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Unconjugated Pterins and Related Biogenic Amines
Unconjugated Pterins and Related Biogenic Amines Proceedings of the First International Workshop Flims, Switzerland February 28-March 7,1987 Editors Η-Ch. Curtius · N. Blau · R. A. Levine
W DE
G Walter de Gruyter · Berlin · New York 1987
Editors Prof. Dr. Hans-Christoph Curtius Dr. Nenad Blau Division of Clinical Chemistry Dept. of Pediatrics University of Zurich Steinwiesstr. 75 CH-8032 Zurich Switzerland Dr. Robert A. Levine Laboratory of Molecular Neurobiology Lafayette Clinic 951 East Lafayette Street Detroit, MI 48207 U.S.A.
Library of Congress Cataloging in Publication Data
Workshop on Unconjugated Pterins and Related Biogenic Amines (1st: 1987 : Flims, Switzerland) Unconjugated Pterins and related biogenic amines. Bibliography: ρ Includes index. 1. Pteridines-Metabolism-Congresses. 2. Biogenic amines-Metabolism-Congresses. 3. Metabolic conjugation-Congresses. I. Curtius, H. Ch. Hans-Christoph) II. Blau, Ν. (Nenad), 1946- . QP801.P69W67 1987 612'.01575 87-22341 ISBN 0-89925-368-7 (U.S.)
CIP-Kurztitelaufnahme der Deutschen Bibliothek
Unconjugated pterins and related biogenic amines : proceedings of the internat. workshop, Flims, Switzerland, February 28 - March 7,1987 / ed. H.-Ch. Curtius ; N. Blau. - Berlin ; New York : de Gruyter, 1987. ISBN 3-11-011341-4 NE: Curtius, Hans-Christoph [Hrsg.]
Copyright © 1987 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 GmbH, Berlin. Binding: Dieter Mikolai, Berlin. - Printed in Germany.
Dedicated to the Memory of Alois Niederwieser
PREFACE
This volume contains the proceedings of the First Workshop on Unconjugated Pterins
and
Related
Biogenic
Amines,
February 28 to March 7, 1987.
held
in
Flims,
Switzerland,
from
Contributors from all over the world re-
ported on the latest developments in the field of pteridines and biogenic amines.
The workshop brought together pteridine researchers in the fields of chemistry, biochemistry, immunology, pediatrics, and internal medicine from 10 countries; there were 61 participants and 38 papers were presented. Biochemical, main the
analytical,
immunological,
and
themes discussed, but we also heard fields
pteridines.
of
biogenic
amines,
pediatric
problems
were
interesting contributions
chemistry,
and medical
from
applications
of
Each topic was introduced by a plenary lecture.
On February 5, 1987 our colleague and friend, Alois Niederwieser, away
the
after a long
illness.
We dedicate
the proceedings
passed
to him for his
important and lasting contributions in the field of pteridines. Finally we wish to express our gratitude other
participants
who
helped
to
make
to the speakers, chairmen, and the
workshop
a
success;
to
the
authors and all those who helped directly or indirectly with the production of this volume; to M. Killen and M. Stucki for excellent secretarial assistance; to the sponsors, listed separately, for their financial
sup-
port, which made publication of the proceedings possible; and to Walter de Gruyter & Co., for their professional assistance with publication.
H.-Ch. Curtius N. Blau R.A. Levine
ACKNOWLEDGEMENTS We gratefully acknowledge contributions from the following sponsors: Almedica AG, Gal mi ζ, CH ßrechbühler AG, Schlieren, CH Burkard Instrumente AG, Zurich, CH Ciba-Geigy AG, Basel, CH Digitana AG, Horgen, CH Henning Berlin GmbH, Berlin, FRG Hewlett Packard (Schweiz) AG, Widen, CH LKB Instrument AG, Littau, CH Nestle Produkte AG, Zurich, CH Spectronex AG, Basel, CH Technicon Schweiz, Zurich, CH VG Instruments GmbH, Wiesbaden, FRG Milupa AG, Friedrichsdorf, FRG
CONTENTS
In Memorlam: Alois Niederwieser (1935 - 1987) H.-Ch. Curtius
1
SECTION A: CHEMISTRY AND ANALYSIS OF PTERINS Homogeneous Catalytic Hydrogenation of L-Biopterin: Influence of the Ch1ra11ty of the Side Chain and the Catalyst on its Diastereoselective Induction S. Antoulas, M. Viscontini
7
Synthesis of D-Neopterin-3'-Phosphates B. Zagalak, F. Neuheiser, R. Bosshard, U. Redweik
13
5-A1 kyl-5,6,7,8-Tetrahydrobiopteri ns A. Kaiser
23
Mass Spectroraetric Investigations of Pteridines Th. Küster, A. Niederwieser
31
The Structural Characterization of 6-Pyruvoyl Tetrahydropterin by Fast Atom Bombardment Mass Spectrometry with One- and TwoDimensional Mass Analysis (FAB/MS and FAB/MSMS) W.J. Richter, F. Raschdorf, R. Dahinden, Th. Küster, A. Niederwieser, W. Leimbacher, H.-Ch. Curtius
39
χ
SECTION Β: BIOCHEMISTRY AND METABOLISM OF PTERINS
Tetrahydrobiopterin: Other Physiological Roles in Addition to Aromatic Amino Acid Hydroxylation? S. Milstien
49
iH-NMR Studies with Tetrahydrobiopterins, Evidence for the Structure of 6-Pyruvoyl Tetrahydropterin, an Intermediate in the Biosynthesis of Tetrahydrobiopterin S. Ghisla, P. Steinerstauch, Th. Hasler, N. Blau, H.-Ch. Curtius ..
67
Purification of 6-Pyruvoyl Tetrahydropterin Synthase from Salmon Liver Th. Hasler, A. Niederwieser, H.-Ch. Curtius
81
Purification of 6-Pyruvoyl Tetrahydropterin 2'-Keto Reductase from Human Liver H.-Ch. Curtius, P. Steinerstauch, W. Leimbacher, U. Redweik, Sh.-I. Takikawa, S. Ghisla Human GTP Cyclohydrolase I: Monoclonal Antibodies
89
Purification and Preparation of
G. Schoedon, A. Niederwieser, H.-Ch. Curtius
99
Dihydromonapterin Triphosphate: Occurrence, Analysis, and Effect on Tetrahydrobiopterin Biosynthesis in vivo and in vitro N. Blau, P. Steinerstauch, U. Redweik, K. Pfister, G. Schoedon, L. Kierat, A. Niederwieser
105
Biosynthesis of Pteridines and Deaza Flavins in Methanogenic Bacteria B. Schwarzkopf, Q. Le Van, W. Eisenreich, P.J. Keller, H.G. Floss, A. Bacher
117
Tetrahydrobiopterin Biosynthesis and Pteridine Metabolism in Cells of the Blood System, Lymphoid Tissues and in Biological Fluids B. Andondonskaja-Renz, H.-J. Zeitler
125
XI Modified Pteridine Synthesis in Transformed Cell Lines and during Heat Shock J. Seidl, M. Przybylski, Ch. Meinschad, I. Ziegler
137
SECTION C: PTERINS IN IMMUNOLOGY Disease Associated Alterations of Pterin Biosynthesis: Enhancement in Inflammatory Disease, Hemopoietic Regeneration and Endotoxinemla Ch. Huber, M. Herold, J. Troppmair, H. Rokos
149
Metabolism of Pterins in the Cellular Immune System of Man and Mouse G. Schoedon, A. Niederwieser, H.-Ch. Curtius, A. Fontana, J. Troppmair, Ch. Huber
161
Tetrahydrobiopterin Synthesis is Triggered by Interleukin 2 Binding and Modulates Receptor Affinity I. Ziegler
169
Kinetics of Production and Release of Neopterin. Comparison of Human PBMC with the Permanent Monocytic Cell Line U937 and its Subclones K. Rokos, R.O.F. Kunze, Μ.A. Koch, H. Rokos, K. Nilsson
177
SECTION D: PTERINS IN DIFFERENT DISEASES
Variations of Neopterin, Dihydroneopterin and Immunological Parameters during Physical Exercise (Jogging) H. Rokos, K. Rokos, R.O.F. Kunze
187
XII
Biopterin and Neopterln In Plasma and Lympho-Mononuclear Biopterin 1n Graft versus Host Disease and Infection after Bone Marrow Transplantation M. Fink, V. Nüssler, Κ. Demtröder, Ε. Höniges, H.J. Kolb, I. Ziegler
197
Effects of Pirenzepine, Aciclovir and Trimethoprim on Pterins in Blood Cells and Plasma M. Fink, V. Nüssler, Κ. Demtröder, Ε. Höniges, Μ. Goldberg
SECTION Ε: TETRAHYDROBIOPTERIN
207
DEFICIENCIES
Heterogeneity of Tetrahydrobiopterin Deficiency J.-L. Dhondt
219
Prenatal Diagnosis of Tetrahydrobiopterin Deficiency N. Blau, A. Niederwieser, H.-Ch. Curtius, W. Leimbacher, L. Kierat, A. Matasovic, W. Staudenmann, I. Ozalp
237
Sepiapterin Reductase in Human Amniocytes, Skin Fibroblasts, Chorionic Villi and Stimulated Mononuclear Blood Cells J. Ferre, E.W. Naylor
247
Impaired Biopterin Synthesis in a Patient with Mild Hyperphenylalaninemia. A New Variant? J.L. Dhondt, G. Forzy, J.M. Hayte, P. Guibaud, M.O. Rolland, C. Dorche, S. Andre
257
Dihydropteridine Reductase Activity in Fetal Tissues G. Bracco, A. Iavarone, S. Pagliardini, F. Levis, 0. Guardamagna, S. Ferraris, A. Ponzone
265
Molecular Analysis of Human Dihydropteridine Reductase and Dihydropteridine Reductase Deficiency R.G.H. Cotton, W.M. Hutchison, S. Wake, I.G. Jennings, W.J. McAdam, D.M. Danks, Η.-Η.Μ. Dahl
275
XIII Fate of Peripherally Administered Tetrahydrobiopterln 1n Congenital Tetrahydroblopterin Deficiency S. Ferraris, 0. Guardamagna, G. Borietti, G. Bracco, L. Leone, A. Ponzone, A. Niederwieser
283
6-Pyruvoyl-Tetrahydropter1n Synthase Deficiency: Therapeutic Trial with Two Different Synthetic Pterin Analogues in Three Patients D. Leupold, H. Lehmann, H.-Ch. Curtius, A. Niederwieser
293
Placental Barrier in Mother-to-Fetus Transfer of Tetrahydrobiopterin in Humans A. Ponzone, S. Ferraris, S. Biasetti, I. Dianzani, 0. Guardamagna, L. Kierat, A. Niederwieser
303
SECTION F: MONOAMINE NEUROTRANSMITTERS AND ENZYMES Therapeutic Potential of Tetrahydrobiopterin Therapy in Neurological and Psychiatric Illness R.A. Levine
315
Organization of the Catalytic and Regulatory Sites of Rat Liver Phenylalanine Hydroxylase M. Parniak
327
Immunochemical Studies of Phenylalanine Hydroxylase R.G.H. Cotton, I.G. Jennings, W. McAdam, S. Smith
339
Influence of Substrates and Cofactors on Tyrosine Hydroxylase D. Kuhn
343
Mechanism of Activation of Tryptophan 5-Monooxygenase by Mercaptides H. Hasegawa, A. Ichiyama
353
XIV
Effects of Tetrahydropterins on DOPA Production in v i t r o and in vivo M. Bräutigam, W. P f l e i d e r e r Pterins and Monoamine Metabolites in Cerebrospinal
359 Fluid
J . L . Dhondt, G. F o r z y , J.M. Hayte, J . P . F a r r i a u x , C. L a r g i l l i e r e
..
367
AUTHOR INDEX
375
SUBJECT INDEX
379
L I S T OF PARTICIPANTS
393
In Memoriam ALOIS NIEDERWIESER 1935 - 1987
On February 5, 1987 Professor Alois Niederwieser died after a long illness at the age of 52.
We mourn the loss of an outstanding scientist of world
renown, a dear colleague and friend, who shaped to a considerable extent international research in the field of inborn errors of metabolism.
Alois Niederwieser was not only my coworker, he also was a close
friend
for many years and we had been colleagues at the university, thus experiencing a quality of friendship which is not often found in the course of a 1ifetime.
2 Niederwieser came from a practicing catholic family in Laupheim/WLirttemberg and had originally planned to become a priest.
But the life sciences
had caught his interest early and one year before entering university he decided to study chemistry. After two semesters at the University of Tübingen, Niederwieser continued his studies at the renowned Organic Chemistry
Institute of Nobel
prize
winner Tadeus Reichstein in Basle and did his Ph.D. with Max Brenner on thin-layer chromatography of peptides and amino acids. first met Niederwieser.
That is where I
The years of post war reconstruction in Europe
were happy and positive years for all of us. At that time Niederwieser suggested to our future friend, Max Brenner, to separate peptides and amino acids with the help of thin-layer chromatography.
In order to appreciate this proposal one must remember that in
those days chromatography was still in its infancy:
Egon Stahl had just
held a lecture at Roche Company on the separation of pigments by thinlayer chromatography. Organic Chemistry
W.H. Stein, from the USA, had held a lecture at the
Institute on the separation of amino acids by ion ex-
change chromatography, and Max Brenner with his coworker, Rolf Weber, had constructed the first amino acid analyzer in Switzerland according to the specifications by Stein and S. Moore. The first pioneering work on the separation of amino acids and peptides by thin-layer Pataki.
chromatography
was
by
Niederwieser,
Brenner,
and
Four books by Niederwieser and G. Pataki were published, followed
by a number of publications. wieser
published
chamber"
was
Among other inventions the "Brenner-Nieder-
developed which was
still
available
on
the market
until recently. After successfully completing his dissertation, Niederwieser first started work as scientific assistant in the research laboratory of the Neurology Department at the University of Basle.
In 1965 he moved to the University
of Düsseldorf where he worked as research assistant until those years we did not see much of each other. wieser again at the Analytica meeting
1968.
During
By accident I met Nieder-
in Munich and
I aaked him if he
3 would like to join me at the University of Zurich Children's
Hospital.
At that time the new laboratory wing was being completed and we had just started
with
gas
chromatography.
Soon
after
the
Analytica
meeting,
Niederwieser wrote that he would very much like to come to Zurich. In Zurich began.
the most
important 18 years of his fruitful
scientific
work
He published more than 130 papers and was invited to hold more
than 60 lectures which underlined his worldwide reputation as scientist. He discovered and characterized six inborn errors of metabolism, such as ß-mercaptopyruvate
sulfur
transferase
deficiency,
transferase deficiency, 4-hydroxyphenyl
isolated
pyruvate dioxygenase
formimino deficiency,
amino peptidase deficiency, and two enzyme defects of the tetrahydrobiopterin biosynthesis.
In addition, he isolated and elucidated drug metabo-
lites and artefacts of food technology, did analytic pioneering work, such as the separation of peptides as copper complexes, the selective isolation of peptides from biological material by chemical
transformation to poly-
ami no alcohols, GC-MS of oligopeptides in urine, quantitation of mercapturic
acid by mass
fragmentography, measurement of pterins
in urine
by
GC-MS and HPLC, and much more. In the last few years most of his energy was devoted to the pterins. elucidated
two
inborn errors of metabolism, i.e., GTP cyclohydrolase I
deficiency and 6-pyruvoyl tetrahydropterin synthase deficiency. oped a treatment for tetrahydrobiopterin deficiency using pterin
and
He
neurotransmitter
precursors.
From Zurich
He devel-
tetrahydrobio-
he conducted
the
screening for atypical phenylketonuria in many central European countries and overseas. prenatal
Just a short while ago it became possible to perform the
diagnosis of a 6-pyruvoyl
tetrahydropteriη
synthase deficiency.
In the case of an Italian mother who had already given birth to a 6-pyruvoyl
tetrahydropterin
synthase deficient child, Niederwieser performed a
prenatal diagnosis during her second pregnancy which showed normal enzyme activity.
A
healthy
girl
was
born
whom
the
grateful
parents
named
Aloisia, after Alois Niederwieser.
Niederwieser played an important part in the characterization of the most important steps in the tetrahydrobiopterin
biosynthesis.
Recently, to-
4
gether with Wolf Endres pheral
in Munich he proposed that the so-called peri-
defects of 6-pyruvoyl
tetrahydropterin synthase deficiency are to
be found in patients with remaining activity and in heterozygotes. A number of
projects
remain
to be completed.
Niederwieser's
enormous
knowledge and his lucid mind would have facilitated the solving of many more problems. In June of 1986, already marked participated
by
in the 8th International
Acid Derivatives in Montreal.
his terminal
illness,
Niederwieser
Symposium on Pteridines and Folic
As you may have heard, he and I were at
that time nominated to organizethe 9th Symposium in Zurich in 1989. His pioneering work brought him a number of honors. from various
parts of
Many guest scientists
the world visited us in Zurich and
always maintained a warm relationship with them.
Niederwieser
Representative for many
other colleagues in various parts of the world, I would just like to mention the following names: Levine,
Emilio
Oradi,
Martin Gal, Paolo Giliberti, Judy Hammond, Bob Alberto
Pignero,
Haruo
Shintaku,
Shin-Ichiro
Takikawa, Patricia Tippett, and Wang Muti. Niederwieser worked up to the last moment, manuscripts and a book were on his deathbed.
Shortly before he died on February 5 at one o'clock in the
afternoon, he had given instructions to his coworker, Ana Matasovic.
He
died the way he had lived. The
University
of
Zurich
and
the
Children's
Hospital,
pediatricians
throughout the world, and his colleagues have lost a dedicated scientist and a dear friend.
H.-Ch. Curtius
SECTION A: CHEMISTRY AND ANALYSIS OF PTERINS
HOMOGENEOUS CATALYTIC HYDROGENATION OF L-BIOPTERIN: INFLUENCE OF THE CHIRALITY OF THE SIDE CHAIN AND THE CATALYST ON ITS DIASTEREOSELECTIVE INDUCTION
S. Antoulas, M. Viscontini Organisch-chemisches Institut der Universität, Winterthurerstr. 190, CH-8057 Zürich, Schweiz
Introduction Heterogeneous catalytic hydrogenation of L-biopterin (I) under acidic conditions yields a mixture of diastereomers βα-ΐΐ"^ and 60-III in a ratio of approximatively 1/2 [3]. In order to improve this ratio in favour of the 6β-ΙΙΙ isomer (natural form, clinically employed for the treatment of atypical PKU [4]), we tried to hydrogenate the triacetylated derivative IV [5 ] of L-biopterin in presence ot the "Wilkinson catalyst" IX[6].
Η Η I I C-C-CH3 Hzl 1,1 1
0 II
, R2
Η Η ιI
+
OR OR
hAANA l·
CO-CH, = CO-CH,
III : R1 = R2 = Η 1 = CO-CHj ; 2 VI : R R = 1 =2 VIII : R R = CO-CH,
The terms β and α are used according the I UP AC rules for the nomenclature of steroids as propoCI IX, Ph
sed by one of us (M.V.)[1 ] [2 ] .
: Triphenylphosphine
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
8 Even under drastic conditions (60°, 50 At.) no hydrogenation was observed and the substrate could not be recovered from the reaction mixture. On the contrary, the McQuillin catalyst (X)[7] proved to be very efficient. We postulate for this in situ generated catalyst, the following three structures: χ, XI, XII.
ryr-
r
BH4
Vr
Rh r
DMF-
BH4 X
-BH 4
»r
Rh
Rh DMF -
r
CI
DMF-
yr
CI
XI
r
XII
yr
c
·
DMF = Dimethylf ormamide, Pyr = Pyridine, BH^ = Sodium borohydride X and XI are enantiomeric to each other, whereas the third strucsture XII represents a "meso"-form, with a plane of symmetry.
XIV
a=
DMF
b =
EPF*
R VI
1
=
CO-CH
Η
XIII R
3
=
C 1
C 1
1
CH3 1
OR
AC20
Pyr
r VIII
3
Η
OR1 AC2O
XV
Scheme 1
VII
ν
9 We assume that each of the three postulated structures forms a complex with the substrate IV to yield the achiral 7,8-dihydroderivative XIII, which undergoes a second complexation with each of the three structures of the catalyst. In scheme 1 we consider only the second complexation of XIII with the chiral catalyst XI. Depending on wether this new complex formation occurs on the Re(XV) or the Si-side (XIV) of the prochiral C(6) center, hydrogen addition finally gives rise to 60-triacetyl-5,6,7,8-tetrahydro-L-biopterin
(V) and
6a-triacetyl-5,6,7,8.-tetrahydro-L-
biopterin(VI) respectively, which then were converted to the corresponding pentaacetylated derivatives VII and VIII [8]. The approximative 6α/6β ratio was determinated by "^C-NMR spectroscopy, because the spectrum and the absolute configuration of VIII are well known [8]. By comparing the relative intensities of the C(2), C(4) and C(8a) -CO-(CH )
signals, we found that a ratio of ca 1/1 was obtained with McQuillin's catalyst (Figure 1) . C(8a)
In order to get an effective asymmetric induction,
C (4 )
we modified the McQuillin C (2)
α β
catalyst by replacing dime-
βία α 0
ty If ormamide (DMF) with a chiral amide, lR-l-phenyl-
tyVW 13 Figure 1. C-NMR Spectrum of the mixture 6a- 4 6ß-pentaacetyl-tetrahydro-L-biop^^i π i n r n -^n-rn
ethylamino-formamide
(XVIa )
[9] (Figure 2 and 3). The inverse ratio nhfai nod
figure 4. H
C,H.
Figure 2. XVIb = lS-EPF*;(XVIa = 1R-)
With the described experiments we have tried to
10
demonstrate the importance of homogeneous catalysis for the asymmetric hydrogenation of L-biopterin. In order to improve the diastereoselectiv excess -CCMCH )
of the natural 6ß-tetrahydoL-biopterin, other more efficient chirality inducing asymmetric ligands should be developed.
13, Figure 3. Part of the C-NMR spectrum of the mixture VII + VIII after hydrogenation with XVIa (in CD-SO-CD.).
Experimental Part
McQuilling catalyst. According to [7 ] . 1R- and lS-Phenylethylamino-
-CO-(CH 3 )
formamide. According to [9]. Homogeneous Hydrogenation. A solution of lg (2,37 mmol) 2-N-acetyl-l',2'-O-diacetylL-biopterin (IV) in 50 ml CH 3 0H was added to 50 ml C( 8a) CH 3 0H containing 200 mg of in situ generated McQuillin catalyst, and reduced under H^ C(4)
for 3 hours (stirring). The c( 2:
ß
ß p.
reaction mixture was evaporated to dryness and 1,5 ml 12N HCl was added to the residue. The obtained concentred mixture was taken up
13 Figure 4. Part of the C-NMR spectrum of the mixture VII + VIII after hydrogenation with XVIb (in CD 3 SO-CH 3 ) .
in 10-20 ml water and the Rh-complex was extracted twice with 80 ml chloroform.
11
The aqueous phase was evaporated in vacuo and the remaining hydrochlorid was peracetylated under the conditions described in [8]. The crude product was then examinated by "^C-NMR spectroscopy in order to estimate its diastereomeric composition (cf. figures 1,3,4).
References
1.
Ganguly, S.N., Viscontini, M. 1978. Helv. Chim. Acta 61,166.
2.
Antoulas, S., M. Viscontini. 1986. In:Chemistry and Biology of Pteridines (B.A. Cooper, V.M. Whitehead eds.). Walter de Gruyter & Co. Berlin, New York, p. 95.
3.
Schircks, B., J.H. Bieri, M. Viscontini. 1978. Helv. Chim. Acta 61, 2731; S.W. Bailey, J.E. Ayling. 1978. J. Biol. Chem. 253, 1598.
4.
Schaub, J. S. Dämling, H.-Ch. Curtius, A. Niederwieser, K. Bartholome, Μ. Viscontini, Β. Schircks, J.H. Bieri. 1978. Arch, of Diseases in Child. 53, 674; H.-Ch. Curtius, A. Niederwieser, A. Otten, J. Schaub, M. Viscontini, S. Scheibenreiter, Η. Schmidt. 1979. Clin. Chim. Acta 93^ 251.
5.
Furrer, H.J., J.H. Bieri, M. Viscontini. 1979, Helv. Chim. Acta 62_, 2577 .
6.
Osborn, J.Α., F.Η. Jardine, J.F. Young, G. Wilkinson. 1966. J. Chem. Soc.(A) p. 1711.
7.
Love, C.J., F.G. McQuillin. 1973. J. Chem. Soc. Perkins Trans, p. 2509.
8.
Ganguly, S.N., M. Viscontini. 1982. Helv. Chim. Acta 65, 1090; R. Prewo, J.H. Bieri, S.N. Ganguly, M. Viscontini. 1982 . Helv. Chim. Acta 6J5, 1094 .
9.
Kraus, Μ.A. 1973. Synthesis, p. 361.
SYNTHESIS OF D-NEOPTERIN-3"-PHOSPHATES
B. Zagalak, F. Neuheiser, R. Bosshard and U. Redweik University of Zurich, Department of Pediatrics, Division of Clinical Chemistry, Steinwiesstrasse 75, CH-8032 Zurich, Switzerland
Introduction
Recent research in the field of pterins has been focused on the biosynthesis of
(6R)-tetrahydrobiopterin
phosphate
(7,8-H2-3'-NTP).
(BH4)
from
D-7,8-dihydroneopterin-3'-tri-
Obviously, this investigation requires a suit-
able method for the preparation of pure 7.8-H2-3'-NTP.
Enzymatic prepara-
tions of 7,8-H2-3'-NTP obtained from GTP and GTP-cyclohydrolase pure and contain always free GTP and
I are not
7,8-dihydromonapterin-3'-triphosphate
(7,8-H2"MTP) and therefore they cannot be used in a precise
spectroscopic
or enzymatic study.
We have earlier
reported that D-neopterin can be directly
phosphorylated
1
with POCI3 and that D-neopterin-3'-monophosphate
(3 -NMP) was formed
The 3'-NMP was further phosphoryl ated to 3'-NTP.
Unfortunately, we obser-
ved
that a cyclisation
of D-neopterin-3'-monophosphoimidazol idate
(1).
with
a
1
hydroxyl group of the chain takes place after the activation step of 3 -NMP with 1,1 1 -carbonyldiimidazole. low yield
of 3'-NTP.
The
Naturally, this cyclisation causes a very
obtained
3 1 -NTP after catalytic
reduction
to
7,8-H2"NTP was active in the enzymatic synthesis of BH4 (1). Recently we improved the chemical
synthesis of 3'-NMP and 3'-NTP and this
is the subject of this communication.
