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Chemistry of Peptides and Proteins Volume 1
Chemistry of Peptides and Proteins Volume 1
Proceedings of the Third USSR—FRG Symposium Makhachkala (USSR), October 2-6,1980 Editors Wolfgang Voelter • Erich Wünsch Yuri Ovchinnikov • Vadim Ivanov
W G DE
Walter de Gruyter • Berlin • New York 1982
Editors: Wolfgang Voelter, Prof. Dr. rer. nat. Director Department of Physical Biochemistry Institute for Physiological Chemistry Hoppe-Seyler-Strasse 1 D - 7 4 0 0 Tübingen • Germany Erich Wünsch, Prof. Dr. rer. nat., Dr. med. h.c. Director Department of Peptide Chemistry Max-Planck-lnstitute for Biochemistry D - 8 0 3 3 Martinsried • Germany Yuri Ovchinnikov, Prof. Dr. Vadim Ivanov, Prof. Dr. Director Shemyakin Institute for Bioorganic Chemistry USSR Academy of Sciences Moscow • USSR CIP-Kurztitelaufnahme der Deutschen Bibliothek
Chemistry of peptides and proteins : proceedings of the . . . USSR-FRG symposium. - Berlin ; New York : de Gruyter Vol.1. Proceedings of the third USSR-FRG symposium : Makhachkala (USSR), October 2 - 6 , 1 9 8 0 . - 1982. ISBN 3-11-008604-2
Library of Congress Cataloging in Publication Data
USSR-FRG Symposium (3rd : 1980 : Makhachkala, R.S.F.S.R.) Chemistry of peptides and proteins. Bibliography: p. Includes index. 1. Peptides-Congresses. 2. Proteins-Congresses. I. Voelter, W. II. Title. QD431.A1U88 1980 547.7'5 82-14937 ISBN 3-11-008604-2
Copyright © 1982 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: Karl Gerike, Berlin. - Binding: Dieter Mikolai, Berlin. Printed in Germany.
PREFACE The USSR-FRG Symposium on the Chemistry of Peptides and Proteins was conducted to reinforce between scientists of both countries the hitherto existent contact and exchange of information at the level of the European Peptide Symposium. Based on the scientific agreement between the Union of the Soviet Socialist Republics and the Federal Republic of Germany, represented on the one hand by the Soviet Academy of Sciences and on the other by the Deutsche Forschungsgemeinschaft, the bilateral symposium series was initiated at the 1st Meeting in Dushanbe-Tadjikistan in April, 1976. As the scientific basis of these meetings, we have attempted to combine the three main research areas in the field of chemistry of peptides and proteins, i.e. a) isolation, b) structure elucidation and c) synthesis as a discussion platform in order to reestablish the working community previously existing in chemistry of natural products. The first meeting has already confirmed the usefulness of such a programme . Additionally, our idea was to incorporate, if required, discussions on special, closely-related topics of particular scientific interest. Consequently, at the 2nd Meeting in Grainau-Eibsee in May, 1978, membrane chemistry was added to the programme. The positive aspects of this choice were clearly confirmed at the 3rd meeting in Makhachkala in October, 1980, where a first, tentative discussion on immunological problems in connection with the chemistry of peptides and proteins took place. We believe that this widening of the scientific programme may, in future meetings, lead to a fruitful exchange of experience and knowledge in the individual sectors of this field of chemistry. The strong resonance of the scientific communications and related discussions among
VI
the participants of both countries is clearly shown by the increasing interest in these meetings and by the continuous demand for publication of the reports. Following a simple abstract booklet on the occasion of the 1st Meeting, a proceedings volume with shortened versions of the lectures was printed for the 2nd Meeting. In the present proceedings the detailed reports of the lectures and communications of the 3rd Symposium on the Chemistry of Peptides and Proteins are published in full. The organizers of these series of symposia on Chemistry of Peptides and Proteins would like to take the opportunity of expressing their gratitude to the Soviet Academy of Sciences as well as to the Deutsche Forschungsgemeinschaft for their generous support and sponsorship.
For the Editors E. Wünsch
VII
CONTENTS
I. Isolation and Structure Elucidation of Peptides and Proteins The Primary Structure of DNA-Dependent RNA Polymerase from E.coli. Nucleotide Sequence of rpoB Gene and Amino Acid Sequence of the B-Subunit V.Lipkin, G.Monastyrskaya, V.Guvanov, S.Guryev, 0.Chertov, V.Grinkevich, I.Makarova, T.Marchenko, 1.Polovnikova, E.Sverdlov, Y.Ovchinnikov
3
Study on the Primary Structure of the Elongation Factor G from E.coli Y.B.Alakhov, L.P.Motuz, N.V.Dovgas , Y.A.Ovchinnikov
13
Intracellular Serine Proteases of Bacilli A.Ya.Strongin, V.M.Stepanov
19
Structure and Biological Function of Proteinase Inhibitors from Yeast K.Maier, H.Holzer, R. Barth ,P . Biinning , E.Kominami
29
Inhibitors of Human Neutral Granulocytic Proteinases from the Leech: Biochemical Characterization and Pathobiochemical Aspects U.Seemuller, M.Eulitz
39
Isolation of a Specific Protein Inhibitor of Fungal Proteinase and Yeast Proteinase B from the Kidney Bean Seeds V.V.Mosolov, E.L.Malova, A.N.Tcheban,V.M.Lakhtin , A.N.Bakh
47
Isolation of Membrane Glycoproteins from Paramyxovirus SV5 for Analysis of their Carbohydrate Structure P.Prehm
53
Haemoglobin Polymorphism in Chironomus(Diptera) H.Aschauer, T.Kleinschmidt, W.Steer, G.Braunitzer
61
High Altitude Respiration of the Bar-Headed Goose (Anser Indicus) and the Different Evolution of thecC- and 6-Chains in Avian Haemoglobins G. Braunitzer, W. Oberthiir
71
VIII T h e S t r u c t u r e of the D i c y c l o h e x y l c a r b o d i i m i d e Binding Subunit E.Wächter,T.Graf, G.Wild, W.Sebald
83
Structural Studies of the Active Ion Trans-port Systems N . M o d y a n o v , A . B a b a k o v , N . A r z a m a z o v a , K. Dzhandzhugazyan, S.Kocherginskaya
85
I s o l a t i o n of t h e T T X - S e n s i t i v e P r o t e i n ( S ) of E x c i t a b l e T i s s u e s V.K.Lishko, M.K.Malysheva, A.V.Stefanov,A.M. Chagovetz, A.A.Bogomoletz
93
