
serve
it
that
a regulatory
with is
still
these
role.
lesser not
substrates
Instances
of
channeling of intermediates between c a t a l y t i c centers have been documented, and a major question
is
whether
this
part of the problem includes
integral
phenomenon occurs the potential
more widely.
enzyme-enzyme associa-
t i o n that has been proposed for many metabolic pathways i n vivo. concept
is
potential role,
not
unique
feature
perhaps
to
folate-mediated
metabolism,
provided by the polyglutamates in
maintaining
specific
is
An
While the
the
that of
additional
a
protein-protein
structural
interaction.
Precedent exists from the observation that the polyglutamates bind to other proteins,
such as hemoglobin, strengthen the quaternary structures of some
enzymes, and in the best-docmented and most elegant studies, have been shown to be important structural components associated with the proteins of the T4 baseplate assembly. To demonstrate
the
types
of
roles
postulated
for
with associating enzyme systems i s extremely d i f f i c u l t .
the
polyglutamates
This i s true both
to i s o l a t e or reconstitute such putative complexes as well as to assay in a meaningful high
fashion
concentrations
permeabilized
maintained
mammalian
exogenous substrates amates.
so as to distinguish
cells
to
in assay
specific
"channeling"
microenvironments. certain
pathways
from simple The
"in
use
situ"
has c l e a r l y demonstrated the requirement for
of with
polyglut-
This approach holds some promise for future studies in this area.
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
RECENT ADVANCES IN THE STUDY OF DIHYDROFOLATE
REDUCTASE
Raymond L. Blakley and James R. Appleman Department of Biochemical and Clinical Pharmacology, St. Jude Children's Research Hospital, Memphis, Tennessee
38101
Introduction
Recently
information
about
dihydrofolate
(DHFR) has been accumulating
rapidly.
Striking
obtained
Refined
results crystal
have
been
structures
have
DHFR from several sources: of
Escherichia
coli
DHFR
Lactobacillus casei triazine
binary
complex
(1);
with with
ternary
chicken
ternary
DHFR
DHFR
of
consists
of
secondary cutting
structure.
hydrophobic DHFR.
one
side
and
quite
trimethoprim
the
DHFR
with
chains
E.
of witn
the
The
coli
DHFR
site
the the
that
of
of
groove
of
join
the
the
exception
It of
is
elements lined
Asp-27
B-sheet.
The
(E^ in
in an extended
stretches
nicotinamide
Chemistry and Biology of Reridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
of
deep with coli
chicken
conforma-
across
moiety
are
structure
is a cavity about 15A
structure.
that
(Figure
containing
Four a helices
remainder
to all three enzymes
a shallow
strands
ternary
(4).
structure
in the case of bacterial enzymes or Glu-30
NADPH Dinds
a
binary
trimetho-
is a twisted B sheet
large,
The active face
tion, occupying five
the
(3); and
the same basic backbone
some
of
(5,6).
8-sheet
loops,
across
numbering)
the
of
complex
complex
(2);
chicken
eight strands, all parallel except the last. against
complexes
binary
complex of NADPH and
liver
1) in which the principle feature packed
for
(MTX)
NADPH-MTX
liver
1.5.1.3)
crystallographers.
reported
inhibitors with
complexes
three enzymes have
(EC
coli DHFR (3); the ternary
have also been described All
the
chicken
of eight other
and
the
the methotrexate
trimethoprim complex with complexes
by
DHFR (1); the ternary
innibitor
prim-NADPH
been
reductase
is
the
ends
located
770
Figure
1 .
Lactobacillus
and m e t h o t r e x a t e . to
tiis-4i> a n d
f r o m Kef. in
the
entrance
side
of
and
chains.
the
coli.
hydrophobic
moieties
hydrogen
carboxamide boxyls,
complex
with
indicate A r g - 4 4 a n d Thr-116,
in
or van der waals
and n i c o t i n a m i d e many
ternary
UHFK
Reproduced
NADPH
equivalent
with
permission
1«.
hydrophobic and
Arrows
Thr-113
casei
uonds
to polar to
bound
of
MADFh with
from
the
side chains, water
cavity.
interactions
There
are
numerous
of the adenine, amino
phosphates,
acid
side
adenine
ribose chains, and
to back bone amide Ns and
molecules
that
form
bridges
to
the carpolar
771 Ail
inhibitors
tnidine,
bind w i t h the 2 , 4 - d i a m i n o
^-triazine
or
pteridine)
h e t e r o c y c l i c ring
similarly
positioned
(pyriin
the
a c t i v e site cavity so that N-1 and the 2 - a m i n o group are close Asp-27 the tion the
(Glu-30
existence
of
(Figure 4-amino
in c h i c k e n
DHFR)
two h y d r o g e n
2).
with a
and
two
consistent
bonds and a c h a r g e - c h a r g e
In addition,
group
geometry
there
backbone
are
hydrogen
carboxyl
the 2 - a m i n o group and a bound w a t e r m o l e c u l e w h i c h bonds to o x y g e n or a c o n s e r v e d Thr residue. otrexate
between
and
between
also
hydrogen
In the case of m e t h -
(MTX) N - 8 is also h y d r o g e n bonded to a b o u n d w a t e r
in turn is h y d r o g e n and
van
heterocyclic
der
Waals
In all cases n u m e r o u s
interactions
ring and side
chain of
also
the
cooperativity
tors
is
mide
inoiety
in part due
side
chain
of of
to some
bound the
in the NADPH
bound
binding
direct and
occur
of
inhibitor
the chain
residues.
NADPH
interaction
its
hydro-
between
inhibitor and m a i n
and side c h a i n a t o m s of n u m e r o u s amino a c i d Positive
which
bonded to the active site carboxyl and to the
h e t e r o c y c l i c N of a c o n s e r v e d T r p . phobic
interac-
bonds
oxygens
to
with
of
associated (3,6).
and most the
ribose
Another
inhibi-
nicotinawith
the
important
c o n s e q u e n c e of the p r o x i m i t y of bound N A D P H and inhibitor
is
that
R
H
ILE 5
H
l
. 0 —
405
THRII3
TYR III
WT- MTX Figure E. coli
2.
Probable
hydrogen
bondings
DHFR. R e p r o d u c e d w i t h p e r m i s s i o n
1y«6 by A A A S .
between
methotrexate
from Ref.
20;
and
copyright
772 binding that
of
are
NADPH
probably
otherwise
expels
bound
in
seven
the
lower
to
nine
part
of
enhance
its b i n d i n g .
a m a r k e d change joining
cavity
of a t t a c h e d
(6).
and
side
This
loop
its change chains
of p a r t of forms
one
in c o n f o r m a t i o n
bringing
some
The
trimethoprim
been
inhibitor
(3).
It
particularly DHFR,
very
favorable
binding that
to bound
inhibitors)
to aB where
backbone the
significant Matthews
with
the
less
its
and
is
4-amino instead
E.
coli
al.
have
ring
usual of
of to
E.
bound
tri-
trimethoprim
binding
(and
other
geometry
approximately
hydrogen two.
bond
to
of
they
so 1 A
only
Although
binding
holoenzymes,
recently
is
it m a k e s ( a
trimethoprim
can
for t r i m e t h o p r i m s e l e c t i v i t y
et
chicken
factors
where
a position
the
DHFR
formed
from
above
aspect
an a l t e r e d
of
inter-
the t e r n a r y complex of
that
in the g e o m e t r y
position
bacterial
and
the
benzene
group
the
in
loop
hydro-
complexes
(3,6)
favorable
(4) have
to
ternary of
the
favorable
a position
ring o c c u p i e s
carbonyl
chicKen
third
into
holoenzyme
are other d i f f e r e n c e s to
moved
Another
the n e t e r o c y c l i c
closer
the
in the case of
interaction
chicken
the
from E. coli
that
being
(3,6).
of
comparing
DHFR
appears
Met-20
methoprim
by
with
favorable
coli
weakly
binding
investigated
this
liver
tight
of
alters
into m o r e
chain.
selectively
the flexible
side
a c t i o n s w i t h the i n h i b i t o r ' s side
one
site
Finally, binding of the c o f a c t o r results
in the c o n f o r m a t i o n
8A and a B
phobic
by
molecules
active
This c o f a c t o r - i n d u c e d d e s o l v a t i o n of the inhibitor may well
(3).
has
water the
there
trimethoprim
seem
not
to
be
(3,4).
reported
(7)
crystallographic
r e s u l t s on DHFR of a quite d i f f e r e n t s t r u c t u r e , a type II R p l a s mid-specified bition =
90
somal
by uM)
despite
E ^ coli
78 amino tion.
This enzyme
The
a
DHFR.
acid
and
Km
of
adjacent
the
H 2 folate
each
surfaces
together barrel
is c o m p l e t e l y very
weakly close
of
folded the
in
three
a
r e s i s t a n t to
inhibited to
It is a d i m e r i c m o l e c u l e
that with
beta
by
interface.
between
corresponding
strand
beta
for
of
subunit
two
identical conforma-
longest
beta
strands
runs
D in s u b u n i t II,
(K^
chromo-
barrel
An 8 A g r o o v e strand
inhi-
MTX
form a third beta barrel having six
the p r o t o m e r - p r o t o m e r
length
is
for
subunits,
outer
each m o n o m e r at
DHFR.
trimethoprim
and
it
is
in
strands the
full
I and
the
proposed
773 that
NADPH
binds
in
this groove.
ternary
complex with NADPH and
suggest
that
with
type
similar
II R-plasmids
catalytic
A hypothetical
H 2 folate have
machinery
model
is proposed
independently
to
that
of
for
which evolved
the
the
would DHFR
chromosomal
enzyme.
Nuclear Magnetic Resonance
Complexes alogues
of
L.
exist
casei
The
NMR
nicotinamide surface
(8,9)
evidence
into solution
enzyme
methoprim
trimethoprim of
NADP+
and
two conformations
that slowly
suggests
or
in
one
in
with
concomitant
the other
changes
undergoes
conformation.
"ring
flipping"
The
the
in the ring
benzyl
s-1 )
(65
at
conformation
By contrast the nicotinamide
(9).
an-
(6 sec - 1
interconvert
that
its
(8) in approxi-
ring of the coenzyme has swung away from
phate moiety the
with
as a mixture
mately equal amounts 31°).
Studies
the
enzyme
pyrophos-
is bound ring of
(10).
to
tri-
Similarly
there are three interconvertiny conformational states of the complex of L. casei DHFR with folate and NADP+
(11).
In
casei
3',5'-difluoromethotrexate
benzoyl
ring
of
the
bound
axis at a rate of 7.3 x 10 3 approximately to
rotation
estimated
bound
inhibitor s-1
to
L.
"flips"
at 25°C with
DHFR
about AHf
(12)
its
symmetry
11.5 kcal/mol,
two-thirds of which is due to the intrinsic about
the
contribution
bonds of
at
the
C-l'
and
protein
C-4'.
to
the
the
The
barrier
rather
observed
low
barrier
(=4.8 Cal/mol) implies that the binding site for the benzoyl ring is not rigid
and
flipping
is facilitated
by
"relaxation"
of
the
protein, ie small transient displacements of protein atoms.
Resonances
have
casei DHPR (13).
been
assigned
to
32 of
the
These residues are widely
out the structure of the protein.
162 residues distributed
of
through-
Assignments have been made for
774 complexes
with
MTX,
witn MTX
C o m p a r i s o n of a s s i g n e d plexes
indicates
coenzyme 13-23)
but
there
structure
in a - h e l i x form
many
in s p e c t r a of
are
in the loop c o n n e c t i n g and
firms
resonances
and w i t h
the
C
sides
earlier
of
studies
three
coenzyme-induced
the
44-49).
These
hydrophobic
(e.g.
14,15)
by
conformation (residues
regions
cavity.
which
com-
is u n a f f e c t e d
8 - s t r a n d A and a - h e l i x B
(residues
NADP+.
MTX and
these
that the B - s h e e t of tne p r o t e i n
binding
changes
and N A D P H ,
the
of
This
con-
the
cer-
lacked
tainty that the s p e c i f i c a s s i g n m e n t s p e r m i t
in the p r e s e n t
work.
That
bacterial
verte-
N—1
of
inhibitors
bound
to
DHFR
from
and
brate sources remains p r o t o n a t e d o v e r the a c c e s s i b l e pH range been confirmed
(16,17).
Oligonucleotide-Directed
Mutagenesis
This
is a new m e t h o d of studying
ship
in e n z y m e s .
tions
into
Figure
E^
1).
DHFR
was
Chen et al.
coli
Both
conformation. intrinsic
enzyme
DHFR
3).
Km
for
for
Gln-45
DHFR:
make
by
(18)
introduced +
have
of NADPH
fluorescence. KQ for
NADPH
These
Gin
and
restricted, measurement
Changes higher
adenine results
in
than
relation-
two s p e c i f i c Thr-113
*
local
to the w i l d - t y p e
stopped-flow
acetylpyridine DHFR.
the s t r u c t u r e - f u n c t i o n
His-45
replacements
Binding
studied
Gln-45
of
kon
crystallographic
m o d e l , does
than a H - b o n d .
This
water
crystal
in
is stronger
the
than w i t h
effects
quenching and
on
Gln-45
k oj =f
of for
wt
DHFR
(Figure
dinucleotide
is
also
greater
not p r o m o t e
is c o n s i s t e n t w i t h Gln-45.
(see
for
indicate
structure.
muta-
Val
(wt) and
that
the
salt
b e t w e e n His-4 5 and the 2 ' - p h o s p h a t e of N A D P H , p o s t u l a t e d
as
has
b e t t e r binding of H i s - 4 5 being
However,
either
bridge
from
the
NADPH
exposed
to
interaction
775
kon
His-45 DHFR
k„.
G l n - 4 5 DHFR
I
*
-O-
_I
2
k 0 ff G l n - 4 5 DHFR
D
I
—k ff fH i s - 4—5
I
0
DHFR
7
0
8
10
PH
Figure
3.
pH
dependence
wc and Gln-45
of
Kon
and
kQff
for
NADPH
binding
to
coli DHFR. Reproduced with permission from Ref.
1 a. Replacement of Thr-113 network, involving 25-rold of
the
and
dependence DHFR.
K.u tor
ertect of
This
is
(thought to have its hydroxyl in an H-bond
H 2 folate) the
due
V and
suggests
pK a -
can
also
loss account
of for
Vai
i-l'l'A binary
V/Kln
are
that
removal
increases
complex
to a faster
and Asp-27 destabilizes its
with
0.4
K.m for
20
to
30-fold.
off
rate.
The
pH
units
lower
of
H-bonding
pK.as than
between
the acid form of Asp-27 with this
the
single
effect
hydrogen
on K m
for
H 2 folate
bond
pH
for
wt
Thr-113
lowering
(2-3
ti2 folate
All
from
of
kcal/mol) and
Kq
for
HTX. Since
neither
113) must
not
change alters V the mutated be
involved
binding of the substrates.
in the
residues
catalytic
process
(His-45, Thrbut
only
in
776 Two
other
franca acid
mutants
et al.
of
(19) in which
(Asp-27)
is
is a revertant
essential
hydride
(Figure reduced which
tor the
4), by
has
the
4.
27 m u t a n t
DHFK
that rate
profiles for (A).
in
of
For
fact
In
as
the
the bound
(a)
log
case
pH
further
from Kef. 2U by p e r m i s s i o n ;
the
The read-
pH
and
is
wt
wt
(b)
(20) is
enzyme, appar-
even at a pH
log
k^t-/!^
(o) and
see R e f e r e n c e
copyright
not
lowered
H2folate
the
DHFK
is
DHFR
7, A s p - 2 7
substrate,
kcat
details
of
oligo-
Asn.
of
6 and
(x), A s n - 2 7 m u t a n t
by
of A s p - 2 7
that
Villa-
low, but
preprotonated
between
of
with
have
carboxylate
only
V/K
wt DhFK
Asp-27
by
carboxylic
constructed
approaches
enzymes.
V and
obtained
active site
replaced the
that
a protonation
pti
(dihydrotolate)
duced
mutant
a maximum
been
both mutants
transfer.
suggesting
ently m e d i a t e s
Figure
so
catalytic
had
mutation,
to Ser-27.
activity
5
One
mutagenesis,
ily m e a s u r a b l e towards
L)HFR
the invariant,
replaced.
nucleotide-directed other
t,. coli
20.
1y86 by A A A S .
Ser-
Repro-
777 w h e n little p r o t o n a t e d H 2 f o l a t e Asp-27
is n o t e s s e n t i a l
bound H2folate. low
pH.
is
consistent
folate
tonated folate
is less
with
in solution.
subsequent
M u t a n t DHFRs are unable
This
for N - 5 of
is p r e s e n t
for e v e n t s
this
interpretation
Km
for
H 2 folate
the
MTX Dinary
and
comparisons
(20).
The
chain
or
bound
MTX.
with
the
no
the
is
for
nearly
positions
of
side
this
the
of
featureless close
unmutated
the
in wt e n z y m e .
The
of
(0.9 A). of
to
H-bonding
to A s p - 2 7
wat-403,
in
arrangement
of
to
(Figure
turn the
to
tne
by
UV d i f f e r e n c e
showed
that
5).
moves
shown
even
amide
mutant
1.4
enzymes
is
spectra
MTX
DHFRs
bound
to
of
is in
compared
H-bonded
again
because
of
the
re-
network.
As
expected,
MTX
and
(21).
wt
at 13
by
C
neutral NMR
The
enzyme
pH
as
spectra
of
latter
technique
remains
even
down
(5.7).
The m o s t likely H - b o n d i n g systems for interaction of
tonated
MTX
Asn-27 the
enzyme
Asn-27
elimination
are
enzyme of
the
wt
enzyme,
and
times
only
27
interaction
The
Ser-27
for
reveals no c o o r d i n a t e
pKa
higher
of
than
sacrifices
minus
wt
unpro-
free
MTX
K Q for
Since
DHFR-MTX
changes g r e a t e r
the
remains
unprotonated
is
energy.
map
of
similar.
kcal per mol of binding difference
below
remarkably ionic
enzymes
protonated
tonated
with
the m u t a n t well
to
is
pH, M T X D o u n d
4.5,
the with
hign
pH
the
identical
at
to
to
or
This is due
Asn-27
unprotonated (20)
the
which
A
bonding
to the m u t a n t
whereas
group
Fixed W a t - 5 6 7 ,
by
hydrogen
bound
[ 2 - 1 3 C]MTX D o u n d
the
A
backbone
change
different
1.9
binding
the
chains
from
in
MTX
a position
largest
for
DHFR-MTX
except
to
side
occupies
at
Asn-27
in
KQ
clear
refined
map
conformation
chain
in
became
p o s i t i o n of fixed w a t e r m o l e c u l e W a t - 4 0 3 bonding
pro-
increase
increase
structures
molecules in
that of A s p - 2 7
marked
difference
change
The A s n - 2 7
more
x-ray
water
fixed
is
in
pKa
no
DHFR.
reasons
density
DHFR-MTX
two
There
even The
of
electron
wild-type
site.
an
complex.
elegant
of
since
is p r e s e n t in s o l u t i o n even at pH 5, so no p r e p r o -
S u b s t i t u t i o n of Asn or Ser for Asp-27 c a u s e s a m a r k e d
vicinity
of
to reduce folate even at
than - 1 . 5 , so that e s s e n t i a l l y
t o n a t e d folate can bind to m u t a n t
minus
However,
to p r o t o n a t i o n
pro-
with
the
binding
for
wt
only
the
to
enzyme,
about
DHFR-MTX
than 0.2 A in
MTX
1.8
again
backbone
778 chain, of
uninutated
(UD1 )
Asp-27
of
Wat-UU5, by
side
i>er-2/ o c c u p i e s
a
takes
serine
binding
in
the p l a c e
going
or H'i'A. just
wild-type
hydrate.
in
enzyme:
chains
a position
from
DHt'K,
of 0D2.
There wt
However,
below
where
and
a
the g a m m a
oxygen
the
oxygen
new
delta
water
In effect, A s p - 2 7
are
three
binary
important
complex
to
molecule,
is
replaced
changes
that
of
in
the
loss of ionic i n t e r a c t i o n b e t w e e n N-1 and the side
chain
of r e s i d u e 27; loss of a h y d r o g e n bond b e t w e e n r e s i d u e 27 and Z-ainino
group;
2-amino
group
interaction energy kcal
(as
in the must gap
it is e v i d e n t combination for
creation the
accounts
inol"1
der Waal's
tool
and and
for
case
enzyme.
1.6 k c a l the
bond
will
crystallography, the
role
undoubtedly
of be
the in
and
the 3000-fold
that the use of d i r e c t e d m u t a g e n e s i s , x-ray
between
exploited
the
binding the
2.6 van
increase
in
especially
in
is an extremely
structural
the
ionic
an a d d i t i o n a l
hydrogen
for
gap
loss of
decrease
enzyme),
lost
to a c c o u n t
If
per m o l
the A s n - 2 7
from
in order
with it
a
of
result
determining
enzyme.
of a van der Waal's
surrounding
MTX
Ser-27
powerful
features much
more
of
the
in
the
future. R
R
HE 5
H
H
H
ASN 27 MTX
Figure
5.
mutant
OtiFK
HE 5
H
Probable (left)
SER 27 MTX hydrogen and
Ser-27
bondings mutant
trom Kef. 20 by p e r m i s s i o n ; c o p y r i g h t
between DtiFK
MTX
(right).
1986 by A A A S .
and
Asn-27
Reproduced
779 Stopped-Flow Spectrophotometry and Fluorimetry
Cayley et al. (22) obtained evidence that wild-type E. coli DHFR exists as an equilibrium between ers),
only
folate.
one
of
which
is
two forms
able
to
(presumably
bind
NADPH,
conform-
H 2 folate
or
MTX and trimethoprim are able to bind to both forms.
In
stopped-flow measurements of the rate of quenching of the protein intrinsic
fluorescence
by mixing
with
ligand,
analyzed as the sum of a rapid process the binding
the decay
(reaction of ligand with
conformer) and a slower process
(conversion
non-binding conformer to the binding conformer). al.
(23) nad obtained
curve
similar evidence
of the
Earlier Dunn et
that L^ casei DHFR also
exists as an equilibrium mixture of two forms, only one of which can bind NADPH. Penner and catalyzed
Frieden by
substrates, the reaction substrate.
(24) recently
coli
DHFR
tne reaction
rate
is abolished
showed
is started
that when
by
adding
increases with
by preincubation
Preincubation
about twice that obtained
also
results
the
reaction
enzyme
time.
to
of DHFR with
in an
initial
for the non-preincubated
the
The lag in either
velocity
enzyme.
The
half-time for the increase in velocity observed with nonpreincubated enzyme is about 0.9s, which corresponds to the half-time of the conversion of the non-binding form of the enzyme to the binding form. We
have
performed
similar
casei, Streptococcus
with
DHFR
faecium and bovine
studies
liver
from
similar results to Penner and Frieden with E. coli. the
other
two
bacterial
enzymes
were
col i, L.
(25) and obtained Results with
qualitatively
similar
(Figure 6) except that the fraction of the enzyme in the ligandbinding
form was less.
(pH 7.5, 20°C) , 58% of
We estimated E. coli
that under our conditions
DHFR was
in
the
ligand-binding
form, 40% of S. faecium DHFR, and 9% of L. casei DHFR.
No lag in
reaction was found when bovine DHFR was added last to substrates, and initial velocity was no greater when the enzyme was preincubated with either substrate.
780
0
10
20
30
Time
Figure casei
6.
Substrate
DHFR.
preincubated final
substrate.
The
pg/ml),
50
50
yM
NADPH,
Equilibria case
of
Ki
enzyme
inhibitor
value
the
(26),
the
binding
of
and
chicken
liver
enzyme
by
taining over
of
50
mM
Tris
of
both
of
L.
H2folate
or
DHFR
(8.8
buffer,
500
to o c c u r
in
If
to
The
and
in
is
inhibitor,
inhibition" which
that
and
this
mM
DHFR
(Figure
is
enzyme or
in
added
com-
a to
E.
rate
to
coli
of
was the
tight-binding a mixture
velocity
"recovery to
con-
decreases
obtained
last
his
sudies
equilibria the
of
last
From data
experiments, H2 folate
the in
presence the
their
S^ faecium,
for
changes
7).
overall
with
by M o r r i s o n a n d
from
added
the
vertebrate
occurs
extended
evidence
the
enzyme
minutes
bacterial
first presented
time-dependent
reaction
in
also appear
Evidence
inhibitors
MTX.
experiments
activity
NADPH,
contained:
subsequently
(27-29).
substrates
"progress ty"
have
measuring
a period
of
DHFR was
who
many
like
the
h a v e a p r o f o u n d e f f e c t on the
inhibitor.
catalytic
inhibitor
H2folate,
complexes
p l e x e s of Sj_ f a e c i u m colleagues
mixture
conformers
these e q u i l i b r i a
for
obtained
pM
in
with
20°C.
between
D H F R s , and
hysteresis
was
without
KCl at p H 7 . 3 5 ,
(s)
induced
Enzyme
40
in
of the
such
activiother
781 components,
it
corresponds
to
forward the
and
is
possible
the
initial
compute:
binding
rate constants
reverse
complex;
corresponding
to
initial and
Ki*
to inhibition
the
initial
reaction;
kf
K^,
and
which
kr
the
for the slow isomerization of
the
after
final
inhibition
constant
the slow isomerization
is com-
plete .
K
K E +
MTX + H
+
.
""
f
- E.MTX.H"\
-
E.MTX.H+*
off Kn
(initial)
V K
The
equilibrium
tion
reaction
11.9
min-1 ,
min).
constant
ranges and
The
Clearly, resulting
(kf/k r
from
kr
can
ratio
development
of
the
as
that
many
conventional
low
kr/kf+kr
initial
inhibition
with
=
for a routine
Kiso)
for
1.1 to 747, kf has be
the final inhibition from
(final)
d
as
of
min-1
the
0.33
(ti/2
ratio
requires
of
inhibitor,
quite
a long
spectrophotometric
Ki*/Kj..
of
tne
and
inhibition
of
that
the
period
assay.
to 116
is often very much lower than
binding
estimates
isomeriza-
values
0.006
gives
the
full
compared
Consequently DHFR
by
anti-
folates produce much too high a value of KiWe have also studied conformational
isomerizations
and
DHFR
ternary
flow
inhibitor
measurements
of
binding.
In our
was
to occur
found
complexes
fluorescence
initial
collaboration
by
with
the
quenching
studies MTX binding
in two steps, a rapid
subsequent isomerization in
of
(30,31).