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
14
Results D-neopterin-3'-monophosphate We found in the course of our further phosphorylation study that preparations of 3'-NMP obtained from direct POCI3 phosphorylation of D-neopterin in tri ethyl phosphate contained up to 15% of unknown D-neopterin monophosphate. This was shown by performing an analytical HPLC on a RP-8 column, using 30 mM Et3N:H3PC>4 buffer, pH 7.0.
The mixture of monophosphates was chromato-
graphically unresolvable at the preparative scale when ion exchangers were used, therefore we gave up this method of phosphorylation of D-neopterin. Recent improvements in the regiospecific synthesis of C-6 substituted pterins and easy
synthesis
of D-ribose-5-monophosphate
gave
us the
idea to
synthesize D-neopterin phosphates via condensation according to the method by Viscontini et al. (2).:
H-C = 0
Η
Η
OH
Η
OH + H 2 N - N - ^
Η
H
OH
-
Η
^ 1 ~C= Ν— Ν
ϊ IV I
+
Η,
R
R
Ο
Ο
Η
,
Η2- C - Ν- Η - P
Η - 4 — O H
CH2OH
Fig. 1
—Φ
Η
C-6-Regiospecific condensation of phenylhydrazones of sugars with 4-hydroxy-2,5,6-triaminopyrimidine.
15 In order to know the pH range of the condensation reactions we began our investigation
with
precise
determination
2,5,6-triaminopyrimidine-2HCl·Η2θ following
pK a
constants:
(7)
and (Τ) 4-OH pK a = 10.076.
(HTAP) 5-NH2
of (Fig.
pK a
pK a
values
2).
= 5.214, ( ? )
We
of
4-hydroxy-
determined N-l
pK a
=
the 1.667
According to Traub & Pfleiderer (3) the pK a
constants of 1, 2 and 3 should be positioned at N-5, N-l and 4-OH respectively.
Fig. 2
Determination of pK a values of 4-hydroxy-2,5,6-triaminopyrimidine-2HCl Ή 2 Ο (2.146mg) using KNO3 (46.6mg) as a standard.
Synthesis de novo via condensation: Adenosine 5'-monophosphate was hydrolyzed with Dowex 50-H + (4) to D-ribose-5-monophosphate which was immediately reacted with Phenylhydrazine at pH 6.2.
Phenylhydrazone of D-ribose-5-
monophosphate was isolated as a barium salt which was further with HTAP in Me0H:H20 (1:1, reflux, 60').
Finally the crude reaction mix-
ture was oxidized with hydrogen peroxide and purified on ion (see
Fig.
10-17%,
3).
The
overall
yield
of
condensed
3'-NMP
tri ethyl ammonium
exchangers salt
was
however according to the HPLC analysis the yield of the condensa-
tion reaction was at least 25-35% (HPLC-assay after the I2:HCl oxidation). Since the triethylammonium
salt is unstable, the end product can be con-
16 Η Η—C = Ο Η·
ΟΗ
Η
ΟΗ
Η
Η—C = Ν - Ν 1.
0 - Ν Η - Ν Η 2 ; lh, RT; pH 6.2
2.
Ba(Ac)2
ΟΗ
Η•
ΟΗ
Η•
ΟΗ
Η
ΟΗ
CH2OPO3H
CH20P03Ba
H s N v ^ A ^ H || Ι *2 H C l η , Ν ^ ν ^ Ν
+
lh, 70°C pH 2.5
Οχ. 1. Lewatit SP 1080 Η+ 2. DEAE-Sephadex; Gradient
OH Η
Fig. 3
2'
Η I ,3' Ο Η
OH — U o I OH
10% yield
Synthesis of D-Neopterin-3'-monophosphate via condensation. (Gradient: Li CI , 0.05-0.4M, pH 7.4 or Et 3 N:H2C03, 0.05-1M, pH 7.6)
17
verted to a stable sodium s a l t by treatment of i t s methanolic solution with an excess of Nal in acetone. this
synthesis
gave
The KMn04 oxidation of 3'-NMP obtained from
pterin-6-carboxylate.
also confirmed by spectroscopic
Structure of
this
31-NMP was
(H-NMR, IR, UV, see F i g . 4) and chromato-
graphic methods. Partial
reduction of t h i s 3'NMP (H2~Pd or sodium hyposulfite) gave 7 , 8 - d i -
hydro-3'-NMP which was identical with enzymatic one obtained from GTP (GTPcyclohydrolase and a l e . phosphatase).
Fig. 4
UV-spectrum of 3'-NMP Na-salt obtained from the condensation.
Synthesis of D-neopterin-3'-triphosphate. a) Enzymatic approach (see F i g s . 5,6):
Guanosine-5'-monophosphate
kinase
(EC 2.7.4.8) catalyses the phosphorylation of GMP using GTP as a phosphate substrate in t h i s system.
The produced GDP i s further phosphory-
lated to GTP in the presence of phosphoenolpyruvate kinase and phosphoenolpyruvate ( 5 ) .
Unfortunately, in our hands t h i s system did not work
when we used 3'-NMP.
Neither did we observe phosphorylation of 3'-NMP
1
to 3'-NDP or 3 -NTP using a similar system with nucleoside-monophosphate kinase (EC 2.7.4.4)
(6).
18
ATP
:
Nucleoside-Monophosphate-Phosphotransferase Ρ
PEP Nucleoside^
Nucleoside^
Nucleoside-Pi ADP
Pyruvate
Nucleoside-Pj-Kinase EC
PEP-Kinase
2.7.4.4
EC 2.7.1.40 (or Nucleoside-5'-P2-Kinase + ATP) 3'-NMP
Fig. 5
(pH 7.4; 37°C)
3'-NDP
Nucleoside-moriophosphate-kinase (EC
ATP
:
2.7.4.4).
(pH 7.4; M g + + ; 37°C)
GMP-Phosphotransferase
PEP GDP
GMP
GTP
ADP
Pyruvate
GHP-Kinase
PEP-Kinase
EC
EC
2.7.4.8 3'-NMP
Fig. 6
-X
Guanosine-5 1 -monophosphate-kinase (EC
2.7.1.40 — 3'NDP
2.7.4.8).
b) Synthesis de novo via the condensation of HTAP with
phenylhydrazone
of D-ribose-5-triphosphate: D-ribose-5-monophosphate monotriethyl ammonium salt was
activated with
phosphorylated
with
l.l'-carbonyldiimidazol
pyrophosphate
(7,8) and
mono-n-tributyl ammonium
yield of D-ribose-5-triphosphate was 60%.
further
salt.
The
This triphosphate was conver-
ted to the phenylhydrazone and further condensed with HTAP. Unfortunately, no 3'-NTP formation was observed (see Fig. 7).
19
H-C = 0 Η — C Η •
O H
Η
O H
Η
O H
H4P20yBU3N
Ο
CH«OP-O 2 I
=0
Η
O H
Η
O H
Η
O H
e
CH2O0
ΟΝ
60% yield
0-NH-NH 2
Ψ H - C = N-N-/0/ Η
O H
Η
O H
Η
OH
NO
CH 2 O(^P 3
g. 7
c)
H
2
N s /
, H
jl j n
TRACE
internal
of protective
groups
MTP
x 2 HCl
Condensation of 4-hydroxy-2,5,6-triaminopyrimidine phenylhydrazone of D-ribose-5-triphosphat.
Inserting
OF
into 3'-NMP:
cyclisation of 3'-NMP-imidazolidate
In order to avoid the
during the
with pyrophosphate, we tried to insert several
with
phosphorylation
O-protective groups into
the chain of 3'-NMP. The
1'-2'-ketalisation
samples
were
refluxed
of
the
3'-NMP
proceeds
with 3 equivalents
with
a good yield
of p-toluenesulfonic
when
acid
in
2,2-dimethoxypropane.
The
1 1 ,2 1 -ethoxyethylether
of 3'-NMP was prepared at 0°-10°C using
vi-
20 nylethyl ether (excess) and 3 equivalents p-tol uenesulfonic acid.
Since
the cleavage of this derivative proceeds relatively fast at pH 4.0 it could be used for the synthesis of 3'-NTP.
On the other hand, we found
the derivatisation procedure (8) to be irreproducible. We have found that 3'-NMP can easily be esterified with 100% formic acid and the produced mono- and diesters can be cleaved under very mild conditions
(pH 8.5-9.0, R.T., 2 h).
This gave us the chance of further
1
phosphorylation of 3'-NMP to 3 -NTP avoiding the cyclisation of 3'-NMPimidazol idate. d) Chemical phosphorylation of 3'-NMP formates to 3'-NTP: is summarized in Fig. 8.
This synthesis
The overall yield of 3'-NTP sodium salt was
10-18%. Preparation of 7,8-dihydro-D-neopterin-3'-triphosphate lithium salt. According
to our experience 7,8-H2~NTP can be easily prepared from much
more stable 3 1 -NTP by partial H2:PdO catalytic reduction at pH 7.0 or using sodium hyposulfite as a reduci ng reagent at pH 6.8. reduction was
terminated
reached 4:1.
The reaction mixture was purified on a DEAE-Sephacel
(9) (see Fig. 9). of
when
In both causes the
the ratio of 7,8-H2-derivatives
to 3'-NTP column
The yield of this step depends on the aerobic conditions
the chromatographic
purification
procedure
and may end up as low as
7,8-^-3'-NTP
preparations was identical
approximate!ly 12%.
The
structure
of both
and con-
firmed by HPLC (RP-8, Et3N:H3P04, pH 7.0 buffer), UV spectrum and kinetics of phosphate release by alcaline phosphatase, when compared with an enzymatically
prepared 7.8-H2-NTP.
Also both preparations obtained by cata-
lytic or hyposulfite reductions were fully active in two different enzymatic systems: the synthesis of BH4 and in the epimerisation of 7,8-H2-3'-NTP to 7,8-H2-3'-MTP.
21
R = Pterin OH
R
•i 1
Η
OH
Η
OH
! 1 Η
f- Ο — l· Η
Ρ = Ο OH
1) HCOOH (100%, RT, 7d) 2) Et3N
c=o i Ο
R
i
c=o Ο
1
1
Η
Η
© ® 0 Et3NH
Η f— 0 Η
OH
1) 2) 3) 4) D-NE0PTERIN-3'-TRIPHOSPHATE·^
Fig. 8
? = 0
60% diester 30% monoesters 10% 3--NMP
H4P20yßU3N, 24h, RT, DMF NaHCOß, H20, 2h, RT DEAE-Sephadex, pH 7.6, gradient NaJ in MeOH/Acetone (10% yield)
One-pot synthesis of D - n e o p t e r i n - 3 ' - t n ' p h o s p h a t .
22
7 , 8 - H z N T P (enzy.)
Fig. 9
Purification of 7.8-H2-NTP on DEAE-Sephacel (1.6 χ 25cm, 0.2M LiCl, flow llml/h, +4°C).
References 1. Zagalak et al. 1985. In: Biochemical & Clinical Aspects of pteridines Vol. 4, (Wächter et al. eds.). W. de Gruyter, Berlin p. 159. 2. Viscontini M. et al.
1970.
Helv. Chim. Acta 53, 1202.
3. Traub H., W. Pfleiderer. 1985. In: Biochemical & Clinical Aspects of pteridines, Vol. 4 (Wächter et al. eds.). W. de Gruyter, Berlin p. 45. 4. Walt D.R. et al. 1984. J. Am. Chem. Soc. 106, 234. 5. Shimono Η., Y. Sugino. 1971.
Eur. J. Biochem. 19, 256.
6. Liebermann I. et al. 1955. J. Biol. Chem. 215, 429. 7. Hoard D.E., D.G. Ott. 1965. J. Am. Chem. Soc. 87, 1785. 8. Kozarich J.W. et al. 1975. Biochemistry 14, 981. 9. Smith G.R., Ch.A. Nichol. 1983. Arch. Biochem. Biophys. 227, 272.
5-ALKYL-5.6.7.8-TETRAHYDROBIOPTERINS
A. Kaiser Pharmaceutical Research Department F. Hoffmann-La Roche & Co. AG CH-4002 Basel
Summary:
Catalytic hydrogenation of 2-N-acyl-l 1 .2 1 -di-O-acylbiopterins and of 1 1 .2'-di-O-acylbiopterins leads to the corresponding 5-alkyl-5,6,7.8-tetrahydrobiopterins hitherto unknown class of compounds.
- a
The mechanism and
the scope of this reductive alkylation and its similarity to the reduction of N(10)-formylfolic acid are being discussed.
During the work on tetrahydrobiopterins that catalytic hydrogenation
it was found
(RT. atmospheric pressure) of
2-N-acetyl- 1',2'-di-O-acetylbiopterin
(1J and
subsequent
acetylation with acetic anhydride/pyridine yielded not only the expected mixture of δα- 1 ^ and 6ß- 2-N. l'-O, 2'-0, 5-tetraacetyl-5.6.7.8-tetra-
hydrobiopterins
(3a. and lb) but
in addition a mixture of 6a- and 6ß-5-ethyl-2-N, 1
l'-O,
2 - Ο , 8-tetraacetyl-5.6.7,8-tetrahydrobio- pterins
(4a^ and
4b). This result was practically independent of the solvents
"^The terms α and β are used for the description of the stereochemistry at C-6 as proposed by Viscontini
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
[1].
24 ( C H 3 C O O H . C F 3 C O O H , M e O H ) u s e d in the
catalytic
h y d r o g e n a t i o n . H y d r o l y s i s of the m i x t u r e of 4a and 4b w i t h a q u e o u s 5N h y d r o c h l o r i c acid gave a m i x t u r e of the 6a- and 6ß-5-ethyl- 5,6,7,8-tetrahydrobiopterins w h i c h one pure d i a s t e r e o i s o m e r
(5a. and 5b).
from
( c o n f i g u r a t i o n at C6 not yet
d e t e r m i n e d ) c o u l d be isolated as its s u l f a t e
(Scheme 1). The
s t r u c t u r e of the 5 - e t h y l a t e d d e r i v a t i v e s 4a^ 4b. 5a^ and E^b 1 13 has b e e n e s t a b l i s h e d by H - and C-NMR-. MS-spectroscopy and e l e m e n t a l a n a l y s i s .
In a d d i t i o n , the
chemical
e v i d e n c e s h o w n b e l o w also points to a 5 - a l k y l a t i o n : a)
C a t a l y t i c h y d r o g e n a t i o n and s u b s e q u e n t a c e t y l a t i o n of 11,2'-O-diacetylbiopterin products
(2_) gave e s s e n t i a l l y the same
(Scheme 1). This result shows that the
N - 2 - a c e t y l g r o u p in the t r i a c e t y l b i o p t e r i n 1. is not i n v o l v e d in the b)
5-alkylation.
C a t a l y t i c h y d r o g e n a t i o n of propionyl-biopterin
2-N-propionyl-l1.2'-di-O-
(6.) f o l l o w e d by h y d r o l y s i s
a q u e o u s 5N h y d r o c h l o r i c acid and s u b s e q u e n t
with
acetylation
w i t h a c e t i c a n h y d r i d e / p y r i - dine lead to a m i x t u r e of the 2 - N . l'-O, 2 1 - 0 , 5 - t e t r a a c e t y l - 5 . 6. 7 , 8 - t e t r a h y d r o b i o p t e r ins 3a. and 3Jb and the 5-propyl-2-N,
l'-O. 2'-0,
8-tetraacetyl-5.6.7,8-tetra-
h y d r o b i o p t e r i n s 7a^ and 7b. H y d r o l y s i s of the m i x t u r e of 7a and 7J3 t h e n y i e l d e d a m i x t u r e of 6a- and 6ß-5-propyl-5,6.7,8-tetrahydrobiopterins f r o m w h i c h a g a i n one pure d i a s t e r e o i s o m e r i s o l a t e d as its sulfate
(Scheme 2). This
(£a and 8b) could be reaction
s e q u e n c e shows that the 5 - a l k y l s u b s t i t u e n t is derived f r o m the l'-0-(or 2'-0-) acyl group and is f o r m e d the c a t a l y t i c c)
during
hydrogenation.
A l l a t t e m p t s failed to h y d r o g e n a t e
the 6a- or
6 ß - t e t r a a c e t y l - t e t r a h y d r o b i o p t e r ins 3a^ and 3J> and the c o r r e s p o n d i n g p e n t a a c e t y l d e r i v a t i v e s £a and
SCHEME
1
OCOCH, OCOCH, 1
^ W C H
ΗΝ
R
—
I CH-CH.
Λ NH R = COCRF-J R = Η H2/PT V
SOLVENT (CH3C0)20 PYRIDINE
0
FOCH3
' \
^
Ν
^ Ν Η
3A
CH7
OCOCH3OCOCH3 —
CH-CH3
FH2
+
OCOCH, OCOCH, ! •> I -> 'CH -CH—CH,
CH3COH ( A COCH3
(6>)
3b ( 6 3 )
MA
(6Α)
4B
(SP)
5Ν HCL
AQ
CH, FH2
OH
YN
N\J;H-CH-CH
5A (.6S)
5b (6R)
3
26 SCHEME
2
OR OR I I N^/CH—CH-CH
6
R =
3
C0CH2CH3 H2/PT
-J' S O L V E N T I 5N H C L
AQ.
(CH3C0)20 ^
fH3
PYRIDINE
CH-, 0
CHJCOH
C O C H , ? C 0 C H 3 OCOCH3
11 j NH
^ H
tH—CL·
+
IH2 ΗΝ
9 C O C H 3 OCOCRL-J £H
CH—CR
CH3C0N! COCH-
3a
(6a)
7a
(6a)
3b
(6e)
7b
(68)
r
5N H C L
AQ.
CH, I 5 CH2 ^ < J H - C H - C H
5
27 respectively
(Scheme 3). indicating that the formation of
these products during the hydrogenation of 1 and 2 is not the reason for the formation of 5-ethylated
products.
SCHEME 3
2a
R = Η 9α R = C0CH3
(6α)
^
R = Η 9b R = C0CH3
(6ß)
h2/Pt
V NO
CF7COOH 3
REACTION
The results described above point out that the formation of 5-alkylated products during the catalytic 1
of 1',2 -di-O-acylbiopterins
hydrogenation
can best be explained by the
intermediate formation of an oxazolinium compound B) which is then hydrogenated
(e.g. A or
to the 5-alkyl derivative.
Theoretically, this oxazolinium compound can be formed either from N(5)- or from 1 1 -O-acylated
tetrahydrobiopterins
(e.g. C or D ) (Scheme 4). All attempts to isolate acyl derivatives of these structures in pure form have not met with success.
28
SCHEME 4
Η
Η
C
D
Preliminary results indicate that the catalytic hydrogenation described above is applicable to a broad range of 1',2'-di-O-acyl-biopterins and thus constitutes the first general synthesis of the hitherto unknown 5-alkyl-5.6.7.8tetrahydrobiopterins. Moreover, the reaction sequence Ε—>F—>G
(Scheme 5) seems to be applicable to other
6-hydroxyalkylpteridines as well. Finally, the similarity of the hydrogenation of O-acylated biopterins to the reduction of N(10)-formylfolic acid should be mentioned. The question arises whether reaction of O-acylated biopterin and other
this
6-hydroxyalkyl
substituted pteridines or their tetrahydro derivatives is also of biological
significance.
29 SCHEME 5
Ε
0
OCOR'
F R'
G
Acknowledgement The help of Ms. N. Erhardt, Dr. U. Fischer. Ms. S. Herzig, Ms. C. Piers, Dr. W. Arnold. Dr. A. Dirscherl, Dr. E. Englert, Mr. W. Meister and Dr. W. Vetter is gratefullyacknowledged.
Reference
M. Viscontini 1985. In: Biological and Clinical Aspects of Pteridines (W. Wächter. Η. Ch. Curtius, W. Pf leiderer, eds.) Walter de Gruyter u. Co.. Berlin. New York. p. 57
MASS
Th.
SPECTROMETRIC
Küster,
Department CH-8032
A. of
INVESTIGATIONS
OF
PTERIDINES
Niederwieser Pediatrics,
Zurich,
University
of
Zurich,
Switzerland
INTRODUCTION
Due
to
field
the
of
lyzing
increasing
biochemistry
this
microbiological
for
routine
The on
hand
compounds
very
present
or
well here
mental
in
high
details
see
been
performance
however, many
cases.
to
developped. are
of
from
our
of
the ana-
Whereas suited
chromatography (1,2).
chromatographic
methods
identification
Mass
such
mainly
in
results
spectrometry
chromatography
solve
examples
methods
liquid
prevents
gas
gained
quantitative
selectivity
suited
various
radioimmunoassays
without
some
have
promising
poor
other
combination be
very
inherent
known
and
pteridines
medicine,
class
analysis,
yields
the
and
compound
the
(HPLC)
interest
(GC)
problems
un-
(MS)
in
arises
to
(3-7)
laboratory.
of
For
and
we
experi-
(6-8).
RESULTS
GC-MS
For
the
trace it
in
ments, a
identification
analysis, our for
control
GC-MS
laboratory the for
of is for
unknown
the the
method
routine
of
choice
monitoring
characterization
HPLC
compounds
of
new
of
as
well
and
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
for
we
applied
loading
experi-
metabolites
determinations.
as
and
as
32
a ) Loading
experiments
Atypical
forms
of
a
BH^,
barrier.
tutes
which
patient
served 1
can
enter
lites found
only
the
the
more
easily
with
doses
the
blood
passes
find
cofactor
than
before
excreted
and
and
after
loaded
and
loading.
identified
in urine samples during
substi-
BH^, we
6-methyltetrahydrobiopterin
pterin
that laoading
obTable
metabo-
test.
Identified Pterins
Time after loading(hrs)
Biopterin Neopterin 6-Methylpterin 6-Methylisoxanthopterin + + +
+ + + +
Excreted
pterins
before 2-4 4-6 12-24
-
Table
slightly to
pterins
mainly
successfully
efforts
brain
with
excreted
the
be treated
which
During
orally
the
shows
PKU
cofactor
brain
a
of
1:
-
after
+ +
+ +
+
+
loading
with
6-Methyltetra-
hydrobiopterin.
Fig.
1
shows
the
excretion
6-methyl-isoxanthopterin value 4
of
hours
slower than
212
and
after
of
pterin
due
to
excreted
mainly
is produced
(from
from
unchanged
During
tests
the
by
HPLC
recovery
resting
reached
between
shows
to
a
whereas
for
the
lies
in
maximal 2 and
a
25
fact
the measured
to
0.7)
that
is
6-methylwhich
was
6-methylisoxanthopterin oxidase.
metabolites usually
occurence the
and
significantly
(from
0.3),
that
by the action of xanthine
loading
The
6-methyltetrahydropterin
of new
gated
212
circumstance
b) Characterization BH^
neopterin.
is
figure
6-methylpterin
6-methylisoxanthopterin
the
originates
The
of
to
respectively
6-methy lpterin
possibly
relative
loading.
decrease
of
25
pattern
region
urine
samples
of pterin of
are
investi-
metabolites.
1-5% only,
if these metabolites are also excreted
it
was
in the
Since inte-
feces.
33
100-
10-
hrs.
2-4 Figure
1: Total
τ
4—β
12—24
ion current peak area r a t i o s
Methylisoxanthopterin +
to Neopterin
of
6-Methylpterin and 6-
versus time a f t e r
loading
with 6-Methyltetrahydropterin. Figure feces the C
2
shows
fraction.
sample
has
a
total
For
the
been
ion
current
determination
spiked
with
even
chromatogram of
of
the methylene
numbered
such a units,
n-alkanes
C101ο
26 "
RIC.
2Θ0
Figure
250
2:
Total
ion
3Θ0
8:20
6:40
5:00
current
chromatogram
10:00 of
a feces
350 11:40 fraction
34 Table
2
lists
BH^treatment All
the
identified
together
with
their
listed
have
been
compounds
references
lumazines
and
their
methylene
in
feces
respective verified
units
Compound
after
methylene
by
the
units.
comparison
with
(8).
No .
MU
Μ
Base
'(%)
TMS
peak
6-Hydroxylumazine
3
20 .61
396(100)
7,8-Dihydro-6-hydroxylumazine
4
21 . 5 5
470(100)
2 '-Deoxy-biolumazine
3
21 .67
438(
90) 409
7,8-Dihydro-2*-deoxybiolumazine
4
22 .36
512(
40) 422
2'-Deoxysepialumazine
3
22 . 72
438(100)
Biolumazine
4
23 .07
526(0.6)
7 ,8-Dihydrobiolumazine
5
23 .85
600(100)
Sepialumazine
4
2 3 .93
526(100)
2 '-Deoxysepialumazine
4
24 .67
510(100)
Table
2:
Lumazines
identified
in
feces
after
tetrahydrobiopterin . MU : methylene lecular
c)
Control
The
amount
urine In
for
question
ble
results
we
do
with a
this a
L-threo-neopterin
could
arises An by
of
proof
pterin
is
of
units,
+
M ' :
trimethylsilyl
value
the
0.2 that
the
of mo-
groups.,
with
excreted
is
3
two
HPLC
to
observed of
a reference
really
shows of
monapterin
neopterin. HPLC the
peak
methylene
compound.
and
yields
then
relia-
indicated
and
chromatograms (A)
GC-MS 2
in
(neopterin).
ratio
then
value
comparison
method
this
control
Figure
relative
exeeds
HPLC
independent
excretion
(monapterin)
D-erythro-neopterin
the
if
GC-MS.
through
spectrum
10%
however
normal
ratio
mass
of
cases
the
of
ingestion
HPLC
normally
some
ion,No.TMS:number
410
and
Β
here
really units
with
firstly is and
monathe
34 ι
Fluorescence 350/450 nm
1
U
Β
A
min 3:
HPLC
pterins to
cation
of
bration tive
values
value
Direct
HPLC
determined
0.21 of
excreted for
for
the
ion
monapterin. and
The
the
urine
for
mentioned
Chemical
Ionization
(DCI)
compounds
with
components
a
less
its
advantages
relative volatile
high which
without
decomposition.
As we
pterins
can
volatile
and, which gated
this
made
method
especially does
more
not
therefore
for
results
the
it
4
a
mark
reslults
for
mixture
are
is
pterins
by
gives "true".
fails
be
of with
vaporized TMS-ethers, but
than
determination desirable.
HPLC
analysis
derivatization,
weight
respec-
GC-MS
the
questions
cali-
Thus,
it
cannot
the
the
B.
HPLC
more
2
quantifi-
shows
whereas
with
mona-
biopterin.
sample
here
high
neopterin,
4 =
arrows
often
molecule
reference
(B)
volatility,
by
in
molecular
change some
did
and
allowed
ratio
the
30
=
Figure
GC-MS.
that
has
1
monitoring
indicating
GC-MS
normal
ratio.