Fragments Formed from Neuropeptides of H y p o t h a l a m i c E n d o p e p t i d a s e s T.Akopyan, A.Arutunyan, A.Oganisyan
99
upon
Action
N e w D a t a a b o u t the S p e c i f i c P r o t e i n s of H y p o t h a l a m u s - C a r r i e r s of C a r d i o a c t i v e C o m p o u n d s A.Galoyan, R.Srapionian
103
I s o l a t i o n a n d S t r u c t u r a l S t u d y of N e u r o t o x i n f r o m t h e V e n o m of S p i d e r L a t r o d e c t u s T r e d e cimguttatus S . S a l i k h o v , M . T a s h m u k h a m e d o v , M . A d y l b e k o v , J. Abdurakhmanova, A.Korneyev, A.Sadykov
109
Sea Anemone L.Beress
121
Toxins,
a
Minireview
S t r u c t u r e a n d P r o p e r t i e s of M a s t o p a r a n II O l i g o p e p t i d e from the V e n o m of H o r n e t V e s p a orientalis I.Nasimov, L.Snezhkova, O.Reshetova, A.Miroshnikov
127
Isolation, Physico-Chemical and Biological Prop e r t i e s of t h e I m m u n i t y P o l y p e p t i d e B i o r e g u l a t o r from Thymus O.A.Pisarev, V.G.Morosov, V.K.Khavinson, L.K. Shataeva, G.V.Samsonov
137
Some Recent Advances in the M e t h o d s of Protein Sequence Analysis A.Henschen, F.Lottspeich, W.Brandt, C.v.Holt
143
Field Desorption Mass Spectrometry peptides W.Voelter, M.Przybylski
153
of
Oligo-
IX S e q u e n c e A n a l y s i s of M e m b r a n e - M o d i f y i n g P e p t i d e Antibiotics by Gas Chromatography and Mass Spectrometry W.A.König, M.Aydin
173
S t r u c t u r e E l u c i d a t i o n and P r o p e r t i e s of N i k k o m y c i n s , a N e w C l a s s of N u c l e o s i d e - P e p t i d e A n tibiotics H.Hagenmaier, W.A.König
187
II. P e p t i d e S y n t h e s e s . B i o l o g i c a l A c t i v i t y a n d A n a l y t i c a l P r o b l e m s of S y n t h e t i c P e p t i d e s
Electrochemical Introduction and Selective Rem o v a l of a N e w T y p e o f A m i n o - a n d C a r b o x y - P r o tecting Group for Peptide Synthesis G.Jung, M.H.Khalifa, A.Rieker
193
N e w A s p e c t s of P e p t i d e S y n t h e s i s b y F o u r C o m ponent Condensations I.Ugi, W.Breuer, P.Bukall, S.Falou, G.Giesem a n n , R . H e r r m a n n , G.Hiibener, D . M a r q u a r d i n g P.Seidel, R.Urban
203
Isocyanides as Activating Reagents Synthesis H.Aigner, G.Koch, D.Marquarding
2 09
Impact of C o n f o r m a t i o n on the gies for Peptide Sequences M.Mutter, H.Anzinger, K.Bode, Pillai
in
Peptide
Synthetic F.Maser,
StrateV.N.R. 217
S y n t h e t i c S t u d i e s o f N e u r o t o x i n II f r o m V e n o m of C e n t r a l A s i a n C o b r a N a j a n a j a o x i a n a V.Deigin, V.Ulyashin, I.Mikhaleva,V.Ivanov
229
I n v e s t i g a t i o n on the S y n t h e s i s of S a l m o n C a l c i t o n i n II F r a g m e n t s G.Vlasov, V.Glushenkova, V.Lashkov, N.Kozhevnikova, L.Nadezhdina, L.Krasnikov, I.Ditkovskaja, O.Glinskaja,T.Komogorova
239
Total S y n t h e s i s of S o m a t o s t a t i n w i t h o u t H y d r o x y l G r o u p P r o t e c t i o n of H y d r o x y l A m i n o A c i d R e sidues Y.P.Shvachkin, S.K.Girin, A.P.Smirnova, A.A. Shishkina, N.M.Ermak
245
X Total Synthesis of Somatostatin-28 L.Moroder, M.Gemeiner, E.Jaeger, E.Wünsch
249
Synthesis, Structure and Membrane Properties of Gramicidin A Dimer Analogs L.Fonina, A.Demina, S.Sychev, A.Irkhin, V.Ivanov, J.Hlavacek
259
Cyclic Analogues of Bradykinin and Kallidin G.Chipens, F.Mutulis, N.Mishlyakova
269
Inhibition of RNA Polymerase by Analogs of Amaninamide T.Wieland, C.Birr, A.E.Vaisius, G.Zanotti
275
Structure-Activity Relationship of ActinBinding Peptides H.Faulstich
279
Synthesis, Spectral and Biological Properties of DSIP and its Analogs I.Mikhaleva, A.Sargsyan, T.Balashova, V.Ivanov
28 9
Polyoxyethyleneoxide(POE) Peptides, Models for Rhodopsin and Myoglobin E.Bayer
299
Chemical Mutation: Replacement of Reactive Site Residue P^=Lys in Bovine Kunitz Inhibitor by other Amino Acids and Concomitant Specificity Change H.Tschesche, H.R.Wenzel
301
Semisynthetic Modification of the N-Terminus of the Insulin A-Chain P.Trindler, D.Brandenburg
307
Enzymatic-Chemical Transformation of Porcine Insulin into Human Insulin E.N.Voluyskaja, S.P.Krasnoschokova, V.V.Knjazeva, M.N.Rjabtsev, S.M.Funtova, T.I.Zujanova, A.I.Ivanova, V.P.Fedotov, Yu.P.Shvachkin
315
Trypsin Catalyzed Peptide Synthesis: Modification of the ß-Chain C-Terminal Region of Insulin H.-G.Gattner, W.Danho, R.Knorr, H.Zahn
319
XI
Semisynthesis with Insulin-B-Chain E.E.Büllesbach, E.W.Schmitt, H.-G.Gattner, V.K.Naithani, J.Föhles
327
Investigation of the Influence of A1, B29 Amino Group Modification on the Structure and Biological Activity of Insulin G.Vlasov, N.Izvarina, N.Illarionova
337
Bacterial Cell Wall Glycopeptides: Synthesis, Conformation and Antitumor Activity T.Andronova, L.Rostovtseva, I.Sorokina, V.Mal'kova, V.Ivanov 343 Use of Dipeptide Substrates in Studies of Specific Features of Thrombin Catalysis V.K.Kibirev, S.B.Serebryany
353
Studies on the Efficacy of Preparative and Analytical HPLC in Peptide Chemistry W.Göhring, M.Gemeiner, L.Moroder, R.Nyfeler, E.Wünsch
359
A Method for Amino Acid Separation with a Microcolumn Chromatograph E.Ya.Kreindlin, V.S.Onoprienko, O.V.Evseeva, L.B.Kaminir
367
An Express Method for Determination of Absolute Configuration and Quantitity of Amino Acid Enantiomers in Mixtures N.A.Voskova, V.V.Romanov, G.A.Korshunova, Yu. P.Shvachkin
3 73
III. Structural Features of Proteins Structure-Activity Studies on Neurotoxin 1 from Sea Anemone Radianthus Macrodactylus E.Kozlovskaja, H.Vozhova, G.Elyakov
379
Cobra Venom Neurotoxins: Conformation and Interaction with the Acetylcholine Receptor V.Tsetlin, E.Karlsson, Y.Utkin, A.Arseniev, K.Pluzhnikov, A.Surin, V.Pashkov, V.Bystrov, V.Ivanov
389
XII
The Study of the Scorpion Neurotoxin Membrane Receptors N.Soldatov, V.Kovalenko, E.Grishin
399
Dehydration of Ionogenic Groups in Peptide Ligands on Receptor Surface G.V.Nikiforovich, S.A.Rozenblit, G.Chipens
407
The Study of the Structural and Functional Organization of the Somatotropin Molecule Y.A.Pankov, A.A.Bulatov, Y.M.Keda, T.A. Osipova, V.I.Pozdnyakov
415