Dr.
James
of
the
use of due
binary
stopped-
to
ligand
to S. faecium
initial
binding
DHFR and
Recent results with human Freisheim
(32) have
shown
a
DHFR that
binary complex formation with this enzyme also involves an isomerization step following the
human
enzyme
kon
initial complex formation is
extremely
high
and
the
(Table 1). initial
Ki
For (=
782
0
1
2
3 Time
6
(min)
7.
DHFR.
DHFR added last to a mixture with final composition:
DHFR,
90
uM
NADPH,
50 mM Tris,
76
uM
of
5
Figure
shown,
Slow development
4
inhibition
H 2 folate,
25 mM acetate,
MTX
by MTX of at
the
25 mM MES,
S.
faecium 6 nM
concentrations
100 mM NaCl
at pH
7.4, 20°C.
k0ff/K0n)
is
correspondingly
low.
We
have
also
performed
a
preliminary examination of the formation and isomerization of the ternary not K0ff
complex
altered
of
oy
is decreased
initial mined
Ki.
human
the
DHFR
presence
100-fold
Although
(Table of
with
k.on
and
I).
NADPH
in
The
value
the
active
a corresponding k0ff
for enzyme from other sources,
have
not
For all four enzymes
zation ther than case
of
to the of
the
give
initial a
final
initial human
large enough all binding
Ki. as
K^
complex that
Although
the
been
DHFR
lowers
decreases is is
from
deter-
the
40
to
not
other
K^
400 as
still times
great
in
the
over-
DHFR.
it
furlower
that this change exerts a major effect on the of MTX by human
sources
initial isomeri-
still
release
for
lowering of yet
is
and
DHFR
ternary
is but
for which data are available
value
kon
site
in two other cases the pre-
sence of NADPH in the active site drastically Ki.
of
Thus, after
com-
783 piete equilibration of the ternary complex, release of MTX and its replacement by another ligand such as H2folate is limited by the rate of reversal of the isomerization step with t\/2 of 5.9 min (at 20" and pH 7.5). Although the evidence is still fragmentary it appears likely that the binary and ternary complexes of tight-binding inhibitors like H'i'X with IMFK from most sources undergo conformational changes that make a critical contribution to overall binding. The difrerence in conformation of the initial complex and the final
Table 1 .
Kinetics of Methotrexate binding to DHFR
from bacterial and Vertebrate Sources
Binary Complexes Initial Source
¿.coli i-.. casei S. faeciuiii z Chicken liver rluiuan
k
on
H"1 s"1 1.6 x 10 7c x 10 6e 3.0 x 10 5e 2.0 x 1 U8
k
off
s"1 10e 17.2e 0.52e 1
K
D
a
Final K
Db
nM 620c 3000e 1730e
pM 0.62d 4.0e 75e
5
0.11e* = 0,
eclipsed
for
atoms, to
averaging
-1.000
important
these for
atoms N1,
The charges on the endocyclic
an N2,
N1 and
N3 are uniformly more negative than those on N2 and N4, reflecting the formers' greater basicity and proton-binding Table II: Coaparison of the Pyriaidine Ring X-ray Structure, CNDO/2, and MM2P Results. Bonds
X-ray
CNDO/2
MM2p
C6-N1 N1-C2 C2-N3 N3-C4 C4-C5 C5-C6
1 .349 1.332 1.327 1.336 1 .434 1 .410
1 .358 1 .347 1 .347 1 .360 1.356 1 .405
1 .349 1 .340 1 .337 1 .343 1 .400 1 .370
C2-N2 C4-N4 C5-C7 C6-C61
1 .353 1.365 1.555 1 .527
1 .392 1.453 1 .490 1 .494
1 .343 1 .343 1 .548 1 .515
0.047
0 .019
RMSD Torsion
angle
C6-N1-C2 -N3 N1-C2-N3 -C4 C2-N3-C4 -C5 N3-C4-CS -C6 C4-C5-C6 -N1 C5-C6-N1 -C2 RMSD
Angles
Geoaetry DAEP
froa
The
MM2p
used
X-ray
CNDO/2
MM2p
C6-N1-C2 N1-C2-N3 C2-N3-C4 N3-C4-C5 C4-CS-C6 CS-C6-N1
117..0 125..1 117..2 123 .7 111..8 123..5
116 125 114 125 110 123
119. 5 122. 3 117. 2 122. 8 111. 4 121. 8
N1-C2-N2 N3-C4-N4 C4-C5-C7 C5-c6-C61
117..1 112..0 126..2 123..8
117 .4 108 .2 125 .1 126..4
118. 8 112. 2 123. 5 126. 5
1 .9
1 .8
X-ray
CNDO/2
MM2p
-11.3 7.0 6.1 -13.0 8.3 2.7
- 9.1 8.4 3.2 -12.0 10.8 - 1.7
•12.3 6.7 7.2 •13.6 9.8 2.7
2.0
0.9
.9 .2 .4 .5 .9 .5
affinities. method
here
is
that
(4)
and
developed
by
Allinger modified (9)
by
to
aromatic gated
and TT
ed
and
obtain-
Allinger,
from
associated exo-
para-
were
from
apart
conjusystems.
Force-field meters
Rohrer
accommodate
those with endo-
802 cyclic N atoms which were derived based on an analysis of the Xray
crystallographic
calculated torsion
values
angles
structures
for
are
selected
listed
in
listed bond
in Table
lengths,
Table
II
I.
bond
along
The
Mis-
angles,
with
the
and
corre-
sponding observed crystalline and CND0/2-calculated values. MM2p
calculated
pyrimidine
ring
structures
in
nonplanarity
general
in DAMP,
short exocyclic NH2-C bonds observed They are also superior of root-mean-square
accurately DAEP,
and
reflect
DAPP,
in the crystal
(RMSD)
from
the
the
and
the
structures.
to the CND0/2-calculated values
deviation
The
in terms
observed
struc-
tures . Acknowledgement This research was supported by NIH grant no. CA 34714 awarded by the National Cancer
Institute.
References 1.
For a general review of antifolates, see Blaney, J.M., Hansch, C. Silipo, A. Vittoria. 1984. Chem. Rev. 84.»
2.
Pople, J.A., D.L. Beveridge. 1970. Approximate Orbital Theory. McGraw-Hill, New York.
3.
Jaffe', H.H.. 1977. QCPE 315, Exchange, Indiana University.
4.
Allinger, N.L., et al. 1981. QCPE 395, Program Exchange, Indiana University.
Quantum
5.
Welsh, W.J., V. Cody, J.E. Mark, Cancer Biochem. Biophys. ]_, 27.
Zakrzewski.
6.
Welsh, W.J., J.E. Mark, V. Cody, S. Zakrzewski. 1983. In: Chemistry and Biology of Pteridines (J.A. Blair, ed.). Walter de Gruyter, Berlin, 463.
7.
Cody, V., W.J. Welsh, S. Opitz, S. Zakrzewski. 1984. In: QSAR in Design of Bioactive Compounds, Proceedings of the 1st Telesymposium on Medicinal Chemistry. J.R. Prous, 241.
8.
Cody, V. 1986. J. Mol. Graphics 4, 69.
9.
Rohrer, D., private
Quantum
communications.
S.F.
C.
Molecular
Chemistry
Program Chemistry 1983.
BINDING OF INHIBITORS WITH SPIN-LABELED SIDE CHAINS TO DIHYDROFOLATE REDUCTASE (DHFR) FROM SEVERAL SPECIES
R.L. Blakley, R.F. Kulinski, J.R. Appleman Department of Biochemical and Clinical Pharmacology, Research Hospital, Memphis, Itennessee 38101
St.
Jude
Children's
J.R. Piper Drug Synthesis Section, Southern Research Institute, Birmingham, Alabama 35255
Introduction
The use of spin-labeled ligands in the investigation of ligand-enzyme interactions offers a method of investigating the degree to which side chains of bound ligands are immobilized by complex formation, and the degree to which this mobility i-s altered by various factors.
Here we report on the dissocia-
tion constants of complexes of four spin-labeled antifolates with DHFRs from Lactobacillus casei, Streptococcus faecium and bovine liver, and the degree of immobilization of the spin label in these complexes. follows:
4-(2-4-aminopyrimidine-6-ylmethylamino)TEMPO
The ligands used are as ( 1 ), 4-(2,4-diamino-
pteridin-6-ylmethylamino)TEMPO ( 2 ), 4-(metliotrexate-+-amido)TEMPO ( 3 ), and 4-(methotrexate-Y-amido)TEMPO ( 4 ) (Figure 1).
Methods
DHFR was purified from L. casei, S. faecium and bovine liver according to published procedures (1,2,3,4).
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
804
N—• 0
4-(2,4- Diaminopynmidin-6-ylaminomethyl) TEMPO
/
N
.AN HoN
N—•O
N
4-(2,4-Diaminopteridin-6-ylaminomethyl) TEMPO
Figure 1.
Structures of spin-labeled ligands.
The spin-labeled ligands were synthesized by condensing 4-aminoTEMPO with the 6-bromomethyl derivatives of 2,4-diaminopyrimidine and 2,4-diaminopteridine and with y- and a-methyl esters of methotrexate, respectively. For recording EPR spectra, the spin-labeled ligand (100 wM) in 0.5 M KC1 and 015 M potassium phosphate buffer, pH 7.3, was treated with an excess of EHFR
805
(646 pM S. faecium, 663 pM L. casei, 203 yM bovine). mation NADPH was present in excess over DHFR.
Por ternary oomplex for-
EPR spectra were recorded at
23° on a Varian E-104 spectrometer at 9.52 (Hz, 15.4 dB microwave power, 0.8 G and 100 KHz modulation.
Samples contained in 100 &1 capillary pipettes were
placed in a standard quartz EPR tube.
For correction of spectra, spectra were
collected and stored by an E-935 Varian Data Acquisition System (HewlettPackard 1350A graphics translator, 9835B computer).
Titration of spin-labeled
ligand with DHFR was performed by preparing a series of reaction mixtures (volume 100 pi) of the above composition but containing different amounts of DHFR.
K d was calculated by fitting the amplitudes of the h_! peak and the
enzyme concentrations to appropriate equations by the use of an Apple Ilemicrocomputer.
Figure 2. EPR spectra of spin-labeled ligands in presence of excess EHFR.
806 Results Dissociation constants obtained for binary and ternary complexes of the two methotrexate derivatives 3 and 4 were >1 nM for all three enzymes. The ternary complexes of the other two ligands ( 1 and 2 ) ranged from 2.8-31.8 yM. Binary complexes were not examined for these two ligands because it was anticipated that Kq value would be so high tnat measurements of changes in peak amplitude would be difficult. The spin label side chains of
3
and
4
were immobilized only slightly
(Figure 2).
Correlation times were not significantly different in the ternary
and binary
complexes.
This
is in agreement with X-ray crystallography
structures which indicate that the spin label would be outside the hydrophobic cavity.
By contrast, the spin label of
1
and
2
were highly immobilized
(Figure 2), again in agreement with crystallographic structures that indicate the spin label should be inside the active site cavity and would make hydrophobic and van der Waals interactions with hydrophobic residues lining the cavity. This research was supported in part by research grant CA31922 and Cancer Center Support (CORE) grant P30 CA21765 from the National Cancer Institute, Biomedical Research Support Grant SOI RR05584 from the Division of Research Resources and by American Lebanese Syrian Associated Charities.
References
1.
Nixon, P.F., R.L. Blakley.
1968. J. Biol. Chem. 243, 4722.
2.
Blakley, R.L., L. Cocco, R.E. London, T.E. Walker, N.A. Matwiyoff. Biochemistry 17, 2284.
3.
Gocco, L., C. Temple, Jr., J.A. Montgomery, R.E. London, R.L. Blakley. 1981. Biochim. Biophys. Res. Commun. 10£, 413.
4.
Kaufman, B.T.
1974. Methods Enzymol. 34B, 272.
1978.
AFFINITY
LABELING
OF
DIHYDROFOLATE
REDUCTASE
WITH
AN
IODOACETYL
LYSINE
ANALOGUE OF METHOTREXATE
T.J. Delcamp*, A. Rosowsky + , P.L. Smith*, J.E. Wright +
and J.H. Freisheim*
*Department of Biochemistry, Medical College of Ohio, C.S. 10,008, Toledo, Ohio 43699, + Dana-Farber Cancer Institute, Boston, Massachusetts 02115
Introduction Studies
in
recent years
on
dihydrofolate
structural
analogues' possessing
reactive
(MTX)
2),
and
(1,
trimethoprim
(3)
a
reductase
(DHFR)
have
functional
groups
of
acid
sequences
and
closer examination of the
X-ray
crystallographic
(4)
react
The availability of
structures
has
allowed
identity and orientation of the reactive
with respect to inhibitor binding.
that
methotrexate
2,4-diaminodihydrotriazine
covalently with the enzyme purified from various sources. amino
shown
a
residues
This communication describes the covalent
labeling of three DHFRs by one such compound, an iodoacetyl lysine analogue of MTX.
Results and Discussion The
N a -(4-amino-4-deoxy-Nl0-methyl-pteroyl)-N E -(iodoacetyl)-L-lysine
compound
(APA-Lys-IA) (Fig. 1) was synthesized and shown to inactivate I. casei DHFR in apparent covalent to
identify
the
fashion
(2).
In order
labeled residue
[ H]APA-Lys-IA (labeled at HjN-^V
the methylene hydrogens of the was
incubated with
in phosphate experiments
njv
3
molar excess of moiety)
a 4-fold
buffer were
at
pH
U
iodoacetyl casei
7.0.
performed
APA-LYS-IA
DHFR
Similar
with
DHFRs
L 1
purified from chicken liver and an MTX-resistant line.
an initial rapid binding of the compound. to
human
lymphoblastoid
cell
In each case APA-Lys-IA completely inhibited enzyme activity indicating
allow
the
Quantitation
covalent was
incorporation
achieved
by
of
counting
protein after dialysis against 8 M urea.
Incubation for 2 hours was required 1 mol the
inhibitor
radioactivity
Acid hydrolysis
Chemistry and Biology of Fteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
per
mol
enzyme.
associated
with
followed by
amino
808 acid analysis of the covalently-labeled L. casei DHFR revealed a loss of 1 out of
7
histidines
and
both
the
appearance
(Table I).
substituted forms) the chicken
liver
of
carboxymethylhistidine
Carboxymethylcysteine
and human
enzymes.
An
(1-
and
3-
appeared in the case of
increase
in approximately
1
lysine residue that was derived from the compound itself occurred in each of the
compositions.
Finally,
a
difference
UV-VIS
absorbance
spectrum
of
modified human DHFR vs native human DHFR also revealed that 1 mol of APA-LysIA was covalently associated with 1 mol enzyme (Fig. 2).
«111«
ACID CMPOSITIOHS
OF
Tryptic digestion of the modified bac-
«»THE
AND APA-LYS-IA-M0D1FIED DHFRS
terial HUNAN
I . CASFI AMINO
ACID
NATIVE
MODIFIED
NATIVE
HODIFIED
(HHOE)
(NMOI )
(NHOL)
IHWOI )
ASP
17.9
18.9
19.!
THR
12. 4
13.3
6.3
6.6
SER
3.9
3.9
12.0
12.6
GLU
15.2
17.2
21.4
20.1
7.6
8.9
11.5
9.1
GLY
10.1
11.7
13.»
14.1
ALA
13.7
15.0
5.6
5.7
CYS
-
--
-
--
VAL
12.6
12.8
12.1
12.0
BET
1.9
2.5
6.0
5.9
ILE
5.0
OF
NATIVE
ACID.
AND 1)
MODIFIED
NATIVE.
3) MODIFIED DHFR.
2)
crystal casei
sources.
differences sites The
structure
of X-ray
of
MTX-NADPH-DHFR
J.. (5)
809 shows that histidine-28
interacts closely with the y-carboxyl
Reaction
with
of
APA-Lys-IA
L.
casei
DHFR
is
thus
not
group of MTX.
unexpected.
In
contrast, X-ray crystallographic studies of chicken liver DHFR show that the single
cysteine
residue
at position
11
in
the
N-terminal
participate directly in inhibitor or NADPH binding (6). free APA-Lys-IA was
in solution
investigated
by
is responsible for the
incubating
large
molar
region
does
labeling of the cysteine
excesses
(50
to
iodoacetic acid for one hour with native human and chicken
100-fold)
liver DHFR.
effect on enzyme activity was observed nor was carboxymethlycysteine upon
amino
sufficient
acid length
analysis. and
Thus,
APA-Lys-IA
conformational
may
flexibility
not
The possibility that
possess to
a
extend
No
detected
side-chain away
of
from
of the
active site in order to react with the cysteine residue of either the human or avian
enzyme.
functional
Further
studies
with
MTX
analogues
possessing
reactive
groups may contribute a better understanding of the disposition in
solution of the reactive groups of DHFRs both near and distant from the active site.
Acknowledgment This research was supported in part by NIH grant number CA-41461 (J.H.F.) and in part by CA-25394 (A.R.)
References 1.
Johanson, R.A. and J. Henkin.
1985.
2.
Rosowsky, A., J. E. Wright, C. Ginty, J. Uren. 960.
3.
Tansik, R.L., D.R. Averett, B. Roth, S.J. Baccanari. 1984. J. Biol. Chem. 259, 12299.
4.
Kumar, A.A., J.H. Mangum, Biol. Chem. 256, 8970.
5.
Matthews, D.A., R.A. Alden, J.T. Bolin, D.J. Filman, S.T. Freer, R. Hamlin, W.G.J. Hoi, R.L. Kisliuk, E.J. Pastore, L.T. Plante, N. Xuong, J. Kraut. 1978. J. Biol. Chem. 253, 6946.
6.
Volz, K.W., D.A. Kaufman, J. Kraut.
D.T.
J. Biol. Chem. 260, 1465.
Blankenship,
1982. Paterson,
J. Med. Chem. 25, D.
Stone,
J.H. Freisheim.
Matthews, R.A. Alden, S.T. Freer, 1982. J. Biol. Chem. 257, 2528.
C.
1981.
Hansch,
D.P. J.
B.T.
ESCHERICHIA COLI DIHYDROFOLATE REDUCTASE ISOLATED AS A FOLATE COMPLEX
S.S. Joyner and D.P. Baccanari The Wellcome Research Laboratories, Research Triangle Park, NC
27709
Introduction Multiple forms of dihydrofolate reductase (DHFR, EC 1.5.1.3) can be caused by a variety of factors.
For example, the two isozymes of E. coli RT 500 DHFR
(called form 1 and form 2) differ in a single amino acid (1).
Another type
of multiplicity is seen with the chicken liver (2), Lactobacillus casei (3) and L1210 enzymes (4).
These reductases can be isolated as both the free
enzyme and as a naturally occurring, enzyme-NADPH binary complex.
The present
study shows that E. coli RT 500 DHFR exists in multiple enzyme-folate complexes in vivo.
Results E. coli RT 500 DHFR was purified by a combination of gel filtration and hydrophobic chromatography on hexylamine agarose.
The hydrophobic matrix had a
high capacity for the enzyme (>77 units/ml), and elution was easily achieved with a KC1 gradient.
However, under these conditions, three peaks of enzymic
activity were observed (for example, see Fig. 1).
The first had the electro-
phoretic mobility and kinetic properties of the form 2
coli DHFR isozyme,
whereas enzyme from both the remaining peaks was similar to the form 1 isozyme. Although this multiplicity could have been caused by a variety of factors, one interpretation is that the form 1 enzyme was being isolated as both a free enzyme and an enzyme-ligand complex.
This was tested further.
E. coli RT 500 was grown in the presence of [ l 4 C]p -aminobenzoic acid to determine whether or not folates synthesized in vivo were associated with the enzyme.
Cells were harvested, lysed, subjected to ammonium sulfate fractiona-
tion, and applied to an AcA 54 gel filtration column.
Although proteins
eluted throughout the total fractionation range of the column, only two peaks of radioactivity were observed.
One co-eluted with the DHFR activity, and
Chemistry a n d Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
812 the other eluted in the total volume of the column.
Both of these fractions
were shown to contain biologically active folates by their ability to support the growth of L_¡_ case i. The DHFR pool from the gel filtration step was loaded onto a hexylamine agarose column and eluted with KC1. observed (Fig. 1, left).
Three peaks of enzymic activity were
The first had a high pH 5 to pH 7 enzymic activity
ratio, which is characteristic of form 2 RT 500 DHFR (5).
The other two
peaks had higher enzymic activities at pH 7 than at pH 5, which is characteristic of the form 1 isozyme.
Radioactivity was associated only with the
form 2 peak and the first form 1 peak, and of these, only the form 2 peak was capable of supporting the growth of L^ casei (Fig. 1, right).
However,
folates are isolated from E\_ coli (and most other organisms) as polyglutamates containing up to 7 additional glutamate residues (6), yet L c a s e i can only utilize pteroyl mono-, di- or triglutamates.
When the hexylamine agarose
column fractions were treated with hog kidney conjugase to hydrolyze folylpolyglutamates, the radioactive form 1 enzyme peak then supported the growth of U
casei (Fig. 1, right).
Figure 1. Hydrophobic chromatography of DHFR isolated from E\ coli grown in the presence of [ ^C]p-aminobenzoic acid. 30 units of DHFR (specific activity = 41 U/mg) from an AcA 54 gel filtration column were applied to a 10 ml hexylamine agarose column. Left panel: 1 ml fractions were assayed both in 0.1 M imidazole-Cl pH 7 and 0.1 M succinate-Tris pH 5. Right panel: The same fractions were assayed for their 14C radioactivity [ ] and ability to support the growth of casei with [ ] or without [ ] pretreatment with conjugates. The arrows indicate the locations of the three peaks.
813 The three peaks from the hexylamine column were subjected to analytical Polyacrylamide electrophoresis, and each fraction was found to be free of nonreductase proteins (Fig. 2). small amount of form 1.
The first peak was predominately form 2 with a
Peak 2 contained a mixture of the two isozymes, and
the third peak was pure form 1.
Folates (measured by their radioactivity)
dissociated from both isozymes during electrophoresis and co-migrated with the bromophenol blue front.
RELATIVE MOBILITY Figure 2. Polyacrylamide electrophoreses of hexylamine-agarose purified DHFR. Peak 1, left; peak 2, middle; peak 3, right. Gels were stained for protein and scanned at 600 nm. The origins and bromophenol blue fronts are marked.
Discussion The biological significance of the DHFR-folate association is not known, but its existence may be related to the intracellular enzyme concentration. Silhavy et al. (7) have shown that ligands do not readily diffuse from proteins when the concentration of protein is much greater than its K 95% pure.
is not a multimer
and kinetic properties
for this enzyme (7).
The enzyme exhibits
as reported
by others
a Mr
(7).
=
The
are quite different from those reported
Antibodies to the human DHFR bound to the
by
plant
TABLE I. PURIFICATION OF D1HYDR0FQLATE REDUCTASE FROM SOYBEAN SEEDLINGS VOLUME STEP
TOTAL PROTEIN
(ML)
1) POST PROTAMINE
3000
"(KG)
SPECIFIC ACTIVITY
RECOVERY
*(UMOLES/MIH)
TOTAL ACTIVITY
(UMOLES/HIN/HG)
(I)
(10)
0.0005
22.000
2)
MTX-SEPHAR0SE
0.076
3)
ULTR0GEL AcA 51
0.25
4)
BLUE SEPHAROSE
0.053
30 56.6
30
* ONE UNIT OF ACTIVITY IS DEFINED AS THAT AMOUNT OF ENZYME WHICH CATALYZES THE CONVERSION OF 1 UMOLE OF DIHYDROFOLATE TO TETRAHYDROFOLATE PER MINUTE AT pH 7.5 AND AT 45°C. "
PROTEIN IS ESTIMATED BY THE B10RAD PROCEDURE USING BOVINE SERUM ALBUMIN AS A STANDARD.
enzyme on Western blots and cross-reacted significantly (about 70 percent) in immunoassays
indicating some sequence homology between the two enzymes.
The
Km values of NADPH and FAH2 were determined to be 21 yM and 15 yM, respectively.
These values are 5-10 fold higher than those reported for other DHFRs
suggesting
lower
affinity
for
FAH2
and
NADPH
[Table
II].
It
was
also
surprising to find that FA which has a high affinity for the vertebrate DHFRs, had
very
little
affinity for plant (I50
=
130
ferences at site.
TABLE II. KINETIC PROPERTIES OF DHFRS
enzyme
indicating mode
the pM) dif-
in
its
of
binding
the
active
The
soy-
KM (M x IO6) SOURCE
MR
-,
(x 10"3)
FAH?
NADPH
pH
SPF AC1
OPTIMUM
EFFECT O F KCL
EFFECT O F MERCURIAL
SOYBEAN
22
21
15
7.4
15 (22°C)
INHIBITION
NO EFFECT
L. CASE I
18.3
0.36
0.78
6.5
12 (30°C)
ACTIVATION
NO EFFECT
HUMAN
21
0.04
0.25
15 (22°C)
ACTIVATION
ACTIVATION
4; 7.3-8.3
817 bean DHFR exhibits
a single
have two pH optima (8).
pH optimum, unlike other eukaryotic DHFRs which
Human DHFR is activated 1-2 fold in the presence of
0.1 -1.0 M KC1 (8), but KC1 inhibited the soybean enzyme ( I 5 0 = 0.8 M).
Also,
the plant enzyme, unlike human DHFR, showed no activation upon treatment with organomercurials cysteines
either
present
may
in
the
presence
therefore
be
or
absence
inaccessible
of
to
NADPH.
The
modification
two
or,
if
modified, cause no perturbation of the active site.
table
in.