0.22
Whereas
times,
(A)
3 = isoxanthopterin,
selected
the
plots
yielded a
of
with
neopterin
monapterin,
method
min
30 0
of
pterin
The
2
3
,0 Figure
35
We
direct
some-
answers a
method
investichemical
36
Figure 4: Ratio determination of Monapterin to Neopterin by HPLC(·--—•) and GC-MS(# # ) . Ratio values determined, ( • ) using the corresponding c a l i b r a t i o n graph: HPLC.0.21, GCMS.0.22.
ionization,
a technique
and
so
can
be
usually
is
a
evaporated high
molecular
weight.
determines
the
intensity So,
3 lists
the
the
gated
pterins
and
pterin-6-carboxylic limits
quasi
from d e c a r b o x y l a t e d
ions
the
5
in
protonated
molecular
acid. acid
of
sample
shows
This ion rather
the
The
result
region
molecular
of
ion
the often
weight. ions
(MH+)
the
DCI
example
also
at
is flash vaporized
decomposition.
molecular
Figure
since
the
without
respective
Table
method's
by which
m/z
than
of
mass
the
investi-
spectrum
shows some o f
164 a r i s e s from the
to
intact
of the
originate molecule
37
Compound
MG
MH+
(%)
Lumazine 6-Hydroxylumazine Pterin Pterin-6-carboxylic acid Xanthopterin Isoxanthopterin Sepiapterin Biopterin Neopterin Monapterin
164 180 163 207 179 179 235 237 253 253
165 181 164 208 180 180 236 238 254 254
(100) (100) (100) ( 27) (100) (100) ( 48) (100) (100) ( 75)
Base peak
164
103
103
Table 3: Molecular weights (MG), Quasimolecular ions (MH ) and base peaks of reference pterins under direct chemical ionization conditions with methane as reactant gas (9).
100
-
75
-
164
190
50 UJ >
147 25
-
94
122
r^U, f M r
80
130
208
MH*
Jvi I .1 • , 180
230
m/z
Figure 5: DCI (methane) spectrum of pterin-6-carboxylic acid (9).
" r ~T~ r 280
38 ACKNOWLEDGEMENT
We
express
Houston,
our
thanks
Texas,
USA
for
to
Prof.
the
E.C.
Horning, University
of
DCI-analyses.
REFERENCES 1.
Fukushima, 176 .
T.,
J.C.
Nixon.
1980.
2.
Niederwieser, a . , W. S t a u d e n m a n n , Ε . W e t z e l . 1982. In: B i o c h e m i c a l a n d C l i n i c a l A s p e c t s of P t e r i d i n e s ( H . W ä c h t e r , H . C h . C u r t i u s a n d W. P f l e i d e r e r , e d s . ) de G r u y t e r , B e r l i n , I, p. 8 1 .
3. K o b a y a s h i , Κ . , M . G o t o . 1 9 7 0 . of P t e r i d i n e s (M. G o t o a n d Y. P r i n t i n g C o . , T o k y o , p. 5 7 . 4. L l o y d , T . , 108. 5. R ö t h l e r , 6.
S.
F.,
Markey,
Μ.
N.
Karobath.
Anal.
Biochem.
102,
In: C h e m i s t r y and Biology Iwanami, eds.) Int. Acad.
Weinen.
1976.
1971.
Clin.
Anal.
Chim.
Biochem.
Acta
69_,
42,
457.
Küster, 245.
Th. ,
A.
Niederwieser.
1983.
J.
Chromatogr.
2 78,
7. K ü s t e r , 303.
Th. ,
A,
Niederwieser.
1984.
J.
Chromatogr.
290,
8. N i e d e r w i e s e r , Α . , A. M a t a s o v i c , T h . K ü s t e r , W . S t a u d e n m a n n 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 . 1 9 8 6 . I n : C h e m i s t r y a n d B i o l o g y of P t e r i d i n e s (B.A. C o o p e r , V.M. W h i t e h e a d , e d s . ) de G r u y t e r , B e r l i n , p. 3 0 5 . 9. H o r n i n g , ration .
E.C.,
Η.-Ch.
Curtius,
A. N i e d e r w i e s e r :
in
prepa-
THE STRUCTURAL CHARACTERIZATION OF 6-PYRUVOYL TETRAHYDROPTERIN BY FAST ATOM BOMBARDMENT MASS SPECTROMETRY WITH ONE- AND TWO-DIMENSIONAL MASS ANALYSIS (FAB/MS AND FAB/MSMS)
W.J. Richter, F. Raschdorf, R. Dahinden Central
Function Research, Ciba-Geigy AG, CH-4002 Basel, Switzerland
A. Niederwieser+, H.-Ch. Curtius, W. Leimbacher, Th. Küster University of Zurich, Department of Pediatrics, Division of Clinical Chemistry, CH-8032 Zurich, Switzerland
Introduction
Tetrahydrobiopterin important
role
(BH4),
in the
the cofactor
biosynthesis
of various
hydroxylases,
of the neurotransmitters
plays
an
catecholamine
and indoleamine (1), and inborn errors in the BH4 biosynthesis cause atypical phenylketonuria.
Clarifying the biosynthetic pathway (Scheme 1) there-
fore is of great importance for the elucidation of metabolic defects. key
intermediate
hydropterin mode
of
(2-6).
hereby
(PPH4)
formation,
is
a compound
structure.
This
its chemical
with
a
hypothesis
proposed has
6-pyruvoyl
been
deduced
reactivity, and from trapping
The
tetra-
from
its
experiments
Whereas all these experiments led to indirect evidence for the PPH4
structure, Ghisla et al. (7) presented direct ^H-NMR evidence for the pyruvoyl
tetrahydro
structure.
In order
to
have
further
direct evidence
we
present here mass spectrometric results toward the structure elucidation of the
intermediate.
Results and Discussion
The in
intermediate Scheme
bombardment
2)
had (FAB)
in the been mass
BH4 biosynthesis, inferred,
was
spectrometry.
for which a PPH4 structure
subjected A
to
useful
analysis
by
positive
ion
Unconjugated Fterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
fast
{Αχ, atom
spectrum
40
Ο
^
OHOH
F ^ - C - C H j - O ® ® ® NhUTP H
HjN^N^V Η
0
Η
^ B '
0 OH
0 Mg2+
V.
Η
NAD(P)H
0
Η
xXT
OHO
Η
'PPH^S"
h
0 0 ii ii
Hv
^B-v
PPH A (A t )
c-c-ch3
Η 2, κ τ ν Ν τ Η tSR)
0
VH
NAD(P)H
•'PPH4R"
Η
Ηι II0 C-C-CH3 1 OH η2Ν-%"%Τ * Η
0
ύΥΤ
ί
Η
Ο Η
ΟΗ Η
SR>>NAD(P)H
NAOfPJH-^^SR γ 9
Π Η ι-Ηι Η
ΗΝ
ΒΗ> N"Sr
OHOH
Scheme 1 : Biochemical pathway of BH4 biosynthesis from dihydroneopterin triphosphate. (Fig. 1) was acquired using thioglycerol
(glySH) as the liquid matrix, in
which a [M + H] + ion of moderate abundance was observed at m/z 238 (ca. 20% rel. int.). elemental
This
indicated the presence of a molecule with the correct
composition
C9H11N5O3
(base peak) was attributed
(M=237).
to a [M + H]
The +
intense
signal
at m/z
ion of 7,8-dihydropterin
166
(PH2,
C6H7N5O, M=165) which was formed by decomposition of the moderately stable new compound either before or during analysis. the
formation
protonated
of the m/z 166 ion by genuine
An alternative route for gas phase
fragmentation
of
PPH4, e.g., via loss of 0=C=C(0H)CH3 from an intact [M + H] +
41
precursor,
appeared
less
probable
importance
in the metastable
since
such
a process
is of only
ion (MI) decomposition which may be
minor
observed
by FAB/MSMS (see below).
Scheme 2. Structures considered as the intermediate in tetrahydrobiopterin biosynthesis: Al, 6-pyruvoyl tetrahydropterin; A2, sepiapterin; A 3 , biopterin; A4, A5, see text.
The
(+)FAB behavior of known isomers and hydrogenate analogues of
different matrices was of special
interest in this context.
mers, the most important ones, i.e., sepiapterin were readily available spectrum in a glycerol
for a preliminary
1
study .
[M +
Difficulties H]
+
A2 yielded a useful
(glyOH) matrix displaying a [M + H ]
formation
were
however
required
the
encountered
use
(A3),
(A2) and biopterin +
with
A3,
in
Of these iso-
FAB
ion at m/z 238,
ca. 15% rel. int., together with other major ions of the (glyOH) n type.
PPH4
as
of m-nitrobenzylalcohol
even
cluster modest
(ΝΟΒΑ)
as a
1) A more detailed study of the FAB behavior of pteridines is currently in progress (W.J. Richter, F. Raschdorf, Th. Küster, and H.-Ch. Curtius).
42
liquid
matrix
(8)
since
t h e 10% r e l .
int.
signal
at
a "chemical
noise"
l e v e l o f up t o 8% appeared t o be u s e l e s s u n l e s s MS-MS was employed.
While
t h e A4 and A5 isomers were n o t o b t a i n a b l e , t h e h i g h l y u n s t a b l e analogue 0 - or p - q u i n o n o i d d i h y d r o b i o p t e r i n f o r comparison.
As e x p e c t e d ,
hydrogenated
( q u i n o n o i d BH2) was
available
t h i s analogue (M=239) a l s o proved
difficult
t o a n a l y z e ( g l y S H m a t r i x ) , as an e f f i c i e n t uptake o f 2 Η atoms was observed which p r o b a b l y y i e l d s 1:5). the
The a n a l y s i s (+)FAB
spectrum
BH4 as t h e s t a b l e
product
(m/z 2 4 0 / 2 4 2 r a t i o
about
o f BH4 (M=241) d i d however prove t o be s u c c e s s f u l (glySH m a t r i x )
showed e x c l u s i v e
[M +
H]+
as
formation
( m / z 2 4 2 , base p e a k ) .
10 Ch
166
/
50-
(M+H) + 238
I···"!' .1.11.1 ·ί ι. • • I. i.l • ι. • ] 1 i·. ι. ι .Iii 11 ii •• • .1•-ιlillllllllMilillilillllliilllillillllll mtii mhln.iiiilll m/z
140
—
180
220
F i g . 1 . (+)FAB spectrum o f the i n t e r m e d i a t e A^ ( t h i o g l y c e r o l 10 keV xenon a t o m s ) . From F i g .
1 and t h e
preliminary
results
,III,ill
obtained with
analogues i t i s q u i t e obvious t h a t s t r u c t u r a l
matrix,
these
isomers
and
p a r a m e t e r s , o t h e r than molec-
u l a r s i z e , c a n n o t be d i r e c t l y deduced from FAB/MS, owing t o a l a c k o f p r o -
43 nounced FAB
fragmentation
in conjunction
of
with
a clear-cut origin. two-dimensional
mass
Under
these
spectrometry
circumstances, (FAB/MSMS)
peared highly promising since the ions of interest, i.e., the [M + H]
+
apions
of intact PPH4, can be singled out for further MS analysis as more or less pure
species.
The "dynamic", i.e., nonchromatographic
ions, that
is, separation
prevailing
"chemical
from other
ions
noise", is accomplished
the employed tandem mass spectrometer.
such
as
"isolation" of the
those
of
PH2 and
in the first stage, MS-I
permits
of
MS-II then performs the mass analy-
sis of the daughter ions which are generated in a collision cell between MS-I and MS-II.
the
positioned
Operation of the cell with or without a target gas
the options of collision
induced dissociation
(CID) and
spontane-
ous, i.e, metastable ion (MI) decomposition, respectively.
m/z 238
Fig. 2. Mass analyzed ion kinetic energy (MIKE), FAB/MSMS spectra of [M + H] + ions (m/z 238) of the intermediate Aj (_a, upper trace), sepiapterin (b, center trace) and biopterin (c, lower trace).
44
F i g . 2 shows the FAB/MSMS spectra of the relevant mass-selected [M + H] + The [M + H] + ion of the
i o n s , m/z 238, which were recorded in the MI mode.
"unknown", which i s to be compared with those of the reference ions derived from ß>2 and A3, shares a pronounced l o s s of H2O with i t s isomers. case of
structure A^, which lacks a hydroxy!
substituent as a preformed
leaving group, a rearrangement by hydride s h i f t ( s ) of H2O from protonated ketones see ( 9 ) ) .
In the
i s indicated (for
loss
The pronounced elimination of a
42-Dalton neutral, which i s most l i k e l y to be CH2=C=0 from the terminus of the side-chain,
seems to be highly s p e c i f i c
for the new d e r i v a t i v e .
The
genesis of the corresponding daughter ion at m/z 196 may a l s o be r a t i o n a l ized by assuming that a f a s t 1,2-hydride [M + H]
+
species
occurs
as the i n i t i a l
shift step
in a carbonyl-protonated
(Scheme 3 ) .
The
rearranged
species, i . e . , the product of an intramolecular "redox" process leading to a dihydropterin,
should permit a "Grob-type"
fragmentation which produces
m/z 166 Scheme 3. Proposed mechanism f o r CH3C(0H)=C=0 from [M + H] + of PPH4.
the
elimination
of
CH2=C=0
and
45 an acetyl cation CH3C=0 + together with a neutral hydroxymethylenamine molecule.
The high proton affinity of the neutral may favor subsequent proton
abstraction from CH3CsO +
(the potential
Bronsted acid) prior to dissocia-
tion of the intermediate ion/dipole complex, thereby rendering CH2=C=0 the final neutral ejected.
It seems plausible that the di- and nonhydrogenated
pterins such as A2 and A3 do not lend themselves readily to analogous reaction pathways. of
The "compound specificity" of the MI daughter ion spectrum
the [M + H]
+
of
the new derivative
existence of the new isomer, but also
supports
not only the
its isolation
without
postulated large-scale
decomposition by rearrangement into A2 or A3 during the workup and/or FAB analysis. As mentioned above, the formation of a protonated PH2 (m/z 166) by MI ejection of CH3C(0H)=C=0, rather than chemical decomposition, is inconspicuous. It should nevertheless be considered, as it places the additional
oxygen
1
atom clearly into the C(1 )-carbonyl group of the assumed CH3COCO substituent.
The specificity of this latter process
is unfortunately
not suffi-
ciently well established owing to the low relative intensity and broadness of the m/z 166 MI signal
(see e.g. A2).
The MS evidence for a tetrahydro-
genated pterin nucleus is therefore insufficient.
When specificity is only admitted for the MI elimination of ketene from the C3
substituent
in a di- or tetrahydrogenated
assignment of Αχ has still these
alternatives
quinonoid
0-
or
p-tautomer
pterin via an endiol
structural
two major competitors, i.e., A4 and A5.
represent
1'-hydroxy-2'-oxopropyl
pterin skeleton,
dihydropterins, 6,7-dihydro
substituent.
i.e.,
a 7,8-dihydro-
derivative
carrying
a
A 4 , which is tautomeric with
Both and
a
common sepia-
intermediate, is ruled out because of its chromophore
which is incompatible with the observed UV absorption.
The
UV-compatible
chromophore A5 is a highly unlikely competitor owing to its FAB/MS behavior which
sharply
contrasts
that
of
0-
or
p-quinonoid
6,7-dihydrobiopterin
since the quinonoid BH2 reference compound A3 rapidly takes up 2 Η atoms prior to or during FAB analysis.
In the case of the new derivative no such
hydrogen uptake was observed (Fig. 1). derived
from
other
spectroscopic
The PPH4 structure Αχ, which was
evidence
without
actual
isolation,
therefore complemented and fully supported by mass spectrometrie means.
is
SECTION Β: BIOCHEMISTRY AND METABOLISM OF PTERINS
TETRAHYDROBIOPTERIN: OTHER PHYSIOLOGICAL ROLES IN ADDITION TO AROMATIC AMINO ACID HYDROXYLATION? Sheldon Milstien, Ph.D. Laboratory of Neurochemistry National Institute of Mental Health Bethesda, MD 20892
Introduction
The two major unconjugated pterins present in human serum, urine and cerebrospinal fluid are dihydroneopterin and tetrahydrobiopterin (BH^) (1).
The only established physiological role for BH^ is as the natural
cofactor in the hydroxylation of the aromatic amino acids, phenylalanine, tyrosine, and tryptophan (2).
BH^ is used by the three different enzymes
which catalyze the hydroxylation reactions in conjunction with enzyme-bound iron to reduce molecular oxygen (2).
A genetic defect in
phenylalanine hydroxylase blocks the metabolism of phenylalanine and causes phenylketonuria (3).
Children with genetic defects in either de
novo BH^ biosynthesis or in dihydropteridine reductase, the enzyme responsible for maintaining BH^ in its reduced form, have both an inability to metabolize phenylalanine, as well as a lack of the important neurotransmitters, dopamine, epinephrine, and serotonin, which are derived from the hydroxylated amino acids (A).
The origin of dihydroneopterin in human tissues has not yet been
This paper is dedicated to the memory of Dr. Alois Niederwieser
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
50
unequivocally established.
It probably arises as a result of
dephosphorylation of dihydroneopterin-triphosphate, the first pterin derivative in the de novo BH^ pathway (5).
The measurement of
dihydroneopterin levels in blood and urine has proven to be a useful clinical parameter in cancer (6), AIDS (7), and organ transplantation (8). Dramatic increases in neopterin excretion are seen whenever lymphoid cells, such as Τ cells or macrophages, are stimulated by interferon or IL-2 (9).
The role of dihydroneopterin in this or any other physiological
process has as yet not been established.
Clearly, dihydroneopterin cannot
be an indispensable factor, since: many species have essentially no neopterin in their body fluids or tissues (1); many human cells, such as fibroblasts, do not produce any neopterin; and children with a genetic block in GTP-cyclohydrolase, the enzyme which catalyzes the formation of dihydroneopterin triphosphate, have no apparent anomalies in their immune systems (10).
The presence of BH^ in many tissues and in brain regions nearly devoid of any aromatic amino acid hydroxylase activity (1), raises the possibility that BH^ might also be necessary for the activity of a different kind of enzyme system.
Several other oxidation reactions have been proposed to
utilize a tetrahydropterin as a cofactor.
These include: ether lipid
oxidation (11); proline hydroxylation (12); and mitochondrial electron transport (13).
The evidence for the requirement for a tetrahydropterin
in these enzyme systems is reviewed below.
In addition, as a guide to the
discovery of other roles for BH^ and it's biosynthetic enzymes, the significance of the discovery that dihydropteridine reductase, an enzyme
51 which had previously been thought to only be involved in maintaining BH^ in the fully reduced state, also plays an important role in tetrahydrofolate metabolism, is discussed.
Distribution of BH^ and Its Biosynthetic Enzymes in Rat Brain
BH, is present in every region of the rat brain (1A) and the human brain (15) with a fairly narrow concentration distribution.
Since the only
known function of BH^ in the CNS is to serve as a cofactor for tryptophan and tyrosine hydroxylases, it is not surprising that a correlation has been found between the activity of these enzymes in various regions of the rat brain and the concentration of BH^ (1A).
Using an enzymatic cofactor
assay, Levine, et al (1A), showed that there was a high degree of correlation (r = 0.8) between reduced cofactor content and total tryptophan plus tyrosine hydroxylase activities in the rat brain.
In
Figure 1, are plotted BH^ concentrations, determined by a high performance liquid chromatographic assay (1), against the total tryptophan and tyrosine hydroxylase activities in seven areas of the rat brain.
There is
a high degree of correlation between BH^ content and hydroxylase activities, even though the HPLC method gives somewhat greater values than the cofactor assay.
It should be noted that there is more than a 120 fold
range in the hydroxylase activities between the cerebellum and the striatum, whereas there is only a 5 fold range in BH^ concentration. difference in the ranges suggests that if the BH^ in the striatum is concentrated almost solely in aminergic neurons as has been suggested (16), this cannot be the case in other areas of the brain since the concentration of BH, would be extremely high in those areas with only
This
52
relatively few aminergic neurons, such as the cerebellum and cortex. Also, extrapolation of the data in Figure 1 to a hypothetical region of the brain with no hydroxylase activities indicates that there would still be significant amounts of BH^ remaining.
Another approach which can be used to evaluate the localization of BH^ and its biosynthetic enzymes in specific aminergic neurons is the application of neurotoxins, such as 6-hydroxydopamine, 5,7-dihydroxytryptamine, kainic acid, and MPTP.
These toxins are taken up by receptor-mediated processes
and then kill those cells which concentrate them by still not well characterized mechanisms.
6-Hydroxydopamine and MPTP are taken up
selectively by cells in the substantia nigra dopaminergic pathway and cause symptoms in animals similar to those of Parkinson's Disease in
Μ
1 2 3 4 5 6 ?
60τ
striatum cerebellum medulla htypothalumus hippocampus cortex midbrain
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a
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+->
ί .
.—•
ε
*
Ο 05
— , -—»
ε «•Μ*
LO ΙΟ Ο
—
ο ο Γ—
•
ο ο ΙΟ
ο ιο r—
ο
— ,
•
CO •
ο
«3-
Ο
LO CO I
CSJ csj I
CSJ
αϊ i . Ζ3
Ό Φ υ ο s_
+J Ο A3 S-. +J Χ αι αι •σ ίΟ
(β 4t— 3 (Λ ε •r—
C ο ε
C ο • r— +J Ο (β S4S« Ο LO I Ο
αι -Μ •Γ—
re
+->
ο. > χ ο iΤ3 >5
υ 1
αι
13 CQ
ι 0Ω
+->
95 After Blue Sepharose a f f i n i t y chromatography the increase of s p e c i f i c tivity
was about 550-fold.
This
purification
ac-
factor does not take
into
account the f i r s t two p u r i f i c a t i o n steps which lead to a 100-fold p u r i f i c a t i o n , approximately.
The total amount of protein was
human l i v e r corresponding to an overall
recovery of 28%.
Sepharose step some contaminating proteins were s t i l l in
Fig.
1).
Mono Q ionic
single
After the Blue
present (see SDS-PAGE
These were eliminated by threefold FPLC chromatography
on
exchanger.
at
This
resulted
in
two f r a c t i o n s
280 nm), both of them showing PPH4R a c t i v i t y . still
0.3 mg from 300 g of
contaminated
with minor
band corresponding
protein
While the f i r s t
impurities,
to a molecular
(detection
the
peak was
second y i e l d e d a
weight of approx. 35ΌΟΟ
D on
66 kDa
US kDa 56 kDa 29 kDa 2t kDa 20 kDa
-
ο ο
14 kDa
in Οι
F i g . 2. SDS-Page with 12.5% Polyacrylamide. Left gel: enzyme preparation from d i f f e r e n t p u r i f i c a t i o n steps, as mentioned in the f i g u r e ; r i g h t g e l : active fractions from the t h i r d Mono Q run. The mixture of standard proteins contained: bovine albumine (66 kD), egg albumine (435 kD), g l y c e r i n aldehyde-3-phosphate dehydrogenase (36 kD), carbonic anhydrase (29 kD), trypsinogen (24 kD), t r y p s i n i n h i b i t o r (20 kD), a-1actalbumin (14 kD).
96 SDS-PAGE (Fig. 2).
Since this corresponds to the molecular weight deter-
mined by using gel
filtration, it must be concluded that the enzyme is a
monomer. Analytical
isoelectric
focusing
(pH range 4-9, Servalyt Τ 4-9) on G-200
superfine revealed an isoelectric point of pH 6.0 ±0.2.
Glycoprotein de-
tection using Concanavalin A and peroxidase was negative.
In the presence
of 10 mM DTE less activity was found than with a 1 mM solution, suggesting that PPH4R is not particularly sensitive to -SH group oxidation.
Only PPH4
and not 6-(Γ-oxo-2'-hydroxypropyl)-5,6,7,8-tetrahydropterin or sepiapterin is a substrate for this enzyme. 5,6,7,8-tetrahydropterin
will
Most probably 6-(r-hydroxy-2'-oxopropyl)also
turn out to be a substrate
for this
enzyme, however, so far this has not been investigated in detail. indicates a much higher catalyzing
This
specificity of PPH4R compared to SR, the latter
the reduction of a variety of diketo functions
(25).
It is,
therefore, reasonable to assume that this new enzyme indeed plays a role in BH4 biosynthesis, although this still remains to be proven by direct experiments.
A particular problem is posed by nomenclature. hydropterin 6-pyruvoyl
reductase"
might
not
be
The name "6-pyruvoyl tetra-
appropriate,
since
SR also
reduces
tetrahydropterin, although with a different preference for the
side chain carbonyl
groups.
"6-pyruvoyl
tetrahydropterin 2'-keto
reduc-
tase" or "6-pyruvoyl tetrahydropterin 2'-carbonyl reductase" might be better choices. The use of specific inhibitors for PPH4R and of antibodies which are currently
in preparation might help to elucidate
the question whether
this
enzyme is on the biosynthetic pathway or not, and to solve the sequence problem mentioned above.
97 C o n d usion An enzyme which catalyzes the reduction of the
2'-keto group of 6-pyruvoyl
tetrahydropterin, the intermediate in tetrahydrobiopterin biosynthesis, has been purified from human liver to apparent homogeneity.
The enzyme has a
native molecular weight of approx. 3 5 Ό 0 0 D and is a monomer.
It appar-
ently contains no carbohydrates and has an isoelectric point of pH 6.0.
In
the presence of NADPH this enzyme efficiently catalyzes the formation of 6-(r-oxo-2'-hydroxypropyl)-5,6,7,8-tetrahydropterin hydropterin.
from 6-pyruvoyl tetra-
1
6-(l -oxo-2'-hydroxypropyl)-5,6,7,8-tetrahydropterin
and
sepiapterin are no substrates.
Acknowledgements This work was supported by the Swiss National no. 3.395-0.86.
We are grateful
Science Foundation, project
to Dr. B. Mermuth for providing us with
the carbonyl reductase.
References 1.
Curtius, H.-Ch., S. Takikawa, A. Niederwieser, S. Ghisla. 1986. In: Chemistry and Biology of Pteridines 1986 (B.A. Cooper and V.M. Whitehead, eds.). de Gruyter, Berlin, p. 141.
2.
Curtius, H.-Ch., D. Heintel, S. Ghisla, Th. Küster, W. Leimbacher, A. Niederwieser. 1985. J. Inher. Metab. Dis. 8 Suppl. 1, 28.
3.
Switchenko, A.C., G.M. Brown. 1985. J. Biol. Chem. 260, 2945.
4.
Milstien, S., S. Kaufman. 1099.
5.
Masada, M., M. Akino, T. Sueoka, S. Katoh. 1985. Biochim. Biophys. Acta 840, 235.
6.
Nie hol, C.A., G.K. Smith, D.S. Duch. 1985. Ann. Rev. Biochem. 54, 729.
7.
Blau, Ν., A. Niederwieser. 1983. Anal. Biochem. 128, 446.
1985. Biochem. Biophys. Res. Commun.
128,
98 8.
Ghisla, S., P. Steinerstauch, Th. Hasler, N. Blau, H.-Ch. Curtius. 1987. In: Unconjugated Pterins and Related Biogenic Amines. (H.-Ch. Curtius and N. Blau, eds.). de Gruyter, Berlin (this volume).