Structural Features of Bacillus thuringiensis Crystal Protein V.M.Stepanov, G.G.Chestukhina, I.A.Zalunin, L.I.Kostina, A.L.Mikhailova
423
X-Ray Investigation of Three Dimensional Structure of Actinoxanthin V.Pletnev, A.Kuzin, S.Trakhanov, V.Popovich, I.Tsigannik
4 29
Aldimine Bond Migration in the Photochemical Cycle of Bacteriorhodopsin N.Abdulaev, V.Tsetlin, A.Kiselev, V.Zakis, Y.Ovchinnikov
435
Chemical Modofication of Purple Membrane Topography of Bacteriorhodopsin H.-D.Lemke, J.Bergmeyer, D.Oesterhelt
441
Formation and Unusual Properties of Bacterioopsin-Ag + -4-Dimethylaminochalcone Triple Complex A.Aldashev, A.Rodionov, E.Efremov, A.Shkrob 4 51 Peptide from Beef Heart Mitochondria Inducing Ion-Selevtive Channels on Planar Bilayer Membrane L.A.Pronevich, G.P.Mironov, G.D.Mironova 457 Functional Role of the Protein Component of the Ca -Transporting Glycoprotein from Beef Heart Homogenate and Mitochondria T.V.Sirota, L.A.Pronevich, G.D.Mironova
463
Optical Spectroscopy Study of Substrate Binding by Leucine Specific and Leucine - Isoleucine - Valine Binding Proteins from E.coli I.Nabiev, S.Trakhanov, A.Surin, T.Vorotyntseva, E.Efremov, V.Pletnev
4 67
Investigations of Immunoglobulin Structure in Solution V.Zav'yalov, V.Abramov, O.Loseva, V.Tishchenko E.Dudich, I.Dudich Conformational Lability of Immunoglobulin M Molecule E.Kaverzneva, F.Shamkova, Y.Khurgin, R.Kayushi na Structure-Functional Studies of DNA-Dependent RNA Polymerase from E.coli O.Chertov, V.Efimov, O.Chakhmakhcheva, Y.Smirnov, S.Tsarev, N.Skiba, T.Marchenko, V.Lipkin, E.Sverdlov Structure of the Proteolipid Subunit of the ATP Synthase J.Hoppe, W.Sebald Quaternary Structure and Reconstitution of Acetylcholine Receptor from Torpedo californica W.Schiebler, L.Lauffer, G.Bandini, F.Hucho
I
Isolation and Structure Elucidation of Peptides and Proteins
THE PRIMARY STRUCTURE OF DNA-DEPENDENT RNA POLYMERASE FROM E. ooli. NUCLEOTIDE SEQUENCE
OF rpoB GENE AND AMINO ACID
SEQUENCE OF THE (3-SUBUNIT
Valéry Lipkin, Galina Monastyrskaya, Valentin Gubanov, Sergey Guryev, Oleg Chertov, Vladimir Grinkevich, Irina Makarova, Tatjana Marchenko, Irina Polovnikova, Eugene Sverdlov, Yuri Ovchinnikov Shemyakin Institute of Bioorganic Chemistry, USSR Academy of Sciences, Moscow, USSR
Introduction Elucidation of the transcription mechanism requires detailed knowledge of the active center's organization of RNA polymerase at the various stages of the RNA synthesis. This, in turn, can be obtained only after determining the primary and spatial structure of the enzyme. Earlier we had established the amino acid sequence of the a-subunit of E. coli DNA-dependent RNA polymerase resorting solely to the ordinary methods of protein chemistry
(1). In
the case of the g-and B'-subunits with their much higher molecular weights
(-155.000 and -165.000, respectively), such an
approach could no longer suffice.
Results One of the approaches to the structure determination of large protein molecules is their initial cleavage into a small number of fragments, which then can be analyzed by conventional methods. The search for the conditions of limited proteolysis of the g- and g'-subunits was undertaken. Considerable obstacles were encountered in the course of these studies owing
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter &. Co., Berlin • N e w York
4 to the fact that the RNA polymerase subunits are not the native proteins. However, the conditions for limited tryptic proteolysis of the B-subunit were found. These are an enzvme/substrate ratio of 1:500, temperature 0°C, 4 hr (2). Herein there seems, what we believe,to be an optimal set of large fragments (mol. wt.62.000, 52.000, 37.000, 24.000 and 10.000). Initial separation of the resultant hydrolysate was carrisd out by chromatography on Sephadex G—100 in 6 M guanidine hydrochloride. This yielded 10 fractions. Their analysis by polyacrylamide gel electrophoresis showed that all large fragments mentioned above are in the first three fractions, while the rest contain about 9 5 smaller peptides. 53 low molecular weight peptides were isolated from the hydrolysate. They consist of approximately 400 amino acid residues. Their sequencing was very useful for a further structure investigation (3). Isolation of the high molecular peptides proved difficult because of both the little hydrolytic specificity and the low yield of most products. So we could not use limited proteolysis as the main procedure for fS sequencing. The progress in DNA sequencing methods allowed to realize the possibility of using the genetic code to obtain information on the primary protein structure from the nucleotide sequences. However .here there are many pitfalls in the way, requiring considerable caution to avoid possible sources of error. In the first place the mRNA can undergo processing, leading to erroneous deduction of the protein structure. This holds particularly for eukaryotic cells, wherein "splicing" has been noted. Secondly, the protein itself can be processed. Thirdly, it is often difficult to recognize in the overall DNA structure the beginning of a structural gene. Moreover, one has to bear in mind that a single error (deletion or insertion) in the DNA sequence could lead to a completely erroneous amino acid sequence of the protein. Thus, primary structure determination of DNA cannot serve as a substitute for the direct sequencing of the protein. In view of this, we decided to utilize the methods of both protein
5 rpoC
EcoRI
rpo B
t ^D
Sail
E
—i
T
Fig. 1. EcoRI and Sail restriction cleavage m a p of the E.aoli DNA region including the structural genes (rpoB and rpoC) of the g-and g'- RNA polymerase subunits. and nucleotide chemistries, performing of the structural genes rpoB
the parallel
(g-subunit) and rpoC
sequencing
(3'-subunit)
and of the corresponding proteins. Knowledge of the nucleotide sequence of the pertinent DNA segments would permit
aligning
of the peptide fragments from the protein analysis into an uninterrupted polypeptide chain. Such an approach provides key to the most complicated problem in the primary analysis of high molecular
the
structure
proteins.