'50/150(methotrexate)
inhibition of various » F R s by wiTiFOLATCs
T2
3
„
soybean
? Y methotrexate
i
*
33300
TRIMETHOPRIM
4Q700
triuetrexate
tJOQOOO
„
900
-,
against
y
"2 NHj ' 0 H J^grs"-»-©-^" „„
8 4
„
3 0 0 0 0 0
Q 5
m e
the
compared
bacterial
and
human
DHFRs
III). enzyme,
The plant like the other
enzymes,
0
10.6
(Table
showed
stoichiometric
a
26
binding to the plant 3 1" enzyme was ca. 37-fold
COOH
weaker
COOM
„ o
„
J ^ ^ i ^ ^ W
prim 123461
176700
1
56
6-fold the
y^
U T W S t S s * *
1 2 7 7 5 5
j^^SW^z-jO^Q)-^ ,20921
53.3
3.5
6
500
24
32
J"1 oR
3 2
l5Q=AM0UNT OF INHIBITOR NECESSARY TO ACHEIVE FIFTY PERCENT ENZYME INHIBITION compounds
were
potent
inhibitors
while
was
greater
than
DHFR.
restingly, ate,
which
potent
ally
trimetho-
binding human
human 128750
quinazoline
inhibi-
tion by MTX with a Kd < 10" 1 0 M. Pyrimethamine
H365
T!
and
were
H
rgjori^'^x^A00"3
nh2
inhibitors
tested e n z
1
^ pyrimethamine
1
"
7299% pure
was 15-20 U/mg p r o t e i n .
amino a c i d sequence a n a l y s i s o f 50 % of
in the crude
The s p e c . a c t i v i t y
confirmed
but r e v e a l e d t h a t
approx.
M15 c o n t a i n e d an a d d i t i o n a l
The two forms c o u l d not be
separated. Broad pH-optima were o b s e r v e d a t
5.5 and 8 . 0 ,
whereas pH optima
f o r mouse S-180 DHFR were a t pH 4 . 5 and 8 . 0 . K i n e t i c f o r the s u b s t r a t e and NADPH were v e r y s i m i l a r bovine-,
mouse-,
and rat-DHFR
between human-, b o v i n e - , testing
(Table
(Table
2,
t o those
1 ) . Small
of
differences
mouse- and rat-DHFR were r e v e a l e d by
t h e enzyme w i t h s e v e r a l
inhibitors,
constants
structurally
different
Fig.3).
During c h r o m a t o f o c u s i n g o r chromatography on a B i o r e x - 9
column,
s t a b i l i t y problems were e n c o u n t e r e d w i t h t h e h-DHFR i n
contrast
t o t h e mouse S-180 enzyme. The p i PAG-plates
(LKB,
pH 3 . 5 - 9 . 5 )
focusing process,
could not be d e t e r m i n e d
due t o p r e c i p i t a t i o n d u r i n g
p r o b a b l y caused by removal of
enzyme was more s t a b l e i n phosphate b u f f e r , Tris-HCl,
i n t h e p r e s e n c e of
4000 as t h e p r e c i p i t a t i n g They b o t h d i f f r a c t meters a r e as Form A :
bound f o l a t e .
pH 7 . 0 ,
than
The
in
pH 7 . 8 .
The pure h-DHFR, o b t a i n e d lized
on the
from t h e a f f i n i t y
step,
was
crystal-
MTX and NADPH u s i n g p o l y e t h y l e n e agent.
Two c r y s t a l
forms were
t o h i g h r e s o l u t i o n and t h e i r
glycol
obtained.
unit c e l l
para-
follows:
s p a c e group P3^12 w i t h a = b = 3 8 . 5 A and c = 2 2 6 . 8 A
Form B: space g r o u p C2 w i t h a = 65.8 A,
b = 4 0 . 1 A,
and B = 1 1 0 . l o . X-ray s t r u c t u r a l
studies are in
progress.
c = 76.3 A
842 Table 1:
Comparison of K m -values for substrate and NADPH Km
Substrate
Human
(^M) for DHFR from
Bovine
Mouse S-180
Rat
Dihydrofolate
0.72
1.2
0.57
0.79
NADPH
2.5
1.0
1.9
1.8
Table 2
Inhibition constants of several inhibitors Ki (nM) for DHFR from
Inhibitor
Human
Bovine
Mouse S-180
0. 017
0.027
Compound 1
7.33
2 . 99
18 . 1
Compound 2
5.04
0.33
2 .6
Methotrexate
Compound 3
487
418
3 2
NH2
y ° 'm
t y j V v 1
kA^J
0 . 033
NH;
Hs n
576 • 0CH:
h
2
3
Figure 3: Structures of some inhibitors tested (Table 2)
References 1. Matthews, D .A . , J.F.Bolin, J.M.Burridge, D.J.Filman, K.W.Volz, B.T.Kaufman, C.R.Beddell, J.N .Champness, D.K.Stammers, J.Kraut. 1985. J.Biol.Chem. 260, 381-391 2. Kuyper, L.F., B.Roth, D.P.Baccanari, R.Ferone, C.R.Beddell, J .N.Champness, D.K.Stammers, J.G.Dann, F.E.Norrington, D.J.Baker, P.J.Goodford. 1985. J.Med.Chem. 28, 303-311 3. Kompis, J., R.L.Then. 1984. Eur.J.Med.Chem. 19, 529-534 4. Masters, J.N., G.Attardi. 1983. Gene 21, 59-63 5. Stueber, D., I.Ibrahimi, D.Cutler, B.Dobberstein, H.Bujard. 1984. EMBO J. 3, 3143-3148
LEVELS OF FOLATES AND METHOTREXATE POLYGLUTAMATE FORMATION IN CHINESE HAMSTER OVARY CELLS LACKING DIHYDROFOLATE REDUCTASE
P. Joannon, H. Goldberg, V.M. Whitehead, D.S. Rosenblatt, M.J. Vuchich, D. Beaulieu McGill University-Montreal Children's Hospital Research Institute, Montreal, Canada, H3H 1P3
Introduction Accumulation of methotrexate polyglutamates (MTXPGs), particularly those with more than 3 glutamyl residues, appears to contribute both quantitatively and qualitatively to MTX cytotoxicity (1).
We have found that mutant (DUK) Chinese
hamster ovary (CHO) cells which lack dihydrofolate reductase (DHFR) (2) accumulate higher levels of MTXPGs and longer chain-length MTXPGs than do control (UTC) CHO cells (3).
We
report levels of folates in these two cells as well as evidence that differences in folates do not explain the differences in MTXPG formation.
Methods Both DUK and UTC were grown in monolayer culture in modified Ham's F12 medium which contains glycine, hypoxanthine, thymidine and 2.3 mM folic acid together with 10% fetal calf serum (FCS). Heated cell extracts were treated with hog kidney tf-glutamyl hydrolases.
Folates were assayed by Dr. B.A. Cooper using
differential microbiological assay (4).
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
844
UTC were folate depleted by growing them in folate-free Eagle's minimal essential medium (MEM) with the addition of 10% undialysed FCS.
After 7 days, doubling times increased from
about 20 to 70 hours. /uM folic acid.
Controls were grown in MEM containing 2.3
Starting on days 8,9 and 10, cells were
incubated with 1.0 /uM [ 3 H]MTX (Moravek Co.) for 24 h.
After
incubation, cell extracts were prepared directly (total MTX) or after 1 h incubation in MTX-free medium (non-exchangeable MTX) and analysed by HPLC (5).
Results Levels of total folates in UTC measured by L. casei were higher than in DUK (Table 1).
About half the folates were active for
growth of S. fecalis and P. cerevisiae, consistent with the presence of reduced folates such as 5-CHO-H4folate, lO-CHOH4folate, 5,10-CH2~H4folate and I^folate.
The remaining
folate which was detected by L. casei only was 5-CH3~H4folate. In DUK, all the folate was active for growth of L. casei and S. fecalis, but not for P. cerevisiae identifying it as folic acid. Since the predominant folate supplied was folic acid, this finding provides additional evidence of the absence of DHFR in these cells.
The complete absence of reduced folates from DUK suggests
that they do not utilize or retain reduced folates present in the FCS.
To determine whether reduced MTXPG formation in UTC was due to their increased level of reduced folates compared to DUK, UTC were depleted of folates by prolonged growth in low-folate medium and MTXPG formation studied (Table 2).
No increase in levels of total
845 TABLE 1 Cell line
LEVELS OF TOTAL FOLATES IN UTC AND DUK CELLS n
Lactobacillus casei
Pediococcus cerevisiae
Streptococcus fecalis
nmol/g protein (mean ± 1SD) UTC
8
40.2+7.2
DUK
8
6.1+2.3
TABLE 2
Folate status
16.5+3.8 0.0
n
control
lh Efflux
intracellular MTX and MTXPGs - nmol/g (% total)
12.5
control
deficient
7.4+2.8
EFFECT OF FOLATE DEPLETION ON TOTAL AND NON-EXCHANGEABLE MTX AND MTXPGs UTC
Total
deficient
26.9+5.2
9.7
3
3
12.4
8.3
MTX
MTX
MTX
MTX
G1U2
G1U3
GIU4
TOTAL MTXPGs
7.4
2.0
2.8
0.4
5.1
(59)
(16)
(22)
(3)
(41)
4.0
2.1
3.1
0.5
5.7
(41)
(22)
(32)
(5)
(59)
8.2
1.8
2.2
0.2
4.2
(66)
(14)
(18)
(2)
(34]
4.0
1.7
2.4
0.2
4.3
(48)
(21)
(29)
(2)
(52)
846
and non-exchangeable MTX, in proportion of total MTXPGs or in the predominant chain-length of MTXPGs was found in folate-depleted UTC compared to controls.
Prolongation of the
doubling time of UTC after growth in low folate medium for 7 days indicated that they were folate deficient.
These findings
support the hypothesis that the longer chain-length MTXPGs formed in DUK cells compared to UTC is due to differences in the level of DHFR.
Binding of MTXPGs to DHFR as they are formed
interferes with their further elongation (3).
References 1.
Chabner, B.A., C.J. Allegra, G.A. Curt, N.J. Clendennin, J. Baram, S. Koizumi, J.C. Drake, J. Jolivet. 1985. J. Clin. Invest. 76, 907.
2.
Urlaub, G., L.A. Chasin. 1980. Proc. Natl. Acad. Sei. 77, 4216.
3.
Joannon, P., V.M. Whitehead, D.S. Rosenblatt, M.-J. Vuchich, D. Beaulieu. 1986. Proc. Amer. Assn. Cancer Res. 21_, 254.
4.
Cooper, B.A., E. Jonas. 1973. J. Clin. Path. 26, 963.
5.
Whitehead, V.M., D.S. Rosenblatt. 1985. In: Proceedings of the Second Workshop on Folyl and Anti-folyl Polyglutamates (I.D. Goldman, ed.). Praeger Scientific, p. 214.
METHOTREXATE
IN A D J U V A N T
ARTHRITIS
John Galivan, Mary-Catherine
Rehder
W a d s w o r t h C e n t e r for L a b o r a t o r i e s a n d R e s e a r c h , D e p a r t m e n t of H e a l t h , A l b a n y , N e w York 1 2 2 0 1
Suresh
N e w York
State
Kerwar
D e p a r t m e n t of I n f l a m m a t i o n a n d I m m u n o l o g y , M e d i c a l R e s e a r c h Division, American Cyanimide Company, Lederle Laboratories, Pearl River, New York 10965
Introduction Numerous clinical v a l i d i t y of
studies
in r e c e n t y e a r s h a v e d e m o n s t r a t e d
low dose m e t h o t r e x a t e
rheumatoid arthritis
(1-5).
in the a m e l i o r a t i o n
Because
little
the m e c h a n i s m o f a c t i o n of m e t h o t r e x a t e we have
i n i t i a t e d a s t u d y of
on animal models arthritis that used
this
We have shown that
to d o s e s of m e t h o t r e x a t e
arthritis
antimetabolite adjuvant
(6) a n d s t r e p t o c o c c a l c e l l w a l l a r t h r i t i s
both respond
concerning
in r h e u m a t o i d
the e f f e c t of
for a r t h r i t i s .
is k n o w n
the
of
(7) in
that are equivalent
in t h e t r e a t m e n t of r h e u m a t o i d a r t h r i t i s
rats to
in m a n .
Further studies have been u n d e r t a k e n with the a d j u v a n t model determine
a) t h e i m p o r t a n c e
achieving
a therapeutic
of the t i m i n g
response
requirements
of the a n t i f o l a t e .
are reported
here.
Results and
the
treatment
in
structural
T h e r e s u l t s of t h e s e
low d o s e m e t h o t r e x a t e
inflammation associated with adjuvant
w h e n g i v e n a t a d o s a g e of to d e t e r m i n e
of d r u g
b) the
studies
Discussion
Our prior study has shown that alleviate
and
to
15 )jg o n a b i w e e k l y
if e f f e c t i v e n e s s
basis.
can arthritis In o r d e r
c o u l d be r e t a i n e d by r e d u c i n g
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
the
848 Table
I:
E f f e c t s of A n t i f o l a t e s o n Paw I n f l a m m a t i o n with Adjuvant
Agent
Dose
Arthritic
Index
12.0 + 0
None Methotrexate
0.0 + 0.0
15 ug
Aminopterin Bakers
Associated
Arthritis
antifol
CB3717 Trimétrexate
15 u g *
6.9 + 1.1
120 tig*
4.0 + 4.0 0.0 + 0.0
30 yg 600 yg 300 yg
10
1.6
11.7 + 0.5
600 yg 300 yg
Metoprine
+
12.0 + 0 10.8 + 2.2
The i n d u c t i o n of a d j u v a n t a r t h i t i s and scoring of
inflammation
(arthritic index) were c o n d u c t e d as p r e v i o u s l y d e s c r i b e d R e s u l t s are e x p r e s s e d as the m e a n +_ S.D. (N=4). at the i n d i c a t e d dose twice w e e k l y (*) w h i c h w a s o n c e
(6).
Drug was g i v e n
i.p. e x c e p t as indicated by
weekly.
frequency of d o s a g e m e t h o t r e x a t e w a s a d m i n s t e r e d o n c e w e e k l y (Table 1).
Restriction
in the 15 yg d o s a g e o n c e weekly
a severe r e d u c t i o n in t h e r a p e u t i c e f f e c t .
A n increase
caused in the
o n c e w e e k l y d o s a g e to 120 yg did not s i g n i f i c a n t l y e n h a n c e r e d u c t i o n in i n f l a m m a t i o n .
These results s u g g e s t e d
importance of the timing of m e t h o t r e x a t e suppressing
treatment
in
inflammation.
In o r d e r to test the s t r u c t u r a l
s p e c i f i c i t y of m e t h o t r e x a t e
the a d j u v a n t m o d e l , s e v e r a l a n t i f o l a t e s were e v a l u a t e d . n u m b e r of d i f f e r e n t d i h y d r o f o l a t e widely different structure
reductase
than m e t h o t r e x a t e .
i n e f f e c t i v e u n d e r these c o n d i t i o n s .
was
Only a m i n o p t e r i n , showed
which
significant
H o w e v e r , s y m p t o m s of toxicity
o b s e r v e d e v e n at the d o s e s used h e r e .
and
primarily
s y n t h a s e , CB3717 or p r o p a r y l q u i n a z o l i n e
r e d u c t i o n in i n f l a m m a t i o n .
A
10 to 20 fold h i g h e r
The a n t i f o l a t e w h i c h i n h i b i t s
s t r u c t u r a l l y h i g h l y similar to m e t h o t r e x a t e
on
i n h i b i t o r s of
(Bakers a n t i f o l , t r i m e t r e x a t e ,
m e t o p r i n e ) h a d no e f f e c t at c o n c e n t r a t i o n s thymidylate
the
the
Further studies
are
were
849 needed to determine if lower, non-toxic doses of aminopterin can be used in place of methotrexate. These results demonstrate that anti-inflammatory activity
in
adjuvant arthritis is exhibited only by analogs that have a structure highly similar to methotrexate. It is not certain this time if dose modification or other structural
alterations
may enhance the activity of the compounds shown to be inactive here. It is difficult to make direct comparisons between animal models of arthritis and rheumatoid arthritis since differences between the human and animal pathology have been established (8). However the similarity in dose response to methotrexate between the human disease and two animal models suggest that useful information concerning the therapeutic efficacy and mechanism of action of antifolates in the treatment of arthritis may be obtained
in the model systems.
Acknowledgement
This study was supported by NIH Grants CA25933 and CA34314.
References 1.
Wilkens, R.F., M.A. Watson. 1982. 314-321
J. Lab. Clin. Med. 100,
2.
Weinblatt, M.E., J.S. Colby, D. A. Fox et. al. 1982. N. Engl J. Med. l\2> 818-822.
3.
Steinsson, K., A. Weinstein, M. Abeles. 1982. J. Rheumatol. 8, 860-866.
4.
Russell, A.S., C. Watts, R. Thompson, et al. 1984. Arthritis Rheum. 21_, 559.
5.
Williams, H.J., R.F. Wilkens, C.D. Samuelson, Jr. et al. 1985. Arthritis Rheum. 28^, 721-729.
6.
Welles, W.L., J. Silkworwth, A.L. Oronsky, S.S. Kerwar, J. Galivan. 1985 . J. Rheumatol. 904-906.
7.
Ridge, S.C., N. Rath, J. Galivan, J. Zabrisbe, A.L.
Oronsky, S.S. Kerwar: J. Rheumatol., in press. Decker, J. L., Mulone, D. G., Haraqui, B. et al. Intern. Med. 101, 810-824, 1984
Ann.
COMPUTER GRAPHIC MODELING IN DRUG DESIGN:
CONFORMATIONAL ANALYSIS AND ACTIVE-
SITE MODELING OF LIPOPHILIC DIAMINOPYRIMIDINES
Vivian Cody Medical Foundation of Buffalo, Inc., 73 High St., Buffalo, New York
14203 USA.
Introduction The enzyme dihydrofolate reductase (DHFR), a necessary component for all cell growth, is strongly and specifically inhibited by certain substrate analogues with binding affinities so great that they are not readily displaced by the natural folic acid substrates.
These antifolates have been the focus of chemo-
therapy for infectious and neoplastic diseases because of their ability to interfere in the synthesis of purine and pyrimidine nucleotide precursors of DNA and RNA (1,2).
Lipophilic diaminopyrimidines are a class of drugs that act as
inhibitors of DHFR and which show striking differences in their inhibitory activity with only small changes in their structure (1,2). Moreover, among 5-adamantyl 6-substituted antifolates, there is a further sharp increase in cytotoxic activity as the 6-substituent increases from hydrogen to methyl to ethyl, but drops again at propyl (3).
These lipophilic antifolates have the advantage of
a more extensive cellular uptake, with rates about 10,000 times more rapid than methotrexate (MIX), the most effective and most widely used anticancer agent, and show strong cytotoxic activity in cultured cells (4). In order to delineate the structural, conformational and electronic properties which are important for species specificity and selectivity, X-ray crystallographic analyses were carried out on a series of lipophilic antifolates (5,6) and computer graphic modeling of the binding interactions of these antifolates within the active site of chicken liver DHFR were investigated (7,8).
Structural Results Crystallographic analyses of 5-(1-adamantyl) diaminopyrimidine antifolates (Fig. 1) reveals that within the series of 6-substituted analogues (DAHP, DAMP, DAEP, DAPP), the pyrimidine ring in each structure is distorted from planarity
Chemistry and Biology of Pteridines 1986 © 1986 Walter d e Gruyter & Co., Berlin • New York - Printed in Germany
852
Fig. 1.
Structure of a) DAHP, b) DAMP, c) DAEP, d) DAPP, e) DCXMP, and f) DTMP.
with its substituents, with the exception of DAHP, which is planar.
As a re-
sult of the steric strain placed upon the system by the close intramolecular interactions of the adamantyl hydrogen atoms and those of the 4,6-substituents, these molecules have a bowed shape (6-8).
This strain causes the pyrimidine
ring to become a flattened boat with C(2) and C(5) below the N(l), N(3), C(4), C(6) plane.
As illustrated (Table I), these distortions cause the exocyclic
groups, to be significantly displaced from the pyrimidine plane. positionaliy disordered in both DAEP and DTMP.
Atom C(61) is
Since the high binding affinity
of antifolates for the enzyme active site is assumed to involve strong multiple hydrogen bonding interactions (9), these pyrimidine ring distortions can influence the placement of the diaraino groups and affect the strength and directionality of their hydrogen bonds in the enzyme active site. Table I:
Deviations of Substituents from the Pyrimidine Nl, N3, C4, C6 Plane.
Structure DAHP DAMP DAEP1 DAEP2 DAPP DCXMP DTMP1 DTMP2
N(2)
N(4)
C(7)
0,.015 -U,.233 -0,.254 -0,.254 -0,.291 -0..052 0..040 0..040
-0..040 0..238 0..241 0,.241 0,.372 0..003 -0,.093 -0,.093
0 .036 -0 .419 -0 .461 -0 .461 -0 .470 0 .061 0 .240 0 .240
C (61) 0..031 0 .055 0 .418 -0 .405 0 .180 -0 .020 -0 .217 0 .280
C(2) 0 . 009 -0 .088 -0 .087 -0 .087 -0 .132 -0 .008 0 .019 0 .019
C(5) 0 .024 -0 .121 -0 .122 -0 .122 -0 .160 0 .022 0 .084 0 .084
As illustrated (Fig. 2), the deviations of C(7) and N(4) in the adamantyl antifolates (DAEP, DAMP, DAPP) are significantly different from the more planar structures.
These displacements are correlated in pairs:
N(4); C(61), C(7), with those of DAPP the most variable.
C(2), C(5); N(2),
853
N(2) -•- N(4) * C(7) > h; > -o- C(61) Moo
a
v
C(2) C(5)
DAEP1DAEP2 DAMP DAPP DAHPDCXnFOTMP 1DTMP2 ANALOGUE
Fig. 2 Activity correlation with substituent displacement from pyrimidine plane. Crystallographic data delineating the DHFR enzyme structure and inhibitor/cofactor complexes are available from two bacterial and one avian species (10,11), and show that the active site is located within a 15$ cavity cutting across one face of the enzyme.
Structural data show that DAMP also binds to chicken liver
DHFR in a similar manner (11).
Modeling the interactions of DAMP in the DHFR
active site shows that the adamantyl ring fits tightly into the hydrophobic pocket near that occupied by the p-aminobenzoyl ring of MTX, and that the 6methyl is in a hydrophobic pocket surrounded by the residues Trp-24, Glu-30 and Tyr-31. Investigation of the 6-ethyl environment of DAEP shows that, while there is a reasonable fit, a 110° rotation of the ethyl side chain moves it into a more suitable pocket (6).
A similar comparison of the 6-propyl side chain indicates
that it also fits into this space.
In its observed orientation, the propyl
side chain atom C(63) is 2.38X from the hydroxyl oxygen of Tvr-31. o
A 60° ro-
tation of the side chain increases this distance to 3.64A (8). These observations suggest that other 6-substituted antifolates can be proposed which could take advantage of specific interactions with these residues.
Ac-
cordingly, computer generated models were made for other 6-substituted 5-adamantyl antifolates and their fit tested in this pocket. toxy group
For example, a 6-ace-
has an 0...0 contact distance to Tyr-31 of 3.3oX, favorable for
hydrogen bonding.
854 Summary The results of these structural studies show that the pyrimidine ring and its substituents become more distorted from planarity as the size of the 6-substituent increases and that there is a correlation between the activity of these adamantyl antifolates and the displacement of C(7) and N(4) from the leastsquares plane through Nl, N3, C4, C6.
These data also indicate that other pa-
rameters are of importance to the binding affinity of these lipophilic antifolates which could better explain the activity of DAEP. Acknowle dgement s This research was supported in part by NCI CA-34714, American Cancer Society Faculty Research Award, FRA-287, and the Buffalo Foundation. References 1.
Blakely, R.L. 1984. In: Folates and Pterins (R.L. Blakely and S.J. Benkovic, eds.). John Wiley f, Sons, New York, Vol. 1, p. 191.
2.
Zakrzewski, S.F., Dave, C. § Rosen, F. 1978. J. Natl. Cancer Inst. 60, 1029.
3.
Jonak, J.P., Zakrzewski, S.F. § Mead, L.H. 1971. J. Med. Chem. 14, 408; 1972. 15, 662. ~~
4.
Greco, W.R. § Hakala, M.T. 1982. Mol. Pharmacol. 18, S21.
5.
Cody, V. § Zakrzewski, S.F. 1982. J. Med. Chem. 25, 427.
6.
Cody, V., Welsh, W.J., Optiz, S. q Zakrzewski, S.F. 1984. In: QSAR in Design of Bioactive Compounds (Kuchar, M., ed.). J.R. Prous Science, Barcelona, Spain, p. 241.
7.
Cody, V. 1984. In: Molecular Basis of Cancer, Part B: Macromolecular Recognition, Chemotherapy and Immunology (Rein, R., ed.). Alan R. Liss, Inc., New York, p. 275.
8.
Cody, V. 1986. J. Mol. Graphics 4, 69.
9.
Zakrzewski, S.F. 1963. J. Biol. Chem. 238, 1,485; 4002.
10.
Bolin, J.T., Filman, D.J., Matthews, D.A., Hamlin, R.C. § Kraut, J. 1982. J. Biol. Chem. 257, 13650.
11.
Matthews, D.A., Bolin, J.T., Burridge, J.M., Filman, D.J., Volz, K.W., Kaufman, B.T., Beddell, C.R., Ch;unpness, J.N., Stammers, D.K. § Kraut, J. 1985. J. Biol. Chem. 260, 381, 392.
EFFECT OF ANTIFOLATES 10-METHYL- AND 10-ETHYL-10-DEAZA-AMIN0PTERIN ON A HUMAN BREAST CANCER CELL LINE
Frederika Mandelbaum-Shavit
Department of Bacteriology, Jerusalem, Israel.
Hebrew University-Hadassah
Medical
School,
Introduction
New folate analogs of the 10-deaza-aminopterin
series were shown during the
recent years to be less toxic to normal tissues and more effective against several
tumors of murine and human origin than methotrexate (MTX) (1-4).
Analogs with methyl or ethyl group at the 10 position of 10-deaza-aminopterin were more effective than MTX in reduction of tumor and increasing s u r v i v a l time of mice with L1210 or S180 ascites tumor and studies like E0771 mammary adenocarcinoma,
with solid
tumors
T241 fibrosarcoma and others proved
also
that 10- ethyl-10-deazaminopterin (lO-Et-lOdAm) was 5-fold more effective than MTX in retarding tumor growth (2). Experiments ¿n vitro
supported the above
results showing that 10-methyl- and 10-ethyl- derivatives are more potent inhibitors of various cells grown in culture, than MTX (3). We now present data on cytotoxicity
of
lO-Et-lOdAm and the 10- methyl-
derivative (lO-Me-lOdAm) as compared to that of MTX in MCF-7 cells, a human breast cancer cell line.
Since
5-methyltetrahydrofolate (5-CH3-H^PteGlu) is
a normally circulating form of folate (5), it appeared also of importance to study transport of this derivative vs MTX and the 10-deaza analogs.