9.
Richter, W.ü., F. Raschdorf, R. Dahinden, A. Niederwieser, H.-Ch. Curtius, W. Leimbacher, Th. Küster. 1987. In: Unconjugated Pterins and Related Biogenic Amines. (H.-Ch. Curtius and N. Blau, eds.). de Gruyter, Berlin (this volume).
10. Switchenko, A.C., J.P. Primus, G.M. Brown. 1984. Biochem. Biophys. Res. Commun. 120, 754. 11. Smith, G.K., C.A. 761.
Nichol.
1984. Biochem. Biophys. Res. Commun. 120,
12. Smith, G.K., C.A. Nichol. 1985. J. Biol. Chem. 261, 2725. 13. Takikawa, S., H.-Ch. Curtius, U. Redweik, S. Ghisla. 1986. Biophys. Res. Commun. 134, 646.
Biochem.
14. Takikawa, S., H.-Ch. Curtius, U. Redweik, W. Leimbacher, S. Ghisla. 1986. Eur. J. Biochem. 161, 295. 15. Milstien, S., S. Kaufman.
888.
1983. Biochem. Biophys. Res. Commun.
115,
16. Katoh, S., T. Sueoka, S. Yamada. 1982. Biochem. Biophys. Res. Commun. 105, 75. 17. Heintel, D., W. Leimbacher, U. Redweik, B. Zagalak, H.-Ch. Curtius. 1985. Biochem. Biophys. Res. Commun. 127, 213. 18. Wermuth, B. 1981. J. Biol. Chem. 256, 1206. 19. Hasler, Th., A. Niederwieser, H.-Ch. Curtius. 1987. In: Unconjugated Pterins and Related Biogenic Amines. (H.-Ch. Curtius and N. Blau, eds.). de Gruyter, Berlin (this volume). 20. Laemmli, U.K. 1970. Nature, London 227, 680. 21. Clegg, J.C.S. 1982. Anal. Biochem. 127, 389. 22. Radola, B.J. 1974. Biochim. Biophys. Acta 386, 181. 23. Katoh, S. 1971. Arch. Biochem. Biophys. 146, 202. 24. Niederwieser, Α., W. Staudenmann, E. Wetzel. 1984. J. Chromatogr. 290, 237. 25. Sueoka, T., S. Katoh. 1985. Biochim. Biophys. Acta 843, 193.
HUMAN GTP CYCLOHYDROLASE
I:
PURIFICATION
AND PREPARATION
OF MONOCLONAL
ANTIBODIES *
G. Schoedon, A. Niederwieser+ , H.-Ch. Curtius D i v i s i o n of C l i n i c a l Chemistry, Department of P e d i a t r i c s , U n i v e r s i t y of Zurich, CH-8032 Zurich, Switzerland
Introduction The f i r s t
step
in
the biosynthesis
of
tetrahydrobiopterin
(BH4)
is
the
conversion of GTP to dihydroneopterin triphosphate (NH2TP) and formic acid, which i s catalyzed by the enzyme GTP cyclohydrolase I (GTPCH; EC 3 . 5 . 4 . 1 6 ) . This enzyme has f i r s t been characterized from Escherichia c o l i ( 1 , 2 ) , l a t e r its
purification
from several
other microorganisms
(3,4,5),
insects
(6),
chicken ( 7 ) , rat (8) and, p a r t i a l l y , from human (9) has been described. GTP cyclohydrol ase I deficiency in man causes atypical to the lack of BH4 b i o s y n t h e s i s
and deficiency
of
phenylketonuria due
the
neurotransmitters
dopamine and serotonin (10). Immune stimulation causes a d r a s t i c a l of
GTPCH a c t i v i t y
in the responsible c e l l s
increase
of both man and mouse
(11).
These findings gave the reason for further studies of the human GTPCH on the molecular and gene l e v e l , including p u r i f i c a t i o n and s t a b i l i z a t i o n the enzyme as well as production of monoclonal
of
antibodies.
Two c h a r a c t e r ! s t i e s of human GTPCH made i t s p u r i f i c a t i o n e s p e c i a l l y
diffi-
c u l t : One i s the f a i l u r e of a f f i n i t y chromatography for the mammalian enzyme and the other first
is
its
extreme i n s t a b i l i t y when beeing p u r i f i e d . The
has been overcome by development of a new a f f i n i t y material
8-aminoguanosine
triphosphate
and
sepharose
4B,
which
resulted
using in
a
300-fold p u r i f i c a t i o n (12). But due to the i n s t a b i l i t y of the enzyme, only 5% of a c t i v i t y has been recovered.
* This paper i s dedicated to the memory of Prof. A l o i s Niederwieser
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
100 The present paper describes a p u r i f i c a t i o n
procedure of GTPCH from human
l i v e r modified with respect to the s t a b i l i z a t i o n of enzyme a c t i v i t y .
Materials and Methods All
chemicals
procedure
for
used are commercially GTPCH w i l l
available.
be reported elsewhere
The detailed (13).
purification
GTPCH a c t i v i t y was
measured as described in (9). Proteins were determined by the dye binding method {Bio Rad). Production of monoclonal antibodies has been done according to Köhler and M i l s t i e n ELISA and Western b l o t t i n g .
(14). Monoclonal
antibodies were selected by
Isotyping was performed by use of
Ig-subclass
s p e c i f i c double sandwich ELISA (Bio Rad, subisotyping k i t ) .
Results and Discussion Based on the repeated observation that GTPCH a c t i v i t y i s unstable in d i l u t e solution,
studies
of
the conditions
under which the a c t i v i t y
unstable or stable have been made. For t h i s ,
is
either
GTPCH a c t i v i t y was measured
after storage for 24 h at 4°C, -20°C or -70°C in l i v e r homogenate as well as in diluted
samples
in d i f f e r e n t
buffers
with and without
stabilizing
agents. Generally,
all
diluted
fractions
tested were very unstable,
freezing
of
these samples at -20°C eliminated even more a c t i v i t y than storage at 4°C. Lyophilization of the samples was not successful. The loss of a c t i v i t y the diluted
samples was p a r t i a l l y
avoided only by the addition of
in
large
amounts of bovine serum albumin, but not by DTE or 2-mercaptoethanol to the buffer.
In homogenate, the enzyme was found to be more stable in phosphate
buffer than in T r i s , therefore a 50 mM potassium phosphate buffer at pH 7.8 was chosen as basis solution for GTPCH extraction. Addition of glycerol to this buffer even increased the s t a b i l i t y of the enzyme, but did not cause an a l t e r a t i o n of a c t i v i t y . Almost no loss of a c t i v i t y was found in the ammonium sulfate fraction, and, when i t was necessary to store the enzyme between p u r i f i c a t i o n steps, the best way was p r e c i p i t a t i o n and storage of the p e l l e t at 0-4°C.
101
Additionally,
highly diluted samples were found to be f u l l y active
after
storage as a suspension in Sephadex G-200 superfine ( s f ) at 4°C.The a c t i v i ty from aliquots of t h i s suspension could e a s i l y be eluted over small G-25 columns. S l u r r i e s stored
of p u r i f i e d enzyme in G-200 sf and 10% glycerol
can be
several days at 0-4°C without l o s s of a c t i v i t y .
For longer time, rapid concentration and storage in 50% glycerol at -70°C was found to counter the l o s s of a c t i v i t y at l e a s t for 3 months. Since i t became cl ear that GTPCH s t a b i l i t y
i s dependent on concentration
and protein environment, and that l o s s of enzyme a c t i v i t y
i s a factor of
time, a p u r i f i c a t i o n procedure had to be developped, which i s f a s t , keeps the enzyme as concentrated as p o s s i b l e ,
avoids
freezing
steps or
longer
storage periods, and in which the main s t a b i l i z e r s , ammonium s u l f a t e ,
gly-
cerol and superfine dextran p a r t i c l e s , can be used. Thus, human l i v e r GTPCH was p u r i f i e d by 1. extraction with 50 mM phosphate b u f f e r , pH 7,8, containing 5% g l y c e r o l , 2. ammonium s u l f a t e
precipitation
between 30% and 40% saturation, 3. chromatography on Ultrogel
AcA 34 and
f i n a l l y , preparative i s o e l e c t r i c focussing on Sephadex G-200 superfine. The f i r s t two steps can be done in 1 day from a large batch of l i v e r , and the 40% ammonium sulfate p e l l e t can be stored at 4°C overnight or, i f not the whole batch i s processed further, a l i q u o t s can be stored at -20°C. Step 3 has the advantage that no desalting step ( d i a l y s i s , G-25) which causes l o s s of a c t i v i t y i s needed for the processing of the ammonium sulfate
fraction.
The enzyme i s eluted from the AcA 34 column in phosphate buffer containing 25% glycerol
and i s
running as a sharp peak j u s t behind the void volume.
This makes separation f a s t and removes proteins of lower molecular weight nearly t o t a l l y .
The AcA 34 pool containing GTPCH i s concentrated r a p i d l y
on an Amicon PM-10 u l t r a f i I t e r and a s l u r r y i s made of 50 mg Sephadex G-200 sf/ml protein s o l u t i o n . The s i u r r y can be stored at 4°C until i t i s aplied on a horizontal
preparative
isoelectric
focussing
gel
made of
Sephadex
G-200 s f , 10% (v/v) g l y c e r o l , and 2% (v/v) ampholine Τ 4-9. The dimension of the gel layer i s dependent on the amount of protein in the mixture, the loading capacity beeing 5-10 mg protein per ml gel suspension. GTPCH focusses at pH 5,6 =pl with high recovery of a c t i v i t y .
102
A purification
summary
of the GTPCH is given in Table 1. Analysis of the
fractions by SDS-polyacrylamid gel electrophoresis showed reduction of the complex the
protein mixture to a few bands. The major band is enriched during
purification
procedure,
beeing
a
protein
of
50Ό00
dal tons.
By
gel
filtration, an apparent molecular mass of 4 4 0 Ό 0 0 dal tons was estimated for the active enzyme. Thus, human GTPCH is a complex of 8 subunits.
Table 1
Purification of GTP-Cyclohydrolase I from Human Liver
Procedure
Total protein
Crude extract Ammonium sulfate
Total units
Specific activity
Yield
Purification
uU/mg prot.
%
fold
mg
uU
57 050
44 000
0.7
100
1
5 240
38 800
7.4
88
10
1 100
32 600
30.0
74
43
18 980
9 040.0
43
13 300
30-40 % Ultrogel AcA 34 IEF G-200 sf/
2.1
G-25 m pool
GTPCH I is purified from 300 g of human liver.
After isoelectric focussing, the enzyme is
eluted from the G-200 gel over Sephadex G-25 m, concentrated, substituted Hith glycerol to 50 X (v/v), and stored at -70°C.
The activity Is stable for 3 months.
1 uU = lpmol NTP/min at 37°C.
Recently, we were able to produce monoclonal antibodies against human GTPCH. For immunization the protein isolated by isoelectric 1
focussing was
used. Mixed with complete Freund s adjuvant, 20 ug were injected neously in each of 4 Balb/c mice. One month after the primary
subcuta-
immunization,
antigen in incomplete Freund's adjuvant was injected. Serum obtained after two additional
immunizations was tested for activity of specific antibodies
by Ouchterlony double diffusion and ELISA. The two mice with highest titers were
boosted with
days before well
antigen
fusion. The
as cloning
in 0.9%
NaCl
intraperitoneal ly one week and 3
fusion was achieved
in HT-medium
in PEG, and HAT-selection
by use of the limited dilution method
as
were
performed. Eleven monoclonal antibodies were obtained, two of IgM subclass, the others IgG^.
103
In ELISA against homogenous GTPCH from E.coli, 4 of the monoclonals showed activity. In western blotting, they bound against the 50'000 dal ton protein of the human enzyme. With these antibodies, an immunocytochemical method is under
investigation
to localize
staining
GTPCH in the stimulated
human
macrophages and T-cells. They may also be useful for enzyme studies on the molecular and gene level.
Acknowledgement This work was supported by the Swiss National
Science Foundation, project
No. 3.601-0.84 and No. 3.395-0.86. We are grateful Zurich, for the possibility to perform monoclonal
to Dr. H. Hengartner, antibody production in
his laboratory and Mr. U. Redweik for excellent technical assistance during isoelectric focussing experiments.
References 1.
Burg, A.W., G.M. Brown. 1968. J. Biol. Chem. 243, 2349.
2.
Yim, I.I., G.M. Brown. 1976. J. Biol. Chem. 251^, 5087.
3.
Cone, I.E., I. Plowman, G. Gurolf. 1974. J. Biol. Chem. 249, 5551.
4.
Jackson, R.J., T. Shiota. 1975. Biochim. Biophys. Acta 403, 232.
5.
Kohashi, Μ., T. Itadani, K. Iwai. 1980. Agric. Biol. Chem. 44, 271.
6.
Weisberg, Ε.P., J.Μ. 0'Donnell. 1986. J. Biol. Chem. 26^, 1453.
7.
Fukushima, K., W.E. Richter, Τ. Shiota. 1977. J. Biol. Chem. 252, 5750.
8.
Bellahsere, Z., J.L. Dhondt, J.P. Farriaux. 1984. Biochem. J. 217, 59.
9.
Blau, Ν., A. Niederwieser. 1983. Anal. Biochem. 128, 446.
10.
Niederwieser, Α., Ν. Blau, Μ. Wang, Ρ. Joller, Μ. Atares, J. GardesceGarcia. 1984. Anal. Biochem. 141, 208.
104
11.
Schoedon, G., J . Troppmair, A. Fontana, Ch. Huber, H.-Ch. A. Niederwieser: Eur. J . Biochem. ( i n p r e s s )
Curtius,
12.
B l a u , Ν., A. Niederwieser. 1986. Biochim. Biophys. Acta 880, 26.
13.
Schoedon, G., A. Niederwieser, H.-Ch. C u r t i u s : et al .: i n
14.
K ö h l e r , G., C. M i l s t i e n . 1975. Nature (Cond.) 256, 495.
preparation
DIHYDROMONAPTERIN TRIPHOSPHATE: OCCURRENCE, ANALYSIS, AND EFFECT O N 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 in vivo AND in vitro
N.Blau, P.Steinerstauch, U.Redweik, L.Kierat and A.Niederwieser+
K.Pfister,
G.Schoedon,
D i v i s i o n of Clinical Chemistry, Department of Pediatrics, U n i v e r s i t y of Zürich, CH-8032 Zürich, S w i t z e r l a n d
SUMMARY 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 synthase (PPH4S) f r o m h u m a n and salmon liver is inhibited by L-monapterin (L-threo-neopterin). D - M o n a p t e r i n as well as d i h y d r o and t e t r a h y d r o - L - m o n a p t e r i n h a v e no e f f e c t on PPH4S. Lowered biopterin excretion as well as induction of neopterin excretion in u r i n e of mice was o b s e r v e d after t r e a t m e n t with L - m o n a p t e r i n . Incubation of m y e l o m a cells w i t h L-monapterin indicates t h a t a p t e r i n d e f i c i e n c y can be induced in v i v o by inhibition of PPH4S. L-Monapterin is formed from dihydromonapterin triphosphate (MHaTP) after dephosphorylation and oxidation. MH2TP produced from dihydroneopterin triphosphate (NH2TP) by dihydroneopterin triphosphate 2 ' - e p i m e r a s e was separated as monapterin t r i p h o s p h a t e (MTP) by HPLC. Dihydroneopterin triphosphate 2'-epimerase from E. coli was p u r i f i e d b y ammonium sulfate precipitation, DEAE-Sephadex A25 chromatography, Sephadex G 1 5 0 gel f i l t r a t i o n and isoelectrofocusing on S e p h a d e x G200 SF.
INTRODUCTION L-Monapterin is the major pterin found in some microorganisms. R e m b o l d and Heinz (1) isolated this compound from cell lysates of E s c h e r i c h i a coli in 1971 b u t its
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
106 biological function is still unknown. The function of m o n a p t e r i n in C o m a m o n a s sp. w a s p r o p o s e d b y G u r o f f and R h o d a s t o b e t h a t of a c o f a c t o r of p h e n y l a l a n i n e hydroxylase (2). They a l s o d e s c r i b e d the occurrence of a dihydroform of m o n a p t e r i n in t h i s bacteria. U r u s h i b a r a et al. (3) suggested t h a t t h e c y c l i c m o n o p h o s p h a t e of m o n a p t e r i n m i g h t b e i n v o l v e d in m e t h a n o l oxidation by a non-specific primary alcohol dehydrogenase
in
Bacterium
methylococcus
capsulatus.
M o n a p t e r i n h a s b e e n r e p o r t e d t o occur a l s o in S e r r a t i a i n d i c a (4) and in P s e u d o m o n a s roseus fluorescens (5), however in n e i t h e r r e p o r t t h e b i o l o g i c a l s i g n i f i c a n c e w a s stated. A n u m b e r of a u t h o r s (6,7,8) s u g g e s t e d t h a t t h e c y c l i z a t i o n of D-erythro-neopterin monophosphate to 2', 3 ' - c y c l i c - n e o p t e r i n monophosphate in some m i c r o o r g a n i s m s may result in an i n v e r s i o n of t h e 2 ' - h y d r o x y 1 g r o u p of t h e p r o p y l side chain of n e o p t e r i n t o y i e l d t h e L - t h r e o epimer. However, later on it w a s v e r i f i e d t h a t d i h y d r o n e o p t e r i n triphosphate is the initial pterin formed from GTP and t h a t the initially r e p o r t e d c y c l i c m o n o p h o s p h a t e of n e o p t e r i n a p p e a r s t o b e an artifact produced during purification procedures when an a l k a l i n e s o l v e n t is used. A n i n t e r e s t i n g p o i n t is t h e o c c u r r e n c e of m o n a p t e r i n in h u m a n tissues and urine but neither the biosynthesis nor its b i o l o g i c a l f u n c t i o n in m a m m a l i a n s was explained. Monapterin like n e o p t e r i n in u r i n e is m o s t l y p r e s e n t in its d i h y d r o form and t h e r a t i o of m o n a p t e r i n t o n e o p t e r i n is u s u a l l y about 1:10. In d i f f e r e n t b l o o d cells this r a t i o v a r i e s from 1:10 to 1:3 (9). H o w e v e r , w e h a v e n o p r o o f t h a t its f o r m a t i o n occurs n o n e n z y m a t i c a l l y f r o m d i h y d r o n e o p t e r i n or e n z y m a t i c a l l y from dihydroneopterin triphosphate. We just have some observations that monapterin may possibly be formed from d i h y d r o n e o p t e r i n if u n t r e a t e d u r i n e s are s t o r e d for a longer p e r i o d of time. Furthermore, w e n e v e r n o t i c e d t h a t m o n a p t e r i n w a s f o r m e d e n z y m a t i c a l l y in a n y m a m m a l i a n m a t e r i a l . Ten y e a r s ago, H e i n e and B r o w n (10) d e s c r i b e d in E. coli an enzyme, named D-erythro-dihydroneopterin triphosphate 2'-epimerase, that catalyzes the c o n v e r s i o n of N H ^ T P to
107
MHaTP. They were able to show that, all three phosphate residues of the substrate are retained in the product and that the product is of the L-threo configuration but they were not able to separate the phosphorylated product from the substrate chromatographically. Recently, we noticed that different preparations of NH2TP which we use as a substrate in the PPH4S assay show different activities. We were surprised that some preparations of NH 2 TP, which we synthesized enzymatically from GTP by GTP cyclohydrolase I, contained up to 50% MH 2 TP. In this paper we describe the separation of M H a T P from N H 2 T P by HPLC after oxidation with iodine, as well as the effect of M H 2 T P and its metabolites on BH4 biosynthesis in vitro and in vivo. The purification of N H 2 T P 2'-epimerase from E. coli is also described.
MATERIALS AND METHODS Most of the pterins were purchased from Dr. B. Schircks Laboratories, 8645 Jona, Switzerland. D-Monapterin was synthesized by Prof. M. Viscontini, and dihydroand tetrahydro monapterin were prepared by reduction with Pd/H 2 . N H 2 T P was synthesized with GTP cyclohydrolase I immobilized on Sepharose 4B (11). Measurement of PPH4S and sepiapterin reductase activities were performed as described earlier (12). The HPLC system for measurement of pterins was the same as described elsewere (13). Isoelectrofocusing was performed on Desaga flat bed electrophoresis unit (Heidelberg, GFR). Gel (8 mm thickness) consists of Sephadex G200 SF with 10% glycerol and 2% Servalyt T4-9. Electrofocusing was performed at 5 W for 100 min and at 7 W for 170 min at 3"C. 5-mm slices of the gel were assayed for enzyme activity. HPLC of neopterin and monapterin phosphates The HPLC analytical procedure was essentially as described earlier (14), except that the RCM system with Guard Pak C18 + Nova Pak C18 5ju (5 χ 100 mm) from Waters was 'used.
108 I s o p r o p a n o l in m o b i l e p h a s e w a s o m i t t e d a n d f l u o r e s c e n c e m e a s u r e d on a H i t a c h i F 1000 f l u o r o m e t e r . A s s a y for N H 2 T P
was
2'-epimerase
T h e a s s a y for N H 2 T P 2 ' - e p i m e r a s e a c t i v i t y w a s based on the H P L C m e a s u r e m e n t of M T P ( o x i d a t i o n p r o d u c t of MH2TP) formed f r o m N H 2 T P . The p r o c e d u r e of H e i n e and B r o w n (10) was u s e d t o generate M H 2 T P from NH2TP. The reaction mixture (100 |ul) c o n t a i n e d 25 μ Μ N H 2 T P , 5 m M M g C l a , 1.4 m M EDTA, 0.1 g/1 BSA, and 50 jul e n z y m e preparation in 25 m M 2-(N-morpholine) e t h a n e s u l f o n i c acid b u f f e r p H 6.25. The r e a c t i o n p r o c e e d e d at 3 7 e C for 15 m i n in t h e d a r k and w a s terminated by the a d d i t i o n of 10 jul of a 1 Μ HCl s o l u t i o n c o n t a i n i n g 130 iodine and 2% KI. A f t e r s t a n d i n g at r o o m t e m p e r a t u r e for 15 min, p r o t e i n s w e r e r e m o v e d b y c e n t r i f u g a t i o n and e x c e s s iodine w a s r e d u c e d b y a d d i t i o n of 10 μ ΐ 1% a s c o r b i c acid. The c o n t e n t of M T P w a s a n a l y z e d in 5 /al of s u p e r n a t a n t b y HPLC. The volume of t h e e n z y m e p r e p a r a t i o n in t h e a s s a y m i x t u r e was c h o s e n so that the ratio MTP/NTP at t h e end of incubation never e x c e e d e d 1.0. P u r i f i c a t i o n of N H 2 T P
2'-epimerase
The enzyme was purified from Escherichia coli using m o d i f i c a t i o n s of t h e p r o c e d u r e of H e i n e a n d B r o w n (10). The protein precipitate obtained after fractionation between 50 and 8035 a m m o n i u m sulfate was dissolved in 60 ml 50 mM p o t a s s i u m p h o s p h a t e buffer, pH 8.0. The concentrated and dialyzed enzyme preparation was applied to a DEAE-Sephadex A 2 5 c o l u m n (5 χ 30 cm) equilibrated with 0.1 Μ Tris-HCl buffer, pH 8.0 (starting buffer). NHaTP 2'-epimerase was e l u t e d w i t h 2 0 0 0 ml of a linear g r a d i e n t t o 0.5 Μ LiCl in t h e s a m e b u f f e r at a flow rate of 100 ml/h. F r a c t i o n s b e t w e e n 520 and 9 6 0 ml containing NH2TP 2'-epimerase activity were pooled, c o n c e n t r a t e d t o 16 ml on an A m i c o n Y M - 1 0 u l t r a f i l t e r , and a p p l i e d t o a Sephadex G150 column (2.6 χ 100 cm) e q u i l i b r a t e d w i t h 0.1 Μ p o t a s s i u m p h o s p h a t e buffer, pH 8.0. T h e p r o t e i n s w e r e e l u t e d w i t h t h e same b u f f e r at a flow rate of 10 m l / h and 5 ml f r a c t i o n s w e r e collected. The fractions
109
53 to 66 with NHaTP 2'-epimerase activity were combined and concentrated to a volume of 5.8 ml. An aliquot of the fraction (2.5 ml) was concentrated to a volume of 0.9 ml on an Amicon YM-10 ultrafilter and applied to a Sephadex G200 SF gel prepared for isoelectrofocusing as described above. The gel slide at 8 to 9 cm (pH 7.0 - 6.4) was taken out and 2 ml of 1 Μ NaCl were added. The enzyme was eluted from gel with 0. 5 Μ NaCl in 10 mM potassium phosphate buffer, pH 7.0 and washed from ampholyte on a Sephadex G25m column (1.6 χ 26 cm) equilibrated with 10 mM potassium phosphate buffer, pH 7.0. The eluate was concentrated on an Amicon YM-10 ultrafilter to a volume of 2.8 ml and stored at -20°C.
RESULTS AND DISCUSSION We modified our HPLC system for the separation of neopterin phosphates and guanine nucleotides so that we were able to separate neopterin phosphates from monapterin phosphates (Fig. 1).
1 I
0
2 |V.
Η 10
L· ain
Fig. 1 HPLC of neopterin and monapterin phosphates l=neopterin, 2=monapterin, 3=NMP, 4=MMP, 5=NDP, 6=MDP, 7=NTP, 8=MTP Omission of isopropanol in the mobile phase improved the separation of isomers and use of the shorter column enabled the separation in less than 20 min. However, separation of
110
d i h y d r o f o r m s of n e o p t e r i n and m o n a p t e r i n t r i p h o s p h a t e is not p o s s i b l e w i t h this system. Neopterin and monapterin t r i p h o s p h a t e o b t a i n e d after incubation of N H 2 T P with NH2TP 2'-epimerase and s u b s e q u e n t oxidation w i t h iodine were h y d r o l y z e d at room t e m p e r a t u r e to the c o r r e s p o n d i n g d i - , and m o n o p h o s p h a t e s y i e l d i n g finally n e o p t e r i n and m o n a p t e r i n as hydrolysis p r o d u c t s (Fig. 2). α min
b min
Ι-
-Λ
20 nln
10 mir
V
60 nln
80 min
V| 1\ -.-/Λ...