In Fig. 1 restriction endonucleases cleavage m a p of E. ool-i DNA region containing the structural genes of the g-and g '- subunits of the RNA polymerase given. We determined EcoRI-F
(rpoB and rpoC correspondingly)
the total sequence of the EcoRI-C
is
(4),
(5) and EcoRI-A - Hindlll fragments and partial
sequ-
ence of the EcoRI-G fragment carrying the beginning of the rpoB gene
(6). These fragments were obtained from DNA of
47 and rpoBC operon
18 transducing phages, containing the E. (7, 8), or corresponding plasmids by EcoRI
aoli
restric-
tion endonuclease digestion. In the case of EcoRI-A - Hindlll fragment EcoRI and Hindlll
digestions were used.
The fragments w e r e consecutivelv digested with one of the restriction endonucleases
(Sau 3AI, Hinf I, Hpa II and Taq I)
cleaving the DNA into relatively
small blocks. The resulting 32 subfragments were phosphorylated by means of |y- P|-ATP and
phage T4 polynucleotide kinase and the mixture was
separated
by electrophoresis on polyacrylamide gel. As a rule both
6
complementary chains obtained after denaturation of each subfragment and separation were analyzed. Their sequencing was performed by a modified Maxam-Gilbert procedure. As another method of the B-subunit polypeptide chain splitting, the digestion with Staphylococcus
aureus protease was chosen.
Initial fragmentation of the hydrolysate was performed by gel filtration on biogel P-4. This yielded four fractions. Subsequent separation of the peptides was achieved by chromatography on the cation exchanger AG-50Wx4 and paper chromatography. Fraction I contained a mixture of the largest peptides. To facilitate the separation and analysis of the peptides in this fraction the mixture was additionally digested with chymotrypsin. Altogether 3 peptides were isolated from fraction IV, 73 from fraction III, 48 frcm fraction II and 60 frcm frac tion I. In order to obtain the missing fragments, the exhaustive tryptic digestion of the B-subunit was carried out after modification of the lysine residues with citraconic anhydride. The tryptic peptides were separated according to the same scheme as that used for staphylococcal peptides. After removal of the citraconic protection the high molecular weight peptides were subjected to additional tryptic cleavage at the lysine residues. In order to determine the primary structure of the B'-subunit its cyanogen bromide cleavage was carried out. For separation of the resulting peptides we used gel filtration, paper and thin-layer chromatographies, electrophoresis in acetate cellulose slabs and butanol exstraction of hydrophobic peptides. The tryptic
digestion of the B'-subunit was also carried out af-
ter modification of the lysine residues with citraconic anhydride. The amino acid sequence of the peptide fragments determined up to now covers more than 80% of the total B-subunit polypeptide chain and about 30% of the B 1 -subunit polypeptide chain. During this investigation the comparison of the nucleotide and amino acid sequence was carried out continually. The search for similarities between the amino acid sequences of the
7 TTC CGG TCA ACA AAA TAG TGT TGC ACA AAC TGT CCG CTC AAT GGA CAG ATG GGT CGA CTT GTC AGC GAG CTG AGG AAC CCT ATG GTT TAC TCC TAT ACC GAG AAA AAA CGT ATT CGT AAG GAT TTT GGT AAA CGT CCA CAA GTT CTG GAT GTA CCT TAT CTC Het-Va1-Tyr-Ser-Tyr-Thr-Glu-lys-lys-Arg-l I e-Ar9-Lys-Asp-Phe-6 » y-Lys -Arg»?ro-ttIn-V«>-leu-Atp-Vat-Pro-Ty r -leu« CTT TCT ATC CAG CTT GAC TCG TTT CAG AAA TTT ATC GAG CAA GAT CCT GAA GGG CAG TAT GGT CTG GAA GCT GCT TTC CGT Leu-Ser-lle-Gln-Leu-Asp-Ser-Phe-Gln-Lys-Phe-lle-6lu-61n»Asp»Pro«Glu-Gly-Glri»Tyr-G1yleu»Clu-Ala-Al»*Phe*ArflTCC GTA TTC CCG ATT CAG AGC TAC AGC GGT AAT TCC GAG CTG CAA TAC GTC AGC TAC CGC CTT GGC GAA CCG GTG TTT GAC S e r - V a l - P h e - P r o - I I e - G 1 r > - S e r - T y r - S e r - G 1 y -Asn- S e r - G I u - L e u - G 1 n - T y r - V a 1 - S e r - T y r » A r g - l e u - G t y « G t u - P r o - V » ' - P h « - A » p « GTC Í A G GAA TGT CAA ATC CGT GGC GTG ACC TAT TCC GCA CCG CTG CGC GTT AAA CTG CGT CTG GTG ATC TAT GAG CGC GAA Val-Gln»Glu»Cy&-Gln-Ile-Arg-Gly-VaI»Thr-Tyr-Ser-Ala-Pro-leu-Arg-Val-Lys-leo-Arg-leu-Val-I Ie-Tyr»6tu-Arg»61 w GCG CCG GAA GGC ACC GTA AAA GAC ATT AAA GAA CAA GAA GTC TAC ATG GGC GAA ATT CCG CTC ATG ACA GAC AAC GGT ACC Al a-Pro-Çlu-Gl y-Thr-Va 1 - f c y s - A s p - M e - l y s - G l u - G l n - G 1 u - V a l - T y r » H e i - G 1 y - G l u - H e - P r o - l e u « H e t - T h r - A s p « A s r i - G » y - T h r TTT GTT ATC AAC GGT ACT GAG CGT GTT ATC GTT TCC CAG CTG CAC CGT AGT CCG GGC GTC TTC TTT GAC TCC GAC AAA GGT P h e - V a I - I l e - A s n - G l y - T h r - G l u - A r g - V a l - l I e - V a ) - S e r - G I n - l e u - H i s - A r g - S e r - P r o - G I y•Va I - P h e - P h e - A s p - S e r - A » p - l y S - G 1 y AAA ACC CAC TCT TCG GGT AAA GTG CTG TAT AAC GCG CGT ATC ATC CCT TAC CGT GGT TCÊ TGG CTG GAC TTC GAA TTC GAT l y s - T h r » H i s - S e r - S e r - G l y - L y s - V a I - L e u - T y r - A s n - A l a - A r g - I l e - l ) e - P r o - T y r - A r g - G 1 y • S e r - T r p - l e u - A » p - P h e - G 1u-Phe-AspCCG AAG GAC AAC CTG TTC GTA CGT ATC GAC CGT CGC CGT AAA CTG CCT GCG ACC ATC ATT CTG CGC GCC CTG AAC TAC ACC Pro-lys-A>p-Asn-leu-Phe-Vat-Arg-l1e-Asp-Arg-Arg«Arg-Lys-leu-Pro-Ala-Th r - I l e - l le-leu-Arg-Ala-leu-A>n-Tyr-ThrACA GAG CAG ATC CTC GAC CTG TTC TTT GAA AAA GTT ATC TTT GAA ATC CGT GAT AAC AAG CTG CAG ATG GAA CTG GTG CCG Th r - G Iu-G I n » I I e - 1 e u - A s p - l e u - P h e - P h e - G 1u-Ly s-Va I - I l e - P h e - G l u - l I e » A r g - A s p - A s n - L y * - L e u - G 1 n - H e t - G 1 u - l e u - V » I - P r o GAA CGC CTG CGT GGT GAA ACC GCA TCT TTT GAC ATC GAA GCT AAC GGT AAA GTG TAC GTA GAA AAA GGC CGC CGT ATC ACT G)u-Arg-Leu-Arg-G1y-G)u-Thr-Ala-Ser-Phe-Asp-ne-Glu-Ala-Asn-C1y-Lys-Val-Tyr»Val-Glu-lys-G1y-Arg-Arg-lle-ThrGCG CGC CAC ATT CGC CAG CTG GAA AAA GAC GAC CTC AAA CTG ATC GAA GTC CCG GTT GAG TAC ATC GCA GGT AAA GTG GTT A l a - A r g « H i s - I l e - A r g - G I n - L e u - G Iu-Ly s - A s p - A s p - V a l - l y s - l e u - l l e - C l u - V a l - P r o - V a l - G l u - T y r - M e - A > e - 6 » y - l y S - V a i - V a 1 GCT AAA GAC TAT ATT GAT GAG TCT ACC GGC GAG CTG ATC TGC GCA GCG AAC ATG GAG CTG AGC ¿ T G GAT CTG CTG GCT AAG Ala-Ly>»Asp-Tyr-Ite-Asp-G1u-Ser-Thr-Gly-Glu-Leu-Me-Cys-Ala-Ala-Asn-Het-Glu-leu-Ser-Leu-Asp-Leu-leu-Ala-Lys» CTG AGC CAG TCT GGT CAC AAG CGT ATC GAA ACG CTG TTC ACC AAC GAT CTG GAT CAC GGC CCA TAT ATC TCT GAA ACC TTA Leu-Ser-Gln-Ser-Gly-Mis-Lys-Arg-Ile-Clu-Thr-Leu-Phe-Thr-Asn-Asp-Leu-Asp-His-Gly-Pro-Tyr-Me-Ser-Glu-Thr-LeuCGT GTC GAC CCA ACT AAC GAC CGT CTG AGC GCA CTG GTA GAA ATC TAC CGC ATG ATG CGC CET GGC GAG CCG CCG ACT CGT Arg-Val-Asp-Pro-Thr-Asn-Asp-Arg-Leu-Ser-Ala-Leo-Val-GIu-lle-Tyr-Arg-Wet-HefArg-Pro-Gly-Glu-Pro-Pro»Thr»Arg»
AAC CGT TCT CTG CTG CGC GAA GAA ATC GAA GGT TCC GGT ATC CTG AGC AAA GAC GAC ATC ATT GAT GTT ATG AAA AAG CTC A s n - A r g - S e r - l e u - l e u - A r g - G I u-GI u - I le-61 u - G l y - S e r - G l y - I l e - l e u - S e r - l y s - A > p - A i p - M e - M e - A s p - V » l - H e t - l y i - l y » - l c w ATC GAT ATC CGT AAC GGT AAA GGC GAA GTC GAT GAT ATC GAC CAC CTC GGC AAC CGT CGT ATC CGT TCC GTT GGC GAA ATG I le-Asp-t le-Arg-Asn-G I y - l y s - G l y - G l u - V a l - A s p - A s p - I l e - A s p - H i s - l e u - G 1 y - A > n - A r g - A r g - l l e - A r g - S e r - V a l - G l y - G l u - H e t GCG GAA AAC CAG TTC CGC GTT GGC ÈTG GTA CGT GTA GAG CGT GCG GTG AAA GAG CGT CTG TCT CTG GGC GAT CTG GAT ACC A l a - G l u-As n» G 1 n - P h e - A r g - V a I - G ) y - l c u - V a l - A r g - V a 1 - G l u - A r g - A l a - V a I - L y s - G l u - A r g - L e u - S e r - l e u - G I y - A s p - L e u * A s p - T h r CTG ATG CCA CAG GAT ATG ATC AAC GCC AAG CCG ATT TCC GCA GCA GTG AAA GAG TTC TTC GGT TCC AGC CAG CTG TCT CAG Leu-He t - P r o - G l n - A s p - H e t - l l e - A s n - A l a - l y s - P r o - l l e - S e r - A l a - A l a » V a l » l y s - G ) u - P h e « P h e - G I y - S e r - S e r - G l n - l e u - S e r - G I n TTT ATG GTC CAG AAC AAC CCG CTG TCT GAG ATT ACG CAC AAA CGT CGT ATC TCC GCA CTC GGC C Í A GGC GGT CTG ACC CGT Phe-Het-Val-GIn-Asn-Asn-Pro-leu-Ser-Glu-lle-Thr-Hi s-Lys-Arg-Arg-lle-Ser-Ala-leu-Gly-Pro-Gly-Gly-leu-Thr-ArgGAA CGT GCA GGC TTC GAA GTT CGA GAC GTA CAC CCG ACT CAC TAC GGT CGC GTA TGT CCA ATC GAA ACC CCT GAA GGT CCG Glu-Arg-Ala»61y-Phe-Glu-Val-Arg-Asp-Val-His-Pro»Thr-His-Tyr»Gly*Arg-Val-Cys*Pro-lle-Glu»Thr-Pro-Glu»Gty-Pro» AAC ATC GGT CTG ATC AAC TCT CTG TCC GTG TAC GCA CAG ACT AAC GAA TAC GGC TTC CTT GAG ACT CCG TAT CGT AAA GTG A s n - l l e - G l y - L e u - l l e - A s n - S e r - l e u - S e r - V a l - T y r - A I a•G I n - T h r - A s n - G I u - T y r - G 1 y - P h e - I e u - G I u - T h r - P r o - T y r - A r g - I y > - V a I ACC GAC GGT GTT GTA ACT GAC GAA ATT CAC TAC CTG TCT GCT ATC GAA GAA GGC AAC TAC GTT ATC GCC &AG GCG AAC TCC Thr-Asp-Gly-Val-Val-Thr»Asp-Glu-lle-His-Tyr-Leu-Ser-Ala-lle-Glu-Glu-Gly-Asn-Tyr-Val»lle»Ala-Gln»AI«-Asn-SefAAC TTG GAT GAA GAA GGC CAC TTC GTA GAA GAC CTG GTA ACT TGC CGT AGC AAA GGC GAA TCC AGC TTG TTC AGC CGC GAC Asn-leu-Asp-Glu-Glu-GI y H i s-Phe-Vat-6lu-Asp-leu-Va1-Thr-Cys-Arg»Ser«Lys-Cly-61 u-Ser-Ser-lcu-Phe-Ser-Arg-A»pCAG GTT GAC TAC ATG GAC GTA TCC ACC CAG CAG GTG GTA TCC GTC GGT GCG TCC CTG ATC CCG TTC ¿ T G GAA CAC GAT GAC Gln-Val-Asp'Tyr-Het-Asp-Val-Ser-Thr-Gln-Gln-Val-Val-Ser-Val-Cly-Ala-Ser-leu-l)e-Pro-Phe-leu-Glu-HI$-A»p-A»pGCC AAC CGT GCA TTG ATG GGT GCG AAC ATG CAA CGT CAG GCC GTT CCG ACT CTG CGC GCT GAT AAG CCG CTG GTT GGT ACT Ala-Asn-Arg-Ala-leu-het-Gly-Ala-Asn-Het-Gln-Arg-Gln-Ala-VaI-Pro»Thr-L - G t y - V I - S e f G I y-Th r - V « I - I ¡ • • A i p - V i l - G l n - V a l - P h e - T h r - A r q - A i p - G l y - V a l - G l u - L y t - A s p - L y s - A r g - A l a CTG GAA ATC GAA GAA ATG CAG CTC AAA CAO GÇG AAG AAA GAC CTG TCT GAA GAA CTG CAG ATC CTC GAA GCG GGT CTG TTC AGC CGT ATC CGT GCT GTG CTG GTA GCC GGT GGC GTT GAA GCT GAG AAG CTC GAC AAA CTG CCG CGC GAT CGC TGG CTG GAG S e r-A rq- I ( e - A r q - A 1 a - V a I - l « w - V a I - A I a - G ) y - G I y - V » l - G l u - A l a - G l u - L y » - l e M - A « p - l