Results
Cytotoxicity of Methotrexate, 10-Methyl- and 10- Ethyl-10-deaza-aminopterin in MCF-7 cells. The results depicted in Fig. 1 show that upon continuous exposure to various
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
856 concentrations of the f o l a t e analogs,
lO-me-lOdAm and 10-Et-dAm were 3.6 and
3 . 2 - f o l d r e s p e c t i v e l y more c y t o t o x i c than MTX (comparing required for 50% inhibition,
concentrations
IC^Q)
Figure 1. Inhibition of growth of MCF-7 c e l l s by antifolates. Chemicals: 10Me-lOdAm and lO-Et-lOdAm were synthesized by Dr. Joseph I. DeGraw, Department of Pharmaceutical Chemistry, Stanford Research Inst., Menlo Park, California (1) and kindly provided by P r o f . Roy L. K i s l i u k , Dept. of Biochemistry and Pharmacology, Tufts University School of Medicine, Boston, Massachusetts. The analogs were p u r i f i e d by chromatography and the concentrations determined s p e c t r o p h o t o m e t r i c a l l y (1). C e l l growth: MCF-7 c e l l s were c u l t i v a t e d in Earle's.based minimal e s s e n t i a l medium supplemented with 10% f e t a l bovine serum (Grand Island B i o l o g i c a l Co., NY), 0.2 U/ml of i n s u l i n , non e s s e n t i a l amino acids, 1 mM sodium pyruvate, 2 mM glutamine, 100 U/ml of p e n i c i l l i n and 100 ug/ml of streptomycin. C e l l s were subcultured following resuspension in a RDB s o l u t i o n s ( a novel agent of plant o r i g i n f o r dispersing monolayer culture, product of Israel Inst, for Biological Research, Ness Ziona), diluted in medium and 2 ml of the c e l l suspension (about 10 c e l l s were plated i n t o 35x10 mm t i s s u e c u l t u r e dishes. A f t e r incubation f o r about 40 hr in a humidified incubator under an atmosphere of air with 5% COn at 37°C, to allow enter the exponential growth phase, the medium was removed and the drugs were added in 2 ml of fresh medium. The cultures were reincubated and after 3 days resuspended and counted. Symbols: MTX (t); lO-Me-lOdAm (0); lO-Et-lOdAm (*•). Transport of 5- M e t h y l t e t r a h y d r o f o l a t e , Methotrexate, 10- E t h y l - and 10Methyl-10-deaza-aminopterin. In the presence of 2 >iM of S-CHg-H^PteGlu (both stereoisomers) the influx was linear
for
about 8-10 min and a double
accumulation against extra c e l l u l a r typical
reciprocal
plot
of
substrate
concentration (0.2-10 jiM) exhibited
Michaelis-Menten kinetics (not shown). The apparent Km for S-CHg-H^
PteGlu was 3.2+0.28 jiM, e s s e n t i a l l y as the Ki determined with [ 3 H] MTX and the Vmax was 11.6^0.71 nmol/min/g protein. The apparent Km f o r transport of MTX was 7.85+0.61 JJM, a v a l u e c l o s e to that obtained by Schilsky et a l . f o r MTX transport in MCF-7 c e l l s (6),
and the Vmax was 6.50^0.52 nmol/min/g protein.
The Ki values obtained for 10—Et—lOdAm and 10—Me—10-dAm, when measured with
857
[ 3 H]MTX
or
[UC]5-CH3-H4PteGlu
were
lower
by 3 . 3 ' a n d
about
5-fold,
r e s p e c t i v e l y , t h a n t h a t f o r MTX ( T a b l e 1 ) . T h i s i n d i c a t e s t h a t t h e 1 0 - d e a z a analogs are better
s u b s t r a t e s f o r t h e t r a n s p o r t c a r r i e r f o r f o l a t e s than MTX
w i t h a p p a r e n t Ki v a l u e s c l o s e r t o t h a t of t h e n a t u r a l
substrate,
5-CHg-
H 4 PteGlu. T a b l e 1.
T r a n s p o r t of 5 - M e t h y l t e t r a h y d r o f o l a t e and A n t i f o l a t e s i n MCF-7
Cells. Compounds
I n f l u x Ki (uM) A
5-CH 3 -H 4 PteGlu
3.17
MTX
7.90
10-Et-10dAm
2.40
10-Me-10dAm
1.61
+ + + +
B 0.24a
3 .20
0.63
7,.83
0.23
2,.34
0.20
1,.50
+ + + +
0 .16 0 .58 0,.18 0 .14
[ 3 ' , 5', 7- 3 H] MTX, sodium s a l t , sp. a c t . 18 Ci/mmol and 5 - [ 1 4 C ] methylt e t r a h y d r o f o l i c a c i d , s p . a c t . 5 8 . 3 . mCi/mmol, p u r c h a s e d f r o m Amersham, England, were p u r i f i e d and q u a n t i t a t e d by s p e c t r o p h o t o m e t r y (7). Exponential c u l t u r e s a t a l m o s t c o n f l u e n c y i n 3 5 x 1 0 mm d i s h e s were washed w i t h PBS and i n c u b a t e d i n 2 ml of t h e u p t a k e s o l u t i o n ( i n g / L : C a C l ^ - 0 . 2 ; KC1 - 0 . 4 ; MgS0 4 .7H 2 0 - 0 . 2 ; NaCl - 6 . 8 ; NaHC0 3 - 2 . 2 ; NaHnPO^.HjO - 0 . 1 4 , g l u c o s e 0.1%) f o r 1 hr a t 37°C. The s o l u t i o n was removed and t n e l a b e l e d coumpound was added i n 1 ml of f r e s h s o l u t i o n . The c e l l s w e r e i n c u b a t e d a t 37°C. U p t a k e was t e r m i n a t e d by r a p i d c o o l i n g and 3 w a s h e s w i t h i c e - c o l d PBS. The c e l l s w e r e d i g e s t e d i n IN NaOH, n e u t r a l i z e d and c o u n t e d . P a r t of t h e NaOH d i g e s t was used f o r p r o t e i n d e t e r m i n a t i o n (7). I n i t i a l u p t a k e k i n e t i c s were determined i n c e l l s i n c u b a t e d f o r 1 min with v a r i o u s c o n c e n t r a t i o n s of t h e compound examined and Ki v a l u e s were d e r i v e d from d o u b l e r e c i p r o c a l p l o t s of drug a c c u m u l a t i o n v e r s u s c o n c e n t r a t i o n i n t h e absence and p r e s e n c e of t h e competing a n a l o g . A - Ki v a l u e s d e r i v e d from e x p e r i m e n t s measuring i n f l u x of M h ] MTX; B - Ki v a l u e s d e r i v e d from e x p e r i m e n t s measuring i n f l u x of [ C] S-CHg-H^PteGlu; a Mean i S . E . of t h r e e e x p e r i m e n t s in t r i p l i c a t e . I n h i b i t i o n of D i h y d r o f o l a t e Reductase. The v a l u e s d e p i c t e d
in Table 2 a r e derived
from i n h i b i t i o n p r o f i l e s of DHFR
a c t i v i t y o b t a i n e d in t h e p r e s e n c e of v a r i o u s drug c o n c e n t r a t i o n s .
The enzyme
from MCF-7 c e l l s e x h i b i t e d o n l y a s l i g h t l y h i g h e r s e n s i t i v i t y t o t h e 1 0 - d e a z a a m i n o p t e r i n a n a l o g s a s compared t o t h a t a c h i e v e d with MTX.
858 T a b l e 2. I n h i b i t i o n of D i h y d r o f o l a t e R e d u c t a s e by M e t h o t r e x a t e and Other Antifolates Compound
Drug concentration for 50% inhibition (nM) 4..20
+
0 ,25 a
10-Et-10dAm
3..87
+
0 .30
10-Me-10dAm
3..94
+
0 .36
MTX
E x p o n e n t i a l l y growing c e l l s were washed with PBS and the monolayers were suspended in PBS c o n t a i n i n g 0.1% EDTA. F o l l o w i n g c e n t r i f u g a t i o n , the c e l l s were resuspended in 10 mM Tris-HCl, pH 7.5,containing 1'mM EDTA and sonicated. The supernatant obtained a f t e r c e n t r i f u g a t i o n (4°C) at 45,000xg for 45 min was u s e d a s enzyme s o u r c e . DHFR (EC 1 . 5 . 1 . 3 ) a c t i v i t y was a s s a y e d s p e c t r o p h o t o m e t r i c a l l y ( 9 ) . The a s s a y mixture in 1 ml c o n s i s t e d of 100 mM potassium phosphate b u f f e r , pH 6.8, 200 mM KC1, 0.1 mM NADPH and e n z y m e . T h e r e a c t i o n was i n i t i a t e d by a d d i t i o n of 0.08 mM d i h y d r o f o l a t e with 10 mM 2 m e r c a p t o e t h a n o l . The a b s o r b a n c e change a t 340 nm was monitored f o r 4 min a t 30°C. For i n h i b i t i o n a s s a y s v a r i o u s drug c o n c e n t r a t i o n s were added t o the reaction mixture, containing 2 enzyme units (1 unit of a c t i v i t y i s the amount of enzyme reducing 1 nmol of dihydrofolate in 1 min) and incubated for 2 min prior to addition of d i h y d r o f o l a t e . The s p e c i f i c a c t i v i t y of the enzyme used was 4.2 units/mg protein. a
Mean
S.E. of t r i p l i c a t e determination for each drug concentration.
Discussion We have shown t h a t
lO-Et-lOdAm and lO-Me-lOdAm a r e 3.2- and 3.6 - f o l d
r e s p e c t i v e l y more potent growth i n h i b i t o r s for MCF-7 c e l l s than MTX (Fig. 1). These r e s u l t s corroborate with the data of others showing increased a c t i v i t y of the 10-deaza-aminopterin analogs a g a i n s t various tumor c e l l l i n e s , as well as against f o l a t e requiring microorganisms (1-4). The f o l a t e analogs and S-CH^-H^PteGlu were found to enter the MCF-7 c e l l s by the same c a r r i e r mediated mechanism exhibiting a markedly higher a f f i n i t y for lO-Et-lOdAm and lO-Me-lOdAm than f o r MTX. In s t u d i e s of i n h i b i t i o n of DHFR a c t i v i t y the deaza-compounds were only s l i g h t l y more e f f e c t i v e than MTX. In conclusion, the higher c y t o t o x i c i t y of lOEt-lOdAm and lO-Me-lOdAm than that of MTX in MCF-7 c e l l s appears to be r e f l e c t e d mainly by the lower i n f l u x Ki v a l u e s , which i s in agreement with the r e s u l t s obtained with other tumor c e l l l i n e s (1,3,4).
859 Acknowledgment
T h i s r e s e a r c h was supported Association.
in p a r t
by a g r a n t from the I s r a e l
Cancer
The author i s g r a t e f u l to P r o f e s s o r s Roy L. K i s l i u k and Joseph
I. DeGraw for kindly providing the deaza- compounds. References 1.
DeGraw, J . I . , V.H. Brown, H. Tagawa, R.L. K i s l i u k , Y. Gaumont and F.M. S i r o t n a k . 1982. S y n t h e s i s and antitumor a c t i v i t y of 1 0 - a l k y l - 1 0 d e a z a m i n o p t e r i n s . A c o n v e n i e n t s y n t h e s i s of 10-deazaminopterin. J . Med. Chem. 25, 1227-1230.
2.
S i r o t n a k , F.M., J . I . DeGraw, F.A. Schmid, L . J . Goutas New f o l a t e analogs of the 10-deaza-aminopterin s e r i e s . Pharmacol. ^2, 26-30.
3.
S i r o t n a k , F.M., J . I . DeGraw, D.M. Moccio, L.L. Samuels and L . J . Goutas. 1984. New f o l a t e a n a l o g s of the 1 0 - d e a z a - a m i n o p t e r i n s e r i e s . Cancer Chemother. Pharmacol. 12, 18-25.
4.
Moccio, D.M., F.M. S i r o t n a k , L.L. S a m u e l s , T. Ahmed, A. Yagoda, J . I . DeGraw and J.R. P i p e r . 1984. S i m i l a r s p e c i f i c i t y of membrane t r a n s p o r t f o r f o l a t e a n a l o g u e s and t h e i r m e t a b o l i t e s by murine and human tumor c e l l s : A c l i n i c a l l y directed laboratory study. Cancer Res. 44^ 352-257.
5.
H e r b e r t , V., A.R. L a r r a b e e and J.M. Buchanan. 1962. S t u d i e s on the i d e n t i f i c a t i o n of a f o l a t e compound in human serum. J . Clin. I n v e s t . 41, 1134-1138.
6.
S c h i l s k y , R.L., B.D. B a i l e y and B.A. Chabner. 1981. C h a r a c t e r i s t i c s of membrane transport of methotrexate by cultured human breast cancer c e l l s . Biochem. Pharmacol. 30, 1537-1542.
7.
Mandelbaum-Shavit, F. and N. Grossowicz. 1970. Transport of f o l i n a t e and r e l a t e d compounds in Pediococcus c e r e v i s i a e . J . B a c t e r i o l . 104, 1-7.
8.
Lowry, O.H., N.J. Rosebrough, A.L. F a r r and R.J. R a n d a l l . 1951. P r o t e i n measurement with the Folin phenol reagent. J . B i o l . Chem. 193, 265-275.
9.
Mathews, C.K. and F.M. Huennekens. 1963. Further s t u d i e s on dihydrofolic r e d u c t a s e . J . B i o l . Chem. 238, 3436-3442.
and D.M. Moccio. Cancer Chemother.
BIOCHEMICAL AND CYTOTOXIC EFFECTS OF THE ERYTHRO- AND THREO-ISOMERS OF GAMMAFLUORO- METHOTREXATE
John J . McGuire
Grace Cancer Drug Center, Roswell Park Memorial Institute, Buffalo, NY
14263
John Galivan D i v i s i o n o f L a b o r a t o r i e s and Researcn, New Yorn ¿xaxe Department of Health, Albany, New York 12201 James K. Coward Department of Chemistry, Rensselaer Polytechnic Institute, Troy, NY
12181
Introduction
Gamma-fluoro-methotrexate (FMTX) i s a methotrexate (MTX) analog which contains 4-fluoroglutamate instead of glutamate. properties
as
MTX
itself
This analog has e s s e n t i a l l y the same
(dihydrofolate
reductase
inhibition,
uptake
and
e f f l u x , e t c . ) , except that FMTX forms polyglutamate derivatives poorly, i f a l l (1).
at
As such i t i s a useful tool to investigate the function of MTX poly-
glutamates.
This
previous
work
D,L-erythro:threo-4-fluoroglutamate D,L-erythro- and
was
performed
and i t
with
FMTX
synthesized
thus contained four
D,L-threo-4-fluoroglutamate
containing
from
isomers.
isomers
The
(eFMTX
and
tFMTX, respectively) have now been prepared and their properties determined.
Results
Pure eFMTX and tFMTX were separated from the mixed isomer population by HPLC. Separation was affected i s o c r a t i c a l l y (22°, 1.5 ml/min) on a Whatman P a r t i s i l 10 C-8 column (0.46 x 25 cm) equilibrated with 15 mM Na-phosphate, pH 2.2 containing
10% methanol.
The D,L-eFMTX
(tr
= 16.8 min)
and D,L-tFMTX
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
(tr =
862 19.6 min) were baseline resolved.
Each peak contained only one component when
re-analyzed under the same reverse phase conditions or by anion exchange HPLC. Pure
eFMTX
and
tFMTX
were
compared
to
MTX
as
inhibitors
of
dihydrofolate
reductase (DHFR) from a number of different sources.
For DHFR from H35 cells
[IC 5 Q ,nM=4.9
(MTX);
5.5
human
[IC S 0 ,nM=1.0
(MTX);
1.4
nM=l.1
(eFMTX); (eFMTX);
(MTX); 1.5 (eFMTX); 1.7
5.5 1.4
(tFMTX)], (tFMTX)],
and
leukemic
L1210
cells
(tFMTX)] the inhibition by either
essentially equivalent to that obtained with MTX
itself.
The
spleen [IC 5 Q ,
isomer was
slopes of the
inhibition curves were nearly identical for all drugs. The mixed isomer preparation of FMTX accumulated to the same level in cells as did MTX in short term (30 min) iiicuuations, Dut its initial rate of influx was slightly slower (1).
To assess the transport of the isomers of FMTX,
affect on the transport of 2 nM [ H]MTX was measured cell
line CCRF-CEM (Table I).
half
that
of of
the the
isomers
was
D,L-erythro
leukemia
Inhibition by the isomers was compared to the
isotopic dilution effect of unlabeled MTX. L-isomer
in the human
their
used
for
A concentration direct
and D,L-threo
pair
comparison should
be
of MTX since
that was only
inhibitory.
the The
presence of either 8 or 16 nM unlabeled MTX caused a decrease both in initial velocity and in the level D.L-eFMTX
well as did 8 transport. reduced
of accumulation at 30 min.
inhibited both the initial mM
MTX.
The tFMTX
velocity
The presence of 16 uM
and accumulation at 30 min as
isomer was much less inhibitory to [ 3 H]MTX
These results are consistent with eFMTX being transported by the
folate/MTX
system
with
kinetic
constants
itself while tFMTX probably has a lower affinity.
similar
to
those
The results also
of
MTX
indicate
that the reduced folate/MTX transporter is highly stereoselective. The eFMTX isomer is more cytotoxic than tFMTX against both H35
rat hepatoma
(ID 5 0
and
= 100
and 850 nM, respectively)
respectively) cell
and CCRF-CEM
(ID g 0
= 60
lines following continuous exposure, although both
170
nM,
isomers
are less potent than MTX itself (ID 5 Q = 9-15 nM). The effects of FMTX isomers on folate metabolism were assessed by looking at 3 the reduction of thymidylate synthesis from [ H]l)dR. Short exposure (4 hr) of CCRF-CEM cells to high concentrations 3 essentially
complete
inhibition
of
(2 >iM) of FMTX
[ H]UdR
isomers or MTX
incorporation.
fer of the cells to drug-free medium, incorporation
Following
gave
trans-
in the MTX treated cells
remained inhibited completely for 4 hr and did not even begin to recover until 8 hr.
This sustained inhibition is the result of polyglutamate synthesis dur-
863 Table I:
Effect of FMTX Isomers on [ H]MTX Transport by CCRF-CEM Cells Rate of I n i t i a l Addition
Accumulation at
Uptake pmol/min/10
30 Min
cells
pmol/10
None
0.153
2.55
8 tiM MTX
0.079
1.21
16 nM MTX
0.052
0.90
16 nM eFMTX
0.082
1.23
16
0.112
1.69
tFMTX
ing the i n i t i a l
exposure period (1).
In contrast,
cells
when FMTX treated c e l l s
were placed in drug-free medium, UdR incorporation began to recover by 1 hr and was essentially at control
rates by 4 hr.
Since the major
difference
between these two isomers and MTX i s that they do not form polyglutamates,
it
is most l i k e l y this property i s responsible for the difference in inhibitory behavior.
The isomers of FMTX showed the same kinetics
of
recovery
under
these conditions; however, they were clearly different when tested against H35 c e l l s at low drug concentrations at the long exposure times used in the cytotoxicity
assays.
The concentration
dependent
cytotoxicity
during
a 48 hr
exposure to each isomer wa^. compared to tne concentration dependence of hibition
of
3
[ H]H20
release
from
3
[5- H]UdR
during
the
first
24
hr
inof
exposure. There was a very close correspondence between cytotoxicity and 3 [ H]H,0 release profiles for each individual compound. However, comparing 3 the concentration required for 50% reduction in c e l l count and [ HjHgO release, the eFMTX isomer was about 5-fold more potent. Previous work with mixed isomer FMTX showed that only low levels of i t s polyglutamates could be detected.
The substrate activity of the individual FMTX
isomers with partially purified rat liver folylpolyglutamate synthetase (FPGS) was determined (Table I I ) .
Both isomers had activity near the detection limit
but i t appeared that eFMTX displayed s l i g h t l y higher activity than tFMTX. Higher FPGS substrate
activity
experiments
the
cells.
examining
of
eFMTX was also
metabolism
of
[14C]FMTX
indicated
in
preliminary
isomers
in
intact
H35
Following a 24 hr incubation in 1 ^M drug, there were 4.9 nmol poly-
864 Table II:
Substrate Activity of FMTX Isomers for Purified Rat Liver FPGS
4-NH 2 -10-CH 3 -Pte(F)Glu N Concentration
N =
2
3
4
pmol
Drug 8.5
MTX
17
341
39
2.7
646"
63
1.3
eFMTX
17
23.9
4.6
0
tFMTX
17
18.5
3.7
0
glutamates/mg
protein
from
eFMTX,
but
only
these same conditions MTX formed 23.7 nmol
2.1
nmol/mg
from
tFMTX.
Under
polyglutamates/mg.
The results on polyglutamate formation argue
that eFMTX
is a weak
for mammalian FPGS and that tFMTX is an even poorer substrate.
substrate
The increased
cytotoxicity and more sustained inhibition of jte novo thymidylate synthesis by eFMTX compared to tFMTX is apparently the result of its slightly higher level of
polygl utamate
polyglutamate classical
formation.
formation
is
These a
results
major
thus
determinant
reinforce of
the
the
notion
that
cytotoxicity
of
antifols.
Acknowledgements
This
work
was
supported
by Grants CA25933
Biomedical Research Support Grant.
and CA28097
from
the
NCI
and
a
JJM is a Leukemia Society Scholar.
References
1.
Galivan, J., Inglese, J., McGuire, J .J., Nimec, Z. and Coward, J.K. 1985. Gamma-fluoromethotrexate: Synthesis and Biological Activity of a Potent Inhibitor of Dihydrofolate Reductase With Greatly Diminished Ability to Form Poly-y-Glutamates. Proc. Natl. Acad. Sci. (USA) 82, 2598-2602.
C-^-TETRAHYDROFOLATE-S YNTHASE, A MULTIFUNCTIONAL ENZYME IN P U R I N E M E T A B O L I S M , A N D ITS RELATED M O N O F U N C T I O N A L
K.W. Shannon, T.R. Whitehead, C. Staben, J.C. D e p a r t m e n t o f B i o c h e m i s t r y , U n i v e r s i t y of Berkeley, California 94720
INVOLVED
ENZYMES
Rabinowitz
California,
Introduction The subject of this session thesis."
I would
activities
like
involved
is, " F o l a t e D e p e n d e n t P u r i n e
to d i s c u s s t h r e e p a r t i c u l a r
in t h e f o r m a t i o n of t h e o n e - c a r b o n
u s e d in p u r i n e b i o s y n t h e s i s . a historical manner
f i e l d of
to d e v e l o p
to d e s c r i b e h o w t h e e x p e r i m e n t a l
r e s u l t e d in u n a n t i c i p a t e d questions;
I w o u l d like
experimental
h a s a f f e c t e d t h e q u e s t i o n s w e ask a n d t h e a n s w e r s satisfactory.
This
as n o t o n l y r e l a t i n g previously
results,
b u t a l s o of s u g g e s t i n g
approach affected
w a s the influence of tracers.
Studies with compounds
L5
labeled with ' N showed that purine bases
are not derived from presynthesized 14 lty of
C made
find
However,
I
task some
questions experimen-
disposal.
A n e x a m p l e of h o w e x p e r i m e n t a l cally
the
interpreted my
i n t e r e s t to m e t h a t w e c o u l d a n s w e r w i t h
tal m e a n s a t our
to
approaches
t h e p r e s e n t to the p a s t a n d d e s c r i b i n g
unreported
of particular
so I h a v e
other
that we
is a " S t a t e o f the A r t L e c t u r e . "
am not sure just w h a t that means,
in
work
results that suggested still
and the p o s s i b l e
donors
the topic
h o w our e x p a n d i n g v i e w of a r e a s a p p r o p r i a t e
"biochemistry"
Syn-
enzymatic
it p o s s i b l e
sources
to d e m o n s t r a t e
investigation in r a t
(1).
The
isotopitissues availabil-
that uric acid,
the
purine e x c r e t e d by pigeons, w a s d e r i v e d from small m o l e c u l e s as carbon dioxide and glycine
(2-4).
The
fact that formate
s h o w n to b e a n e x t r e m e l y e f f e c t i v e p r e c u r s o r
of p u r i n e
carbon
a t o m s 2 a n d 8 in u r i c a c i d
(2) w a s a n u n e x p e c t e d
formate had not previously
been recognized as a metabolic
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
such was
finding
since intermediate.
866 E f f o r t s w e r e then d i r e c t e d t o w a r d d e f i n i n g the i n d i v i d u a l
meta-
b o l i c r e a c t i o n s i n v o l v e d in the s y n t h e s i s of h y p o x a n t h i n e
and
i n v o l v e d the use of p i g e o n liver h o m o g e n a t e s
(5).
Through
the 14
use of this s y s t e m for m e a s u r e m e n t s of the i n c o r p o r a t i o n of
C-
f o r m a t e , it w a s r e c o g n i z e d that I n o s i n i c acid w a s the
first
p u r i n e f o r m e d in the iji v i t r o s y s t e m
responsible
(6).
The enzyme
for the " a c t i v a t i o n " of f o r m a t e w a s s h o w n to r e q u i r e A T P tetrahydrofolic acid 10-formyl-THF formylase" nized.
(8,9).
(9).
(THF)
(7) a n d to r e s u l t in the f o r m a t i o n of
It w a s o r i g i n a l l y n a m e d ,
"anhydroleucovorin"
(5-formyl-THF)
or 5 , 1 0 - m e t h e n y l - T H F
recog-
plus ATP
(7), a n d
(13,14)
I w i l l l i m i t my d i s c u s s i o n to the e n z y m a t i c
(10),
serine
S u b s e q u e n t work e s t a b l i s h e d the e n z y m a t i c
i n v o l v e d in the u t i l i z a t i o n of 5 - f o r m y l - T H F (15).
"tetrahydrofolate
O t h e r s o u r c e s of the a c t i v e f o r m a t e w e r e
These included leucovorin
(5,11,12).
and
reactions
and
serine
reactions
r e l a t e d to the a c t i v a t i o n of formate by t e t r a h y d r o f o l a t e
for-
m y l a s e , w h i c h w e n o w c a l l 1 0 - f o r m y l - T H F s y n t h e t a s e and the c o n v e r s i o n of 1 0 - f o r m y l - T H F to o t h e r d e r i v a t i v e s u s e d in p u r i n e biosynthesis.