Fig.2 Hydrolysis of neopterin and m o n a p t e r i n trip h o s p h a t e w i t h alkaline phosphatase. Numbers of the peaks refer to compounds in Fig.1 M H z T P was d e t e c t e d after incubation of GTP w i t h different preparations of G T P cyclohydrolase I from E. coli. P r e p a r a t i o n s of N H 2 T P containing d i f f e r e n t amounts of MH2TP were u s e d in the PPH4S assay and found to p r o d u c e variable results. These observations suggested t h a t MH?TP or one of its metabolites may effect the tetrahydrobiopterin biosynthesis. To find out at w h i c h step the inhibition occurs we started a n u m b e r of experiments by incubating monapterin and its reduced forms w i t h enzymes involved in the biosynthesis of tetrahydrobiopterin. Incubations with enzymes p u r i f i e d from h u m a n and salmon liver showed t h a t monapterin but n o t d i h y d r o m o n a p t e r i n and t e t r a h y d r o m o n a p t e r i n inhibit the a c t i v i t y of PPH4S (Tab. 1). P P H 4 S from salmon liver was inhibited to a lesser e x t e n t and t h e r e was no effect on
111
sepiapterin reductase from human liver. M H a T P present in some substrate (NH 2 TP) preparations shows the same effect but so far we are not able to say if it is an effect of its oxidized form MTP or M H 2 T P itself. TABLE 1 EFFECT OF SOME PTERINS ON ACTIVITY OF 6-PYRUVOYL TETRAHYDROPTERIN SYNTHASE AND SEPIAPTERIN REDUCTASE
Compound
Concentration jjmol/l
none
-
Enzyme activity (%) PPH4S PPH4S SR human salmon human 100
100
100
45
100
L-Monapterin
24
5
L-H 2 -Monapterin
24
100
-
-
L-H4-Monapterin
24
100
-
-
D-Monapterin
24
100
-
L-MH 2 TP
64
79
-
PPH^S-activity SR-activity
100
-
: pmol BfU/imin· mg protein) : pmol S red./(min-mg protein)
Incubations of L-monapterin with mouse myeloma cell lines X63 Ag8 which are not able to produce tetrahydrobiopterin and in which dihydropterin is the main metabolite showed significant decrease in intracellular pterin production (Tab. 2). There was no effect when incubations were performed with D-monapterin. These experiments indicated that in vivo the inhibition of PFH4S might induce a deficiency of pterins.
112
TABLE 2 I N H I B I T I O N O F P T E R I N B I O S Y N T H E S I S IN M O U S E M Y E L O M A C E L L L I N E S BY L - M O N A P T E R I N
Cell line X63 Ag8 incubated with
N u m b e r of cells
Ρ Μ p m o l / 1 0 m i o cells
IMDM
17 m i o
25
IMDM + ImM D - M o n a p t e r i n
15 m i o
27
299
IMDM + ImM L - M o n a p t e r i n
12 m i o
10
248
Medium
: IMDM + 10% F C S + a n t i b i o t i c s + m e r c a p t o e t h a n o l
Incubation
: 6 d a y s at 3 7 * C and 5.5% C 0 2
To investigate further the effect of monapterin on 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 in v i v o a g r o u p of 5 mice were treated for three days with monapterin. 1.15 mg of m o n a p t e r i n in 0.1 Μ NaCl, pH 7.3, w e r e i n j e c t e d into a C57 BL/6 male mouse for t h r e e days, and 12-h u r i n e s were collected. A f t e r t h e m o n a p t e r i n d o s e t h e m i c e w e r e limp and t h e i r c o a t w a s s t a n d i n g up. O n e m o u s e d i e d on t h e f o u r t h day and its blood, liver and brain were collected. The serum p h e n y l a l a n i n e levels r e m a i n e d u n c h a n g e d u p o n t r e a t m e n t with m o n a p t e r i n . U r i n a r y b i o p t e r i n d e c r e a s e d r a p i d l y to a b o u t 25% of t h e initial value, and n e o p t e r i n w h i c h n o r m a l l y c o u l d not be d e t e c t e d in m o u s e was e x c r e t e d 12 h o u r s after the first i n j e c t i o n of m o n a p t e r i n (Fig. 3). This e x p e r i m e n t s h o w e d for t h e f i r s t t i m e t h a t m o n a p t e r i n can lower u r i n a r y e x c r e t i o n of b i o p t e r i n in mice. Inhibition of PPH Ζ •t
«λ aj ι c >.-σ — "" Ίο φ ·· c ο ω Ο Φ 3 _ ω I ,— J3 I— Q-U- -Q Ο. O C —' « I 1/1 c
C O et
ο ζ 3: ·-• ι— ο: «r ι X Ο. s ι [3D
ϊ Ο
φ
paz L LXi|do^ [
Ό ' -
I
χ: ο
C ·> -L ϊ1- +-* Φ >1 Sφ ·— Ο- φ C Ιο Φ -Ο U LLJ ε • TD I— ΙΛ φ >- σι Ο C ο^-Οί . Ο Ε 3: -α > LlJ _Q Ο Οί ·
ßui
Od ΓΟ >3:
ιΛ c
J. φ ο < ο >- TD Li- Ο U. Ο
>Ο ο C O ο Σ : Ό Ο ο α·.
/ßd
• ο -σ.
ο Ε -Μ Ο S- SU- + φ -> ΗLiJ (Ο >· >ι ΟΊ^.1— Ο _1 >> I 3: .-• ε οο α- ο ς: ζ +-> >- Ο 84% and 98%,
of these p t e r i n s
in t h e i r
BIOPTERIN
reduced
forms
respectively).
As e v i d e n t from T a b l e 4 , more than 50% o f the n e o p t e r i n , p t e r i n and b i o p t e r i n fluids
exists
present
detection,
the one hand not d e t e c t a b l e
tissue.
moiety p r e s e n t blastic
10. T h i s
acidic conditions biopterin
is
These reduced p t e r i n s
and chemical
The f r e q u e n t l y
concerns
conversion
used
and of i t s
on
thereeven CSF
biopterin
(e.g.
1ympho in
the
are very s e n s i t i v e even under
to
less
temperatures.
(11,12,13,14,15,16,17,18)
"extraction"
of
reduced forms from u η ο χ i d i ζ e d b i o l o g i c a l
samples by a u t o c l a ν i ng ( a p p r o x . , bioassay with C r i t h i d i a of reduced p t e r i n s .
is
the
known to e x i s t
reactions,
and at i n c r e a s e d
HPLC
in part
in p a r t i c u l a r
i n C S F , u r i n e or i n t r a c e l l u l a r l y
tetrahydro-form. oxidation
detection markedly,
biopterins)
Using
samples and
On the o t h e r h a n d , most o f the
and l y m p h o c y t i c
biological
the reduced p o r t i o n
in n o n - o x i d i z e d
the a n a l y t i c a l
by a f a c t o r of about and t o n s i l
and i n
i n the d i h y d r o - or t e t r a h y d r o - f o r m .
methods w i t h f l u o r e s c e n c e fore decreases
intracellularly
mona-
10 min at
fasciculata
leads
12 0°C) p r i o r to some
(Note t h a t some p t e r i n s
to
conversion
o t h e r than
bio-
132 pterin/reduced
biopterins
pterin, sepiapterin, thro-neopteriη
(34)
in
). The m e c h a n i s m
tions ported
buffer
in d e t a i l
18%
(!) of o r i g i n a l means
after
less
above
the
as
levels
(after
detection
de-
- 18) at
reac-
forms)
temperatures.
et
in As
re-
biopterin
moiety
pH 4 . 5 , a n d
only
was
converted
autoclaving
whole
limit.
less
than
of l y m p h o b l a s t i c
blood)
10 - 20%
lymphocytic
of u n o x i d i z e d w h i t e
would
In t h i s
or
be at or
connection can h a r d l y
cells
somewhat
intracellular be
demonstrated
significant.
Occurence
of m o n a p t e r i n
We h a v e a l r e a d y neopterin) blood from We
the
5 - 6 ml
of
and
forms.
that even
alterations
reactions
conversion
( 2 1 ) , 55% of the (11
J}-ery-
and Zeitler
a m o u n t of t e t r a h y d r o b i o p t e r i n
stable
than
(20)
on the
increased
autoclaving
tetrahydrobiopterin from
et a l .
schemes
and at
by M i l s t i e n
destroyed
to o x i d i z e d ,
some
by P f l e i d e r e r
forms; biopterin/reduced
systems
was
This
Fukushima
demonstrated
(neopterin/reduced
different
L.-erythro-neo-
of a u t o x i d a t i o n
was e l u c i d a t e d
(19), likewise
al . (4) h a v e
Crithidia-active:
6-hydroxymethyl pteriη, monapterin,
of t e t r a h y d r o b i o p t e r i n scribed
are
and
reported its
know
diseases
nothing
monapterin
about
in h u m a n
in h u m a n shima thetic
in rat
urine
in p l a s m a
in h e a l t h y the
liver
by F u k u s h i m a
and
patients
of
was
. As e a r l y
proposed
that
the
pathway
from
GTP to t e t r a h y d r o b i o p t e r i n
(28).
and neopterin
Twelve years
concentrations
tetrahydrobiopterin
were
deficiency
reported
in n e w b o r n s
the
described
as
1970,
in
of the
are
urinary for
of
first
metabolites
increased
role
phenylalanine
some
(29).
Fuku-
biosyn-
dihydroneo-
( d i h y d r o m o n a p t e r i n ) , and
later,
suffering
et al . r e p o r t e d
as a c o f a c t o r
intermediary
peripheral
and b i o c h e m i c a l
cells.Iwai
et a l .
of the
(threo-
.
(27). M o n a p t e r i n
pterin, threo-dihydroneopteriη pterin
subjects
biosynthesis
be a c t i v e
of m o n a p t e r i n
and cells
(2-4, 9, 22-26)
and animal
reduced monapterinto hydroxylase
on the o c c u r e n c e
levels
and b o n e m a r r o w various
( t h r e o - n e o p t e r i η ).
sepia-
monapterin cases
of
133 In o u r urine
study
on n o r m a l
(see T a b l e s
and monapterin compartments found
human
2 - 4 ) , the
as well
is e v i d e n t .
Analogous
findings
were
malignant
diseases
(tumor,
monapterin
simultaneous
concentrations
were accompanied
than
obtained
in m o s t
levels
cells,
as t h e i r n e a r l y
investigated
in h i g h e r
blood
before
occurrence
constant
in p a t i e n t s
by a n a l o g o u s
and during
pancreas
and
cyte
fraction,
The f a c t
that
threo-isomer systems Table
the
ago
EPIMERASE
which
results
moiety ative
type
neopterin
(L-) would
related
intermediates
(substrate,
rather
in the
now t h a t the reaction
group
a hydroxymethyl
The occurrence a n d e f f e c t tetrahydrobiopteriη
and
its
the
cell
and
(see
reported
cell
of
systems
phosphorylated
neopterin The
of
deriv-
epi-
L-monapterin
occuring
euglena-
steps
cascade
at
the
between
di-
L^-tetrahydrobiopterin:
phosphate-eliminating triphosphate)
reaction
results
at C - 3 ' . H o w e v e r ,
group
leuco-
reaction
reduction
biosynthesis and
beta-
reaction
occurs
before
in the
formation
(30);
phosphate-eliminating
of a m e t h y l
animal
formation by
the
caused
-as
triphosphate).
than
the
impressive
an e n z y m i c
the
in
peripheral
f o r us
to the n a t u r a l l y
dihydroneopteriη
reduction
is
of a r e d u c e d
explain
neopterin
cytostatics
in all
f r o m an a p p r o p r i a t e
triphosphate
It is a s s u m e d
b) The
formation
from ^ - n e o p t e r i n
hydro
obvious
D-dihydroneopterin
reaction
of
identical
to s u g g e s t
with
neopterin
investigated
it was q u i t e
from
(26).
of b o t h
nearly
in
affects
in the
urine
portion
the
always
hyperglykemia,
in m o n a p t e r i n - f o r m i n g
in the
level
the
fluids/urine
is c l o s e l y
pterin)
and
was
(22, 24)-
(probably
(which
any
reduced
of m o n a p t e r i n
merization
a)
plasma
4). T h e r e f o r e ,
induces
in b o t h p t e r i n s
monapterin
and body
some y e a r s the
the
in
suffering
treatment
cells
decrease
was
neopterin
alterations
Proglicem, which
a significant
of
ratio
alterations
(22-25).
human
and
monapterin.
and/or antibiotics in the
fluids
Neopterin
leukemia):
cases
body
( - C H ^ O H ) at
monapterin
has
C-3 .
of d i h y d r o m o n a p t e r i η
biosynthesis
still
1
in v i t r o
and
triphosphate in v i v o
is
on
dis-
134
cussed
in t h i s
volume e l s e w h e r e
There have been many r e p o r t s (or i t s
reduced f o r m s )
the p o t e n t i a l roles
(35).
on the o c c u r r e n c e of
in several
importance
of t h i s
microorganisms.
investigated,
Methylococcus hol
is
dehydrogenase
the c y c l i c
(32).
In S e r r a t i a
m e t h y l p t e r i n were i d e n t i f i e d merization
triphosphate pterin
(33)
epimerase ),
i n E. c o l i
of J_-difor
alco-
p h o s p h a t e and 6 - h y d r o x y from GTP
(27).
r e p o r t e d an enzyme-dependent to
epi-
dihydromona-
( ' JD-ery t h r o - d i h y d r o n e o p t e r i η
the b i o c h e m i c a l
remained
in
i n d i c a j ) - e r y t h r o - n e o p t e r i η,
as p r o d u c t s
i n E. c o l i 1
( 3 1 ) , and
as a c o - f a c t o r
of j)-di h y d r o n e o p t e r i η t r i p h o s p h a t e
pterin triphosphate
micro-
i n the
monophosphoester
t h o u g h t to f u n c t i o n
Brown et a l .
two o f the
to t y r o s i n e
L^-mona p t e r i η , J.-mona p t e r i η 2 ' , 3 ' - c y c l i c Although
metabolic
as a c o - f a c t o r
of p h e n y l a l a n i n e
capsulatus
hydromonapteriη
indicates
i n Comamonas s p . , a reduced form of
m o n a p t e r i n was d e c r i b e d to f u n c t i o n enzymic h y d r o x y l a t i o n
This
p t e r i n , although
f o r m o n a p t e r i n have been assumed i n o n l y
organisms
monapterin
f u n c t i o n of mona-
unknown.
Conclusions ( 1 ) Human bone marrow p r e s e n t e d h i g h e r concentrations (2)
In peripheral
than p e r i p h e r a l blood c e l l s ,
found to be a p p r o x i m a t e l y (3)
Not o n l y b i o p t e r i n , (e.g.,
(4)
CSF, t o n s i l
within
nearly
identical
ii)
nearly
constant
b i o p t e r i n was
the same
range.
in t h e i r
reduced
were
forms
lymphocytes).
As an i n t e r p r e t a t i o n enzymic
cells.
investigated,
NEOPTERIN and MONAPTERIN
i)
pteridine
n e o p t e r i n and m o n a p t e r i n
m a i n l y
In each of the compartments threo-isomers
blood
intracellular
but a l s o
found to be p r e s e n t
intracellular
portions ratios
of t h e i r
the
presented reduced
forms,
(neopterin/monapteriη;
of these f i n d i n g s
N/M).
we s u g g e s t an
r e a c t i o n of the EPIMERASE type between
neopterin triphosphate
erythro-
and L - d i h y d r o m o n a p t e r i η
D-dihydrotriphosphate.
135
References 1. Huber, Ch., J.R. Batchelor, D. Fuchs, Α. Hausen, A. Lang, D. Niederwieser, G. Reibnegger, P. Swetly, J. Troppmair. H. Wächter. 1984. J. Exp. Med. J60, 310. 2. Andondonskaja-Renz, B., H.-J. Z e i t l e r . 1986. In: Chemistry and Biology of Pteridines (B.A. Cooper, V.M. Whitehead, eds.). De Gruyter, Berlin-New York, p. 431. 3. Zeitler, H.-J., B. Andondonskaja-Renz. 1987. In: Biochemical and C l i n i cal Aspects of Pteridines (W. Pfleiderer, J.A. B l a i r , H. Wächter, eds.) De Gruyter, Berlin-New York. Vol 5 (in press). 4. 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, D. McCormick, eds.). Academic Press, Orlando, USA. Vol. 122, p. 273. 5. Pertoft, H., A. Johnsson, Wärmegärd, Β., R. S e i j e l i d . 1980. J. Immunol. Methods 33, 221. 6. Gutierrez, C., R.R. Bernabe, J. Vega, M. Kreisler. 1979. J. Immunol. Methods £9, 57. 7. Ulmer, A.J., H.D. Flad. 1979. J. Immunol. Methods 30, 1. 8. Gmelig-Meyling, F., Τ.Α. Waldmann. 1980. J.Immunol. Methods 33., 1. 9. Zeitler, H.-J., B. Andondonskaja-Renz, G. Küther, A. Struppler. 1986. In: Chemistry and Biology of Pteridines (B.A. Cooper, V.M. Whitehead, eds.). De Gruyter, Berlin-New York, p. 251. 10. Fukushima, T., J.C. Nixon. 1980. Anal. Biochem. H)2,
176.
11. Ziegler, I . 1985. In: Biochemical and Clinical Aspects of Pteridines (H. Wächter, H.Ch. Curtius, W. Pfleiderer, eds.). De Gruyter, BerlinNew York, Vol. 4, p. 347. 12. Fink, M., U. Jehn, W. Wilmanns, I . Ziegler. 1982. In: Biochemical and Clinical Aspects of Pteridines (H. Wächter, H.Ch. Curtius, W. Pfleiderer, eds.). De Gruyter, Berlin-New York, Vol. 1, p. 241. 13. Ziegler, I . , M. Fink, W. Wilmanns. 1982.
Blut 44,
231.
14. Ziegler, I . , H.J. Kolb, U. Bodenberger, W. Wilmanns. 1982. Blut 44, 261. 15. Fink, M., U. Jehn, W. Wilmanns, H. Rokos, I . Ziegler. 1983. In: Biochemical and Clinical Aspects of Pteridines (H.Ch. Curtius, W. Pfleiderer, H. Wächter, eds.). De Gruyter, Berlin-New York, Vol. 2, p. 223. 16. Fink, Μ., I . Ziegler, H. Rokos. 1985. In: Biochemical and Clinical Aspects of Pteridines (H. Wächter, H.Ch. Curtius, W. Pfleiderer, eds.). De Gruyter, Berlin-New York, Vol. 4, p. 387. 17. Fink, Μ., I . Ziegler, H.J. Kolb, K. Demtröder, V. Nüssler. 1987. 1th Workshop on Unconjugated Pterins and Related Biogenic Amins. February 28 - March 7, Flims, Switzerland. 18. Fink, Μ., V. Nüssler, Κ. Demtröder, Ε. Höniges, I . Ziegler, Μ. Goldberg. 1987. 6th Winter Workshop on Biochemical and Clinical Aspects of Pteridines. February 14-21, St.Christoph/Arlberg, Austria. (See also this volume).
136
19. Pfleiderer, W.. 1975. In: Chemistry and Biology of Pteridines (W. P f l e i derer, ed.). De Gruyter, Berlin-New York, p. 941. 20. Fukushima, Τ., J.C. Nixon. 1979. In: Chemistry and Biology of Pteridines (R.L. K i s l i u k , G.M. Brown, eds.). Elsevier, North Holland, p. 31. 21. M i l s t i e n , Sh.. 1983. In: Biochemical and Clinical Aspects of Pteridines (H.Ch. Curtius, W. Pfleiderer, H. Wächter, eds.). De Gruyter, Berlin-New York, Vol. 2, p. 65. 22. Andondonskaja-Renz, B., H.-J. Zeitler. 1984. In: Biochemical and C l i n i cal Aspects of Pteridines (W. Pfleiderer, H. Wächter, H.Ch. Curtius, eds.). De Gruyter, Berlin-New York, p. 295, Vol. 3. 23. Andondonskaja-Renz, B., H.-J. Zeitler. 1985. In: Biochemical and C l i n i cal Aspects of Pteridines (H. Wächter, H.Ch. Curtius, W. Pfleiderer, eds.). De Gruyter, Berlin-New York, Vol. 4, p. 559. 24. Z e i t l e r , H.-J., B. Andondonskaja-Renz. 1984. In: Biochemical and C l i n i cal Aspects of Pteridines (W. Pfleiderer, H. Wächter, H.Ch. Curtius, eds.). De Gruyter, Berlin-New York, Vol. 3, p. 313. 25. 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, ed.). A.R. L i s s , Inc., New York, (in press). 26. Z e i t l e r , H.-J., B. Andondonskaja-Renz. 1985.
(Unpublished data).
27. Iwai, Κ., M. Kobashi. 1975. In: Chemistry and Biology of Pteridines (W. Pfleiderer, ed.). De Gruyter, Berlin-New York, p. 341. 28.
Fukushima, T.. 1970. Arch. Biochem. Biophys. 139, 361.
29. Niederwieser, Α., A. Matasovic, W. Staudenmann, Μ. Wang, H.Ch. Curtius. 1982. In: Biochemical and Clinical Aspects of Pteridines (H. Wächter, H.Ch. Curtius, W. Pfleiderer, eds.). De Gruyter, Berlin-New York, Vol. 1, p. 293. 30. S. Ghisla. 1987. 1th Workshop on Unconjugated Pterins and Related Biogenic Amines. February 28-March 7, Flims, Switzerland. (See this volume). 31. Guroff, G., C.A. Rhoads. 1969. J. Biol. Chem. 244, 142. 32. Urushibara, T., H.S. Forrest, D.S. Hoare, R.N. Petel. Biochem. J. 125, 141.
1971.
33. Brown, G.M., J. Yim, Y. Suzuki, M.C. Heine, F. Foor. 1975. In: Chemistry and Biology of Pteridines (W. Pfleiderer, ed.). De Gruyter, Berlin-New York, p. 219. 34. Nixon, J.C.. 1985. In: Folates and Pterins (R.L. Blakley, St.J. Benkovic, eds.). J. Wiley&Sons, Inc., New York, Vol. 2 (Chemistry and Biochemistry of Pterins), p. 1. 35. Blau, Ν., P. Steinerstauch, G. Schoedon, R. Redweik, A. Niederwieser. 1987. 1th Workshop on Unconjugated Pterins and Related Biogenic Amines. February 28 - March 7, Flims, Switzerland. (See this volume).
MODIFIED
PTERIPINE
LINES
DURING
Seidl 1 ,
J. I.
1
AND
für
für
Ileinschad1 ' ·
Ch.
Experimentelle
D-8000
Institut
Mainz,
TRANSFORMED
CELL
SHOCK
Strahlen
strafte 61, 2
IN
and
1
Institut
schaft
HEAT
Przyby 1 sk i 2 ,
M.
Ziegler
SYNTHESIS
für
und
2,
Gesell-
Landwehr-
FRG
Organische 18-20,
der
Unweltforschung,
München
Becherweg
HSmatologie
Chemie
D-6500
der
Mainz,
Universität
FRG
Introduction
A
pteridine
found
to
lignant a
binding
accumulate diseases
chromophoric
guanidine that
the
nate
by
cell
from
lines
over,
we
and have
to
sponse set
of
certain *New
is
of
its
cells
proteins stages
address:
be
of
cell
to
normal folate
found
shock
In
the
pteridine
cells
this
is
is
differentiation Mannheim
in
trans-
(5)
origi-
study
we
cleavage.
have More-
characterize in
heat
normally
Boehringer
this
by 6 Μ
indicated
pteridines
biogenesis.
heat
which
with
lines.
In
by
ma-
characterized detached
pteridine.
chemically
induction
was
with
analysis a
that
and
(AGPH)
patients
that
postulated
its
to
is
show
typically
elucidate
studied
was
claimed
begun
which
AGPH could
cleavage.
this
have
pteridine
we
(2,3,4)
folate
reinvestigated
of
. Spectral
transformed been
glycoprotein
blood
group
experiments
earlier
formed
which
hydrochlorid
synthesized had
the
( 1 ) . This
group
chromophoric
following It
ofi-acid in
malignant
the
cells
Additional1y, shock, known
become (for
since
to
induce
active review
GmbH,
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
Werk
we rea
during see
6).
Penzberg
138
Material
and
methods
H e L a , H T - 2 9 a n d 2 3 9 c e l l s w e r e c u l t u r e d in M E M w i t h Ι Ο * N B S a n d 1 0 * F C S , r e s p e c t i v e l y . R e h , HL 6 0 a n d T 4 7 D w e r e g r o w n in R P M I w i t h 1 0 * F C S . To study f o l a t e m e t a b o l i s m , medium folate was rep l a c e d by 1 4 C - f o l a t e (Amersham; final concentration 1,5μΜ, specific activity lpCi/18 nmol). H e a t s h o c k w a s p e r f o r m e d by c u l t i v a t i n g t h e c e l l s a n d b a c t e r i a at 4 3 · C f o r 4 h o u r s . R e v e r s e p h a s e H P L C d e t e r m i n a t i o n of p t e r i d i n e s a f t e r acidic iodine oxidation is described in (7). The amount of pterin X was calculated by assuming a f l u o r e s c e n c e i n t e n s i t y of b i o p t e r i n . Fast atom bombardment (FAB) mass spectra were obtained with a modified Finnigen MAT-312 spectrometer, equipped with a h i g h f i e l d laminated magnet system and extended analyzer. A thermal Cesium primary ion source (AMD I n t e r t r a , B e e k e l n / F R G ) w a s e m p l o y e d and operated at ca. 1400 mA and 4.5 kV (relative to s o u r c e p o t e n t i a l ) . A l t e r n a t e a c q u i s i t i o n of p o s i t i v e and negative ion spectra was carried out using a post-acceleration / ion conversion dynode system (AMP) placed in—line before the 17-stage electron m u l t i p l i e r , e m p l o y i n g a d y n o d e v o l t a g e of + 8 kV f o r negative conversion. Lyophilized s a m p l e s of t h e c h r o m a t o g r a p h i c a l l y isol a t e d p t e r i n X of a p p r o x . 10 μ β w e r e d i s s o l v e d in c a . 5 μ ΐ m e t h a n o l : IM H C l ( 5 : 1 ) , a n d l - μ ΐ a l i q u o t s w e r e a d m i x e d t o 0 . 5 μ ΐ of g l y c e r o l or t e t r a e t h y l e n e g l y c o l (TEG) as matrix substance. After brief treatment in an u l t r a s o n i c b a t h , t h e r e s u l t i n g , n e a r l y homogenous s o l u t i o n w a s a p p l i e d on a 2 m m 2 s t a i n l e s s s t e e l F A B t a r g e t at t h e t i p of a s e l f - c o n s t r u c t e d , thermostated direct insertion probe. Samples were introduced in t h e i o n s o u r c e a n d s p e c t r a a c q u i r e d at 17 s e c / d e c a d e by t h e F i n n i g e n S S - 2 0 0 d a t a s y s t e m ; a r e s o l u t i o n of ca. 2 . 0 0 0 (10*) was employed. Results
Origin Fig.L
and
discussion
of A G P H c h r o m o p h o r e demonstrates that the
chromophore
of
AGPH
is
139
PTERIN Χ
ο a
NEQPTERIN
PIE-
Τ
4
-τ-
—Γ"
6
8
—r- r—r 10
12 min
Fig.1 HPLC separation (1% acetonitrile, 7% methanol, 3mM phosphoric acid) of the chromophoric group of AGP (lower lane) and of HeLa pteridines (upper lane) 6- c a r b o x y p t e r i n [1
p t e r i n - 6 - carboxaldehyde
18 pmol folic
6000 e
CL
70 pmol acid 225 pmol ι
4000
°
2000
Timefinin]
Fig.2 HPLC separation (10% methanol) of commercially obtained C-rfolate absorption at 280nm, - - - fluorescence (exc. 350nm, em. 450nm), dotted area: radioactivity
140
identical
with
cells.
all
In
methods) far.
this
Folate
14
section
of
below).
had
originated
of
gave
*C-folate
freshly
the
be
the
at
that not to
predominated present
1
by
only
in
with
alone.