y » - L e u - P r o - A r g - A » p - A r g - T r p - L e u - G l u CTG GGC CTG ACA GAC GAA GAG AAA CAA AAT CAG CTG GAA CAG CTG GCT GAG CAG TAT GAC GAA CTG AAA CAC GAG TTC GAG Leu-Gly-L«u-Thr-A»p-Glu-GU-Ly»-G(n-A»n'G)n-L«u-Glu-Gln-Leu-Ala-Glu-Gln-Tyr-Atp-Glu-Leu-Lys-His-Glu-Phc-G)uAAG AAA CTC GAA GCG AAA CGC CGC AAA ATC ACC CAG GGC GAC GAT CTG GCA CCG GGC GTG CTG AAG ATT GTT AAG GTA TAT L y s - l y » - L e u - G l u - A l a - L y » - A r g - A r g - L y » - t I e - T h r - G In-G 1 y - A i p - A » p - L e u - A I a - P r o - G 1 y-Va 1 - L e u - L y s - I l e - V a l - L y s - V a l -Ty r CTG GCG GTT AAA CGC CGT ATC CAG C Î T GGT GAC AAG ATG GCA GGT CGT CAC GGT AAC AAG GGT GTA ATT TCT AAG ATC AAC Leu-Ala-Val-Lyt-Arg-Arg-lle-6tn-Pro-Gly-A»p-ty»-Het-Ala-Gly-Arg-His-Gly-Asn-tyi-Gly-Val-lle-Ser-Ly»-lte-A»nCCG ATC GAA GAT ATG CCT TAC GAT GAA AAC GGT ACG CCG GTA GAC ATC GTA CTG AAC CCG CTG GGC GTA CCG TCT CGT ATG P r o - I l e - G l u - A » p - H e t - P r o - T y r - A t p - G l u - A s n - G l y - T h r - P r o - V a l - A » p - l I e -Va I - L e u - A s n - P r o - L e u - G 1 y - V a 1 - P r o - S e f - A r q - H e t -
CAG CAA GAA GTC GCG AAA CTG CGC GAA TTC ATC CAG CGT GCG TAC GAT CTG GGC GCT GAC GTT CGT CAG AAA GTT GAC CTG - A I « - L y s L e u A r q G l u -Phe 1 e G i n A r q A l a T y r Asp L e u G l y A l a Asp V a l A r q Asp L e u « Ly. AGT ACC TTC AGC GAT GAA GAA GTT ATG CGT CTG GCT GAA AAC CTG CGC AAA GGT ATG CCA ATC GCA ACG CCG GTG TTC GAC - S e r -Asp - G l u G l u V a l Het -Arq L e u A l a G u Asn L e u A r q L y s u i y He t P r o 1 l e A l a T h r P r o Va 1 AspGGT GCG AAA GAA GCA GAA ATT AAA GAG CTG CTG AAA CTT GGC GAC CTG CCG ACT TCC GGT CAG ATC CGC CTG TAC GAT GGT G l y - A l a •Ly» - G l u - A l a - G l u l l e L y , G l u L e u L e u L y s L e u G y Asp L e u P r o Thr S e r G l y G i n 1 e A r g L e u l y r Asp G l y CGC ACT GGT GAA CAG TTC GAG CGT CCG GTA ACC GTT GGT TAC ATG TAC ATG CTG AAA CTG AAC CAC CTG GTC GAC GAC AAG A r g •Thr - l i l y - G l u G i n - P h e G u * r q P r o Va 1 Thr V a t G l y T y r Met l y r Het L e u L y s L e u A s n HI s L e u Va 1 A s p A s p L y s ATG CAC GCG CGT TCC ACC GGT TCT TAC AGC CTG GTT ACT CAG CAG CCG CTG GGT GGT AAG GCA CAG TTC GGT GGT CAG CGT H e t •Hi S -Arq Thr G l y S e r Ty r S e r L e u Va 1 Thr G i n G i n P r o L e u G l y G l y L y s A l a G i n P h e G l y G l y G i n A r r TTC G6G GAG ATG GAA GTG TGG GCCLCTG GAA GCA TAC GGC RCA GCA TAC ACC CTG CAG GAA ATG CTC ACC GTT AAG TCT GAT Gly ••Het G l u Va 1 U p A l a L e u G l u A l a l y r G l y A l a A l a T y r Thr L e u G i n G l u He t L e u T h r Va 1 L y s S e r AspGAC GTG AAC GGT CGT ACC AAG ATG TAT AAA AAC ATC GTG GAC GGC AAC CAT CAG ATG GAG CCG GGC ATG CCA GAA TCC TTC Ar q Thr L y s Met T y r L y » Asn 1 e Va l Asp G y Asn H s G i n He t Asp G y H e t P r o G l u S e r PheAAC GTA TTG TTG AAA GAG ATT CGT TCG CTG GGT ATC AAC ATC GAA CTG GAA GAC GAG TAA TTC TCG CTC AAA CAG GTC A Asn Lew L e u L y s G l u 1 l e A r q S e r L e u G l y Asn G l u L e u G l u Asp G l u Tt R CTG CTG TCG GGT TAA AAC CCG GCA GCG GAT TGT GCT AAC TCC GAC GGG AGC AAA TCC GTG AAA GAT TTA TTA AAG TTT CTG Het L y s Asp L e u L e u L y s P h e l e u AAA GCG CAG ACT AAA AC f. GAA GAG TTT GAT GCG ATC AAA ATT GCT CTG GCT TCG CCA GAC ATG ATC CGT TCA TGG TCT TTC Lys G l u Phe Asp A l a 1 l e L y s 1 e A l a L e u Ser Asp H e t Arg S e r I r p Ser Phe* lys GGT GAA 6TT AAA AAG CCG GAA ACC ATC AAC TAC CGT ACG TTC AAA CCA GAA CGT GAC GGC CTT TTC TGC GCC CGT ATC TTT Gly Leu L y * L y s P r o G u Thr 1 l e Asn l y r A r g Thr Phe L y s P r o G l u A r g Asp C y s A l a A r g 1 e PheGGG CCG GTA AAA GAT TAC GAG TGC CTG TGC GGT AAG TAC AAG CGC CTG AAA CAC CGT GGC GTC ATC TGT GAG AAG TGC GGC Gly G l u L y s Cys G l y L y » Asp l y r G l u Cys L e u Cys G l y L y s T y r L y s A r g L e u L y s H i s A r g GTT GAA GTG ACC CAG ACT AAA GTA CGC CGT GAG CGT ATG GGC CAC ATC GAA CTG GCT TCC CCG ACT GCG CAC ATC TGG TTC Va 1 G n Thr L y s V a l A r g A r g G l u A r g Het G l y H I S 1 1 G l u L e u A l a H I S I l e I r p PheCTG AAA TCG CTG CCG TCC CGT ATC GGT CTG CTG CTC GAT ATG CCG CTG CGC GAT ATC GAA CGC GTA CTG TAC TTT GAA TCC Arg lyr LysGlu SerLewS e r - Arg- l l e G l y L e u L e u L e u Asp He c P r o L e u A r q Asp 1 l e TAT GTG GTT ATC GAA GGC GGT ATG ACC AAC CTG GAA CGT CAG CAG ATC CTG ACT GAA GAG CAG TAT CTG GAC GCG CTG GAA Tyr-Val-Val-lle-Glu-Gly-Gly-Met-Thr-Aïn-Leu-Glu-Arg-Gln-Gln-lle-Leu-Thr-Gtu-Glu-G1n-Tyr-Leu-A»p-Ala-Leu-Glu-
Fig. 2. The nucleotide sequence of the rpoBC segment, the total amino acid sequence of the g-subunit and the N-terminal amino acid sequence of the 6'-subunit of E. ooli RNA polymerase. The restriction EcoRI cleavage sites dividing the fragments EcoRI-G, EcoRI-C and EcoRI-F are situated between nucleotides 640-641 and 3508-3509. Here and in Fig. 3 the nucleotide sequence of the complementary DNA chain, equal to the sequence of mRNA, is given. The underlined amino acid sequences are those the structure of which has been determined from analysis of corresponding peptides. C* refer to 5-methylcytidine residues.