The
Prokaryotes
T h e e x p e r i m e n t a l s y s t e m s I h a v e d e s c r i b e d for i n v e s t i g a t i n g m e c h a n i s m s of p u r i n e b i o s y n t h e s i s w e r e a u g m e n t e d by work use of other c o n c e p t s t h a t w e r e less o b v i o u s l y a p p l i c a b l e answer this p r o b l e m .
to
T h e y i n c l u d e d the use of b a c t e r i a and
d i e s o n the d e g r a d a t i o n rather than the b i o s y n t h e s i s of T h e i n v e s t i g a t i o n of p u r i n e f e r m e n t a t i o n by a n a e r o b i c
the
making stu-
purines.
organisms
(16) w a s d e p e n d e n t o n the i n f o r m a t i o n a n d t e c h n i q u e s d e r i v e d
from
the work o n p u r i n e s y n t h e s i s in p i g e o n s for the s y n t h e s i s of 14 C-uric acid
(17).
T h e l a b e l l e d u r i c acid w a s used to d e t e r m i n e
the o r i g i n of the p r o d u c t s of this f e r m e n t a t i o n a c i d w a s i d e n t i f i e d as o n e of these p r o d u c t s
(18).
Formic
(19) and the
reac-
t i o n s i n v o l v e d in its f o r m a t i o n w e r e d e t e r m i n e d t h r o u g h the use of c e l l - f r e e s y s t e m s
(20) .
The enzyme 10-formyl-THF
synthetase,
867 originally named tetrahydrofolate formylase, responsible for the activation of formate: Formate
+ THF + MgATP
-2
->
10-formyl-THF + MgADP
+ HPO
4
-2
was purified from Peptococcus asaccharolyticus (ATCC 14963) (previously called Micrococcus aerogenes and Peptococcus aerogenes) (21,22), and from four clostridial species (23-26).
It was
obtained in crystalline form from Clostridium cylindrosporum (23).
These bacterial enzymes are homotetramers of M r = 60,000.
The physical and kinetic properties of the enzymes and the mechanism of the reaction have been reviewed (27,28) and will not be discussed here. It should be noted that these bacterial enzymes are derived from organisms in which the enzyme occurs in exceptionally high levels and is believed to catalyze reactions other than those involved in the synthesis of purine bases.
These are for the generation
of ATP from 10-formyl-THF in the fermentation of a purine substrate, or in the utilization of CO. after its reduction.
Yeast and Other Eukaryotes Partially purified 10-formyl-THF synthetase from pigeon liver (29) and sheep liver (30), were used in studies on the mechanism of the reaction.
The observation that the 10-formyl-THF synthe-
tase activity of porcine liver copurified with two other enzymes, methenyl-THF cyclohydrolase and methylene-THF dehydrogenase:
HCOOH
H*N N (I r T I
ir imirDP H2N
—
n
N
XXX ¡0 - For my! — tetrahvdrofulaie
Synthetase
NADPH NADP® HjN
pQ*
OH
CHO (B)
»"(A) TelruhyJrofulate
HiN M
un
5.10 • Meihenyl — tetrah ydrofotate
Cyclohydrolase
CHj '
5.10 - Methylene lelrahydro/o/oie
Dehydrogenase
-
868 led to the s u g g e s t i o n that these e n z y m e s o c c u r r e d as a c o m p l e x (31).
G e n e t i c e v i d e n c e s u g g e s t e d that the y e a s t A P E 3
gene
e n c o d e d a t r i f u n c t i o n a l p r o t e i n w i t h the 3 a c t i v i t i e s s h o w n above (32,33).
T h e s e o b s e r v a t i o n s s t i m u l a t e d the r e c o g n i t i o n that the
h o m o g e n e o u s 1 0 - f o r m y l - T H F s y n t h e t a s e s a l r e a d y i s o l a t e d from o v i n e (34) a n d p o r c i n e
(35) liver w e r e t r i f u n c t i o n a l p r o t e i n s w i t h
the
three a c t i v i t i e s s h o w n a b o v e and s t i m u l a t e d the p u r i f i c a t i o n of the e n z y m e from S a c c h a r o m y c e s c e r e v i s i a e
(36).
The
trifunctional
p r o t e i n s are d i m e r i c h o m o p o l y m e r s w i t h s u b u n i t s of M r = 100 118
(28).
This molecular
structure
is d i f f e r e n t from that w h i c h
o c c u r s in the p u r i n o l y t i c b a c t e r i a w h e r e the three o c c u r as s e p a r a t e m o n o f u n c t i o n a l e n z y m e s . forms occur
that w i l l be d i s c u s s e d shortly
molecular
(28). polyfunctional
T h e r e f o r e , w e use the name
synthase" for this t r i f u n c t i o n a l e n z y m e . methylene-THF synthase(combined)
"C^-THF
W e find that o t h e r
n a m e s that h a v e b e e n u s e d in the p a s t , such as use.
activities
B u t other
U n f o r t u n a t e l y , n o s t a n d a r d i z e d n o m e n c l a t u r e for e n z y m e s has b e e n e s t a b l i s h e d .
to
formyl-methenyl-
are too c u m b e r s o m e for
general
W e feel that some g e n e r a l c o n v e n t i o n is r e q u i r e d to d i f -
ferentiate multifunctional functional
e n z y m e s from their c o r r e s p o n d i n g
mono-
forms.
C ^ - T H F s y n t h a s e is not the o n l y m u l t i f u n c t i o n a l e n z y m e
involved
in p u r i n e b i o s y n t h e s i s .
proteins
A t l e a s t four m u l t i f u n c t i o n a l
are a s s o c i a t e d w i t h p u r i n e b i o s y n t h e s i s de novo: tional C^-THF synthase, a bifunctional
(37) and
(38) e n z y m e e a c h w i t h one of the r i b o n u c l e o t i d e a c t i v i t i e s and an a d d i t i o n a l b i f u n c t i o n a l e n z y m e ingly, one of the m u l t i f u n c t i o n a l that are n o t all s e q u e n t i a l
Yeast
the
trifunc-
trifunctional transformylase (39).
enzymes catalyzes
Interest-
reactions
(38).
Mitochondria
In s t u d i e s d e m o n s t r a t i n g
t h a t A P E 3 is the s t r u c t u r a l g e n e for S.
cerevisiae C^-THF synthase
(40), w e n o t e d that an ade3
s t r a i n h a d low b u t d e t e c t a b l e
levels of 1 0 - f o r m y l - T H F
deletion synthetase
869 and 5,10-methylene-THF dehydrogenase
(41).
In order
the nature of these a c t i v i t i e s , we p u r i f i e d the
f r o m t h e d e l e t i o n m u t a n t as s h o w n in T a b l e
activity
to
determine
synthetase I.
T a b l e I. PURIFICATION OF f-THF SYNTHETASE FROM AN ade3 DELETION STRAIN
f - T H F synthetase activity
Step
Crude extract Protamine Sulfate Ammonium Sulfate C M cellulose Heparin Agarose Blue Sepharose Hydroxylapatite
Protein mg
Total IU
S.A. lU/mg
Purif. fold
Yield
%
SYN DH
SYN CYC
40,000 30,000 9,400 180 20 3.1 1.6
600 600 570 300 220 100 94
0.015 0.020 0.060 1.7 11 33 59
1.0 1.3 4.0 110 720 2200 3900
100 100 95 51 36 17 16
4 3 3 5 9 8 4
45 14 16 11 13 14 15
We obtained a protein that we estimate in a 16% y i e l d a f t e r cyclohydrolase
to b e m o r e t h a n 90%
4000-fold purification.
encoded by A P E 3 ,
that this protein,
i s o z y m e h a s a M^ = 1 0 0 , 0 0 0 w h i c h
SDS-PAGE
is s i m i l a r
THF synthase.
Gel exclusion chromatography
tein has an M r
= 200,000
identical
suggesting
s u b u n i t s a s is C ^ - T H F
T h e p r e s e n c e o f the e n z y m e the structural g e n e isolated an isozyme. enzyme differed
to t h e v a l u e
for
shows that the
t h a t it is c o m p o s e d of
suggested that we
to c o n f i r m t h e f a c t t h a t
T h e p e p t i d e b a n d i n g p a t t e r n s of
t h e m u t a n t e n z y m e as a n i s o z y m e of C ^ - T H F
We also used immunological r e l a t e d n e s s of t h e s e
techniques
isozymes.
We
purified enzymes with polyclonal of the p u r i f i e d e n z y m e s
protwo
in a y e a s t m u t a n t w i t h a d e l e t i o n
for C ^ - T H F s y n t h a s e In order
(Fig.
the C^-
synthase.
e n z y m e s a r e d i f f e r e n t a n d t h e s e r e s u l t s s u p p o r t our of
synthase
shows that
1).
of
had
this
from C ^ - T H F synthase, we c o m p a r e d the two
by peptide mapping.
and
synthetase
like the C ^ - T H F
is a l s o t r i f u n c t i o n a l .
pure
Dehydrogenase
a c t i v i t i e s c o p u r i f i e d w i t h the
activity, suggesting
S.A. ratios
the
enzymes two
designation
synthase.
to d e t e r m i n e
the
structural
immunotitrated each of
antlsera directed against
the each
870 100
80 60 |
s
40
%
20
•>
100
o
o
H
X
S
R e s t r i c t i o n m a p of p T W 2 .
T h e pUC8 D N A is s h o w n by the thick l i n e , a n d the g e n o m i c by the thin line.
T h e s q u a r e i n d i c a t e s the site of
of s y n t h e t i c o l i g o n u c l e o t i d e s p r e p a r e d from c o d o n s for a c i d s 10-15 of the p r o t e i n .
insert
hybridization amino
T h e a r r o w i n d i c a t e s the l o c a t i o n of
the s y n t h e t a s e g e n e a n d the d i r e c t i o n of t r a n s c r i p t i o n of synthetase message.
d i a l e n z y m e g e n e , a n d h a v e use this s e q u e n c e to d e t e r m i n e corresponding
the
W e h a v e s e q u e n c e d a b o u t 75% of the c l o s t r i -
a m i n o acid s e q u e n c e
the
(Fig. 6).
• DH/CYC— 1
320
469 523 586 S. cerevisiae C -THF Synthase
I
nh
150
151
214
1 h+
3
C. acid-urici 10-Formyl-THF Synthetase COOH
Direct A m i n o Acid Homology
53%
53%
38%
+ AA Substitution
59%
62%
44%
Fig. 6.
A m i n o acid h o m o l o g y b e t w e e n S. c e r e v i s i a e C ^ - T H F syn-
t h a s e and and C. a c i d i - u r i c i
10-formyl-THF
synthetase.
877 T h e bold p o r t i o n of the lower line i n d i c a t e s the p o r t i o n of c l o s t r i d i a l p r o t e i n t h a t we h a v e s e q u e n c e d .
The dashed
the
line
s h o w s the p o r t i o n of the s e q u e n c e that r e m a i n s to be d e t e r m i n e d . T h e d e g r e e of h o m o l o g y to the p o r t i o n s of the y e a s t C ^ - T H F t h a s e i n d i c a t e d are g i v e n b e l o w those p o r t i o n s .
syn-
The homology
is
near 60% for the two s e g m e n t s near the N - t e r m i n a l p o r t i o n , if o n e o m i t s a s h o r t p o r t i o n of the y e a s t e n z y m e .
The carboxy
s h o w s s o m e w h a t less h o m o l o g y , b u t e v e n that is 44%.
portion
We have
n o t e d t h a t the p o r t i o n of the y e a s t e n z y m e b e t w e e n these
two
h o m o l o g o u s p o r t i o n s is q u i t e h i g h in b a s i c a m i n o acids.
This
d e g r e e of h o m o l o g y is u n u s u a l for p r o t e i n s from s o u r c e s as d i v i r g e n t as a b a c t e r i u m a n d y e a s t . entire sequence very
I b e l i e v e t h a t we w i l l have
the
shortly.
W e h a v e c l o n e d y e a s t D N A that h y b r i d i z e s to d e g e n e r a t e
oligonu-
c l e o t i d e p r o b e s d e r i v e d from the amino t e r m i n a l s e q u e n c e of yeast mt-C^-THF synthase.
the
I n a d d i t i o n to s e q u e n c i n g the m t - C ^ -
T H F s y n t h a s e g e n e in o r d e r to d e t e r m i n e the a m i n o a c i d
sequence
of the e n z y m e a n d its r e l a t i o n s h i p to the c y t o p l a s m i c p r o t e i n , h o p e to c r e a t e a m u t a n t in this g e n e by g e n e d i s r u p t i o n .
m u t a n t c o u l d g i v e i n s i g h t to the n o r m a l f u n c t i o n of the g e n e . a d d i t i o n , o v e r e x p r e s s i o n of the p r o t e i n w o u l d m a k e it easier isolate the p r o t e i n a n d c h a r a c t e r i z e
the g e n e a n d the
we
Such a In to
protein.
Occurrence and Significance N o w that w e r e c o g n i z e that 1 0 - f o r m y l - T H F s y n t h e t a s e a c t i v i t y occur
in d i f f e r e n t m o l e c u l a r
forms, and e v e n d i f f e r e n t
can
isozymic
f o r m s w i t h i n o n e o r g a n i s m , I b e l i e v e that it is of i n t e r e s t
to
c o n s i d e r w h a t is k n o w n a b o u t the o c c u r r e n c e of these forms among various organisms.
T h e e n z y m e w a s f i r s t d e s c r i b e d in 1955 b a s e d
o n its a c t i v i t y in pig a n d p i g e o n liver, a n d w a s a s s u m e d to be monofunctional
(8,9), as w a s the c r y s t a l l i n e e n z y m e d e r i v e d
b a c t e r i a in 1958 (27).
(49) .
T h e a c t i v i t y has w i d e s p r e a d
T h e s u g g e s t i o n t h a t the a c t i v i t y o c c u r s in a s e c o n d
associated
(in an u n s p e c i f i e d manner)
from
occurrence form
with other enzymes was
f i r s t m a d e in 1972 a n d 1973 b a s e d o n g e n e t i c a n d
biochemical
878 evidence (31,32).
The occurrence of the monofunctional
form,
10-formyl-THF synthetase, has been established in a number of bacteria (28) .
The trifunctional form of the enzyme, C^-THF syn-
thase, is found in pig, sheep, cow, chicken and rabbit liver and in yeast (28).
It is thought to function primarily in purine
nucleotide synthesis.
Is it possible that the purine utilizing
bacteria contain a trifunctional protein in addition to the monofunctional 10-formyl-THF synthetase?
It should be noted that the
monofunctional enzyme has been isolated only from sources that contain the enzyme in concentrations about 2500 times higher than are found in most other bacteria that we have examined.
This may
result from the enzyme's involvement in reactions related to the utilization of the carbon source provided rather than exclusively for biosynthetic reactions.
Is it possible that we have over-
looked the presence of a trifunctional enzyme that might occur in concentrations that are exceedingly low relative to the amount of monofunctional enzyme in these particular cells?
This does not
appear to me to be such a far-fetched possibility in view of the very highly organized and complicated nature of the enzymatic components required for purine nucleotide biosynthesis in animal systems where it seems plausible that the structure of each element involved is essential for the activity
(37).
When we consider how representative these examples are of the organisms representing life on this earth, I think we must recognize how inadequate our present state of knowledge is since these examples do not include any examples from Protoctista or Plantae and are obviously inadequate even with respect to the kingdoms that have been e x a m i n e d — t h e Monera, Animalia and Fungi
(50).
Without pretending to tackle this problem, but responding to the stimulation in considering it, we have decided to determine the nature of this enzyme in various species with these considerations in mind.
Our approach to the problem has been to consider
the phylogenetic classification of life, to try to choose examples that represent some variety within each kingdom and that are available to us, and to first answer the simple question of whether the 10-formyl-THF synthetase activity is associated with
879 a monofunctional enzyme or with one possessing either or both the dehydrogenase and/or cyclohydrolase.
The experimental means for
doing this is based on our observation that heparin-agarose appears to bind enzymes that use THF or its derivatives as a substrate.
Thus, by passing a crude extract of the cell over such a
column and eluting it with a salt gradient, we can separate the three activities when they occur as monofunctional enzymes.
If
we detect all three activities in a single peak, this suggests that the enzyme occurs in a polyfunctional form. an extract of C. acidi-urici
The behavior of
(Fig. 7) shows that the enzymes in
this source are monofunctional proteins.
Analysis of an extract
of yeast shows a single peak with these three enzymic activities eluting with about 150 mM KC1.
Fraction Number (5 ml) Fig. 7.
Chromatography of extract of C. acidi-urici on heparin-
agarose. If we consider just the kingdom Monera (bacteria), we realize that our knowledge concerning the organization of is based on the analysis of very few species.
We have started to examine a group
of bacterial species that we believe represents a reasonable cross-section of organisms (Table III).
880 Table
III.
SURVEY OF PROCAYOT1C ORGANISMS FOR IO-FORMYL-THF SYNTHETASE GRAM-POSITIVE ORGANISMS: A. Aerobic Rods: Bacillus subtilis B. Aerobic Cocci: Micrococcus luteus C. Facultative Cocci: Staphylococcus epidermidis Streptococcus faecalis DL Anaerobic Rods: Clostridium absonum Clostridium pasteurianum Eubacterium sp. V.P.I. 12708 E Anaerobic Cocci: Peptostreptococcus anaerobius F. Actinomycetes: Streptomyces lividens
II. GRAM-NEGATIVE ORGANISMS: A. Aerobic Rods: Pseudomonas aeruginosa B. Aerobic Cocci: Branhamella catarrhalis C. Facultative Rods: Escherichia coli Salmonella typhimurium Klebsiella pneumonia Proteus mirabilis Shigella tlexneri D. Anaerobic Rods: Bacteroides fragile III. ARCHAEBACTERIA: A. Aerobic Rods: Halobacterium salinarium
T h i s s t u d y is j u s t s t a r t i n g b u t I w o u l d like to m e n t i o n some of the r e s u l t s t h a t we h a v e o b t a i n e d in our e x a m i n a t i o n of e n t e r i c b a c t e r i a s h o w n in T a b l e Table
the
IV.
IV. SPECIFIC ACTIVITY OF IO-FORMYL-THF SYNTHETASE AND 5,10METHYLENE-THF DEHYDROGENASE IN CRUDE EXTRACTS OF VARIOUS BACTERIA Organism I. Gram-Negative A. Aerobic Rods: Pseudomonas aeruginosa Facultative Rods: Escherichia coli Klebsiella pneumonia Proteus mirabilis Shigella flexneri Salmonella typhimurium Anaerobic Rods: Bacteroides fragiiis II. Gram-Positive A. Anaerobic Rods Clostridium acidi-urici Clostridium pasteurianum
Synthetase (mU/mg)
Dehydrogenase (mU/mg)
0
10
0 0 12 0 0
25 19 30 58 32
100
19
13,000 60
600 89
W e c a n n o t d e t e c t the s y n t h e t a s e
in E. c o l i in a g r e e m e n t w i t h p r e -
v i o u s r e p o r t s for this o r g a n i s m
(43,51).
Nor d o we d e t e c t
the
s y n t h e t a s e in any of the other b a c t e r i a of this g r o u p , e x c e p t for Proteus mirabilis.
A l l of these o r g a n i s m s d o c o n t a i n
the
881 dehydrogenase.
It remains to be determined whether it is mono-
functional or is associated with cyclohydrolase in a bifunctional enzyme as reported for E. coli
(51).
Also in this table is the
value for synthetase found in Clostridium pasteurianum.
This
organism was of interest to us because other clostridial
species
that have been examined all contain exceptionally high levels of this monofunctional enzyme, and all have unusual one-carbon metabolism.
C. pasteurianum is a saccharolytic organism that is not
unusual with respect to the metabolism of formate.
It has a much
lower level of the synthetase as well as the dehydrogenase does the purinolytic Clostridium.
than
We considered the possibility
that the activity might be associated with a trifunctional protein involved in purine biosynthesis.
In fact, is this the basis
for the distinction between the monofunctional and trifunctional forms of the enzyme?
As shown in Fig. 9, the enzymes appear to
be monofunctional in this organism.
Fraction Number (2 ml) Fig. 9.
Chromatography of extract of C. pasteurianum on
heparin-agarose. We would also like to examine representatives of other for the state of these enzymes.
kingdoms
Synthetase activity has been
reported i n plants (52) , but the functionality of the enzyme is not known.
A preliminary examination of a crude homogenate of
whole spinach leaves suggests that the enzyme is trifunctional
882 (Pig. 13, J. Nour, unpublished observations).
200
-o- Synthetase
• cob( II )alamin + N2 + OH.
[3]
The hydroxyl radical could attack amino acid residues near the active site of the enzyme, or the radical could attack the bridge carbon of the corrin, which would interrupt conjugation and form a xanthocorrinoid
(12); either reaction would lead to an irrevers-
ible inactivation of methionine synthase.
We also observed
the
loss of protein after turnover under N2O; this could also be the result of the cleavage of the protein by hydroxyl radical generated at the active site
(13).
Acknowledgement The research was funded by National Institutes of Health Grant GM24908.
References 1.
Dolphin, D.
1971.
Methods Enzymol. 18C, 34-52.
2.
Taylor, R.T., H. Weissbach. 1502-1508.
1967.
J. Biol. Chem. 242,
3.
Fujii, K., F.M. Huennekens. 6745-6753.
1974.
J. Biol. Chem. 249,
4.
Bayston, J.H., F.D. Looney, J.R. Pilbrow, M.E. Winfield. 1970. Biochemistry 9, 2162-2172.
5.
Firth, R.S., H.A.O. Hill, B.E. Mann, J.M. Pratt, R.J.P. Williams. 1967. J. Chem. Soc. Chem. Commun. 1013.
6.
Hayward, G.C., H.A.O. Hill, J.M. Pratt, R.J.P. Williams. 1965. J. Chem. Soc. 6485.
920 7.
Fujii, K. , F.M. Huerinekens. 1979. In: Biochemical Aspects of Nutrition (K. Yagi, ed.) Japan Scientific Societies Press, Tokyo, pp. 173-184.
8.
Beinert, H., G. Palmer. 1965. In: Oxidases and Related Redox Systems, Vol. 2 (T.E. King, H.S. Mason, and W. Morrison, eds.) Wiley, New York, pp. 567-590.
9.
Deacon, R., M. Lumb, J. Perry, I. Chanarin, B. Minty, M.J. Halsey, J.F. Nunn. 1980. Eur. J. Biochem. 104, 419-422.
10. Banks, R.G.S., R.J. Henderson, J.M. Pratt. Soc. (A), 2886-2889. 11. Blackburn, R., M. Kway, A.J. Swallow. Farad. Trans. 21, 250-255. 12. Bonnett, R. 1982. In: New York, pp. 202-243.
1968.
1977.
J. Chem.
J. Chem. Soc.
Vol. 1 (D. Dolphin, ed.) Wiley,
13. Kim, K., S.G. Rhee, E.R. Stadtman. 15394-15397.
1985.
J. Biol. Chem. 260,
Inhibition of Methylenetetrahydrofolate Reductase by Adenosylmethionine
David A. Jencks and Rowena G. Matthews Biophysics Research Division and Department of Biological Chemistry University of Michigan, Ann Arbor, Michigan 48109
Introduction We have studied the allosteric regulation of the dimeric flavoprotein methylenetetrahydrofolate reductase from pig liver by the inhibitor adenosylmethionine (AdoMet) and the substrate NADPH.
Methylenetetrahydrofolate reductase catalyzes the NADPH-linked reduction of
methylenetetrahydrofolate [eq.l].
Methyltetrahydrofolate serves as a methyl donor for the > NADP* + CH 3 -H 4 folate
NADPH + CH 2 -H 4 folate methylation
of
homocysteine in the reaction
catalyzed
[1]
by 5-methyltetrahydrofolate-
homocysteine methyl transferase, and the combined action of methylenetetrahydrofolate reductase and 5-methyltetrahydrofolate-homocysteine methyl transferase supplies one carbon units for methylation reactions using AdoMet. The reaction [1] proceeds by a ping-pong bi-bi mechanism, and we have taken advantage of this to study the NADPH half-reaction by measuring electron transfer from NADPH to menadione. Electron transfer from the enzyme to menadione is second order, so the NADPH half reaction is rate limiting at appropriate menadione concentrations1.
The inhibition caused by AdoMet takes several minutes to reach its full extent, and so we have been able to study not only the activity at equilibrium of enzyme, AdoMet and NADPH, but also to study the kinetics of approach to equilibrium. As a result of this, we are able to propose a model for the interactions of methylenetetrahydrofolate reductase, AdoMet and
NADPH
involving not only the equilibrium constants between various forms of the enzyme but also some of the microscopic rate constants.
Results We have conducted our experiments by measuring the activity of methylenetetrahydrofolate reductase after incubation of the reduced enzyme with AdoMet and NADPH. We used the
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
922 NADPH-menadione assay to measure activity. In this assay the enzyme is primarily oxidized during steady state turnover1. For equilibrium experiments, a 20 minute preincubation was used, whereas for kinetic experiments, the activity was measured at time points up to 20 minutes.
In one set of experiments the NADPH concentration during the assay was 200 |iM. We find that at concentrations of NADPH in the preincubation up to 200 |iM the dependence of activity on [AdoMet] appears hyperbolic, but that at NADPH concentrations of 1 to 2 mM sigmoidicity appears, indicating the presence of cooperative interactions in AdoMet binding. Furthermore, the activity in the absence of AdoMet rises with increasing NADPH concentration in the preincubation, suggesting that there are two states of the enzyme with differing affinities for NADPH, the form with higher affinity also having higher activity.
When the assay is
conducted at the same NADPH concentration as the preincubation, we again observe that increasing [NADPH] overcomes the inhibition caused by AdoMet and high levels of NADPH appear to increase the amount of active enzyme present.
The kinetics of inhibition by AdoMet are pronouncedly biphasic, with the predominant effect of increasing levels of AdoMet being to increase the extent of the fast phase, although some increase in the rate of the slow phase is also seen. NADPH again has an antagonistic effect, whereby, at high AdoMet concentrations, increasing the NADPH concentration decreases the extent of the fast phase and decidedly reduces the rate of the slow phase.
Since the cooperativity of AdoMet binding suggests that there is more than one AdoMet binding site, we conducted a spectrophotometric titration of methylenetetrahydrofolate reductase, using the flavin as a probe, and found that there is indeed one AdoMet binding site for each subunit.