HeLa in
with
3
HPLC
the
already
whether
and
the
had
and
purified
by 24 or
of
unconjugated
used
sam-
unpurified
the
incubation we
conclude
pteridines
folate
degradation
acti-
purified
cells,
may
the
cells.
unconjugated
medium
folate
HeLa
the
To
cells/ml)
Therefore,
by
6-
(fig.2). for
of the
extended
days.
the
40*
one
as
incubated
period
(2,3,4,5)
of
was
of
that
present
(3.6x10*
without
cleavage of
sample
fraction
of
8
they
separation
demonstrated
was
this
or
to
about
if
obtainable
the
impurities
enzymatic
showed
(see
pteridines
cells
After
maximal
shock
expected,
subsequently
preparations
portion
heat
commercially
Indeed,
irrespective
folate
cells,
by
unconjugated
the
*C-folate
and
folate
HeLa
pteridines
that
impurities
of
in
pterin-6-carboxaldehyde
labelling to
serum to
C
period
both
bute
e.g.,
cleavage.
in
investigators
the due
The
(see
X)
activity
folate
recovered
C-folate a
and
incubated
Earlier over
HeLa
were
induced
radioactivity
37°
pteridines,
14
by
investigated
culture
isolated
notion
HPLC
medium
was
was
present
these
was
cell
preparation.
preparative
ple
(pterin
specific
manufactured
of
eliminate
vity
lines
cleavage X
from
carboxypterin
with
HeLa
The
the
us
already
hours
in
pterin
third
third
produced,
cell
biopterin
C-folate
one
1
and
cleavage
synthesis
may
6
amounts.
examine
This
pteridine the
pteridine
Neopterin
minimal
To
a of
but
was
rather
decomposition.
possibly (for
contri-
review
see
8) .
Induction oxygen HeLa to
of
pterin
X
by
heat
shock
and
by
limited
supply
cells
limited
which oxygen
amounts
of
pterin
tab.l).
Neopterin
had
been
supply X and
as
subjected accumulated
compared
biopterin
to
to at
heat
least
controls
levels
shock
were
or
3-fold (fig.3,
not
rai—
141
|
r
Μ I Pterin X
Ncopterin. 0.07 pniot Bioptcrin 0. Η pmol Pterin X : 0,65 pmol
Ne opterirn 0,34 pmol Biopttrin ; 0,18 pmol Pterin X 3,03 pmol
ι—
F i g . 3 H P L C s e p a r a t i o n of p t e r i d i n e s f r o m H e L a (10 cells) upper lane: control, l o w e r l a n e : r e d u c e d o x y g e n cond i t i o n (2 hours)
•0
120
240
100
Fig.4 U V - s p e c t r u m of p t e r i n X - · - · - pH1, p H 7,
140
Ι·0
DH
«20
13
M0
nm
142
sed
by
stress
phorbol
ester
of
these
both
Heat
pterins
shock-induced
stricted
to
accumulate mally only
conditions. treatment
60
at
least
reported
mally
contrast
an
accumulation
of
pterin
Bacteria,
X
such
is
as
to
not
re-
E.COLI,
also
3-fold
levels
of
pterin
protein).
Levels
of
monapterin,
pteridine
shock-i nduced
micked
in
E.COLI (10),
by
synthesis
incubation
of
sepiapterin
(SEP).
gether
sepiapterin
with
pterin
bination
X.
Maximal
(tab.l).
were
X
(maxi-
only
(MTX). (DHFR)
Temp.
This
Pteridines
controls
at
cells
reached
the
mini-
is
43eC
the
by
X
be
37°C
to
and
is
that
miwith to-
amount
this
induced
pterin
indicates
activity
can
increases
are of
X
cells
the
heat-shock
by
reductase
HeLa of
levels
Both
pterin
further
accumulation
methotrexate
of
the
Transfer
pterin-mediated late
in
raised.
Heat
of
is
causes
(9).
synthesis
eucaryotes.
pmol/mg
This
which
com-
sepia-
inhibited dihydrofo-
essential.
pmol/106cells
+SEP(1)JM)
+SEP(1jjM)
+ΜΤΧ(1μΜ)
+Γ1ΤΧ ( IJJM ) 37° C
Biopterin
0. 4 5
Pterin X
1.94
5. 4 3 3. 0 7
Biopterin
0. 20
Pterin X
4. 77
43° C
Tab.l
It
is
Accumulation (106
cells)
n.d.
= not
known
sepiapterin reductase which (tab.l) However, ted
seem the
6. 9 2
2. 13
0. 12
9. 0 9
4. 6 3
1. 3 2
of pterin with
that
X by incubation
sepiapterin
(SEP)
and
tetrahydrobiopterin successive
DHFR
found to
(11). in
n.d.
of HeLa by heat
of
suggest
may
reduction Increased
the
originate
data
reduction
n.d.
shock;
determined
via
and
were
1. 1 8 0. 74
this
that
sepiapterin
a
arise
of
further
levels
sepiapterin
"salvage
occurs.
from
sepiapterin
biopterin
presence
from
by
pathway".
DHFR-media-
Iodine
oxida-
143
t i o n (at p H 1) of t h i s p r o d u c t y i e l d s p t e r i n X. The product, which results from sepiapterin after incubation with DHFR and NADPH, was identified as dihydrosepiapterin (12). Using the conditions described in (12). a linear progression of dihydros e p i a p t e r i n f o r m a t i o n w a s o b t a i n e d d u r i n g a p e r i o d of 2 0 m i n u t e s . I o d i n e o x i d a t i o n (at p H 1 ) of t h e i n c u b a tion product, dihydrosepiapterin, under acidic conditions yields pterin X. T h e KM f o r sepiapterin in D H F R - m e d i a t ed r e d u c t i o n ( b o v i n e l i v e r ) is 18 f*M a n d t h e Hi for m e t h o t r e x a t e is 2 nil ( f i g . 4 ) . This indic a t e s t h a t t h e a f f i n i t y of s e p i a p t e r i n a s a s u b s t r a t e is c o m p a r a b l e t o t h a t of d i h y d r o f o l a t e (13). From the r e s u l t s described a b o v e we c o n c l u d e that in transformed cell lines and under heat shock conditions a D H F R - d e p e n d e n t r e d u c t i o n of s e p i a p t e r i n occ u r s . It r e m a i n s t o b e d e t e r m i n e d whether resulting dihydrosepiapterin or its o x i d a t i o n product, pterin x, is p r e s e n t in t h e l i v i n g c e l l . T h e h e a t s h o c k — i n duced formation of dihydrosepiapterin appears to branch off the de novo pathway, which results in tetrahydrobiopterin and can be triggered in transformed cell lines by phorbol ester treatment. In c o n t r a r y t o h e a t s h o c k i n d u c e d s y n t h e s i s of p t e r i n X, phorbolester treatment causes a transient accumulat i o n of n e o p t e r i n a n d b i o p t e r i n (9) w h i c h c a n n o t be inhibited by m e t h o t r e x a t e . The key compound in the h e a t s h o c k - i n d u c e d p a t h w a y a n d t h e m e c h a n i s m s of t h e divergence from the de novo pathway remain to be determined.
C h e m i c a l c h a r a c t e r i z a t i o n of p t e r i n X P t e r i n X is h a r d l y t o b e d i s t i n g u i s h e d by H P L C from 2-amino-4-oxo pteridine (pterin). Only with phosphate b u f f e r a s an e l u e n t (15 m M , p H 6 , 4 ) a s h o u l d e r indicates a slightly different retention time. T h e s p e c t r a l d a t a a r e s h o w n in ( f i g . 5 ) . T h e product of alkaline ΚΓΙηΟ* oxidation comigrates with 6-carboxypterin, thus indicating a carbon side chain on p o s i t i o n C6 (14). Initial m o l e c u l a r weight and s t r u c t u r a l data for p t e r i n X w e r e s o u g h t f r o m F A B m a s s s p e c t r a . In t h e s e e x p e r i m e n t s , t h e p r e p a r a t i o n of s u i t a b l e m a t r i x systems
144
Fig.4 L i n e w e a v e r - B u r k p l o t of s e p i a p t e r i n r e d u c t i o n b y D H F R (bovine liver) a n d N A D P H ( 50 m M ) a n d of M T X i n h i b i t i o n
iee-i [M + Η*] a 218 B0-
(β
2β-
ιββ
1SB
200
F i g . 5 F A B m a s s s p e c t r u m of p t e r i n X
25«
300
350
145
was
found
(though tained these
to
not
be
of
entirely)
after or
abundant
protonated
salt
the in
TEG
at
pterin
X.
in
positive
absence
to
m/z
indicating The
of
lack
of
labile,
matrix
any
structure,
vation
more
but
detailed
a
of
of
chain
precluded
de-
sodium spectra ions
217
the
a to
for
fragment
spectra
structural
most
218,
ion
weight
side
At
attributable
abundant
ion
functional
m/z
background
(1C1)
more
ob-
either
yielded at
amounts
and
were
with
negative
molecular
negative
piapterin of
the
252/254
a
and
MH +
ion
nearly
methanol/HCl.
spectra
considerable
sample;
addition ion
(M+Cl) - ,
of
in
consistently
molecular
isolated
in
prominent
the
matrix
presence
the
showed,
as
ion
and
solutions
protonation
positive
glycerol
importance,
homogenous
enforced
conditions,
spite
crucial
ions
suggests
the
from
se-
the
direct
data,
deri-
from
these
spectra.
References 1.
Ziegler,
I.,
Research 2.
Fukushima, 249,
3.
K.
42_, T.,
R.,
Conklin,
B.
Clark,
Halpern,
D.
Hardy,
B.C.
74^
Stea,
Β.,
B.C.,
Halpern,
P.S.
Clynes,
M.M.,
Letters
10.,
Lanks,
7.
Ziegler,
8.
Scott, (R-L. John
T.
Shiota.
K.W.
Cancer
1974.
J.Biol.Chem.
B.
Stea,
A.
Ashe,
A.
L.
Smith.
Dunlap,
Sperling, 1977.
J.A.
Proc.Natl.
587.
Backlund, 38,
and
P.B.
Halpern,
Berkey, R.A.
A.K.
Smith.
Cho,
1978.
2378.
C.
O'Neill.
1980.
Cancer
133. 1986.
Exp.
1985.
J. Ce 11. Β i ochem.
28.,
J.M.
1984.
In:
Pteridines
Blakley J.,
Rembold, Z.
1982.
I.
Wiley
Seidl,
H.
& M.
and
S.J.
Sons.
p.
Cell
H.
Physiol.
G.
Chem.
and
Benkovic, and
Heinz. 352,
165,
1. 197.
ed.)
307.
Borchert,
and
Res.
Folates
Biochem.Biophys.Res.Com. 10.
Fink.
Halpern,
R.M.
Research
6.
9.
and
Halpern,
Cancer 5.
M.
4445.
Acad.Sei.USA 4.
Maier,
1567.
I.
141,
Ziegler. 494.
1971.
1271.
1986.
Hoppe-Seyler~s
Κ
146
11. N i c h o l , C . A . , C . L . Lee, Μ . P . E d e l s t e i n , J . Y . Chao., D.S. Duch. 1983. Proc.Natl.Acad.Sei.USA 80, 15 46. 12. S m i t h , G . K . , and C . A . N i c h o l . 1 9 8 6 . J . B i o l . C h e m . 2 61, 27 25. 13. B l a k l e y , R . L . 1 9 8 4 . In: F o l a t e s and P t e r i d i n e s (R.C. B l a k l e y and S . J . B e n k o v i c , e d . ) , J o h n W i l e y & S o n s . p. 1 9 1 . 14. F o r r e s t , H . S . , H . K . M i t c h e l l . 1 9 5 5 . J . A m e r . C h e n . S o c . , 77, 4 8 6 5 .
Acknowledgement He t h a n k P r o f . D r . A. B a c h e r for m o s t h e l p f u l d i s c u s s i o n s and s u g g e s t i o n s . This research was supported by the Deutsche Forschungsgemeinschaft and by the Bundesministerium für F o r s c h u n g und T e c h n o l o g i e .
SECTION C: PTERINS IN IMMUNOLOGY
DISEASE ASSOCIATED ALTERATIONS OF PTERIN BIOSYNIHESIS: ENHANCEMENT IN INFLAMMATORY DISEASE, HEMOPOIETIC REGENERATION AND ENDOTOXINEMIA
Ch.Huber, M.Herold, J.Trcppmair. Div.Clinical Iimunobiolcy, Dept.Internal Medicine, University of Innsbruck, A-6020
Innsbruck, Austria
H.Rckos Henning Berlin GesiribH Berlin, D-1000 German, Federal Republic
Introduction
Disease associated abnormalities of p t e r i n biosynthesis were f i r s t observed in children with inborn metabolic e r r o r . Atypical phenylketonur i a (PK) i s character!zed by deficiency t o generate appropriate l e v e l s of tetrahydrobiqpterin (BH4) and c l i n i c a l l y presents with CNS dysfunct i o n ( 1 ) . Subsequently, increased l e v e l s of pterins in body fluids were observed in context with disease s t a t e s not a f f e c t i n g brain function. Elevated l e v e l s of necpterin were detected in various inflarmnatory conditions ( 2 ) , during hemopoietic regeneration (3) and in shock p a t i e n t s ( 4 ) . In t h i s a r t i c l e , we suimarize previous and recent data elucidating the pathomechanism(s) underlying increased p t e r i n synthesis in the latter states.
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
150
1. Enhancement of Pterin Biosynthesis During Inflaimnatory Disease Evidence for enhanced pterin biosynthesis during inflarrmatory states i s nainly derived from the observation of increased neqpterin levels in conditions such as viral and bacterial infection, autoiimune disease or allograft rejection. This topic has been recently reviewed (2). In vitro experiments represented the f i r s t clue to unravel the mechanisms underlying this phenomenon. We f i r s t observed that antigenic stinulaticn of a mixture of T-lynphocytes and monocyt es /macrophages leads t o release of iressive amounts of necpterin into culture fluids ( 5 ) . Further studies using highly purified suspensions of T-cells and monocyt es/macrcphages revealed that the macrophage produces necpterin when challenged with T-cell supematants (6). Neutralization experiments and stinulation with various recombinant lynphckines finally enabled t o characterize interferon-garrrra (IFN-garrma) as the active principle contained in these supematants (6). Subsequently, we and others have in detail studied the capacity of various cytokines released frcm inflammatory mononuclear c e l l s t o enhance pterin biosynthesis ( 6 , 1 2 ) . Results are demonstrated in Figure 1. As shown, T-lynphocytes can not be induced fcy any of the cytokines tested. Macrophages cn the other hand are only stimulated with IEN-alpha and IFN-gairma. Peripheral blood mononuclear c e l l s , which are predominantly composed of T - c e l l s and monocytes, are induced t o release necpterin when exposed t o IFN-alpha, IBH-ganna and IL-2. Neutralization experiments with anti-IFN antibodies indicated that the l a t t e r stinulation is indirect and mediated via induction cf interferon-gaima fcy IL-2.
151
Figure 1: Cytokine Specificity and Cellular Cooperations Required for Enhanced Pterin Biosynthesis in Mononuclear Blood Cells
IL·-.! l O n g / H l
ä
Τ + Ho
X I.- i! l O n s / t t l ΧΝF-χOne/Mi I N F - b lOiisi/Ml 1 FN- Ά.
X Ort t f / M
1
Ϊ F N - 3 X Ona/MX GM-CSF lOrig/M 1 i-i^-i-La, ί, I t ) I t I I I I till Mill I 1 I I ,1 Ο ΙΟ Η ΙΟ Ν ΙΟ Ο Η Ν Neoif>te«>in < NMOL/L. P o l t α U a l u e s ) Further experiments, previously published and in detail presented by G.Schoedcn et a l . in this issue aimed t o elucidate the biochemical basis of the phenomenon of IFN-induced enhancement of pterin biosynthes i s (7). A systematic analysis of IFN-induced changes of guanosintriphosphate (GTP), GTP-cyclohydrolase I (GTP-CH I ) , neopterin, biopterin and pterin levels in T-lynphocytes or rronocytes/macrophages gained the following results: IFNs increase substrate concentrations and activate the key-enzyme GTP- CH I in both Τ-eel Is and rronocyt es /macrophages. Macrophages, in contrast t o T-cells are not capable t o further convert dehydronecpterintriphosphate t o BH4. Ihis then leads t o excretion of
152
large anoints of dehydronecpteriη and necpterin into cultur supernatants (7). In conclusion, these in vitro data indicated that both, innune and non-irmune IENs ty selectively activating early steps of pterin biosynthesis in cells of the ncnocyte/macrcphage series lead to increased excretion of necpterin and dehydronecpteriη which is not associated ty enhanced biosynthesis of bicpterin.
Further evidence that I FN mediated enhancement of pterin biosynthesis in certain hemopoietic cells might represent the main cause cf elevated necpterin levels seen during inflammatory disease states are derived frcm in vi\o studies. First, diseases known to be accompanied ty elevated necpterin levels also have detectable levels of circulating IFN (far review see ref.2). Secondly, the view of an intimate relationship between production of endogenous IENs and induction of pterin biosynthesis is further supported ty individuell follow up studies. Exanples for concordant changes of endogenous IEN-levels and necpterin serum concentrations in a patient with cytomegalovirus disease and a patient rejecting his allograft are shown in Figure 2 a and b. Details of such clinical correlation studies were previously published (8,9).
Third, in vivo application of both, reconbinant IEtJ-alpha and reconbinant IFN-gartiTR induce significant elevation of necpterin levels (10,11). In vivo induction of IEN-mediated pterin biosynthesis, as measured ty assessment of necpterin levels is clearly dose dependent (Fig.3). In conclusion, these results prove that activated cells of the monocyte/macrophage series exhibite enhanced pterin biosynthesis. Pterin metabolism in these activated cells is unique because it selectively involves early steps of this pathway and leads to increased production of necpterin without generation of bicpterin. IFNs play a central role ty activating the key enzyme GTP-CH I. These in vitro data and the in vivo studies with recorrbinant interferons indicate that elevated neopterin levels during inflannatory disease reflect the extend of IFNinduced activation of the monocyte/macrophage system.
153
Figure 2: Correlation of Serum Necpterin With IETJ-Ganma Levels in a Patient With CMV-Disease (A) arid a Patient With Acute Rejection (AR) of His Renal Allograft (B)
Ii er· um Hoov'toi'ln < ΜΗΟΙ./Ήαΐι Cr>9ft) or Ζ FH (U/lOOHt) lOOO Nooi>to»>i n 0 00
I FN-Ga>Mi*
η oo
voo GOO aoo
>ίlm^Λr·»β^OWNlt0i>in C ΚΜΟΙ-,'ΜΟΙ, ϋ»οα) ο*· I FH (U/IOOML) 'JOΟ r HooY>feov*ln —β— IFM-aannn 7 0 0
600
BOO
AOO
DAUS
154
Fig. 3. Dose Dependent Enhancement of IETSI-mediated Pterin Biosynthesis
IFN-Gftnnii
F r o n !
Μ Aulltzlcu
a t
Do««
αϊ
(NIarDtfpann)
( 1 1 )
2. Enhanced Pterin Biosynthesis During Hemopoietic Regeneration Elevated levels of bicpterin and/or of necpterin were observed at the time of hemopoietic regeneration subsequent t o autologous or allogeneic bone marrow transplantation (3,13). In contrast to the process of a l l o g r a f t rejection discussed in the previous paragraph this enhancement of pterin biosynthesis, at least as f a r as necpterin levels were concerned, occured independent from the presence of histocompatibility barr i e r s between the bone marrow donor and recipient (13). In f a c t , simil a r patterns were seen in tumor patients, who subsequent t o l e t a l whole-body irradiation were reconstituted with autologous bone marrow (13). A typical pattern of such a patient i s shown in F i g . 4 .
155
Figure 4: Serum Neopterin and Interferon Levels During Hemopoietic Regeneration Subsequent t o Bone Marrcw Transplant at i on
DAMS
rtfto»· Tfnnsvl nntntlon
We asked the question, whether similar mechanisms involving IFNs or other cytokines such as colon/ stiirulating factors are involved. To t e s t this we have followed both neopterin and I FN levels in several autologous and allogeneic bone marrow transplant recipients. An exaitple i s given in F i g . 4 . Details were also previously reported (13,14). In the majority of patients, detectable levels of circulating IFNs were demonstrated at the time of hemopoietic regeneration and this coincided with the peak necpterin values. This observations supported the view that endogenous IENs might be at least partly involved t o enhanced pterin biosynthesis during hemopoietic regeneration. In contrast no evidence was obtained for the involvement of colony
stiirulating
factors which also peak shortly before hematological reoonstitution.
156
The negative r e s u l t s obtained by in v i t r o stimulation of human nacrophages with GM-CSF are shown in Figure 1. Althcucji involvement c£ endogenous IFNs, which presumably are induced fcy oonfrontation of newly formed lynphocytes with ubiquitous enviromental pathogens i s very l i k e l y , t h i s does not explain the elevation of bicpterin levels observed around t h i s time (3). One thus would rather believe that enhanced p t e r i n biosynthesis during hemopoietic regeneration i s determined by two independent f a c t o r s : an IFN dependent enhancement of early p t e r i n biosynthesis which involves activated Τ - c e l l s and monocyte/ macrophages as well as increased bicpterin content c f iimature hemopoietic c e l l s , c e l l s , vdiich appear in the circulation in large numbers at the time of hemopoietic reconstitution ( 3 ) .
3.Enhanced Pterin Biosynthesis During Endotoxinemia Enhanced pterin biosynthesis during infectious disease i s prinarily a feature of systemic virus disease (for review see 2 ) . Elevated levels were however also observed in a variety of b a c t e r i a l i n f e c t i o n s . By f a r the highest levels were detected in patients suffering from virus d i sease complicated by b a c t e r i a l infection and in septic shock patients ( 4 , 9 ) . A composition of these data i s shown in Figure 5. The l a t t e r observation pronpted the question whether lipcpolysaccharide (LPS) the active principle of endotoxin, which i s known to represent a most potent macrophage stinulator, i s capable t o induce pterin biosynt h e s i s . Previous data fcy C.F.Nathan indicated that LPS also induces neopterin release from human macrophages (12). We subsequently shewed, that LPS induced pterin biosynthesis can not be inhibited t y anti-IFN gaima antibodies (results not shown). This finding indicated a direct action o f LPS on human macrophages. We further investigated, whether IFNs might s e n s i t i z e macrophages t o respond t o endotoxin challenge with increased release of necpterin or of other activation s p e c i f i c cytokines such as tumor necrosis factor (TNF).
157
Figure 5: Necpterin Excreticn in Various Infectious Disease S t a t e s : Upinapu No ot> t ο χ» i η
Ζ c: tu tα. ο — 00
T~E
Μ
•
•
Μ
κ
σ ι ι ο
R—I
ζ -
> en ÜJ
X
ω„ if
CN
- Ρ
ι
ο
C
LU ο :
υ
χ
ο -—ι
Ο ο ο
ο
χ _ι ^
CQ
•
Σ
ZD LU I
Μ CM f—t Ζ ι Ο α: —< UJ ι χ CL Ο Ο
Α
Σ
ο ζ ο ζ — UJ ί Ο
Σ
—
•
BC
Χ ΕΣ >_Ι
c ς:
•
α.
ζ -
α. C.
ο
CN ο
—ι
< Σ CO < _J α.
υ φ
m r-H
> 95% pure as determined by SDS-PAGE. Hydroxylase activity was determined by either a spectrophotometric method (as described in ref. 3) or with a fixed-time assay (14). HPGPC analyses were performed with a column (7.5 χ 600 mm) of TSK 3000 SW (Altex) at ambient temperature (23-25°C) with 0. 1M potassium phosphate, pH 6.8, as the mobile phase. The injection volume was 50 uL for all analyses. The column was calibrated with standard proteins of known molecular weight. Further experimental details can be found in the legends to the various Figures.
Results Two protein peaks were observed when purified rat liver PAH was analyzed by HPGPC
(Fig.l). The major peak corresponded to a molecular
weight of 200000 and the smaller protein peak eluted as Mr-100000. Since PAH consists of identical subunits of Mr-50000 (1), these oligomeric forms of the hydroxylase are presumed to be the tetramer and dimer, respectively. Analysis of 10 different preparations of rat liver PAH, purified by either of two different procedures (6, 13), showed that the tetramer accounts for 78 +/- 6% of the total hydroxylase protein under these conditions. The relative amounts of the tetramer and the dimer were unchanged over a 100fold range of protein concentration, from 0.5 to 50 mg/mL PAH injected for analysis (Fig.l, insert). At concentrations less than 0.5 mg/mL protein, the relative amount of dimer appeared to increase. Limitations of detector sensitivity prevented analysis of samples of less than 0.1 mg/mL hydroxylase
329
time (minutes) FIGURE 1: HPGPC of purified rat liver PAH. 50 uL of a 20 mg/mL solution of PAH was chromatographed, as described in Methods, at 0.5 mL/min, and 0.5 min fractions were collected. Aliquots of these fractions were assayed with 40 uM BH 4 and 2 mM phenylalanine, and with 300 uM 6MPH4 and 10 mM phenylalanine. PAH activity (0) is shown as the ratio % of BH^dependent specific activity to 6MPH4-dependent specific activity (14). Insert: Proportion of tetramer ( • ) and dimer ( | ) as a function of the concentration of PAH injected for analysis.
protein. No evidence for the presence of the monomeric M r =50000 subunit was obtained under denaturing conditions. Preincubation of PAH with dithiothreitol prior to chromatography did not lead to the appearance of monomer. In addition,
only
the monomer was detected by SDS-PAGE in the absence of
thiols. Thus it is unlikely that intersubunit disulfide bonds contribute to the oligomeric organization of PAH. Aliquots of the separated tetramer and dimer were reanalyzed by HPGPC at various times after isolation. The tetramer slowly reverted over a 6h period to a mixture of tetramer and dimer in a proportion identical to that seen with
the original
sample
of PAH. In contrast,
the isolated dimer
remained as a dimer under the same conditions. However, certain conditions can affect the dimer. Preincubation of native PAH with 2 mM phenylalanine and subsequent HPGPC using a mobile phase containing 2 mM phenylalanine
330
phenylalanine in preincubation (mM) FIGURE 2: Effect of preincubation with phenylalanine on the conversion of dimer ( | ) to tetramer (•). Dimeric PAH was incubated for 15 min at 25°C in 0.1M phosphate, pH 6.8, containing the indicated concentrations of phenylalanine. Samples were then analyzed by HPGPC using a mobile phase of 0.1M phosphate, pH 6.8, containing 2 mM phenylalanine. Insert: HPGPC profile of dimeric PAH before ( ) and after ( ) preincubation with 10 mM phenylalanine.
showed
PAH
to be >98%
tetramer
(data not
shown).