9 1-75 1-25
GAA TTC GGT CGT ACT AAA GAA AGC TAC AAA GTA CCT TAC GOT GCG GTA CTG GIG AAA GGC GAT GGC GAA CAG GTT G ^ u - P h e - G l y - A ^ g - ^ - l J ' 2 - G ' u - S e r " T y r " l - y 5 " V a ' " p ^ 0 " 1 ^ r " G , y " A , " " V a , -Leu-Ala-Lys-Gly-Asp-Gly-Glu-Gln-Val -
76-150 26-50
GCT GGC GGC GAA ACC GTT GCA AAC TGG GAC CCG CAC ACC ATG CCG GTT ATC ACC GAA GTA AGC GGT TTT GTA CGC A l a - G l y - G l y - G l u - T h r - V a I - A l a - A s n - l r p - A s p - P r o - H i s-Thr-Met-Pro-Val-11e-Thr-G1u-Va1-Ser-GTy-Phe-Val-Arq-
151-225 51-75
TTT ACT GAC ATG ATC GAC GGC CAG ACC ATT ACG CGT CAG ACC GAC GAA CTG ACC GGT CTG TCT TCG CTG GTG GTT Phe-Thr-Asp-Met-I1e-Asp-G1y-G1n-Thr-Ile-Thr-Arg-Gln-Thr-Asp-G1u-Leu-Thr-Gly-Leu-Ser-Ser-Leij-Val-Va1-
226-30C 76-100
CTG GAT TCC GCA GAA CGT ACC GCA GGT GGT AAA GAT CTG CGT CCG GCA CTG AAA ATC GTÏ GAT GCT CAG GGT AAC Leu-Asp-5er-Ala-Glu-Arg-Thr-Ala-G^-Gly-Lys-Asp-Leu-Arg-Pro-Ala-Leu-Lys-Ile-Val-Asp-Ala-Oln-Gly-Asn-
301-375 101-125
GAC GTT CTG ATC CCA GGT ACC GAT ATG CCA GCG CAG TAC TTC CTG CCG GGT AAA GCG AIT GTT CAG CTG GAA GAT Asp-Val-Leu-Ile-Pro-Gly-Thr-Asp-Mrt-Pro-Ala-Gln-Tyr-Phe-Leu-Pro-Gly-Lys-Ala-Me-Val-Gln-Leu-Glu-Asp-
376-450 126-150
C.GC GTA CAG ATC AGC TCT GGT GAC ACC CTG GCG CGT ATT CCG CAG GAA TCC GGC GGT ACC AAG GAC ATC ACC GGT Gly-Val-Gln-lle-Scr-Ser-Gly-Asp-Thr-Leu-Ala-Arg-lle-Pro-Gln-Glu-Ser-Gly-Gly-Thr-Lys-Asp-Ile-Thr-Gly-
451-525 151-175
GGT CTG CCG CGC GTT GCG GAC CTG TTC GAA GCA CGT CGT CCG AAA GAG CCG GCA ATC CTG GCT GAA ATC AGC GGT Gly-Leu-Pro-Arg-Val-Ala-Asp-leu-Phe-Glu-Ala-Arg-Arg-Pro-Lys-Glu-Pro-Ala-11e-Leu-A1a-Glu-IIe-5er-Gly-
526-600 176-200
ATC GTT TCC TTC GGT AAA GAA ACC AAA GGT AAA CGT CGT CTG GTT ATC ACC CCG GTA GAC GGT AGC GAT CCG TAC Ile-Val-Ser-Phe-Gly-Lys-Glu-Thr-Lys-Gly-Lys-Arg-Arg-Leu-Val-1le-Thr-Pro-Val-Asp-Gly-Ser-Asp-Pro-Tyr-
601-675 201-225
GAA GAG ATG ATT CCG AAA TGG CGT CAG CTC AAC GTG TTC GAA GGT GAA CGT GTA GAA CGT GGT GAC GTA ATT TCC Glu-Glu-Met-Ile-Pro-Lys-Trp-Arg-Gln-Leu-Asn-Val-Phe-Glu-Gly-Glu-Arg-Val-Glu-Arg-Gly-Asp-Val-Ile-Ser-
676-750 226-250
GAC GGT CCG GAA GCG CCG CAC GAC ATT CTG CGT CTG CGT GGT GTT CAT GCT GTT ACT CGT TAC ATC GTT AAC GAA Asp-Gly-Pro-Glu-Ala-Pro-Hls-Asp-llc-Leu-Arg-Leu-Arg-Gly-Val-His-Ala-Val-Thr-Arg-Tyr-I le-Val-Asn-Glu-
751-825 251-275
GTA CAG GAC GTA TAC CGT CTG CAG GGC GTT AAG ATT AAC GAT AAA CAC ATC GAA GTT ATC GTT CGT CAG ATG CTG Val -Gin-Asp-Val-Tyr-Arg-Leu-Gln-Gly-Val-Lys-Ile-Asn-Asp-Lys-His-Ile-Glu-Val-1le-Val-Arg-Gln-Met-Leu-
826-9Û0 276-300
CGT AAA GCT ACC ATC GTT AAC GCG GGT AGC TCC GAC TTC CTG GAA GGC GAA CAG GTT GAA TAC TCT CGC GTC AAG Arg-Lys-Ala-Thr-Ile-Val-Asn-Ala-Gly-Ser-Ser-Asp-Phe-Leu-Glu-Gly-Glu-Gln-Val-Glu-Tyr-Ser-Arg-Val-Lys-
30J-975 301-325
ATC GCA AAC CGC GAA CTG GAA GCG AAC GGC AAA GTG GGT GCA ACT TAC TCC CGC GAT CTG CTG GGT ATC ACC AAA lle-Ala-Asn-Arg-Glu-l.eu-Glu-Ala-Asn-Gly-Lys-Val-Gly-Ala-Thr-Tyr-Ser-Arg-Asp-Leu-Leu-Gly-lle-Thr-Lys-
976-1050 326-350
GCG TCT CTG GCA ACC GAG TCC TTC ATC TCC GCG GCA TCG TTC CAG GAG ACC ACT CGC GTG CTG ACC GAA GCA GCC Ala-Ser-Leu-Ala-Thr-Glu-Ser-Phe-Ile-Ser-Ala-Ala-Ser-Phe-Gln-Glu-Thr-Thr-Arg-Val-Lcu-Thr-Glu-Ala-Ala-
I05I-1125 351-375
GTT GCG GGC AAA CGC GAC GAA CTG CGC GGC CTG AAA GAG AAC GTT ATC GTG GGT CGT CTG ATC CCG GCA GGT ACC Val-Ala-Gly-Lys-Arg-Asp-Glu-leu-Arg-Gly-Leu-Lys-Glu-Asn-Val-lle-Val-Gly-Arg-Leu-lle-Pro-Ala-Gly-Thr-