Model for methylenetetrahydrofolate reductase The model we propose for the interactions of methylenetetrahydrofolate reductase with AdoMet and NADPH is similar to the model for allosterism originally proposed by Monod, Wyman, and Changeux 2 . Thus there are two quaternary states, R and T, to which the ligands bind with different affinities; NADPH more tightly to the R state, AdoMet more tightly to the T state. As in an MWC model, this produces homotropic and heterotropic cooperative effects. For instance, as [AdoMet] increases, AdoMet ligated R and T state enzyme become more stable, but due to the greater affinity for T state enzyme, AdoMet ligated T state enzyme
923 eventually becomes the most stable form and accumulates. Since T state enzyme has little activity, this is manifested as inhibition. An MWC model of this kind adequately explains the equilibrium data. However, an MWC model predicts that the kinetics of inhibition will be a single first order process if ligand binding is rapid equilibrium, and will exhibit a lag phase if ligand binding is on a finite time scale. Thus the rapid burst of inhibition we observe at high levels of AdoMet is inconsistent with an MWC model. In order to explain the biphasic kinetics of inhibition, we propose that, on a given subunit in a given quaternary state, binding of one ligand considerably reduces the affinity for the other. AdoMet binding to the R state occurs at a rate commensurate with the burst phase of inhibition, and R—>T conversion at a rate commensurate with the slow phase. The biphasic kinetics is then a result of relatively rapid binding of AdoMet to R state enzyme, thus excluding NADPH binding and hence activity, followed by slow conversion to the thermodynamically more stable AdoMet ligated T state. At high NADPH concentrations, NADPH binds to R state enzyme, thus reducing its availability for AdoMet binding and decreasing the extent of the fast phase; NADPH ligated R state forms do not readily convert to T state, so the reduction of the amount of free R state enzyme also reduces the rate of the slow-phase R—>T conversion.
An additional complication is presented by the differing NADPH affinities of methylenetetrahydrofolate reductase in reduced and oxidized forms, here present during the preincubation and the assay respectively. We are able to take account of this and construct a mathematical model embodying the above features that adequately explains all our equilibrium and kinetic data.
Conclusion We find that AdoMet and NADPH interact antagonistically with methylenetetrahydrofolate reductase with respect to both the equilibria between active and inactive enzyme forms and the kinetics of approach to that equilibrium. AdoMet inhibits the enzyme and increases the extent of the fast phase of the biphasic inhibition, whereas NADPH tends to counteract this inhibition and reduces the extent of the fast phase as well as the rate of the slow phase.
We have
constructed a mathematical model that quantitatively predicts our equilibrium and kinetic data.
References
1. Vanoni, M. A., Ballou, D. P., and Matthews, R. G. (1983) J. Biol. Chem. 258, 11510-11514 2. Monod, J., Wyman, J., and Changeux, J.-P. (1965) J. Mol. Biol. 12, 88-118
REGULATION OP FOLATE HOMEOSTASIS
C. Osborne, K. Lowe, B. Shane Department of Nutritional Sciences, University of California, Berkeley, California 94720 D. J. Cichowicz, D. Sussman, G. Milman Department of Biochemistry, The Johns Hopkins University, Baltimore, Maryland 21205
Introduction Folate retention by tissues is dependent on conversion to p o l y glutamate derivatives, catalyzed by folylpolyglutamate synthetase (FPGS).
Factors i n v o l v e d in the regulation of folate homeostasis
are under study with an in vitro model, using homogeneous pig liver FPGS (1), and an in x i ¥ 2 model, using cultured mammalian cells, including Chinese hamster ovary c e l l FPGS mutants expressing the human FPGS gene.
Some preliminary results are presented.
Results Table 1 shows kinetic constants of H 4 P t e G l u n for pig liver FPGS. Increasing the glutamate chain length of H^PteGlu causes a decrease in k c a t but KJJ, v a l u e s remain low.
The retention of
affinity by polyglutamates, which drops off beyond the pentaglutamate, suggests that long chain length folates that accumulate in c e l l s h a v e the potential of regulating the synthesis of f o l y l p o l y glutamates.
Polyglutamates of other reduced folates also retain
high affinity for the enzyme but their k c a t values drop off more rapidly and only H 4 P t e G l u polyglutamates can be converted to the long chain length derivatives that accumulate in tissues. Competition between competing substrates is shown in Table 2.
The
pig liver enzyme metabolizes low concentrations of H 4 P t e G l u to the same types of derivatives that are found i n 3£iY2> with the hexa-
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
926 Table 1 Substrate
Kinetic Constants of Folylpolyglutamate Synthetase (nM)
THF THF(Glu-2) THF(Glu-3)
7.7 3.4 1.1
THF(Glu-4) THF(Glu-5) THF(Glu-6)
2.0 2.7
THF(Glu-7)
K^ (|iM)
11 14 34 47
V m a x (rel)
V m a x /K m (r
100 45 8.8
100 102 62
4.5 1.6
17 5 1000
Km ( U M ) ± SE
± SE (nM)
k
(min - 1 ) ± SE
Acknowledgement This
research was
CA18856
supported
(FMS) , and CA22764
by PHS grant numbers CA25236 (FMS)
awarded
by
the National
(JRP), Cancer
institute, DHHS.
References 1.
Piper, J. R., McCaleb, G. S., Montgomery, J. A., Kisliuk, R. L., Gaumont, Y., Sirotnak, F. M. 1986. J. Med. Chem. 21, 1080.
2.
Schmidt, H. W., Junek, H.
3.
Elslager, E. F., Davoll, J. 2, 97.
4.
Temple, C., Jr., Elliott, R. D., Montgomery, J. A. Org. Chem. 47, 761.
5.
Taylor, E. C., Harrington, P. J., Fletcher, S. R., Beardsley, G. P., Moran, R. G. 1985, J. Med. Chem. 28, 914.
6.
Beardsley, G. P., Taylor, E. C., Shih, C., Poore, G. A., Grindley, G. B., Moran, R. G. 1986. Proc. Am. Assoc. Cancer Res., 1027.
1977.
Monatsch. Chem. 108, 895.
1974.
Lect.
Heterocycl. Chem. 1982.
J.
AZIDO-SUBSTITUTED ANTIFOLATE DRUGS: ACTIVITY
SYNTHESIS, STRUCTURE, AND
P.K. Bryant, K.P. Wong, J. Colby, C.H. Schwalbe, M.F.G. Stevens, R.J. Griffin, and E.A. Bliss Pharmaceutical Sciences Institute, Department of Pharmaceutical Sciences, Aston University, Aston Triangle, Birmingham B4 7ET, England
Introduction Lipophilic inhibitors of dihydrofolate reductase (DHFR) can enter lipid compartments such as the brain, and cancer cells able to exclude more polar antifolates such as methotrexate. However, 2 many have long biological half-lives, e.g. a plasma tjy2 h (1) for 2,4-diamino-5-(3,4-dichlorophenyl)-6-methylpyrimidine (metoprine, DDMP), resulting in slow clearance of any toxic effects which develop. The aromatic azido substituent, as in compounds offers an attractive alternative: it is lipophilic but it can be transformed to a more polar amino group, aiding elimination.
1
2
3
Results and Discussion Synthesis of _l-_3 from the appropriate nitro compounds involved reduction with hydrazine-Raney nickel or stannous chloride, followed by diazotisation-azidation of the resulting amine in acid solution by adding first NaNO_ and then NaN- solutions.
Chemistry and Biology of Pteridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
1006
The azido group in l-v3 can react in several ways. The sulphydryl reagents solium hydrosulphide, 2-mercaptoethanol, and dithiothreitol all reduced 1 smoothly to the arylamine. Thus it is likely that cellular thiols can effect a similar reduction in vivo. Heating 1 and 2^ with hydrazine hydrate completely removed the azido group leaving only hydrogen at that position, a reaction which may be of synthetic utility. Similar treatment of 3 yielded 2,4-dihydrazinoquinazoline. Treatment of _1 with trifluoromethanesulphonic acid at 0° caused rapid evolution of nitrogen and introduction of a bulky CF^SO^ substituent into the hindered 2'-position of the phenyl ring instead of intramolecular cyclisation. Thermolysis of or photolysis in nitrogensaturated water converted the azide to an amine, while photolysis in oxygen-saturated water produced the nitro compound. Thermolysis in nitrobenzene or dekalin and photolysis in water or methanol of the free base of 2 yielded only products derived from the triplet nitrene intermediate: 2,4,6-triaminoquinazoline and a maroon azo-dye. No singlet-derived ring-expanded products were observed.
N3
Crystal structures of 1 (two independent molecules), 2, and 3 were determined. Features of the molecular geometry are set out below in terms of the common arylazido moiety, in which R represents an attached or fused pyrimidine ring.
X
Table 1. Geometry of azido group attachment and ring junction
Mol.
C-Nl
la
1. 38 1. 36
lb 2 3
N1-N2 1.24
N2-•N3 (8)
1. 401
1. 35 1.218
1. 16 1. 16 1. 111
1.416
1.255
1. 136
c a - c - n i C x -C-Nl
«
/3(°)
119.1
117 116 117.4
171 168 173.2
115.9
115.6
172.5
125 126
117 114
123.0 124.0
1007
Table 1 (continued) Mol. CA-C-N1-N2 la lb 2 3
- 6
-0.4 -3.7
Cx-C-Nl-N2
C-N1-N2-N3
169 175 179.9 175.8
-179 173 -177.4 -178.6
E(°) 112 -86
-73.4 N.A.
The N^ group of lb makes only distant intermolecular contacts; hence it suffers from high temperature factors and imprecise geometrical parameters. In all the compounds the N^ unit is almost linear (#£170°) and N2-N3 is shorter than N1-N2. The rather sharp bend at N1 (a< 120°) brings N2 into contact with the adjacent hydrogen atom at position A. This contact is relieved by opening the C^-C-Nl angle at the expense of C x ~C-Nl, even when X is as bulky as chlorine. Strain relief via out-of-plane twisting about C-Nl is only of minor importance. Pyrimidine geometry in 2 corresponds closely to that in the similarly substituted metoprine (2). There is a large twist between pyrimidine and phenyl rings as measured by ©, the C6-C5-C11-C2' torsion angle, which is 110° in metoprine and matches this value to within a twofold rotation in 2, while the change to a 6-ethyl substituent in i. permits but does not require an even greater twist. The diaminopyrimidine moieties in all three crystal structures follow the general pattern (3) by forming N4-H...N3 hydrogen bonds around a centre of inversion to make a base pair. The protonated ring N1 and the 2-amino group direct protons towards anions to make further hydrogen bonds. The azido groups enter into van der Waals contacts only. Inhibition data against rat liver DHFR show that it is possible to improve an inhibitor by introducing an azido substituent where it may contact a hydrophobic region of DHFR. Thus K^ values with 95% confidence limits are 1.6 + 0.4 nM for _1 compared with 2.6 + 0.3 for pyrimethamine lacking the azido group,
1008
2.6 + 0.8 for 2, and 0.12 + 0.04 for metoprine. Similarly, 2 inhibits mouse L1210 and E. coli RT500 (form I) DHFR more strongly than the rather feeble inhibitors 2,4-diaminoquinazoline and its 6-nitro- and 6-amino-congeners. Even so, two determinations of K^ for _3 against L1210 DHFR gave 5 1 + 6 and 4 6 + 3 nM. Determinations of pK
and log P (octanol-water) for 1 yielded 7.19 — a and 2.94 respectively, compared with 7.54 and 1.25 for the more basic and polar amine product of reduction. In antitumour screening tests 1 proved to be active. This compound is presently in Phase I clinical trial as an antitumour agent. Preliminary results indicate that f°r elimination is 32-43 h. As intended, this is shorter than it is for many other lipophilic antifolates.
Acknowledgements We thank the Cancer Research Campaign for support and the Science and Engineering Research Council for studentships No. 82314925 and 83700621. Computations were carried out at the University of Manchester Regional Computer Centre.
References 1. Cavallito, J.C., C.A. Nichol, W.D. Brenckman Jr., R.L. DeAngelis, D.R. Stickney, W.S. Simmons and C.W. Sigel. 1978. Drug Metabolism and Disposition 6, 329-337. 2. Cody, V.. 1983. Cancer Biochem. Biophys. 6, 173-177. 3. Schwalbe, C.H., V. Cody. 1983. In: Chemistry and Biology of Pteridines (J.A. Blair, ed.). Walter de Gruyter, Berlin . New York. pp. 511-515.
SUMMARY NOVEL ANTIFOLATES Robert C. Jackson Warner-Lambert/Parke-Davis Pharmaceutical Research Ann Arbor, Michigan 48105
The first fifteen years in the history of antifolates as chemotherapeutic agents were highly successful, leading to the anticancer agent, methotrexate, the antimalarial pyrimethamine, and the antibacterial, trimethoprim.
After these early successes,
synthetic efforts continued unabated but for over two decades no new antifolates were introduced into clinical practice and the resulting disappointment and disillusion caused the impression in some quarters that folate analogues were no longer a fruitful area of medicinal chemistry.
In the 1980s this situation has been
transformed, with four new and active agents introduced into clinical trial, and others in advanced preclinical evaluation. The development of 10-ethyl-10-deazaaminopterin
(10-EDAM) repre-
sents the end result of a process of optimization of selective transport and polyglutamylation of drug by tumor cells relative to normal tissues.
10-EDAM is thus a classical antifolate in
which the features believed to confer antitumor selectivity on methotrexate have been maximized.
Meanwhile, two nonclassical
antifolates have been developed to clinical trial.
These com-
pounds, trimetrexate (CI-898) and piritrexim (BW301U) are not transported by the methotrexate carrier and cannot be polyglutamylated.
Despite this, these new nonclassical antifolates are show-
ing promising clinical activity.
10-Propargyl-5,8-dideazafolate
(CB3717) is the first clinically active antifolate directed at a target other than dihydrofolate reductase (DHFR).
CB3717 has
demonstrated that thymidylate synthetase (TS) is an effective target for anticancer agents.
Among compounds still in preclinical
development, 5,10-dideazatetrahydrofolate
(DDATHF) is particularly
interesting in showing excellent antitumor activity in murine systems, though not inhibiting either DHFR or TS.
Beardsley et
al. (this symposium) have demonstrated that GAR transformylase is the primary site of action of DDATHF.
Chemistry and Biology of Reridines 1986 © 1986 Walter de Gruyter & Co., Berlin • New York - Printed In Germany
1010
The papers presented in session 26 provide clear evidence of this reawakening of interest in the development of novel antifolates. The work of Manteuffel-Cymborowska et al. was one of two presentations showing formation of polyglutamate derivatives of CB3717. Clearly polyglutamylation has implications for drug retention and affinity of CB3717 for TS.
As yet, the extent to which polyglut-
amylation contributes to antitumor selectivity of CB3717 remains unclear.
The presentation of Hynes et al. also deals with class-
ical quinazoline analogues of folic acid, including isofolic acid analogues and examines activity of these compounds as substrates for folypolyglutamate synthetase.
All the compounds tested were
substrates, and some were excellent substrates.
The extent of
polyglutamylation, i.e. the number of glutamate residues added to quinazolines, in comparison with pteridines, is still unknown. Piper et al. describe the synthesis and biological testing of 5substituted 5-deaza analogues of classical folate antagonists. These compounds are effective DHFR inhibitors, and some members of the series have good activity against the E0771 murine tumor. The series contains compounds with 10-deaza structures, including the 5-methyl analogue of DDTHF. synthesis and properties of aminopterin.
DeGraw and colleagues report the
5,10-methylenetetrahydro-8,10-dideaza-
This was a rather weak inhibitor of growth of L1210
cells, but the possibility remains that, like DDTHF, it may be more active in solid tumors.
Bryant et al. provide evidence of
the continuing interest in lipophilic DHFR inhibitors in a discussion of azido-substituted antifols.
Their concept is that
these compounds may provide the desirable pharmacokinetic properties of lipophilic compounds, but that within the cell the azido group will hydrolyze to a more polar amine, resulting in good cellular drug retention.
One compound from the series,
MZPES, is now in phase I clinical trial as an antitumor agent. The recent spate of new compounds and new ideas in antifolate development probably owes its success not only to the persistence of several strong groups of medicinal chemists, but also to the feedback from recent advances in folate biochemistry.
The
stimulation that we have all received from this continuing series of symposia on the Chemistry and Biology of Pteridines has surely played a part in this process.
AUTHOR INDEX
Akiba, K. 287 Akino, M. 223,275 Al-Haddad, D. 509 945,981 Allegra, C.J. Amoroso, D. 681 Anderson, J.M. 327 Andersson, K.K. 201 Andondonskaja-Renz, B. 251,431 Antoulas, S. 95 Appleman, J.R. 769,803 Ardizzoni, A. 681 Armstrong, R.A. 327 Aschhoff, H.J. 339 Avery, T.L. 9 63 Awad, W.M. 913 Ayling, J.E. 51,391 Baccanari, D.P. 789,811,823 Bacher, A. 103,227 Bailey, S.W. 51,391 Bairnsfather, L. 489 Banks, S.D. 835 Baram, J. 945,981 Bartunik, H.D. 103 Beardsley, G.P. 61,953 Beaulieu, D. 843 Bel, Y. 335 Bell, C. 351 Benkovic, S.J. 13 Benz-Lemoine, E. 419 Berteiii, G. 681 Bertino, J.R. 793 69 Besserer, J.A. Biehl, K. 257 Bigham, E.C. 111,835 Blair, J.A. 327,509 Blakley, R.L. 769,803 Blecha, H.G. 427 Bliss, E.A. 1005 Bloom, L.M. 13 Bognar, A. 733 Böhm, P. 33 9 Boritzki, T.J. 69 Botez, M.I. 527 Bottiglieri, T. 523 Bowers, S.W. 219 Boyle, P.H. 91 Bracco, G. 407 Broom, A.D. 631 Brown, G.M. 125,183,295 Bryant, P.K. 1005 Bujard, H. 839 Burchall, J.J. 789 Burgert, S.L. 555
Calvert, A.H. 645,675 Carl, G.F. 495 Carney, M.W.P. 523 Chabner, B.A. 945,981 Chan, P.Y. 929 Chanarin, I. 709 539 Chandler, C.J. Chao, J.Y. 377 Chary, T.K.N. 523 Chen, J.T. 13 Chen, T.B.R.A. 687 Chiodo, L.A. 215 Choe, H. 905 Chow, C.W. 351 Chu,, F.K. >~nu r . j\ . 613 D ±J Cìchowicz, tiowicz, D.J. 9 925, 2 E 997 Ciesla, J. 651,663 Clow, C.L. 403 Cody, V. 799,851,969 Colby, J. 1005 Collins, T.D. 489 Conlon, R.M. 475 Conte, P.F. 681 Cook, R.J. 593,893 481 Cooper, B.A. Cossins, E.A. 741,929 Cotton, R.G.H. 231,351,359, 407 Courtney, G. 513 Courtney, L.F. 13 Coward, J.K. 861 Cremer-Bartels, G. 279 Cuello, A.C. 351 Curtius, H.C. 141,299,399 Danenberg, P.V. 985 Darcy-Vri1Ion, B. 579 Daubner, S.C. 13 Davidson, N. 937 Davis, M.D. 363 Deacon, R. 709 DeFrank, T.J. 977 Delcamp, T.J. 807,815,819,959 Delcroix, M. 239 Dennis, T. 887 Dhondt, J.-L. 239,315,385 Di Cecco, R. 933 Dias-Selassie, C. 959 Dierich, M.P. 427 Dillard, S.B. 391 Dix, T.A. 13 Doig, M.T. 973 Dracon, M. 315 Dube, S.K. 793 Duch, D.S. 151,219,283,377
1012
Dunham, W.R.
917
Edelstein, M.P. 377 Eisenga, B.H. 489 Eilwart, J. 209 Emmerich, B. 2 05 Eto, I. 447 243 Evers, M. Farriaux, J.P. 239 Ferone, R. 737 Ferré, J. 107,115,309,335 Fierke, C.A. 13 Finch, R.A. 963 Fitzhugh, A.L. 639 Fiatmark, T. 201 Fletcher, S.R. 61 Fodor, S. 639 Fonrobert, P. 65 Forsch, R.A. 985 Forzy, G. 239 Frasca, V. 697,917 Freisheim, J.H. 571,575,807, 815,819,959,985 Frisius, H. 411 Fry, D.W. 69 Fuchs, D. 263,427,443 Fusco, V. 681 547,847,861,967 Galivan, J. 347 Galloway, M P. 45,671,989 Gaumont, Y. 893 Gettins, P. 299 Ghisla, S. 897 Ghitis, J. 543 Gier, J. de 843 Goldberg, H 85 Gready, J.E Green, J. 901 Griffin, R.J 1005 Grindey, G.B. 953 993 Grzelakowska-Sztabert, B. Guardamagna, 0. 399,407 Guilhot, F. 419 Gulisano, M. 681 Guynn, R.W. 257 Haan, E. 351 Haavik, J. 201 Halsted, C.H. 539 Hamon, C.G.B. 327,509 Hanlon, M. 737 Hansch, C. 959 Hansen, S.I. 603,607 Harpring, K.M. 571 Harrap, K.R. 675 Harrington, P.J. 61 Hase, Y. 247 Hasegawa, H. 369
Hasler, T. 299,319,399 Hausen, A. 263,427 Hayte, J.M. 239,315 Hengster, P. 427 Hilhorst, E. 687 Hilton, J.G. 481 Hinterhuber, H. 427 Hochuli, E. 839 Hoier-Madsen, M. 607 Holm, J. 603,607 Hoppner, K. 531 Hörne, D.W. 559 395 Howe Iis, D.W. Huber, J.F.K. 263 Huber, R. 103 Hung, J. 69 Hunt, D. 737 31 Hutzenlaub, W. Hyland, K. 395 Hynes, J.B. 57,121,997 Ichiyama, A. 3 69 Inoue, K. 517 Isshiki, G. 247 Iwai, K. 517 Jackman, A.L. 645,675 Jackson, R. 1009 Jacobson, K.B. 107,115 Jansen, G. 543 Jaye, D.L. 235 Jencks, D.A. 697,921 Jennings, I. G. 351,359,407 Joannon, P. 843 Jones, T.R. 675 Joshi, G. 887 Joyner, S.S. 811 Kaiman, T.I. 583,763,985 Kaminska, B. 993 Kang, Y. 31 Kapatos, G. 215 Kaplan, P. 403 Katoh, S. 291 Kaufman, S 169,185,351,363, 639,989 Keating, J.M 905 Kedzierska, B. 663,667 91 Kelly, M.F. 373 Keiner, K.L. 571 Kempton, R.J. 339 Kersten, H. 205 Kersten, W. 847 Kerwar, S. 485,973 Kesavan, V. 691 Keyomarsi, K. Khwaja, T. 959 Kisliuk, R.L. 45,655,671,743, 989
1013 Koch, M.A. 415 Kocher, H.P. 839 Kohashi, M. 517 571 Kohrs, F. Kompis, I. 83 9 Kozloff, L.M. 757 Krajewski, K.J. 257 Krause, H. 279 Kraut, J. 789 Krumdieck, C.L. 447 Kuskinsky, R. 351 Kulikowski, T. 667 Kulinski, R.L. 803 Kumar, P. 989 Kumari, J. 475 Kunze, R. 411,415 Küster, T. 305 Rüther, G. 251 Kwee, S. 73 Laberge, C. 403 Ladenstein, R. 103 Lampi, B. 531 Lange, W. 415 Lapp, W. 4 81 Largilliere, C. 239 Laundy, M. 523 Leeming, R.J. 475 Lehmann, H. 399 Lelievre, G 315 Leupold, D. 69,399 Leskopf, W. 31 Levine, R.A. 347,373,381 Lewis, G.P. 909 Lowe, K. 925 Lumb, M. 709 Lura, R. 887 Machnicka, B. 651 MacKenzie, R.E. 767,901 Maley, F. 613 Maley, G.F. 613 Mandelbaum-Shavit, F. 597,855 Mangum, J.H. 913 Manteuffel-Cymborowska, M. 993 Masada, M. 223,275 Matasovic, A. 305 Matsumoto, J. 275 Matsuura, S. 77,81,223 Matthews, D.A 789 Matthews, K.D, 697 Matthews, R.G, 697,901,917, 921 Maubach, P. 205 Mayer, R.J. 13 McAdam, W.J. 351 McCaleb, G.S. 1001 McGuire, J.J. 729,861 McMartin, K.E, 489
McNulty, H. 513 McPartlin, J.M. 513 Meij, P.F.C. Van der 687 Mensua, J.L. 323 Merrill, D.K. 257 Milman, G. 925 Milstien, S. 169,403 Mohyuddin, F. 243,403 Molloy, A.M. 505 Montgomery, J.A. 1001 Moran, R.G. 645,691,937,953 Morgan, F. 351 Morrison, J.F. 827,831 Mura, P. 419 Murata, S. 77,81 Nagatsu, T, 223 Nair, M.G. 45,989 Nakagoshi, M. 271 Nakanishi, N. 287 Nakata, H. 351 Nayak, V.K. 583 Naylor, E.W. 309 Nazarbaghi, R. 659 Neuberger, G. 227 Newell, D.R. 675 Newton, P.A. 9 63 NextfS, E. 603 Nichol, C.A. 151,219,283,377, 835 Niederwieser, A. 141,305,319, 399 Nimec, Z. 547 Noel, C. 315 Noronha, J.M. 485 O'Connor, D.L. 555 Oatley, S.J. 789 Okano, Y. 247 Okeke, C.C. 57 733,925 Osborne, C. Oura, T. 247 Ozawa, K. 287 Panos, C.H. 57 Parniak, M.A 351,359 Pathak, A. 57 Paton, D.R. 295 Pawelczak, K 675 Pember, S.O. 13 Perry, J. 709 Petersson, L. 201 Pfleiderer, W. 31,115,305 Pheasant, A.E. 267,509 Picciano, M.F. 555 Pike, D.C. 51 Piper, J.R. 729,803,1001 Piriou, A. 419 475 Pollock, A.