Preincubation with
phenylalanine did not affect the elution position of the isolated tetramer. However, similar treatment of the isolated dimer resulted in an increased formation of the tetramer with increasing phenylalanine concentration (Fig. 2). Complete conversion of the isolated dimer to the tetramer was not observed - this may be due in part to the low protein concentration in the isolated dimer pool ("0.3 mg/raL) (cf. insert to Fig. 1). PAH activated by phosphorylation has some of the same characteristics as the enzyme which has been activated by preincubation with phenylalanine (15). Analysis by HPGPC of PAH with a phosphate content of 0.6 mol P^/mol Mr«50000 subunit showed that less than 5% of the hydroxylase protein eluted as the dimer (data not shown). This contrasts with the 25% dimer exhibited by the normal enzyme which contains 0.05-0.2 mol P^/mol subunit (15).
331
8.0 Ο) Ε 7.0 c
ε
6.0
ο μ
5.0
y
"
j0 • / V >
_
g
^
/
:/
-1
-1.2
-1.4
log S
α> C
« 4.0 ο
-
3.0 Ο
Ε 2.0 3L αΟ > 1.0 0
•
"
ÜJ^ i
1 1 0.2 0.4 0.6 0.8 1.0 phenylalanine (mM)
FIGURE 3: BH^-dependent activity of isolated dimeric ( | ) and tetrameric ( • ) PAH as a function of phenylalanine concentration. The oligomeric forms of PAH were isolated as described in the legend to Fig. 1 and immediately assayed with 25 uM BH4 and the indicated concentrations of phenylalanine. Insert: Hill plots of the data from the main Figure, njj for the tetramer was 2.1; njj for the dimer was 1.0.
Kinetics of the oligomeric forms of PAH Both the tetramer and the dimer have identical specific activities when assayed with the synthetic cofactor, 6MPH4. However, the full expression of the regulatory properties and the various activation phenomena to which PAH is subject
is noted only with
the natural cofactor, BH4.
Substantial
differences were observed in the BH^-dependent specific activity of the two oligomeric forms of PAH (Fig. 1); the tetramer has a BH^-dependent specific activity approximately 5 to 6 times that of the dimer. When the resolved oligomeric forms of PAH were assayed immediately after isolation, the BH4dependent activity of the tetramer showed a high degree of cooperativity (njj = 2) in response to variations in phenylalanine concentration (Fig.3), similar to that given by native PAH. The activity of the dimer, on the other hand, was strictly hyperbolic up to about 0.5 mM phenylalanine. The
332
Table 1: Activation of B H ^ d e p e n d e n t dimeric and tetrameric PAH
activity
Dimer
Additions
None 0.2mM phe 0.2mM lysolecithin
13 25 1106
Experiment None 2mM phe 5mM Dhe 20mM phe
56 760 1120 1140
isolated
Tetramer
initial rate (nmol/min/mg)
Experiment 1
of
-fold activation
initial rate (nmol/min/mg)
-fold activation
62
88
1080 1175
17 19
14 20 20
240 2510 2640 2510
11 11 11
2
Aliquots of samples were preincubated for 10 min at 25°C in 0.1 Μ phosphate, pH 6.8, with the indicated addition, then assayed with 50 uM BH^ and 0.2 mM phenylalanine {Experiment 1) or with 38 uM BH 4 and 2 mM phenylalanine {Experiment 2).
BH^-dependent activity of the dimer was however greater than that predicted by the calculated kinetic constants,at higher phenylalanine levels. We feel that
this may be
the result
of the formation of some tetrameric PAH
promoted by these higher levels of phenylalanine (cf. Fig. 2). Preincubation dependent activity
of PAH results
in 10 to 20-fold
increases
in BH4-
(13, 16). The apparent half-maximal concentration of
phenylalanine necessary for this activation at pH 6.8 and 25°C is about 0.1 mM (4, 16). As shown in Table 1, preincubation with 0.2 mM phenylalanine gave a 20-fold increase in the activity of the tetramer, but only a 2-fold increase with the dimer. The extent of activation of the dimer increased with increasing amounts of phenylalanine in the preincubation buffer (Table 1). These increases in activation of the dimer correlated almost exactly with the extent of phenylalanine-promoted tetramer formation under these conditions (Fig. 2). The activation of PAH by the phospholipid lysolecithin differs
from that due to preincubation with phenylalanine
hydroxylase
is
desensitized
in
the
presence
of
in that the
lysolecithin
(2).
In
addition, the phospholipid induces a gross conformational change in enzyme structure (17) that is not observed upon preincubation of the enzyme with phenylalanine (12). Table 1 shows that both dimeric and tetrameric PAH are
333
activated by lysolecithin. Note that the BH^-dependent specific activity of both species is essentially identical in the presence of lysolecithin. We have been unable to determine the oligomeric nature of PAH in the presence of lysolecithin levels
of
due to interference
lysolecithin
used.
from phospholipid micelles at the
However,
PAH which
has
been
chemically
modified by reaction with NEM is in an activated and desensitized form, kinetically identical to the phospholipid treated enzyme (3). NEM-modified PAH exists entirely as dimers under our conditions of HPGPC (data not shown).
Discussion
The BH4-dependent activity of rat liver PAH shows positive cooperativity with respect to variations in phenylalanine concentration (2). Such kinetic data have been used to implicate the presence on PAH of distinct catalytic and regulatory (or activator) sites for phenylalanine (16, 18). The first direct evidence in support of this proposal was the finding that native PAH binds more than 1 mol of phenylalanine per Mr=50000 subunit (3). Interpretation
of
the
non-integral
value
of
1.5
phe/subunit
was not
possible at that time, given the paucity of information concerning the subunit composition of PAH. However, others had proposed that PAH possessed 1 regulatory site /subunit (9). A number of subsequent findings in addition to the present work have allowed us to reassess the subunit organization of the catalytic and regulatory sites for phenylalanine on PAH: (i) The Mr=50000 monomeric subunits of PAH have been shown to be identical in primary structure (1). (ii) With BH^ as cof actor, the presence of tryptophan results in the desensitization of the response of PAH to phenylalanine concentration, but does not affect V m a x . The binding of phenylalanine to PAH in the presence of tryptophan is reduced to 1 phe/subunit from 1.5 phe/subunit (4). (iii) Studies of the quenching of the intrinsic fluorescence of PAH by BH4 demonstrate a binding ratio of 1 mol of BH^/mol of Mr—50000 subunit (12). Since the tetrahydropterin is essential for hydroxylation (19), we assume that each subunit must possess a single catalytic site. This assumption is consistent with (ii), and with the observation that PAH, desensitized yet
334 activated by modification with NEM, binds 1 phe/subunit (3). In addition, these observations indicate that conditions which lead to desensitization of PAH (i.e., the abolition of positive cooperativity with respect to phenylalanine) also result in the apparent disappearance of 0.5 sites for the binding of phenylalanine per subunit. It seems likely therefore that each monomeric
Mr—50000
subunit of PAH has 1 catalytic
site and the
equivalent of or potential for 0.5 regulatory (or activator) site. Since no evidence for the presence of monomeric Mr-50000 subunit was obtained in the present study, we consider the minimum reactive unit of PAH to be the dimer. The data which describe the the binding of phenylalanine to PAH (3, 4) are consistent with the idea that this dimer might possess 3 binding sites for phenylalanine - 2 catalytic sites, and 1 regulatory site. However, we do not think that this is an accurate picture of the organization of these sites. The regulatory site is presumably involved in the expression of the complex BH^-dependent kinetics of PAH with respect to phenylalanine, and
is necessary for the activation of PAH noted upon
preincubation of the enzyme with phenylalanine. The dimer, however, shows a strictly non-cooperative response to variations in phenylalanine concentration; only the tetramer shows kinetic cooperativity (Fig. 3). The dimer can apparently be activated by preincubation with phenylalanine, but the extent of activation is strongly correlated with the amount of tetramer formed under the conditions of preincubation (Fig. 2; Table 1). Thus at least part, and perhaps all, of the activation of the dimer induced by preincubation with phenylalanine is due to the phenylalanine-promoted conversion of dimers to tetramers. A simple model for the possible organization of the regulatory binding sites for phenylalanine on PAH is illustrated in Figure 4. Phenylalanine hydroxylase
is
an
oligomeric
protein
composed
of
subunits
which are
identical in primary structure. Each subunit possesses 1 catalytic site and the equivalent of, or the potential for, 0.5 regulatory site. The minimum active catalytic unit of PAH is a dimer. These dimers in the native enzyme exist in equilibrium with tetramers which are thus, in effect, "dimers of dimers". When two dimers associate in the proper manner to form a tetramer, 2 additional binding sites for phenylalanine are "created", in addition to the 4 catalytic sites already in existence. These two newly-formed sites are the regulatory or activator sites for PAH, and may exist at the
335
active
low activity phosphorylation (?)
QQ
Phe
N-ethylmaleimide
active FIGURE 4: Scheme for the oligomeric forms and organization of the regulatory binding sites for phenylalanine on PAH. Details are outlined in the text.
interface of the dimer-dimer interaction. In this model, both the native dimer
and
the
native
tetramer
(circular
figures) have
low
intrinsic
catalytic activity. The binding of phenylalanine to the regulatory sites (this binding is denoted by the shaded ovals), which exist in complete form only in the tetramer, results in (i) stabilization of the tetramer, and (ii) some conformational response in PAH which results in activation of the enzyme. Conformational changes in PAH due to the binding of phenylalanine are well documented
(12, 13). Since the dimer does not possess intact
regulatory sites for phenylalanine, the activity of this species remains low, with no observed cooperativity. The NEM-modified PAH is shown as a dimer in a different conformation than the native dimer, since it is an activated form of PAH. The dimeric nature of NEM-PAH is consistent with both
the absence
of kinetic
cooperativity
and
the
decrease
in
total
phenylalanine binding exhibited by this activated enzyme. Support for the concept of 2 regulatory binding sites for phenylalanine/tetramer has been obtained from recent studies concerning the interaction of a monoclonal antibody with PAH. This antibody binds to PAH only after the enzyme has been incubated with phenylalanine (20). Therefore, this antibody interacts with the tetrameric form of PAH. Binding of the
336 antibody inhibits PAH activity
in a noncompetitive manner
(21) and is
therefore presumably not binding to the catalytic region of the hydroxylase. The interaction results in the abolition of the cooperative response of BH^-dependent PAH activity to variations in phenylalanine concentration (M.A. Parniak, unpublished data), thus the antibody may be interacting with PAH at or near the regulatory region of the enzyme. This antibody binds to 2 sites over the 4 identical subunits of tetrameric PAH. The model presented in this report allows for 1 catalytic site/monomer of PAH, and the data indicate that the regulatory or activator site for phenylalanine is not necessary for the expression of low levels of catalytic activity in the dimer. Thus it is possible that the monomer could be catalytically active, if it could be formed and stabilized under nondenaturing conditions.
Acknowledgements M.A.P. is a Qu£bec. This Dr. Seymour enthusiastic
Chercheur-Boursier of the Fonds de la Recherche en Santfe du work was initiated while the author was in the laboratory of Kaufman, NIMH, Bethesda, MD. I gratefully acknowledge his support, instruction, and stimulating insight and discussions.
References 1. Iwaki, M., Parniak, M.A., Kaufman, S. (1985) Biochem. Biophys. Res. Commun. 126:922-932 2. Fisher, D.B., Kaufman, S. (1973) J. Biol. Chem. 248:4345-4353 3. Parniak, M.A., Kaufman, S. (1981) J. Biol. Chem. 256:6876-6882 4. Phillips, 259:271-277
R.S.,
Parniak, M.A., Kaufman,
S.
(1984) J.
Biol. Chem.
5. Fersht, A. (1977) Enzyme Structure and Mechanism. W.H. Freeman, San Francisco 6. Kaufman, S., Fisher, D.B. (1970) J. Biol. Chem. 245:4745-4750 7. Doskeland, A.L., Jones, Τ., et al (1982) Neurochem. Res. 7:407-421 8. Nakata, Η., Fujisawa, Η. (1980) Biochim. Biophys. Acta 614:313-327 9. Shiman, R. (1980) J. Biol. Chem. 255:10029-10032
337
10. Tourian, Α. (1971) Biochim. Biophys. Acta 242:345-354 11. Ayling, J.E., Pirson, W.D., et al (1974) Biochemistry 13:78-85 12. Phillips, R.S., Parniak, M.A., Kaufman, S. (1984) Biochemistry 23:38363842 13. Shiman, R., Gray, D.W., Pater, A. (1979) J. Biol. Chem. 254:11300-11306 14. Hasegawa, Η., Kaufman, S. (1982) J. Biol. Chem. 257:3084-3089 15. Parniak, M.A., Hasegawa, Η. , et al Commun. 99:707-714
(1981) Biochem. Biophys. Res.
16. Shiman, R., Gray, D.W. (1980) J. Biol. Chem. 255:4793-4800 17. Abita, J.P., Parniak, M.A., Kaufman, S. (1984) J. Biol. Chem. 259:1456014566 18. Dhondt, J.L. , Dautrevaux, Μ., et al (1978) Biochimie 60:787-794 19. Kaufman, S. (1959) J. Biol. Chem. 234:2677-2682 20. Jennings, I.G., Russell, R.G.McR., et al (1986) Biochem. J. 235:133-138 21. Parniak, M.A., Jennings, I.G., Cotton, R.G.H. (1986) in Chemistry and Biology of Pteridines (Cooper, B.A., Whitehead, V.M., eds.), Walter de Gruyter, Berlin-New York, pp. 359-362
IMMUNOCHEMICAL STUDIES OF PHENYLALANINE HYDROXYLASE
R. G. H. Cotton, I. G. Jennings, W. McAdam and S. Smith
Olive Miller Protein Laboratory, Murdoch Melbourne, Australia
Institute,
Introduction
Phenylalanine hydroxylase
(PH) is a complex enzyme which has
three substrates phenylalanine, tetrahydrobiopterin and oxygen and its enzyme activity is activated by phenylalanine, phosphorylation, N-ethyl maleimide, and phospholipids especially lysolecithin
(1).
We have initiated a study to
assess the ability of monoclonal antibodies, in combination with traditional protein chemistry, to define the
structural
regions of PH polypeptide responsible for the catalytic functions of the enzyme.
A monoclonal antibody
(MAb) which
bound the catalytic site of the enzyme might be expected to show the following characteristics
: (a) binding of the MAb
to PH at equimolar concentration would completely enzyme activity
inhibit
(b) binding of MAb to PH would be inhibited
by substrate or enzyme inhibitors
(c) MAb would bind
tyrosine
and tryptophan hydroxylases which share a common substrate with PH and also with other enzymes which have some common substrates
(d) M A b 1 s epitope would be a highly conserved
sequence in PH and thus MAb would recognise PH from a wide range of species in the phylogenic
spectrum.
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
340 Results and Discussion
A series of eleven monoclonal antibodies
(2) recognised at
least five different antigenic regions on PH and were tested for their ability to satisfy the above criteria.
The results
are summarized in Table 1.
Table 1 Group
A
Β C
D Ε
+
Antibody
PHI PH5 PH8 PH7 PH2 PH3 PH10 PHI 2 PH9 PH11 PH6
Effect on Activity 0 -59 +43 -19 +29 + 100 + 100 +33 +33 + 12 +16 -6
Species Reactivity* Η Η Η Η Η Η Η Η Η Η Η
Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ
Ligand
R Phe R Lyso R & others Lyso R P04 Lyso R Lyso R Lyso R Lyso none none R Lyso
χ
(+) (-) (-) (+) (-) (-) (-) (-)
(-)
Antibodies are grouped according to their ability to compete with each other for binding to PH ° Percentage effect on enzyme activity were calculated by using the enzyme activity with no antibody present as 0%; (+) stimulation (-) inhibition of enzyme activity. * Η, M, R designate human, monkey and rat liver PH respectively. χ effect on MAb binding of phenylalanine (PHE), lysolecithin (Lyso) and PO^ (covalently bound phosphate) when bound to PH (+)/ (-) designate promotion and inhibition of MAb binding respectively. It can be seen from Table 1 that no MAb has satisfied the criteria detailed earlier for active site recognition.
PHI MAb inhibited the enzyme by 59%, required for its binding
phenylalanine
(%-maximal phenylalanine concentration is
similar to that required for activation) it has been shown
(2).
In addition,
(3, in preparation) that the MAb inhibition
is non-competitive and thus PHI may be recognising a response
341
of PH to a c t i v a t i o n by
phenylalanine.
PH7 M A b only b i n d s to p h o s p h o r y l a t e d PH is l o c a t e d w i t h i n the
(4) a n d its
epitope
sequence
15
19 Leu-Ser-Asp-Phe-Gly. PO 4
PH7 M A b h a s little e f f e c t o n e n z y m e a c t i v i t y w h i c h is c o n s i s t e n t w i t h o t h e r f i n d i n g s t h a t the p h o s p h o r y l a t i o n is n o t c o n t a i n e d w i t h the c a t a l y t i c
site
site.
The b i n d i n g of a n u m b e r o f M A b s ' to PH is a f f e c t e d b y lysolecithin.
H o w e v e r only P H 2 , 3 a n d 5 show a
stimulation
o f similar m a g n i t u d e to l y s o l e c i t h i n w i t h t h e s e M A b s
also
m i m i c k i n g the c h a n g e s by l y s o l e c i t h i n to the PH e n z y m e kinetics
(2).
The e p i t o p e o f t h e s e M A b s has n o t b e e n
l o c a l i z e d b u t is likely to be in the Ν t e r m i n a l bromide peptide
finally
cyanogen
(unpublished).
PH8 M A b r e a c t s w i t h PH in W e s t e r n b l o t s of l i v e r from a w i d e range of s p e c i e s
extracts
(man, r a t , d o g , p i g , c o w ,
c h i c k e n , fish, frog b u t n o t s q u i d or b a c t e r i a )
(5).
koala,
PH8
has
b e e n s h o w n to b i n d t y r o s i n e h y d r o x y l a s e by E L I Z A a n d t r y p t o p h a n h y d r o x y l a s e by s o l u t i o n r e a c t i o n immuno h i s t o c h e m i c a l
(6).
In a d d i t i o n
s t a i n i n g of b r a i n t i s s u e h a s s h o w n PH8
reacts with tyrosine and tryptophan hydroxylase has b e e n u s e d to study the d i s t r i b u t i o n of n e u r o n e s in the h u m a n b r a i n stem
(6) a n d
it
serotinergic
(in p r e p a r a t i o n ) .
PH8
MAb
e p i t o p e h a s b e e n i d e n t i f i e d as 138 Gly-Ala-Glu-Leu-Asp-Ala-Asp-His-Pro-Gly-Phe-Lys-Asp-Pro 154 -Val-Tyr-Arg
; (5) a r e g i o n s u b s t a n t i a l l y c o n s e r v e d
tyrosine hydroxylase
(7) .
in
342
PH9 has b e e n s h o w n to r e c o g n i s e the Ν t e r m i n a l p e p t i d e o f h u m a n PH
tryptic
(in p r e p a r a t i o n ) .
T h e f i g u r e shows the d i s t r i b u t i o n of the k n o w n b i n d i n g
sites
of the M A b s PH 2, 3, 7, 8 a n d 9. CNBR CLEAVAGE t
PO. Li "9
7
"ΊΓ
2,3 R e c e n t l y w e h a v e i s o l a t e d a s e r i e s of a n t i b o d i e s w h i c h m o r e c l o s e l y fit the c r i t e r i a for a c t i v e site r e a c t i v e One a n t i b o d y b i n d s to PH, h u m a n d i h y d r o p t e r d i n e
antibodies.
reductase,
a n d E. coli d i h y d r o f o l a t e r e d u c t a s e a n d its b i n d i n g to PH is i n h i b i t e d by the p r e s e n c e o f 6,7 d i m e t h y l 7,8
dihydropterin.
T h e i d e n t i f i c a t i o n o f this M A b ' s e p i t o p e o n PH is u n d e r w a y .
References 1.
S h i m a n , R. In P t e r i n s a n d F o l a t e s , V o l . 1 Eds B l a k l e y , R . L . , B e n k o v i c , S.J. J. W i l e y and S o n s , 1984.
2.
J e n n i n g s , I. G . , R . G . M c R . R u s s e l l , W . L . F . A r m e r g o a n d R. G. H. C o t t o n . B i o c h e m . J . (1986) 235 133-138.
3.
P a r n i a k , Μ . Α . , I. G. J e n n i n g s a n d R. G. H. C o t t o n (1986) p . 3 5 9 - 3 6 2 in C h e m i s t r y a n d B i o l o g y of P t e r i d i n e s , 1986. E d s B. A . C o o p e r a n d V . M. W h i t e h e a d . Published W. de G r u y t e r .
4.
S m i t h , S. C . , W. J. M c A d a m , Β. E. K e m p , F. J. M o r g a n a n d R. G. H. C o t t o n (1986) B i o c h e m . J. (in p r e s s ) .
5.
H a a n , Ε. Α . , I. G. J e n n i n g s , A. C. C u e l l o , H. N a k a t a , C. W . C h o w , R. K u s h i n s k y , J. B r i t t i n g h a m a n d R. G. H. C o t t o n (1986) B r a i n R e s e a r c h (submitted).
6.
M a n u s c r i p t in p r e p a r a t i o n .
7.
Grima, B., Lamouroux A, Blanot F., Biguet N.F. M a l l e t J. (1985) P . N . A . S . 82 617-621.
and
INFLUENCE OF SUBSTRATES AND COFACTORS ON TYROSINE HYDROXYLASE
D.M. Kuhn Department of Psychiatry, Lafayette Clinic, Wayne State University School of Medicine, Detroit, Michigan 48207 USA
Introduction
Tyrosine hydroxylase (TH) is the initial and rate limiting enzyme in the biosynthetic pathway for the catecholamines dopamine, norepinephrine, and epinephrine. It was recognized some time ago that the activity of TH in adrenal and brain extracts was dramatically increased upon the addition of reduced pterins (1,2). Since these initial studies, a large amount of information on the pterin dependent enzymes TH, phenylalanine hydroxylase, and tryptophan hydroxylase has emerged concerning the mechanisms by which their level of activity is controlled. Most of these experiments were designed to study posttranslational influences such as phosphorylation, or the effects of various drugs on enzyme activity and little attention has been directed at the role that the pterin cofactor might play, other than the most obvious one of an essential cofactor in altering the activity of the hydroxylase enzymes. With the discovery of variant forms of hyperphenylalanemia (3-5) which involved primary defects in the enzymes of tetrahydrobiopterin (BHu) synthesis and not in phenylalanine hydroxylase, a vastly different etiology for practically all disorders involving the biogenic amine neurotransmitters and the aromatic amino acid hydroxylases was suggested. These disorders range from inborn errors in metabolism such as hyperphenylalanemia, mentioned above, to many psychiatric and neurologic disorders (see Levine (6) this volume). The studies of Kettler et al (7) were perhaps the first to demonstrate that the parenteral administration of BH4 to rats caused an increase in the cerebral levels of the cofactor and an increase in catecholamine
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
344 turnover. These results formed an important basis for the therapeutic treatment with BH« of certain diseases involving deficits in neurotransmitters since they offered the possibility that BHa could produce increases in neurotransmitter levels. The administration of BH4, like any therapeutic agent, to animals or man presupposes that the compound will reach its site of action and result in an increase in the activity of the hydroxylases for which it is the essential cofactor. In general, the most accessible hydroxylase has been phenylalanine hydroxylase because of its location in the liver. The localization of tryptophan hydroxylase and TH principally in brain restricts access of BE» to these enzymes to some extent but structure activity studies with the cofactor have revealed that some congeners can penetrate the blood-brain barrier (8). Once the cofactor reaches the hydroxylase enzyme it can interact with it to result in increased activity and increased production of the neurotransmitters dopamine, norepinephrine, and serotonin. The exact mechanism by which BH4 interacts with the hydroxylase enzymes is gradually becoming more completely understood as the reaction mechanisms of the enzymes are elucidated. Studies with purified phenylalanine hydroxylase have allowed impressive advances in our understanding of how BH4 interacts with this enzyme (9,10). Other equally interesting experiments have discovered numerous means by which BH« can interact with phenylalanine hydroxylase to influence its structure and level of activity by mechanisms which are not strictly limited to a cofactor role (11,12). In an attempt to determine if Bftj can interact with TH as it does with phenylalanine hydroxylase we undertook a series of experiments on BH4-TH interactions which began with purification of the hydroxylase enzyme to homogeneity. TH is a very unstable enzyme but sufficient quantities were purified from cultured PC12 cells to allow studies on its catalytic properties (13). Our initial experiments indicated that if the enzyme was preincubated with BH4, catalytic activity was inhibited in subsequent assays (14). The other cosubstrates for TH, tyrosine and oxygen, did not inactivate the enzyme under the same incubation conditions. The ability of the cofactor to inactivate TH was both time and temperature dependent and was restricted to reduced pterin species.
345 Solutions of BH4 are composed of two diastereoisomers referred to as the 6R and 6S forms (15). The isomers were separated and tested individually for their ability to inactivate TH and we observed that the natural 6R form was far more potent than the 6S isomer. Finally, we tested the pterin analog 6-methyl-5-deazatetrahydropterin and the pyrimidine 2,5,6triamino-4-pyrimidinone for their ability to mimic the BfU induced inactivation of the enzyme and observed these compounds were almost equipotent with BH4. These results were somewhat surprising since these two
compounds have little if any cofactor activity but they are capable
of inhibiting in vitro hydroxylase activity by virtue of their ability to compete for BIU (16). In order to determine further if BH4 was directly inactivating TH by altering the enzyme we carried out additional studies on reversal of the inactivation. Furthermore, we tested the ability of the substrates and cofactor of TH to influence the phosphorylation of TH by the cyclic 3',5' adenosine monophosphate (cAMP) -dependent protein kinase. These studies were important because phosphorylation of TH activates the enzyme (17,18) and this activation is mediated by a reduction in the km of the enzyme for BH4. Since BH4 can dramatically influence the phosphorylation of phenylalanine hydroxylase (12,18) by protein kinases we felt it was important to determine if BH4 could similarly alter the phosphorylation of TH. Such an effect could have an influence on any therapeutic properties of BH4 if the cofactor could alter an important control process for TH.