1014
399,407 Ponzone, A. Price, E.M. 571,575 Priest, D.G. 479,973 Primus, J.P. 125 Pristupa, Z.B. 933 Pronzato, P. 681 Przybylski, M. 65 Pupons, A. 547 Rabinowitz, J.C. 865 Ramamurthy, B. 45 Ratnam, M. 819 Ratnam, S. 815 Rebandel, H. 671 Reddy, A.R.V. 583 Rehder, M.C. 847 Reibnegger, G. 263,427 Reinhard Jr., J.F. 111,377 Reisenauer, A.M. 551 Reiss, D. 419 Renkel, R. 65 Renner, D. 427 Repetto, L. 681 Reynolds, E.H. 523 Rhee, M.S. 547 Riazzi, B.S. 917 Rijksen, G. 543 Rode, W. 651,663,667 Roessler, H. 427 Rokos, H. 411,415 Rosenberg, I.H. 563,579,587 Rosenblatt, D.S. 713,843 Rosowsky, A. 807,985 Rosso, R. 681 Rupar, C.A. 243 Rzeszotarska, B. 675 Said, H.M. 567 Sams, L.A. 571 Sands, R.H. 917 Santus, R. 99 Sato, J.K. 287,977 Sawada, M. 223 Sawada, Y. 247 Scheibenreiter, S. 305 Schirch, V. 887,891 Schmidt, H. 399 Schneider, M. 103 Schornagel, J.H. 543 Schott, K. 103 Schreiber, C. 897 Schulz, T. 427 Schwalbe, C.H. 1005 Schweitzer, B.I. 763 Schwulera, U. 209 Scott, J.M. 467,505,513 Scrimgeour, K.G. 933 Scriver, C.R. 403 Seihub, J. 563,579 Shane, B. 719,733,925,997
Shannon, K.W. 865 Sherman, A.R. 555 Shih, C.J. 61 Shintaku, H. 247,399 Shugar, D. 667 Sikora, E. 675 323 Silva, F.J. Singer, S. 737 Sirotnak, F.M. 1001 Skiba, W.E. 913 Slieker, L.J. 13 Smith, A.G. 571 Smith, G.K. 111,151,835 Smith, I. 395 Smith, P.L. 575,807 Smith, S.L. 789 Soyka, R. 31 Spiro, T.G. 639 Srimatkandada, S. 793 Stäben, C. 865 Staudenmann, W. 305 Steinberg, S.E. 471 Steinerstauch, P. 299 Stevens, M.F.G. 1005 Stokstad, E.L.R. 717,905 Stone, S.R. 827,831 Strong, B. 887 Strum, W.B. 567 Struppler, A. 251 Stüber, D. 839 Sueoka, T. 291 Sugimoto, T. 77,81,223 Sussman, D. 925 Sutton, P.A. 969 Suyama, I. 247 Switchenko, A.C. 125 Szewczyk, B. 757 Szewczyk, K. 757 Tacquet, A. 315 Taira, K. 13 Takikawa, S. 141,299 Talmadge, K. 839 Tansik, R.L. 823 Tanzer, J. 419 Taylor, E.C. 55,61,953 Taylor, S.M. 937 Then, R.L. 839 Thorndike, J. 655 Toghiyani, T.R. 45 Toone, B.K. 523 Tsuruhara, T. 247 Tsusue, M. 271 Unterweger, B. Vickers, P.J. Volk, R. 227 Vuchich, M.J.
427 933 843
1015 687 Waard, E.R. -de 263,427,443 Wächter, H. 593,893 Wagner, C. 539 Wang, T.T.Y. 713 Watkins, D. 403 Watters, G.V Waxman, S. 897 Webber, S. 235,659 Weibel, E.K. 839 Weir, D.G. 467,505,513 Wells, M.S. 913 Welsh, W.J. 799 Werbel, L.M. 69 Werner, E.R. 263,427 West, D.K. 613 Whitehead, T .R. 865 Whitehead, V •M. 843 Whiteley, J.;M. 659 Wick, M.M. 985 Wiesenfeldt, M. 31
Wilson, E. 467 Winkler, F. 839 Wong, G.S.K. 61 Wong, K.P. 1005 Woo1f, J.H. 283 Wright, J.E. 807 Yamada, S. 287,291 Yamamoto, H. 247 Yang, I.Y. 631 115 Yim, J.J. Zeitler, H.-J. 251 Zheng, Y.C. 959 Zhu, H. 959 Ziegler, I. 209 Zielinski, Z 651, Zimmermann, J. 563 Zubrod, E. 205,335
SUBJECT
INDEX
Only the f i r s t page number of the c o n t r i b u t i o n in which the keyword appears i s given. Absolute c o n f i g u r a t i o n , hydropterins 77
6-A1koxymethyl-5,6,7,8-tetrahydropterins - synthesis 111 - cofactor a c t i v i t y 111
tetra-
Acetamidobenzoylglutamate
467
N(5)-Alkylation
6-Acetyl-7,8-dihydrohomopterin - complex with
107
N-Acetylserotonin
151,169
A c e t y l s e r o t o n i n methyl t r a n s f e r a s e 279 A c t i v e s i t e probes Acyl phosphate ADE 3 gene
631
A l l o s t e r i c model
921
Alpha-hydroxyglutaric acid
719
743
Amino a c i d a n a l y s i s , of p l a n t and human DHFR 815
865
Adenosine deaminase
655
Amino a c i d s , aromatic, metabolism
Adenosylhomocysteine 593 - as source of homocysteine
909
Adenosylmethionine 593 - i n h i b i t i o n of m e t h y l e n e t e t r a h y d r o f o l a t e reductase 697 - as i n h i b i t o r 921 - and methionine s y n t h e t a s e 909 Adrenal medullary cells 373
95
6-AlkyIthiomethy1-5,6,7,8-tetrahydropterins - synthesis 111 - cofactor a c t i v i t y 111
chromaffin
Amino a c i d s , t r a n s p o r t p-Aminobenzoylglutamate
467,513
2-Amino-4-keto-6-methyl-7,8-dihydropyrimidodiazepine 51 2-Amino-4-oxo-6-acetyl-3H,9H-7,8-dihyd r o p y r i m i d o ( 4 , 5 - b ) ( l , 4 ) - d i a z e p i n e (PDA), substrate for drosopterins 295
A f f i n i t y chromatography
977
Aminopterin, 5 - a l k y l - 5 - d e a z a 1001
Affinity
807
4-Aminopteroyl-polyglutamyl-esters
Age
l a b e l i n g , DHFR
AIDS
945,989
Amniotic f i b r o b l a s t s
427
309
Amniotic f l u i d p t e r i n s
399
Alcohol - chronic effects 489 - and f a t t y l i v e r 505 - and f o l a t e d e f i c i e n c y 489 - and f o l a t e e x c r e t i o n 489 - and f o l a t e metabolism 489
A n t i c a n c e r drugs
Alcohol
Anticancer folate i n h i b i t o r s
ingestion
Alcoholism, chronic
Amyotrophic l a t e r a l
467 485
6-A1koxymethyldi h y d r o p t e r i ns 6-Alkoxymethyl-7,7-dimethyl 5,6,7,8-tetrahydropterins - synthesis 111 - cofactor a c t i v i t y 111
analogs 65
6 - A m i n o u r a c i l s , as apoenzyme-substrate complex models 687
279
AICAR t r a n s f o r m y l a s e
335
185
671
Antibodies
351,607,819,977
A n t i f o l a t e drugs
251
993,1005
Antifolate activity 835
sclerosis
Antagonism
799
45
1005
Antifolates 69,729,815,861,945,953, 977,981 - adamantyl851 - arthritis 847
1018 -
biology 967 CB 3717 993 crystallographic analysis 851 5-deaza analogs of c l a s s i c a l 1001 l i p o p h i l i c 851 novel 1009 t r i a z i n e 959
A n t i f o l a t e s , spin-labeled 803 - immobilization of ligands 803 - mobilization of side chains 803 - synthesis
803
Antioxidant
547
Aspirin
239, 315, 385
L-erythro-biopterin
251
Biopterin synthetase deficiency B i o t i n Conjugate
363
107
Brain, folate concentrations
Avidin peroxidase
Breast cancer
613
Baseplate assembly
B. s u b t i l i s
103,227,743
Benzoquinone a c t i v a t i o n
563,567
743
Candida gui 11iermondii
757
Carbamazepine 603
227
495
Carbodiimide a c t i v a t i o n
757
Betaine 913 - effect on methionine synthetase 909
Carbonyl oxide, probe for
BH^
Carboxypeptidase Y
see Tetrahydrobiopterin
769
C a t a l y t i c oxygen reduction
Biogenic amine metabolites
CB 3717
385
305
Biomimetic methylene transfer Biopterin 151,271,305,327,339 - in amniotic f l u i d 239,399 - in chronic uraemia 315 - clearance 315 - deficiency 239,243,247,385 - diurnal v a r i a t i o n 267 - excretion, cocaine 257 - in human brain 223 - l e v e l s , human 247 - in l i v e r of animals 319 - N/B r a t i o in urine 243 - in plasma 475 - in red blood c e l l s 475 - reduced d e r i v a t i v e s 235
687
583
737
B i o a v a i l a b i l i t y , of tetrahydro and dihydropterins 835 Biolumazine
51
Carboxypeptidase G, i n h i b i t i o n C a t a l y t i c mechanism
531
495
539,563
Brush border membrane
1005
419
681,945,981
Brush border
607
Bacillus subtilis
Bioassay
419
- treatments, neopterin v a r i a t i o n s
531
Autocatalytic s p l i c i n g
385
607
Bone marrow transplantation
847
Azido compounds
- in urine
Bond Elut, C18
Anti-PAH antibody Arthritis
- in serum 239, 315 - s y n t h e s i s , defective 403 - s y n t h e s i s , inborn error of metabolism 239 - urinary excretion 267
73
Catecholamine synthesis 201,373 993
CB 3717 triglutamate, i n h i b i t i o n of thymidylate synthase 763 CCRF-CEM c e l l s
729,953
Cell mediated immunity
427
Cerebrospinal f l u i d 251,385,395 - biopterin p r o f i l e s 395 - HVA and 5HIAA concentrations 395 5-CH,-H.PteGlnc, i n h i b i t o r of glycine N-meïhyTtransferase 593 Chinese hamster ovary c e l l s Choline turnover Chorionic v i l l i Chromaffin c e l l s
593 309 373
843
1019
Chronic alcoholism
Cytochrome b
485
C h r o n i c ethanol e f f e c t s
489
C4a-hydroxydehydratase
Cytotoxity
51
Circadian rhythm - of Cortisol 411 - of n e o p t e r i n 411 - of T - L y m p h o z y t e s 411 315
- neopterin
315
Cloning
DAEP
DAMP
733
681 calcu-
Coba 1 amin 481,713 - inactivation 709 - in m e t h i o n i n e s y n t h a s e Cocaine a b u s e , p t e r i n Colour dimorphism Conformational
DAPP
969
hydro-
synthase
Crithida fasiculata
185
polyglutamates
989
5-Deazaantifolates,
5-substituted
1001
45
11-Deazahomofolate
45
5-Deaza-5,6,7,8-tetrahydrofolicacid 953 893
Depression Desilylation
607
structures
DHFR
969,
523
C18 s i l i c a c a r t r i d g e s C.-Tetrahydrofolate 865,887
107
synthase
Cumene hydroperoxide Cyclic AMP, analogs
547 283 73
Cystathionine-gamma-synthase 743
305
2'-Deoxysepialumazine 2'-Deoxysepiapterin
757
Cyclic voltammetry
45
2'-Deoxybiolumazine
Copper,in methionine 697
Cross-reactivity
61
10-Deazaaminopterin
Demethylation
823
799
851
10-Deazafolate
271
comparison
Cooperati vity
697
799
851
10-Deazaaminopterin
excretion
C o n j u g a s e (y-glutamyl lase) 583,933 - inhibition 583
CSF folate
799
851
D D A T H F and a n a l o g s
Crossi inking
799
851
D A P P , as DHFR i n h i b i t o r DCXMP
327
Crystal 1005
851
D A M P , as DHFR inhibitor 865
C N D O / 2 M o l e c u l a r orbital lations 799 CNS
861,953
D A H P , as DHFR i n h i b i t o r
C l o s t r i d i u m acidi-urici CMF
339
D A E P , as DHFR i n h i b i t o r DAHP
Clearance - biopterin
339
Cytochromes
305 305
523 91
see D i h y d r o f o l a t e
reductase
2,4-Diamino-5-(l-adamantyl)-6-ethylp y r i m i d i n e (DAEP) 851 2,4-Diamino-5-(1-adamantyl)-6-methyl p y r i m i d i n e (DAMP) 851 2,4-Diami n o - 5 - ( 1 - a d a m a n t y l ) - 6 - p r o p y l p y r i m i d i n e (DAPP) 851 2,4-Diami n o - 5 - ( 1 - a d a m a n t y l ) (DAHP) 851
pyrimidine
2,4-Di ami n o b e n z y 1 p y r i mi di nes 2,4-Diamino-5-t-butyl-6-methyl ine (DTMP) 851
823 pyrimid-
1020 2,4-Diamino-5-cyclohexyl-6p y r i m i d i n e (DCXMP) 851
methyl
2,4-Diamino-5,8-dideazapterins, s y n t h e s i s and p r o p e r t i e s 57 4,6-Diamino-l,2-dihydro-2,2-dimethyl-l-(X-phenyl) triazines 959 2,4-Diamino-6-hydroxy 231
pyrimidine
2,4-Diaminoquinazolines,synthesis and p r o p e r t i e s 57 2,4-Diamino-6-pteri dinecarboxaldehyde 99 - p h o t o s e n s i t i z a t i o n by 99 - t r i p l e t s t a t e 99 Diaminopyrimidines
69
2,4-Diaminopyrimidines, 1ipophilie, as DHFR i n h i b i t o r s 799 Dibutyryl
c y c l i c AMP
5,8-Dideazafolates 5,8-Dideazafolic
287 997
acid
645
5,10-Dideaza-5,6,7,8-tetrahydrof o l i c acid 953 - and a n a l o g s 61 - asparate analog 953 - diastereomers 953 Dietary
iron
Differential
Differentiation
447
275
-
2,6-Difluorobenzonitrile, reactions 57 7,8-Dihydrobiolumazine Dihydrobiopterin
305
151,835
7,8-Dihydrobiopterin Dihydrobiopterin,
305
quinonoid
Dihydrobiopterin synthetase deficiency 243,399
-
363 cleavage
• -
81 (DHBS)
7,8-Dihydro-2'-deoxybiolumazine 305 Dihydrofolate 769,789,831,835, 945 - determination of 973 - i n t r a c e l l u l a r accumulation 981 - r e s p o n s e to m e t h o t r e x a t e 973 Dihydrofolate reductase 13,151,395, 645,671,719,729,757,769,803,819,843, 851,861
-
affinity labeling 807 a l t e r a t i o n o f gene 793 amino a c i d a n a l y s i s 815 antibodies 819 antibody c r o s s - r e a c t i v i t y 819 binding of i n h i b i t o r s 769 bovine 835,839 chicken l i v e r 831 complex d i s s o c i a t i o n c o n s t a n t s 803 crystallization 769,839 crystallography 769 deuterium isotope e f f e c t s 827 dihydrofolate 769,831 dihydropyrirnidodiazepine substrate for 51 E.coli 811,827,835 e n z y m e - N A D P H - i n h i b i t o r complex 823 folate 769,831 f o l a t e complex 811 human 793,839,937,977 inhibition 69,799,815,855,945,959,989 i n h i b i t i o n by MTX a n a l o g s 985 inhibition constants 769 inhibitor binding 823 inhibitor dissociation constants 823 i s o m e r i z a t i o n o f complexes 769 isozymes 811 k i n e t i c mechanism 769 k i n e t i c parameters 827,831 kinetic properties 815 l a c k i n g , C h i n e s e hamster o v a r y c e l l s 843 l i g a n d complexes 819 1 i g a n d - i n d u c e d c o n f o r m a t i o n a l change 819 mapping o f a n t i g e n i c y 819 mechanism 769,827 methotrexate 769 mouse S - 1 8 0 839 m u l t i p l e enzyme forms 811 n e i s s e r i a gonorrhoea 823 NMR 769 o l i g o n u c l e o t i d e - d i r e c t e d mutagenesis 769 pH e f f e c t s 827,831 photoaffinity labeling 575 pK a v a l u e s 827,831 plant 815 p l a s m i d e encoded 789 purification 811,815 radioimmunoassay 818 rat 839 reactive groups 807 r e c e n t advances 769 recombinant 839 sheep l i v e r 989 s i t e - d i r e c t e d mutagenesis 793 soybean 815
1021 -
stopped-flow f1uorimetry 2,8 A structure 789 substrates 799 substrate s p e c i f i t y 831 X-ray d i f f r a c t i o n 769 X-ray structure 839
6,7-Dimethylhydropterin, quinonoid
769
6,7-Dimethylpterin
6,7-Dimethyl-8-ribityllumazine
103,227
6,7-Dimethyl-5,6,7,8-tetrahydropterin 91
Dihydrofolate s y n t h e t a s e - f o l y l p o l y glutamate synthetase, E. c o l i 737
6(1',2'-Dioxopropyl)tetrahydropterin 151
D i h y d r o f o l i c acid
Disorders, neurological
- substrate for DHFR
799
7,8-Dihydro-6-hydroxylumazine Dihydromethanopterin
305
743
6,6-Disubstituted tetrahydropterins DNA sequence
Dihydroneopterin trisphosphate 151,299 - d e r i v a t i v e s 115 - t r i s effect 115
- s y n t h e s i s , modulation
Dihydroorotate
Drosophila melanogaster
Domains
DOPA formation Dopamine
Down's syndrome
Dihydropterins - b i o a v a i l a b i l i t y 835 - quinoid 6 , 6 - d i s u b s t i t u t e d 391 - as substrate for drosopterins 295
E. c o l i DHFR
743, 989
327 323,335
- nonenzymatic synthesis Drug addicts DTMP
295
427
851
DTMP, as DHFR i n h i b i t o r Dynospheres
799
603
Dyspropterin reductase
275
Dyspropterin synthetase E. c o l i
275
743 811
Electrical excitability
215
Electron spin resonance
803
Enzyme a c t i v i t y
959
Enzyme amplification Enzyme conformation
733 769
see i n h i b i t o r s
Enzyme Linked Immuno Sorbent Assay (ELISA) 607
291 835
Dimethylglycine dehydrogenase
347
215
125
Enzyme i n h i b i t o r s
305
6,7-Dimethyl dihydropterin
377
373
Dihydropteridine reductase 185,287, 309,315,391 - a c t i v i t y in animal l i v e r 319 - biopterine p r o f i l e s in CSF 395 - deficiency 385,395,399,407 - homovanillic acid and 5-hydroxyindole acetic acid concent r a t i o n s 395 - human mutant 407 - hyperphenylalaninaemia 395 - quinoid dihydropyrimidodiazepine substrate for 51 - substrates for 111
Dihydropteroylpentaglutamate
937
865
Drosopterin
Dihydropteroylhexaglutamate 757
865
DNA transfection
Dopamine neurons
509
a-Diketo reductase
391
D i s s o c i a t i o n constants 769 - of DHFR complexes 803
7,8-Dihydroneopterin - circadian rhythm 411 - influenced of s t r e s s 411 - in LAV/HTLV-III i n f e c t i o n 411 - in renal i n s u f f i c i e n c y 411 Dihydroneopterin/Neopterin-ratio 411
7,8-Dihydroxanthopterin
81
91
893
Enzyme regulation, k i n e t i c s
921
391
1022 Enzymes - monofunctional 865 - multifunctional 865 - trifunctional 901 Enzymology
953
Epileptics
527
EPR spectroscopy
201,917
Equilibrium d i a l y s i s
603,823
Erythrocytes - folate quantitation 603 - 6-pyruvoyltetrahydropterin synthase a c t i v i t y 399 - sepiapterin reductase a c t i v i t y 399 Erythrophore
275
Erythrophoroma cell
275
10-Ethyl-10-deazaaminopterin 855
45,
10-Ethyl-10-deazaaminopterin glutamates 989
poly-
N(5)-Ethyl-heptaacetyl-5,6,7,8-tetrahydro-D-neopterin 95
- urinary excretion Folate absorption Folate analogs
Fluorescence, tryptophan
o-Fluorobenzoni t r i l e s , preparati on and reaction 57 Dl-threo-4-Fluoroglutamic acid Fluoropyrimidines
729,997
743
691
681,691
Folate see also f o l i c acid 495, 555,769,831 - absorption and transport 587 - active transport 567 - bioavailability 531 - chemistry 55 - CSF 523 - d i e t a r y , digestion 539 - DHFR folate complex 811 - effect of anticonvulsant t r e a t ment 495 - excretion, and alcohol 489 - formylation 709 - human 523 - i n t e s t i n a l absorption 551,579 - i n s t e s t i n a l transport 563,567 - intracellular 811,843,981
953
567
Folate-binding proteins 551,567 - immobilized 603 - i n s o l u b i l i z e d 603 - in milk 607 - in serum 607 - soluble 603 Folate catabolism 467,513 - effect of xanthopterin and a l l o p u r i n o l 509 - in hamster 509 Folate deficiency
467,505,523
489
Folate depletion
201
485,489 485,709
Folate antimetabolites
- and alcohol
893
5-F1uorouraci1
l e v e l s in e p i l e p t i c s 527 l i v e r 471,531 metabolism, and alcohol 489 microbiological assay 843 quantitation 603 red c e l l 523 reduced 843 regulation 925 renal clearance 489 in serum 523 in t i s s u e s and c e l l s 479
Folate binders
ESR spectroscopy, methionine synthase 697
Flavoenzyme
-
843
Folate homeostasis 925 Folate i n h i b i t o r s , theoretical 799
studies
Folate metabolic mutant c e l l s , complementation of 937 Folate monoglutamates 517 - detection and determination - serum l e v e l s 517 Folate oligoglutamate 743
517
transpeptidase
Folate polyglutamates, i n t e s t i n a l sorption 579
ab-
Folate requiring enzymes, mechanism of reaction 13 Folate rescue, in lymphocytes Folate transpeptidase
481
933
F o l i c acid see also folate 843,905 - storage in red blood c e l l s 471 - structure 969 - substrate for DHFR 799
1023 - supply 471 - transport 551,559
Gene cloning
Folinic acid
Glutamate
681,691
Folylpolyglutamate dase 757
carboxypepti-
folylpolyglutamate hydrolase
933
Folylpolyglutamate reductase
861
Folylpolyglutamates 811,925,933 - E. coli, analysis 737 - E. coli, synthesis 737 - kinetic constants 719 - synthesis 719,741,925 Folylpolyglutamate synthetase 729, 733,743,757,763,925,997 - cloning of 937 - corynebacterium 719 - E. coli 719 - endogenous inhibitor of 929 - formation of di and tri glutamates 929 - human 937 - kinetic constants 719 - L. casei 719 - mechanism of action 719 - pig liver 719 Folylpoiy-a-glutamate E. coli 737 Formaldehyde Formate
synthetase,
505,743
Goldfish
275
Graft-versus host disease 419
709
151 603,865
10-Formyltetrahydrofolate 887,945
865,
10-Formyltetrahydrofolate: oxidoreductase 905
NADP
10-Formyltetrahydrofolate tase 865,887
GTP cyclohydrolase 219,275,283,315 - activity, effect of 3-Hydroxykynurenine 323 - deficiency 385 - fast assay procedure 415 - hormonal regulation 219 - in LAV/HTLV-III infection 415 - in monocytes, macrophages 415 GTP cyclohydrolase I 151 - activity in animal liver - in human brain 223 655
synthe-
283
743
Gamma-fluoromethotrexate
319
655
reconstitution
861
HCT8 cell line 419 - development of MTX-resistant cell line 793 - DHFR cDNA cloning 793 - DHFR gene amplication 793 - southern analysis 793 Hepatic polyglutamate synthesis
10-Formyltetrahydropteroy1glutamate 517
Gamma-diglutamate
(G.V.H.D.)