Results Purified TH was first incubated with 0.5 mM BH« for 30 min and the mixture was either dialyzed against 500 volumes of 50 mM potassium phosphate buffer pH 7.2 containing 40X glycerol and 0.1 mM EDTA or Chromatographed over a small column of Dowex 50 cation exchange resin. The results are shown in Table 1.
346 Table 1
Effects of dialysis and Dowex 50 chromatography on the inactivation of TH by BB» % Control
Dialysis
Dowex 50
Control
92
143
115
BH4
51
147
53
Preincubation with Bfti resulted in a 50* reduction of ΊΉ activity as previously observed (14). Upon dialysis, the control preparation was increased in activity as was the BH4 inactivated enzyme. On the other hand, cation exchange chromatography did not reverse the inactivation of TH. These results suggest that the inactivation produced by Bftj is reversible and that incubation of the enzyme in the presence of BH4 (and without tyrosine) generates an inhibitory substance. The incubations were repeated in experiments where tyrosine was added in increasing concentrations and the effects are included in Table 2. Table 2 Effects of tyrosine on the BEi-induced inactivation of tyrosine hydroxylase
Tyrosine (mM)
Tyrosine Hydroxylase (X Control)
0 0.025 0.05 0.075 0.10 0.20
48 50 74 87 100 120
It can be seen that when the incubations with BH4 are carried out in the presence of tyrosine, the inactivation by the cofactor was prevented in a concentration dependent manner. These conditions progressively approximate the normal in vitro catalytic conditions and demonstrate that the inhibition by BH4 can occur only when the enzyme is exposed to
347 the cofactor under non-catalytic conditions.
Thus, it appears that when
the normal oxidation-reduction of BH« takes place as it does during catalysis, the enzyme is obviously not inactivated. However, in the absence of tyrosine, exposure of TH to BH» results in the formation of an inhibitory product and this product does not seem to be an oxygen or superoxide radical (14). Phosphorylation of TH activates the enzyme an causes a reduction in the km of the enzyme for BH4. It has also been shown that incubation of phenylalanine hydroxylase with BH4 can dramatically alter the effects of phosphorylation on this enzyme and these experiments were repeated with purified TH. The enzyme was first incubated with BH4 (with or without tyrosine) to inactivate catalysis and the catalytic subunit of the cAMPdependent protein kinase was added in the presence of (y 32 P)ATP. It can be seen in Figure 1 that the incorporation of
32
P into TH was not
altered by BH4. Other lanes indicate that tyrosine or BH» plus tyrosine are also without effects on the phosphorylation of TH.
Fig. 1
Effects of BH4, tyrosine, or BH4 plus tyrosine incubation on the phosphorylation of TH. Purified preparations of the enzyme were preincubated (from left to right) with 1) buffer, 2) 0.5 nM BH«, 3) 1.0 nM ΒΗ», 4) 0.1 mM tyrosine, 5) 0.5 nM BR» + tyrosine, or 6) 1.0 nM BH« + tyrosine and after 30 min incubation the catalytic subunit of cAMP-dependent protein kinase was added.
348 After a 5 min reaction, samples were prepared for SDSpolyacrylamide electrophoresis. Gels were stained and dried followed by exposure to x-ray film to determine the extent of incorporation of
32
ρ into TH.
It appears from the results in Fig. 1 that the catalytic status of TH does not influence its ability to serve as a substrate for the exogenous protein kinase. Enzyme samples with less than 50* of their catalytic capacity (lane 2) or with complete activity were phosphorylated to the same extent.
Discussion Previous experiments with BH4-TH interactions under non-catalytic conditions were directed at learning more about the processes by which the cofactor could influence the enzyme apart from serving as an essential cofactor (14). It is clear from the present data that Blk can inactivate TH in the absence of tyrosine but this does not represent a normal in vivo condition. However, if large doses of BH4 resulted in the elevation of brain cofactor levels it is conceivable that TH activity could be reduced, especially if the levels of tyrosine were also less than normal. Recent experiments on the mechanism of action of purified TH (19) indicated that BH4 can influence the enzyme in a fashion similar to that reported above. Incubation of TH with stoichiometric amounts of BH4 (1.0 uM) for various times revealed that enzyme activity was reduced by 50* within 1 min of exposure of the enzyme to BH4, and was further reduced to approximately 20* of control after 30 min. Dix et al (19) suggested that a transient hydroxylating species was being generated by TH from BH4 and oxygen and these results confirmed their hypothesis. Furthermore, the loss of activity under the incubation conditions described could not be prevented with catalase, suggesting that hydrogen peroxide was not the inactivating species (19). These data concerning TH-BH4 interactions at very low concentrations of BH4 are in agreement with our previous research (14) and suggest several explanations for the BH4-induced inactivation of TH. First, the BH4
349 could oxidize the enzyme-bound iron (19) which would lead to reductions in activity. It has been demonstrated that the fluorescence properties of TH are altered by BH4 (19). Second, exposure of the enzyme to BH4 in the absence of tyrosine might lead to the production of a chemical species which interferes with subsequent catalytic activity. The reversal of the inactivation of TH by dialysis suggests the existence of such a species and makes less likely the possibility that the enzyme is being directly altered. Additional research will be necessary to identify the inactivating compound. The data with phosphorylation of TH indicate that the cofactor does not influence the ability of the enzyme to serve as a substrate for cAMPdependent protein kinase. TH was phosphorylated to the same extent regardless of its catalytic status. Thus, the enzyme can be phosphorylated in the presence of BH4, even after inactivation of TH with the cofactor. The activation of TH by phosphorylation represents an important control mechanism for the enzyme and it seems clear that the substrates and cofactor do not modulate the actual phosphorylation of TH as they do with phenylalanine hydroxylase, where BH4 can significantly diminish the phosphorylation of phenylalanine hydroxylase (12,18). While BH4 does not alter the phosphorylation of TH, it has been reported that the phosphorylated form of TH is less stable than the non-phosphorylated form (19,20) and BH4 can further enhance the destabilizing effects of phosphorylation (21). In summary, BH4 does not directly alter the phosphorylation of TH but it can lead to the enhanced inhibition of the activated form of the enzyme. It is not possible to determine the status of activation of TH in vivo but it can be hypothesized that it is functioning at less than optimal levels of activity in neuro-psychiatric disorders where transmitter deficits are thought to contribute to the cause of the disease. In this fashion, elevation of cerebral levels of BH4 would not be expected to reduce TH activity but hopefully produce an increase.
350 References 1.
Brennenman, A.R. and S. Kaufman. 1964. Biochem. Biophys. Res. Comm. 17, 177.
2.
Nagatsu, Τ., M. Levitt, S. Udenfriend. 1964. Biochem. Biophys. Res. Comm. 14, 543.
3.
Kaufman, S., N.A. Holtzman, S. Milstein, I.J. Butler, A. Krumholtz. 1975. N. Eng. J. Med. 293, 785.
4.
Niederwieser, Α., Ch. Curtius, 0. Bettoni, J. Bieri, B. Schircks, M. Viscontini, J. Schwab. 1979. Lancet 1, 131.
5.
Niederwieser, Α., Ν. Blau, Μ. Wang, Ρ. Joller, Ν. Atares, J. Cardesa-Garcia. 1984. Eur. J. Pediatr. 141, 208.
6.
Levine, R.A. 1987. In: Unconjugated Pterins and Related Biogenic Amines (H.-C. Curtius, N. Blau, and A. Niederwieser, eds.). Walter de Gruyter & Co.
7.
Kettler, R., G. Bartholini, and A. Pletscher. 1974. Nature 249, 476.
8.
Levine, R.A., H.-C. Curtius, B. Schircks: J. Pharmacol. Exp. Ther. (in press)
9.
Benkovic, S.J., L.J. Slieker, S.C. Daubner, L.F. Couortney, T.A. Dix, S.O. Pember, L.M. Bloom, C.A. Fierke, R.J. Mayer, J.-T. Chen, K. Taira. 1986. In: Chemistry and Biology of Pteridines 1986 (B.A. Cooper and V.M. Whitehead, eds.). Walter de Gruyter, Berlin-New York, p. 13.
10.
Shiman, R. 1985. In: Folates and Pterins, Vol. 2 (R.L. Blakley and S.J. Benkovic, eds.). John Wiley & Sons, p. 179.
11.
Phillips, R.S., I.Iwaki, S. Kaufman. 1983. Biochem. Biophys. Res. Comm. 110, 919.
12.
Phillips, R.S. and S. Kaufman. 1984. J. Biol. Chem. 259, 2474.
13.
Kuhn, D.M. and M.L. Billingsley: Neurochem. Int. (in press)
14.
Kuhn, D.M. and W. Lovenberg. 1983. Biochem. Biophys. Res. Comm. 117. 894.
15.
Bailey, S.W. and J.E. Ayling. 1978. J. Biol. Chem. 253, 1598.
16.
Moad, G., C.L. Luthy, P.A. Benkovic, S.J. Benkovic. 1979. J. Amer. Chem. Soc. 101, 6068.
351 17.
Kuhn, D.M. and W. Lovenberg. 1983. In: Handbook of Neurochemistry, Vol. 4 (A. Ljatha, ed.). Plenum Press, New York, p. 133.
18.
Kaufman, S. and E.E. Kaufman. 1985. In: Folates and Pterins, Vol. 2 (R.L. Blakley and S.J. Benkovic, eds.). John Wiley & Sons, p. 251.
19.
Lazar, M.A., R.J.W. Truscott, J.D. Raese, J.D. Barchas. 1981. J. Neurochem. 36, 677.
20.
Vrana, K.E. and R.Roskoski. 1983. J. Neurochem. 40, 1692.
21.
Roskoski, R., T.P. Finney, D.J. Täte, K.E. Vrana. 1983. Fed. Proc. 42, 2022.
MECHANISM OF ACTIVATION OF TRYPTOPHAN 5-MONOOXYGENASE BY MERCAPTIDES
H. Hasegawa
and
A. Ichiyama
Department of Biochemistry, Hamamatsu University School of Medicine, Hamamatsu 431-31, Japan
Introduction Tryptophan 5-monooxygenase has been assayed in the presence of mercaptides, ferrous iron, and catalase in addition to the substrates, tryptophan and tetrahydropterin under aerobic conditions.
Although the employment of mercaptide,
iron and
catalase is important for obtaining reproducible and high activity, they have been more-or-less empirically used.
Since
the first demonstration of an activation of bovine pineal tryptophan 5-monooxygenase by an anaerobic incubation with dithiothrei tol (DTT) (1), we have been working on the mechanism of mercaptide activation of the enzyme though the source of enzyme was switched from bovine pineal gland to mouse mastocytoma.
The present work is on the same line.
Prelimi-
nary accounts on the effects of catalase and iron were presented before (2,3).
It was possible that the high concen-
tration of DTT in our activation procedure changes conformation of the enzyme by opening disulfide linkage(s).
Then this
possibility was examined by determining the number of sulfhydryl groups
(SH) of the e n z y m e
before
and
after
the
activation.
Materials and Methods N-( 7-Dimethylamino- 4-methy 1 coumarinyl )-maleimide (DACM) was
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
354
used as a fluorogenic reagent for the determination of free SH in the enzyme protein.
This reagent was purchased from Wako
Chemical Industries, Tokyo, Japan, and was dissolved in acetonitryl and stored at -80° until use. Tryptophan 5-monooxygenase was purified essentially according to Nakata and Fujisawa (4) from a mouse mastocytoma, P-815. The purity of the enzyme used was more than 98% as judged by SDS-gel electrophoresis. Reduction of tryptophan 5-monooxygenase with DTT was performed in the same way as that for the activation of the enzyme under N2-
The standard mixture contained 15 m M DTT in 50 mM Tris-
acetate (pH 8.1) as the minimum components. conditions were achieved
The anaerobic
in a Thunberg tube connected to
vacuum line and nitrogen container by replacing air in it with N2.
This procedure was essentially the same as the original
method developed for the activation of bovine pineal tryptophan 5-monooxygenase (1), though catalase and iron salt were omitted because they have been known not to be essential as long as the activity assay was performed just after opening the Thunberg tube and the compounds were supplied into the reaction mixture (3). For determining SH of native enzyme, the enzyme was kept in a stabilizing buffer, 50 mM Tris-acetate (pH 7.5) containing 0.1 Μ KCl,
10% glycerol,
0.05% Tween 20.
Reduced enzyme was
subjected to the SH assay directly as a mixture with DTT used for the reduction as described above.
Denaturation of the
enzyme was performed with 6 Μ guanidine-HCl in the stabilizing buffer to give non-reduced denatured protein and in the 15 mM DTT solution under N2 to give fully reduced denatured protein. The proteins (30-50 pg in 200 p i ) were applied on a column of Sephadex G-2 5 (bed vol. 2.2 ml) equilibrated with 50 pM DACM in 50 m M Na-phosphate (pH 6.8) containing 10% glycerol or 6M guanidine-HCl for native or denatured proteins,
respectively.
Fractions, 200 pi each, were collected by stepwise elution. The peak fractions of protein were acidified by addition of 1/5 vol of 100%-formic acid.
A 200 pi aliquot of the solution
355 was a p p l i e d t o a n o t h e r Sephadex G-25 column o f t h e same d i m e n sion e q u i l i b r a t e d
of
the
e l u a t e f r o m t h e s e c o n d c o l u m n (200 ^il e a c h ) w e r e d i v i d e d
for
assays of
with
10% f o r m i c a c i d .
p r o t e i n and f l u o r e s c e n c e .
Both samples w e r e
l i z e d and s u b j e c t e d t o e a c h a s s a y . fluorescence,
the l y o p h i l i z e d
Li-dodecy1sulfate
in
The f r a c t i o n s
lyophi-
For d e t e r m i n a t i o n of
proteins
were d i s s o l v e d
0.1 Μ L i - b o r a t e
(pH 8 . 5 )
i n 6 mM
and s t o o d
room t e m p e r a t u r e f o r a t l e a s t o n e d a y i n t h e d a r k t o the spontaneous r i n g - o p e n r e a c t i o n ured
at
390
nm
for
excitation
(5).
at
ensure
F l o r e s c e n c e was meas-
and
476
nm
for
emission.
P r o t e i n was d e t e r m i n e d by t h e m e t h o d o f L o w r y e t a l BSA as t h e
the
(6)
with
standard.
Results The
content
of
free
SH o f
m e a s u r e d b e f o r e and a f t e r activation alkylating
of
tryptophan the
5-monooxygenase
anaerobic
incubation
t h e e n z y m e w i t h 15 mM DTT ( 3 ) .
reagent,
DACM,
was employed
mixing
the
reagent
with
pico-mole
as t h e
high
amount o f
for
labeling
total
cysteine
content,
was a l s o s u b j e c t e d it
possible
separation
the
of
with
To
avoid
of
the
mix-
In order
d e n a t u r e d enzyme i n
to the determination.
quick
labeling
of
DTT,
Sephadex
to obtain
the enzyme from t h e bulk o f
the
6 Μ guanidine-HCl
This procedure
the
and
SH ( 5 ) .
concentrations
50 jiM DACM.
probe
conditions
t u r e o f t h e e n z y m e and DTT was a p p l i e d t o a c o l u m n o f G-25 e q u i l i b r a t e d
the
A fluorogenic
w h i c h r e a c t s w i t h f r e e SH q u i c k l y a t n e u t r a l e n a b l e s us t o d e t e r m i n e
was
free-SH DTT.
just
made after
Subsequently,
the t r a c e o f DTT-DACM a d u c t s which c o n t a m i n a t e d
in the
f r a c t i o n and f r e e DACM w e r e removed by a n o t h e r
gel-filtration
t h r o u g h a S e p h a d e x G-25 c o l u m n e q u i l i b r a t e d acid.
Figure
1 shows
chromatography. the
same b e t w e e n
enzyme
reduced
the
elution
The amount o f the
fully
under
the
w i t h 10% f o r m i c
profiles
labeled
activating
of
SH w e r e
reduced d e n a t u r e d
protein
the
second
approximately
protein
conditions.
and
the This
356
40 native
native
denat.
reduced
reduced O) a.
ß
20 f
2
Φ +•« Ο ν· α.
m
Ο
Fractions Fig.l:
m /
(0.2ml)
Determination of SH of Tryptophan 5-Monooxygenase
The e x p e r i m e n t was carried out as described under "Materials and Methods" and "Results". Chromatograms of t h e s e c o n d c o l u m n a r e s h o w n . Enzymes were: r e d u c e d / n a t i v e (left), reduced/denatured (middle) and non-reduced/native (right). Open bar: relative fluorescence, hatched bar: protein amount.
finding indicated that the DTT-treated enzyme is fully reduced with
respect
to
the
SH.
In
the
e n z y m e , about 50-60% of the total reagent. fully
of
SH w a s
the
non-reduced
labeled w i t h the
On the basis of the k n o w n n u m b e r of total
denatured
titration
case
by
and reduced
use
of
BSA,
which
SH of
was determined
5,5'-dithio-bis(2-nitrobenzoic
by
acid)
(DTNB), the n u m b e r of SH of the reduced tryptophan
5-mono-
o x y g e n a s e w a s calculated to be 0.67 mol per mol of
subunit
(MW. 5 0,000 ).
357 Discussion The sub-stoichiometric amount of SH per subunit of the reduced enzyme may be partially due to the different color yield in the protein assay based on BSA as the standard.
The differ-
ences in the quantum yield of the fluorescence of the probe (DACM) bound to different proteins were reported to be negligible under the full denaturation conditions (5).
Then the SH
number of 0.67 mol per mol of subunit calculated for the fully reduced enzyme indicated that the enzyme contains only one cysteine residue per subunit.
This result indicates one of
the features of tryptophan 5-monooxygenase, namely that the SH does not make intra-molecular(subunit) disulfide bond.
The
meaning of the sub-stoichiometric number of SH of the nonreduced enzyme, 0.36 mol per mol of subunit, was not clear, but a part of SH might have been masked by certain transient metal(s).
In this regard,
it is noteworthy that the apo-
enzyme prepared by treating
tryptophan
5-monooxygenase with
EDTA strictly required ferrous iron in the restoration of its activity (3).
If the dramatic activation by DTT is based on
the chelating activity of the mercaptide on non-effective metal(s) in addition to the activity as reductant of iron, an appropriate combination of a chelator and a reducing reagent should be able to activate the enzyme.
In the early works on
this line, the reconstitution of the apo-enzyme with ferrous iron in the absence of DTT was not reproducible nor quantitative; for example, less than 10% of the expected maximum activity was observed when the enzyme was simply mixed with ferrous iron before the assay.
But the enzyme showed near 70%
of its maximum activity when the apo-enzyme was mixed into a reaction mixture containing ferrous iron together with 200 mM ascorbate
and
2 mg/ml
of
catalase;
the
conditions
were
designed to minimize the presence of ferric iron even in the presence of oxygen (3).
Ascorbate itself did not support the
catalytic activity nor was capable of activating the enzyme. These results suggested that ferric iron is not only incapable
358 in supporting the enzyme's catalytic activity but also inhibitory to the reconstitution of the apo-enzyme with ferrous iron; the iron binding site(s) of the enzyme might be easily occupied by the non-effective species of iron, ferric iron. DTT selectively chelates ferric iron and reduces it to ferrous state.
Based on this model, the role of DTT in the activation
of tryptophan 5-monooxygenase by the anaerobic incubation can be explained
by assuming
that
the mercaptide
acted as a
chelator to depriving ineffective metals, presumably ferric iron, and allowed the enzyme to bind free ferrous iron, which was maintained in the reduced state only in the presence of the
mercaptide
or other
reducing
reagents
under
neutral
conditions.
References 1.
Ichiyama, Α., S. Hori, Y. Mashimo, T. Nukiwa, H. Makuuchi. 1974. FEBS lett. 40 , 88.
2.
Hasegawa, Η., M. Yanagisawa, F. Inoue, A. Ichiyama. 1983. In: Chemistry and Biology of Pteridines (J.A.Blair, ed.). Walter de Gruyter & Co., p.795.
3.
Hasegawa, H., A. Ichiyama. 1986. In: Chemistry and Biology of Pteridines (B.A. Cooper, V.M. Whitehead, eds. ). Walter de Gruyter & Co., p.36 9.
4.
Nakata, Η., Η. Fujisawa. 1 984. Eur.J.Biochem. 124 , 595.
5.
Yamamoto, Κ. , T. Sekine, Y. Kanaoka. 1 97 7. Anal .Biochem. 79. 8 3.
6.
Lowry, O.H., N.J. Rosebrough, 1951. J.Biol .Chem. 193 , 265.
A.L. Farr, R.J. Randall.
EFFECTS OF TETRAHYDROPTERINS ON DOPA PRODUCTION IN VITRO
AND
IN V I V O
M.
Bräutigam
Freie Universität Berlin, Institut für T h i e l a l l e e 6 9 - 7 3 , 1000 B e r l i n - 3 3 , F R G W.
Pharmakologie,
Pfleiderer
Universität Konstanz, 7750 K o n s t a n z , F R G
Fakultät für Chemie, Postfach
5560,
Introduction T h e r e p o r t of K e t t l e r ted
e t al.
6(R,S)-tetrahydrobiopterin
production
(1) t h a t i n t r a v e n t r i c u l a r l y (BH4)
accelerates
in rats p r o m t e d c o n s i d e r a b l e
striatal
interest
bility to i n c r e a s e a m i n e s y n t h e s i s in the C N S by replacement
in the
is l i m i t e d b y i t s p o o r o r a l
a n d e v e n m o r e by i t s p o o r e n t r y i n t o t h e b r a i n
(2). W e ,
(in g e n e r a l
lipophilic)
pterins
for t h e i r e f f i c a c y to a c c e l e r a t e
p r o d u c t i o n in d i f f e r e n t in v i t r o a n d in v i v o
possinatu-
availability
fore, tested v a r i o u s (H4-pterins)
more
DOPA
cofactor
therapy. The efficacy of a therapy w i t h the
r a l c o f a c t o r 6(R)-BH^
injec-
there-
tetrahydroDOPA
models.
Methods H^-pterins
where
sine h y d r o x y l a s e
s y n t h e s i s e d b y H. T r a u b (TH) a c t i v i t y
(prepared
(3). T e s t s o n from
p e r f o r m e d i n 5 m M T r i s H C l , p H 7.2 (4). A C r u d e fraction were
(P2) w a s p r e p a r e d f r o m r a t s t r i a t u m .
incubated
in a K r e b s - R i n g e r - p h o s p h a t e
DOPA a c c u m u l a t i o n w a s m e a s u r e d by HPLC w i t h
PC12
tyro-
cells)
were
synaptosomal Synaptosomes
buffer,
p H 7.2;
electrochemical
Unconjugated Pterins and Related Biogenic Amines © 1987 Walter de Gruyter & Co., Berlin · New York - Printed in Germany
360
detect ion (ECD) after blockade of DOPA decarboxylase with 1 * 10"^ Μ 3-hydroxybenzyloxyamine dihydrogenphosphate (NSD 1055) (5). PC12 cells were cultured in Dulbecco's modification of Eagle's minimum essential medium; TH activity in intact PC12 cells was measured by DOPA accumulation after blocking DOPA decarboxylation (6). DOPA accumulation in rat striatum was determined after blocking DOPA decarboxylation with 3-hydroxybenzyl hydrazine (NSD 1015) (7). For determining tissue levels of 6(R)-BH4, 6-methyl-H4-pterin (6MPH4) and ethoxy-6-methylH4-pterin (Et-0-6MPH4) the H4-pterins were extracted in 0.2 Μ _ρ perchloric acid (containing 1 * 10 Μ dithioerythritol), separated by HPLC (ODS Hypersil, 5 jim; 20 mM citrate-phosphate buffer, pH 4.1, containing 1.5 mM octanesulfonic acid and 15% methanol) and detected by ECD (oxidation potential 300 mV).
Results Table 1 shows the activity of the various H4-pteridines as cofactors of TH in comparison to 6(R)-BH4. As can be noted, DOPA production (pmole/mg prot. * min) (6R)(6R,S (6R,S (6R,S (6R,S (6R,S (6R,S (6R,S (6R,S (6R,S (6R,S (6R,S
:etrahydrobiopterin -methylH 4 -pterin -hydroxymethylH 4 -pterin -methoxymethylH 4 -pterin -ethoxymethylH 4 -pterin -acetoxymethylH 4 -pterin -phenoxymethylH 4 -pterin -aminomethylH 4 -pterin -methylaminomethylH 4 -pterin -dimethylaminomethylH 4 -pterin -S-methylsulfonylmethyl- H 4 -pterin -ethoxymethyl-2,4-diamino--H 4 -pterindine
168. 0 79. 4 78. 0 1 86.6 271 . 4 1 48.0 68. 6 0. 0 1 .6 15. 6 31 .8 0. 0
5.9 1 .8 5.1 2.7 4.0 1 .3 + 1 .4
+ + + + + +
+ 1 .2 +
0.3
+ 1 .1
Table 1 : Effects of various H4-pterindines on TH activity. TH was prepared from PC12 cells; the concentration of the various H4-pteridines was 2 * 10 M.
361
especially the methoxy-e-methyl-H^-pterin (Me-O-öMPH^) and the Et-0-6MPH^ show a cofactor activity even higher than 6(R)BH4. To check the ability of the various H^-pterins to cross the cell membrane and to stimulate cellular DOPA production, PC12 cells were pretreated with 2,4-diamino-6-hydroxy-pyrimidine (DAO-Pyr) and were incubated with various H^-pterins. Pretreatment with DAO-Pyr inhibits de novo synthesis of 6{R)BH 4 and correspondingly cellular levels of 6(R)-BH4 and DOPA production are diminished (for details c.f. (8)). Figure 1 demonstrates that in particular Me-0-6MPH^ and Et-O-GMPH^ are more effective than 6(R)-BH4 to accelerate cellular DOPA production in the 6(R)-BH4 impoverished cells.
Acet-0-6MPH 4 Et-0-6MPH4 Me-0-6MPH4
>H
0H-6MPH 4 6MPH4 6(R)-BH4 controls
controls
I
1
1-
~Ί
"T" 40 20 30 DOPA production (pmol DOPA/mg protein · min) T
10
Fig. 1: Effect of various H^-pterins on DOPA production of PC12 cells. The cells were pretreated (24 h) with 1 * 10~2 Μ DAO-Pyr to yield a diminished endogenous intracellular 6(R)-BH4 content (8). In striatal synaptosomes (Fig. 2) the most significant effects on DOPA production were observed with Et-O-eMPH^. All compounds tested showed an inhibition of synaptosomal DOPA production at high concentrations. Despite its high effectivness in vitro no effects could be observed with high doses of Et-O6MPH4 on striatal DOPA production in vivo (Fig 3).
362 ΙΟ—·
8 -
Et-0-6MPH4
< Ο. §6" 6(R)-BH 4
ο Ε
a. Me-0-6MPH4 6ΜΡΗ4
4 c ο " υ •οσ 2