Growth inhibition 953,959 - and hydrophobicity 959
H35 cells
953
5-Formyltetrahydrofolate
Forskolin
Glycine N-methyltransferase - human 593 - rat 593
Haemopoietic
Formylation, folate
Formylpterin
trans-
905
865
Formyl-GAR
547
Glycine amide ribonucleotide formylase 945
Guanosine
Formiminoglutamic acid
205,733,925
719
Glutathione
Guanase
743
865,905
Formylase
865
Gene expression
861
Hepatocytes
547,559
Hepatoma cells Histidine HL-60 cells
485
743
905 897
Homocysteine - formation from adenosylhomocysteine 909 - stabilisation of methyltetrahydrofolate 909 - as substrate for methionine synthetase 909
1024
Homocystinuria
6(1'-Hydroxy-2'-oxopropyl)tetrahydropterin 151
713
Homovanillic acid
385
HPLC 467 - biopterins 395 - of cerebrospinal f l u i d , p t e r i d i n e s 251 - chiral 861 - d o p a m i n e and S e r o t o n i n e m e t a b o lites 395 - e l e c t r o c h e m i c a l and f l u o r e s c e n c e detections 395 - 5 - f o r m y 1 t e t r a h y d r o p t e r o y 1 gl u t a mate 517 - 10-formyltetrahydropteroylglutamate 517 - 5-Methyltetrahydropteroylglutamate 517 - neopterin 263 - pABGlu, ApABGlu 513 - p t e r i d i n e s X, X I , X2, X3 107, 115 - pteroylglutamate 517 - tetrahydropterins 835 - tetrahydropteroylglutamate 517 - u r i n e , N / B r a t i o and BH4 243 - urine, pteridines 251 H2PTeGlu5
743 virus
299
H y d r i d e transfer
901
Hydrodynamic voltamogram, d r o b i o p t e r i n in CSF 395 Hydrogénation
427
tetrahy-
91
H y d r o g e n bonding
969
Hydrophobic pocket
851
7-Hydroxybiopterin
271
811
219
Hypothyroidism
905
1 3 I m i d a z o l i n e s , N ,N - u n s y m m e t r i c a l l y disubstituted 687 I m m o b i l i z a t i o n of l i g a n d s Immunity, cell m e d i a t e d Immunoglobulin, Indoles
5-Hydroxyindoleacetic 3-Hydroxykynurenine radicals
6-Hydroxylumazine
acid
385
323 73 305
7-Hydroxymethotrexate - antileukemic activity 963 - e f f e c t on m e t h o t r e x a t e 963 - host t o x i c i t y 963 6-Hydroxymethyl pterin - f o r m a t i o n in T cells 209
803 427
anti-FBP, rabbit
607
169
Infections
419
Inhibition, of DHFR
959
Inhibition c o n s t a n t s , DHFR
769
839
Inhibitors 659,663,675,729,953 - active a g a i n s t F P G S ' s 929 - binding to DHFR 769 - endogenous 929 Interleukin 2 - internalization - radio i o d i n a t e d - signal function
209 209 209
transmission
Intestinal
209
a b s o r p t i o n , folate
551
613
Iron 555,893 - in m e t h i o n i n e
synthase
Iron a b s o r p t i o n
743
231
905
Hypophysectomy
Intron
8-Hydroxy-7-dimethyl-5-deazaflavin
Hydroxyl
- pterin administration Hyperthyroidism
- signal
Hydrophobic chromatography
651
Hyperphenylalaninemi a 239,385,395 - m o u s e model 231 - newborn s c r e e n i n g for 243,403
Inhibitor d e s i g n
Human immunodeficiency H u m a n liver
Hymenolepsis diminuta
697
363
Iron c o n t e n t , of p h e n y l a l a n i n e lase 363 Iron protein
201
Iron s u p p l e m e n t
363
Isodrosopterin, nonenzymatic 295 Isomerase
hydroxy-
synthesis
291
I s o m e r i z a t i o n , of DHFR c o m p l e x e s Isoxanthopterin
125,251,271,305
769
1025 K562 c e l l s
729
Mesencephalon
Kidney - allograft 315 - b i o p t e r i n metabolism Lactate
315
Methanobacterium 743
339
Methanopterin
L - ( + ) - l a c t a t e cytochrom c o x i d o reductase 339 Lactation
555
Lactobacillus casei 6-Lactoyl 291
659,743
tetrahydropterin
Lactoyl-tetrahydropterin 151
99
427
L1210 c e l l s
575,663,763,953,959
- permeabi1 i zed LDH-isoenzymes
763 339
865
L i g h t melanotonin Liver
141,151,
synthase
Laser f l a s h s p e c t r o s c o p y LAV/HTLV-III
Leucovorin
279
913
Liver folate
471,531
- concentrations L1210 leukemia
495 963
L1210/R71 c e l l s Lumazines
959
305
Lumazine synthase Lymphocytes - human 231 - mouse 231 - stimulated
MCF-7 c e l l s
103,227
Mean c o r p u s c u l a r volume
Membrane
Methionine synthase 481,709 - activation 697 - cobalamin-dependent 917 - from E. c o l i 697,917 - EPR s p e c t r o s c o p y 917 - i n a c t i v a t i o n by n i t r o u s oxide - from p i g l i v e r 697 Methionine s y n t h e t a s e - assay requirements - blanks f o r 909
275 169
567
2-Mercaptomethylglutaric acid 583 - design, synthesis 583 - carboxypeptidase Gi i n h i b i t i o n 583 - conjugase i n h i b i t i o n 583
917
505 909
Methotrexate 543,547,597,681,729,769, 823,839,847,855,861,897,933,945,977 - 5-alkyl-5-deaza analogs 1001 - as a n t i f o l a t e 981 - as DHFR i n h i b i t o r 799 - e f f e c t s on c e l l growth 973 - e f f e c t s on reduced f o l a t e s 973 - i n t e r a c t i o n , 7-hydroxy-MTX 963 - membrane b i n d i n g components in L1210 cells 575 - p h o t o a f f i n i t y analogues 575 - in plasma 475 - in red blood eel I s 475 - s t r e t c h e d analogs 985 - s t r u c t u r a l analogue 807 - structure 969 571 4-fluoroglu659
Methotrexate p o l y g l u t a m a t e s - formation 843 475
865
Methionine 505,713 - biosynthesis 697,717,913
Methotrexate d e r i v a t i v e s
547
855,981
Melanophore
743
5,10-Methenyl-THF c y c l o h y d r o l a s e
Methotrexate d e r i v a t i v e of tamic a c i d 743
481
syn-
thermoautotrophicum
Methotrexate analogues
Malondialdehyd
Melatonin
215
Metabolism, inborn e r r o r , b i o p t e r i n thesis 239,385
475,945,989
Methotrexate-y-polyglutamates - purity 65 - synthesis
65
65
Methotrexate r e s i s t a n c e
69,543
Methotrexate-sepharose
839
Methotrexate t r a n s p o r t
543
5-Methyl-5-deazaaminopterin 10-Methyl-10-deaza-aminopterin
1001 855
1026 5-Methyl-5-deazamethotrexate
1001
5-Methyl-5,10-dideazaaminopterin 1001
Molecular packing Monapterin
Multifunctional enzymes Multisubstrate i n h i b i t o r
5-Methyltetrahydrofolate 713,945
NAOPH
81
Methyltetrahydrofolate-homocysteine methyl transferase 697 5-Methyltetrahydrofolate-Homocysteine transmethylase 743 acid,
6-Methy1 -tetrahydropteri n homolog 51 5-Methyltetrahydropteroylglutamate 517 6-Methyl-tetrahydropyrimidodiazepine 51
Milk
555
593 865
151
N e i s s e r i a gonorrhoea DHFR
597,603,
913
287
NADH-specific dihydropteridine reductase 287
505
6-Methylhydropterin, quinonoid
Methyl trap hypothesis
631
NADH-dihydropteridine reductase
687
Micrococcus aerogenes
369 865
dehydro-
Methyltetrahydrofolate, s t a b i 1 i zation by homocysteine 909
Methyl transferase
865
Mouse mastocytoma, P-815
Methylenetetrahydrofolate reductase 395,697,905 - a l 1 o s t e r i c model 921 - Clostridium formicoaceticum 697 - i n h i b i t i o n by AdoMet 697 - pig l i v e r 697 - regulation by AdoMet and NADPH 921
5-Methyltetrahydrofolic transport 559
251
Monofunctional enzymes
5,10-Methylenetetrahydrofolate 691,945 - models 687 - substrate for FPGS 929
Methyl group wastage
799
969
Monocytes/macrophages - a c t i v a t i o n of 415
Methylenetetrahydrofolate 743 - determination of 973 - response to methotrexate 973
Methylene transfer
547
MM2p F o r c e - f i e l d c a l c u l a t i o n s
835
Methylenetetrahydrofolate genase 865,901
865
Mitoxanthrone
5-Methyl-5,10-dideaza-5,6,7,8t e t r a h y d r o f o l i c acid 1001 6-Methyl dihydropterin
Mitochondria
823
Neopterin 151,271,419,427 - in amniotic f l u i d 239,399 - in animal l i v e r 319 - biopterin r a t i o 239,315,385 - in chronic uraemia 315 - circadian rhythm 411 - determination 263 - diurnal v a r i a t i o n 267 - excretion, cocaine 257 - formation in T c e l l s 209 - in human brain 223 - influence of c o r t i c o t r o p i n r e l e a s i n g hormone 411 - influence of s t r e s s 411 - in LAV/HTLV-III i n f e c t i o n 411 - in LAV/HTLV-111 p o s i t i v e patients 415 - N/B r a t i o in urine 243 - p r o l i f e r a t i o n of lymphocytes 415 - radioimmunoassay for 411 - in renal i n s u f f i c i e n c y 411 - serum l e v e l s , influence of creatinine 411 - in serum 239,315 - urinary excretion 267 - in urine
239,315,385
D-threo-neopterin (monapterin) L-erythro-neopterin
251
Neopterin clearance
263
Neopterin l e v e l s - in a l l o g r a f t r e c i p i e n t s 263 - in autogressive diseases 263
251
1027 -
and c e l l mediated immunity 263 i n c e r v i c a l cancer 263 in diseases 263 and i n t r a c e l l u l a r pathogen i n f e c tions 263 - and other l a b o r a t o r y parameters 263 Nerve growth f a c t o r
287
Nerve terminal a u t o r e c e p t o r s Neuroblastoma c e l l
lines
Neuroblastoma N1E-115 Neurological
Phenylalanine hydroxylase 185,201,335, 363,391 - cofactors for 111 - c o n s e r v a t i o n of epitope 351 - deficiency 395 - inhibition 359 - i r o n content 363 - monoclonal antibody 359 - monoclonal a n t i b o d y , i d e n t i f i c a t i o n of epitope 351 - mechani sm 51 - pH dependence 355
347
283
283
disorders
Phenylalanine hydroxylase proteine 185
391
Neurospora c r a s s a 743,929 - p o l y g l u t a m a t e - d e f i c i e n t mutants
Phenylketonuria
243
- atypical
form
385
N e u r o t r a n s m i t t e r amine m e t a b o l i t e s - homovanillic acid 395 - HPLC 395
Phenytoin
495
-
Phosphate
5-hydroxyindoleacetic acid
Neurotransmitters
395
Nigrostriatal
215
N i t r o u s oxide
481,709,917
- i n h i b i t i o n of methionine
107
synthase
NMR, d i h y d r o f o l a t e reductase NMR, two dimensional
769®^
743
373
729
Osteosarcoma c e l l s
977
O x i d a t i v e demethylations Oxidative stress Oxygen a c t i v a t i o n
Pediococcus c e r e v i s i a e
567
495
Phenylalanine 239,315,385,395 - enzymatic h y d r o x y l a t i o n 185 - tyrosine ratio 315
865
571
by p t e r i d i n e
P h y l o g e n e t i c comparison
613
ir-Electrón d é l o c a l i s a t i o n , e f f e c t on t e t r a h y d r o p y r a z i n e r i n g conformers 85 539
a
275
969
Planarity
Peptococcus a s a c c h a r o l y t i c u s Phénobarbital
l a b e l i n g reagents
Pigmentation
283, 377
399
Phosphoribosylpyrophosphate - folate deficient 897 - in HL-60 c e l l s 897 - methotrexate-treated 897 - phosphate-induced e l e v a t i o n 897 Photoaffinity labeling 575,613
pK
51
893
P h o s p h a t e - e l i m i n a t i n g enzyme
Pig jejunum
893
547
PC12 pheochromocytoma
897
Photosensitization, derivatives 99
0 1 i g o n u c l e o t i d e - d i r e c t e d mutagenesi s 769 Ornithine
559
Photoaffinity
201, 893
Norepinephrine
pH g r a d i e n t
Phosphate, c o v a l e n t
385,523
Nickel-complex with p t e r i n s
Non-heme i r o n
92
stimulating
851
Plasma, f o l a t e c o n c e n t r a t i o n s Plasmids
733
- with encoded DHFR Platelets
Platinum c a t a l y s t 31
P-NMR
Poly G
789
475 893
655
91
495
1028 Pterin requiring enzymes, mechanism of reaction 13
Polyglutamates - a -COOH linked 737 - hepatic synthesis 485 - synthesis in vitro 929 Polyglutamation
953
- of antifolates
993
Polyglutamination
763
Polyglutamylation, regulation Poly-Y-glutamyl Pregnancy
derivatives
583 989
239,467
Prenatal diagnosis
Prodrug Promoter
309
495
733 671
NIO-propargy1-5,8-dideazafolic acid 645,993 N10-Propargyl-5,8-dideazafolic acid polyglutamates 675 Prostitutes
769
Pteridine granule
271
Pteridine pattern, effect of 3-hydroxykynurenine 323 Pteridines 339 - in amniotic fluid 239,309 - biology of 331 - biosynthesis 335 - in chronic uraemia 315 - hydrogénation 91 - side chain chemistry 31 - in thrombozytes 431 - trimethylsilyl derivatives - in urine 431 - in white cells 431 - yellow-green
Pterin-6-carboxylate Pterin deaminase
Purine, synthetic activity Pyrimidodiazepine 91
115
Pteridine symposia, history
1
151
activity 539
381
65
981
51
6-Pyruvoyl-tetrahydrobiopterin, 169,299 - deuterium exchange 299 - H-NMR 299 - mechanism of formation 299 6-Pyruvoyl-tetrahydrobiopterin 299 6-Pyruvoyl-tetrahydropterin 319
305
Pterin-dependent reactions
hydrolase
Pteroyl- y - p o l y g l u t a m a t e s - purity 65 - synthesis 65
115
Pteridines X,X1,X2,X3
743
Pteroyl polyglutamates - analysis 447 - biodégradation 743 - chain length alteration 743 - E. coli, synthesis in vitro 737 - in folate deficient rats 743 - in hepatoma eel Is 743 - interaction with enzymes 743 - intestinal absorption 743 - in sarcoma 180 cells 743
427
Proton donation
671
Pteroylhexaglutamate, cofactor in the TS cycle 763 Pteroylpolyglutamate
77
Pteroyl polyglutamate patterns - in alcohol-fed rats 447 - in liver regeneration 447 - in quail organs 447 - in rat fetuses 447 - in rat organs 447 - in starvation 447 - in Tyzzers disease 447
835
Propargyl
Pteroylglutamate coenzyme Pteroylglutamates 517 - biosynthesis from E. coli
Prenatal diagnosis, 6-pyruvoyltetrahydropterin synthase deficiency 399 Primidone
Pterins 151,251,305 - in animal liver 319 - chemistry 55,121 - GC/MS 151 - and human illness 443 - photosensitization by 99 - stereoselective hydrogénation - triplet state 99
6-Pyruvoyl-tetrahydropterin 151,169
PPH. 4
synthetase
141, 151, synthase
1029 - a c t i v i t y in - a c t i v i t y in 399 - deficiency, 399 - i n man 141 - properties
animal l i v e r 319 (fetal) erythrocytes prenatal
diagnosis
Rhodium DI0P c a t a l y s t s
91
Riboflavin, biosynthesis R i b o f l a v i n synthase Ring s t r a i n e d p t e r i n s
51
141 Saccharomyces c e r e v i s i a e
Queuine
Sarcosine
205,339
Quinespar, structure
57
SCF/ST0-3G
969
SCF/3-21G
85
Scorpion f l y
Quinoid 6 , 6 - d i s u b s t i t u t e d pterins 391
S e n i l e dementia
6,7-dimethyldihydro-
305
S e p i a p t e r i n reductase antibody
spectroscopy,
Quinonoid 6 - m e t h y l d i h y d r o p t e r i n , s y n t h e s i s and p r o p e r t i e s 81
Serine
865
S e r i n e hydroxymethyl 607
R a b b i t a n t i - F B P immunoglobulin Radioimmunoassay Raman s p e c t r a Rat l i v e r
Serotonin
639 495
763 743,
169,523 523
Side chain c h e m i s t r y , p t e r i d i n e s Silylation
31
91
S i n g l e t oxygen, p r o d u c t i o n by p t e r i d i n e derivatives 99
363
513
Stereochemistry,
Reconstitution,
synthetase
Serine hydroxymethyltransferase 887 Serum f o l a t e
729
Rat n u t r i t i o n RDA
607
819
Rat, f o l a t e c o n c e n t r a t i o n s
151
Sep-Pak, C18, r e l a t i v e a d s o r p t i o n of pteridines 107
81
Rabbit a n t i b o d i e s
815
327
S e p i a p t e r i n reductase 169,291,309 - a c t i v i t y in animal l i v e r 319 - a c t i v i t y in e r y t h r o c y t e s 399 - inhibition 169 - in man 141
p-Quinonoid-dihydropterin - conformers 85 - molecular geometries 85
isomerization
SDS Page, p u r i f i e d DHFR
Sepiapterin 125,151,271,305 - n i c k e l complex 107
Quinonoid d i h y d r o b i o p t e r i n , s y n t h e s i s and p r o p e r t i e s 81
pterin, synthesis,
271
Sepialumazine
Quinonemethides, r e d u c t i v e identification 687
893
85
Quinoid d i h y d r o p y r i m i d o d i a zepine 51 dihydro-
865
505,593
S a r c o s i n e dehydrogenase
Quinazolines 997 - synthesis, properties
Quinonoid
103,227
103
haemopoietic
419
hydride t r a n s f e r
901
Red blood c e l l s
471
S t e r e o s e l e c t i v e hydrogénation of p t e r i n s mechanism 77
Red c e l l
523
Stopped-flow f l u o r i m e t r y , DHFR
folate
Regulation
Streptococcus faecium
219
Renal f o l a t e c l e a r a n c e Retina
Retinoic acid
489
5 - s u b s t i t u t e d - 5 - d e a z a a n t i f o l ates Superoxide dismutase
279 287
Superoxide r a d i c a l
73 99
769
655,743 1001
1030 Synergism Tapeworm
(6S)-Tetrahydrobiopterin, synthesis, spectroscopy and conformational study 77
671 651
T cells - DNA s y n t h e s i s 209 - IL-2 signal transmission - pteridine synthesis TE85 c e l l s
T e t r a h y d r o f o l ate 603 - determination of 973 209
209
Ternary complex
887
Tetrahydrofolic acid - deaza d e r i v a t i v e s 953
287
- s u b s t r a t e f o r DHFR
691
- with thymidylate synthase Ternary complex a s s a y s
973 743
Tetrahydrofolate synthase
977
Teratoma 402A
- response to methotrexate T e t r a h y d r o f o l a t e reductase
639
447
Tetradecanoyl e s t e r (TPA) 431 Tetrahydrobiopterin 151,201,215, 219,291,305,319,373,391,431,835 - analogs 377 - c a t a b o l i s m 305 - in dopamine s y n t h e s i s 347 - formation in c e l l s 209 - IL-2 internalization 209 - loading test 315,385 - in man 141 - metabolic r o l e 185 - as % of t o t a l b i o p t e r i n 243 - and r e l a t e d compounds, b i o s y n thetis 125 - S phase p r o g r e s s i o n 209 - synthesis, alteration 315 - s y n t h e s i s , maturation 239 - treatment wi th 399 Tetrahydrobiopterin biosynthesi s 183,299 - i n bovine adrenal medulla 151 - hormonal r e g u l a t i o n 219 - regulation 283 Tetrahydrobiopterin deficiency 243,247,391,399 - c l i n i c a l presentation 385 - t r a n s i e n t form 239,385 - treatment 385 T e t r a h y d r o b i o p t e r i n load t e s t , h e t e r o g e n e i t y i n human response 407 (6R)-Tetrahydrobiopterin, synthesis, s p e c t r o s c o p y , X - r a y a n a l y s i s and conformational study 77 6-R-L-erythro-5,6,7,8-tetrahydrobiopterin - analogues of 111 - deficiency diseases 111
799
Tetrahydromethanopterin T e t r a h y d r o p t e r i di n - conformers 85 - molecular geometry
743
85
Tetrahydropterin regeneration
287
Tetrahydropterin(s) 151,835 - absolute c o n f i g u r a t i o n 77 - bioavailability 835 - b i o s y n t h e s i s in r a t b r a i n 169 - cation radical 73 - conformers 85 - 6,6-disubstituted 391 - e l e c t r o c h e m i c a l d e t e c t i o n of HPLC 151 - HPLC-EC 169 - i n t e r n a l redox r e a c t i o n f o r g e n e r a t i o n 151 - tyrosine hydroxy!ation
377
Tetrahydropteroylglutamate
517
Tetrahydropteroylpolyglutamates T e t r a h y d r o p y r a z i ne - conformers 85 - molecular geometry
887
85
T e t r a h y d r o p y r a z i n e - r i n g conformers, e f f e c t of i r - e l e c t r o n - d e l ocal i s a t i o n
85
Tetrahydropyrazin-ring d e r i v a t i ves, s t e r i c r e p u l s i o n , H-H 85 Tetrahydroquinoxaline
73
Thiamine, l e v e l s i n e p i l e p t i c s Thrombocytes, p t e r d i n e s i n Thymidylate, i n t r a c e l l u l a r 973 Thymidylate c y c l e - t r i t i u m r e l e a s e assay - in v i t r o 671
527
431 synthesis
671
Thymidylate synthase 631,639,645,655, 659,671,691,743,757,945
1031 -
autocatalytic s p l i c i n g 613 cooperativity of dlIMP binding 663 Ehrlich a s c i t e s carcinoma 663 expression, in vivo vs. in v i t r o 613 influence of pH 651 L 1210 663 l a c t o b a c i l l u s casei 659 mouse thymus 663 normal/tumour, comparison 663 p h o t o a f f i n i t y l a b e l l i n g 613 phyllogenetic comparison 613 role of 5-FdUMP phosphate hydroxyl 667 subunit composition 651 tapeworm, hymenolepsis diminiuta 651 temperature dependence 663 ternary complex with 639 T4 phage 613
Thymidylate synthase i n h i b i t i o n 659,663,667,675,989 - CB 3717 763 - 5-FdUMP 651 - mercaptoethanol 651 - methotrexate polyglutamates 763 - MTX analogs 985
Triazine glutamates, as a n t i f o l a t e s 959 Tri functional enzyme
901
1
6-(1',2 ,3'-Trihydroxybuty1) 257 Trimethoprim
671,769,823
Trimethylsilyl Trimetrexate
91 945
T r i p l e t state, of pteridine d e r i v a t i v e s 99 T r i s effect
115
Tritium release assay, for thymidylate cycle 671 tRNA function
205
tRNA guanine-transglycosylases tRNA transglycolase Tryptophan
339
185,391 Tryptophan hydroxylase - immunohistochemical s t a i n i n g 351 - monoclonal antibody 351 Tryptophan 5-monooxygenase - activation 369 - iron free 369
Thyroidectomy
- requirement of Fe^"1"
Thyroxine
Tumors
905
Tissue culture
547
Toluenesulfonylchloride tion 603 Torsion angles T 4 phage
activa-
969
757
Transcription Transfection
369
369
205,953
"Two-tier" hypothesis, regulation
215
T-lymphozyte subsets - circadian rhythm 411 - on physical exercise 411 a-Tocopherol
339
335
Thymidylate synthase reaction, model studies 687 219
pteri n
Tyrosine
Tyrosine hydroxylase 185,201,391 - cofactors for 111 - immunohistochemical s t a i n i n g 351 - monoclonal antibody 351 Tyrosine hydroxylation 377 - pteridine dependence 377 Tyrosine 3-monooxygenase
201,347
Ubiquinone 339 excretion Urinary folate
485, 489
733 925
Transport - lOE-lOdAm, lO-Me-lOdAm 855 - FMTX 861 - f o l i c acid 559,563,567 - methotrexate 855,861 - 5 1 -methyltetrahydrofolic acid 559
447
315,335
Urine, pteridines in 431 Valproate
495
Vinylogous-amide resonance Vitamin B i ?
481,713
85
1032 Vitamin B^2 d e f i c i e n c y Vitamin Bj2 l e v e l s i n 527
719 epileptics
Western b l o t , c r o s s - r e a c t i v i t y DHFR's 815 White c e l l s , p t e r i d i n e s in Xanthine o x i d a s e Xanthopterin
655
125,431
X-ray crystallography Yeast
865
431
799,839
of
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Chemistry and Biology of Pteridines Proceedings of the 5th International Symposium on Chemistry and Biology of Pteridines. Konstanz, West Germany, April 14-18,1975. Editor
W. Pfleiderer
1975.17 cm x 24 cm. XVI, 949 pages. Numerous illustrations. Hardcover. DM 190,-; approx. US $90.50 ISBN 311005928 2 The proceedings of the 5th International Symposium on "Chemistry and Biology of Pteridines" present results in pteridine research as well as some reviews of special subjects in this field. The chemical, biochemical and biological aspects of the recent investigations are discussed in detail as for example the enzymology of various important enzymes involved in the biosynthesis of pteridines in bacteria and mammalian systems, the cofactor activity of hydrogenated pteridine derivatives, the role of folate binding proteins and the transport of folate compounds into mammalian and bacterial cells. The chemistry of pteridines includes new synthetic approaches, azaanalogs, electrochemical, spectroscopical and stereochemical investigations, redox behaviour of tetrahydro forms and their rearrangements. The part of the naturally occurring pteridines consists of new components, interesting pigments, their structural elucidations, their distribution in nature as well as their potential biological activities.
Chemistry and Biology of Pteridines Pteridines and Folic Acid Derivatives Proceedings of the Seventh International Symposium on Pteridines and Folic Acid Derivatives Chemical, Biological and Clinical Aspects St. Andrews, Scotland, September 21-24,1982 Editor
J. A. Blair
1983.17 cm x 24 cm. XXXVI, 1070 pages. Numerous illustrations. Hardcover. DM 280,-; approx. US $133.30 ISBN 311008560 7 The book contains a combination of review articles prepared for the nonspecialist reader and research papers describing the most recent research work. It is regarded as a useful reference work for those whose interests lie in the fields of pteridines and folic acid biochemistry.
Prices are subject to change w i t h o u t n o t i c e
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Verlag Walter de Gruyter & Co., Genthiner Str. 13, D-1000 Berlin 30, Tel.: (030),2 6005-0, Telex 184027 Valter de Gruyter, Inc., 200Saw Mill River Road, Hawthorne, NY 10532, Tel.: (914) 747-0110, Telex 64 6677
Biochemical and Clinical Aspects of Pteridines, Volume 4 Cancer • Immunology • Metabolic Diseases Proceedings • Fourth Winter Workshop on Pteridines, February 23-March 2,1985. St. Christoph, Arlberg, Austria Editors
H. Wachter, H. Ch. Curtius, W. Pfleiderer
1985.17 cm x 24 cm. XXI, 686 pages. Numerous illustrations. Hardcover. DM 350,-; approx. US $166.70 ISBN 311010182 3 The fourth volume in this series deals with the latest developments in chemistry, biochemistry analysis, metabolism'and immunological implications of pteridines. Highlights are contributions on the electrochemistry of pteridines, on new findings regarding biosynthesis of tetrahydrobiopterin and on the close relationship between neopterin production by monocytes - macrophages and interferon-gamma. Thus, the volumes combines fundamental findings from basic sciences with new and important implications for clinical progress. Contents (Main Chapters) Chemistry and Analysis of Pteridines • Biochemistry and Metabolism of Pteridines • Tetrahydrobiopterin Deficiencies, Diagnosis and Therapy • Pteridines in Immunology • Pteridines in Cancer and other Diseases • Miscellaneous • Author Index • Subject Index. Also
available
Biochemical and Clinical Aspects of Pteridines, Vol. 1 Editors
H. Wachter, H. Ch. Curtius, W. Pfleiderer
1982. XV, 373 pages. DM 150,-; approx. US $71.50
ISBN 311008984 X
Biochemical and Clinical Aspects of Pteridines, Vol. 2 Editors
H. Ch. Curtius, W. Pfleiderer, H. Wachter
1983. XV, 435 pages. DM 190,-; approx. US $90.50 ISBN 311009813 X
Biochemical and Clinical Aspects of Pteridines, Vol. 3 Editors
W. Pfleiderer, H. Wachter, H. Ch. Curtius
1984. XII, 514 pages. DM 220,-; approx. US $104.80 ISBN 311010163 7 Prices are subject to change without notice
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\fertag Walter de Gruyter & Co., Genthiner Str. 13, D-1000 Berlin 30, Tel.: ( 0 3 0 ) , 2 6 0 0 5 0 , Telex 1 8 4 0 2 7 Walter de Gruyter, Inc., 200Saw Mill River Road, Hawthorne, N.Y. 10532, Tel.: (914) 747-0110, Telex 64 6677