I126-1200 376-400
GGT TAC GCG TAC CAC CAG CAT CGT ATG CGT CGC CGT GCT GCG GGT GAA GCT CCG GCT GCA CCG CAG GTG ACT GCA Gly-Tyr-Ala-Tyr-His-Gln-Asp-Arq-Met-Arg-Arg-Arg-Ala-Ala-Gly-Glu-Ala-Pro-Ala-Ala-Pro-Gln-Val-Thr-Ala-
I20I-I277 401-421
GAA GAC GCA TCT GCC AGC CTG GCA GAA CTG CTG AAC GCA GGT CTG GGC GGT TCT GAT AAC GAG TAA TCGTTAATCCG CH'-Asp-Ala-Ser-Ala-Ser-Leu-Ala-Glu-Leu-Leu-Asn-Ala-Gly-Leu-Gly-Gly-Ser-Asp-Asn-Glu Ter
1278-1376
CAAATAACGT.AAAAACCCGC.TTCI;GCGGGTTTTT,TTATGGGGGGAGTTTAGGGAAAGAGCATTTGTCAGAATATTTAAGGAATTTCTGAATACTCATAA
1377-1475
TCAATGTAGAGATGACTAATATCCTGAAACTGACTGAACTAATTGAGTCAAACTCGGCAAGGATTCGATACTATTCCTGTGTAACTTTCTTAAGGAACG
¡476-1574
AGAATGAAACAGGAAGTGGAAAAGTGGCGACCTTTTGGACATCCGGATGGTGATATTCGTGATTTATCATTTCTTGATGCTCATCAGGCTGTCTACGTT
1575-1673
CAGCATCATGAGGGCAAAGAGCCTTTAGAGTATCGCTTTTGGGTTACCTACTCTCTTCACTGCTTCACAAAAGATTATGAACATCAGACGAACGAAGAA
1674-1772
AAACAATCGTTAATGTACCACGCGCCTAAAGAATCTCGTCCCTTCTGCCAGCACCGTTATAACTTAGCGCGCACACACTTAAAAAGAACTATTTTGGCG
1773-187I
CTGCCAGAAAGCAACGTTATTCATGCCGGGTATGGTAGCTATGCCGTGATTGAGGTGGACTTAGACGGAGGAGATAAGGCATTTTACTTTGTTGCGTTC
1072-1970
AGGGCTTTCAGGGAAAAGAAAAAACTCCGTTTGCATGTAACTAGCGCTTATCCCATTTCTGAAAAACAGAAAGGTAAATCAGTGAAATTTTTCACCATT
1971-2069
GCCTACAACTTATTGAGAAATAAGCAGCTTCCTCAGCCCTCAAAATAACAAAACCCACCTTAAGGTGGGTTTCGCCAGAGAATTATCTCTGGTATTCAG
2070-2168
AACGCCATTACCGGACTTTGCCTTGACCTTGCGATAATCGCAGGTTGCGGGATGTCTGAATTTCTTCAGTCTGCTGCATCCTGGAAGATGAGAACATGT
2169-2267 2268-2306
GTTCTTATTTTCGTCTCTATCATAGTTGAGTATTTACTCTCTTACAATCAGATCTCTTTCATTGCTCAACAGGCGATGGCTTCAGACTTTGCATTACGG AATTTTTAAGAAAGGCAGGGCGAAACGAGGAAGAAGCTT
Fig. 3. The nucleotide sequence of the EcoRI-A - Hindlll fragment and the C-terminal amino acid sequence of the e'-subunit of E. aoli RNA polymerase.
10
peptides and the nucleotide sequences of the corresponding DNA fragments was carried out by means of a computer. A conjunction of the methods of protein and nucleotide chemistry for the combined structural investigation of a protein and DNA sharply accelerated and considerably simplified the solution of both problems and enhanced the reliability of the structural analysis. As a result the nucleotide sequences of the two segments of the rpoBC operon (4714 and 2306 base pairs) embracing the entire rpoB gene, the initial and terminal parts of the rpoC gene and the intercistronic region, together with the total amino acid sequence of the 3- subunit, comprising 1342 residues
(9, 10), and the N- and C-terminal sequences of the
g'-subunit (176 and 421 residues) were determined (Eig. 2, 3).
References 1. 2.
Ovchinnikov, Yu.A., Lipkin, V.M., Modyanov, N.N., Chertov, 0.Yu., Smirnov, Yu.V.: FEBS Letters 76, 108-111 (1977). Marchenko, T.V., Modyanov, N.N., Lipkin, V.M., Ovchinnikov, Yu.A.: Bioorg. Khim. 6, 325-331 (1980).
3.
Lipkin, V.M., Marchenko, T.V., Khokhryakov, V.S., Polovnikova, I.N., Potapenko, N.A., Modyanov, N.N., Ovchinnikov, Yu.A.: Bioorg. Khim. 6, 332-342 (1980).
4.
Ovchinnikov, Yu.A., Sverdlov, E.D., Lipkin, V.M., Monastyrskaya, G.S., Chertov, O.Yu., Gubanov, V.V., Guryev, S.O., Modyanov, N.N., Grinkevich, V.A., Makarova, I.A., Marchenko, T.V., Polovnikova, I.N.: Bioorg. Khim. 6, 655-665 (1980).
5.
Monastyrskaya, G.S., Gubanov, V.V., Guryev, S.O., Lipkin, V.M., Sverdlov, E.D.: Bioorg. Khim. 6, 1106-1109 (1980).
6.
Monastyrskaya, G.S., Gubanov, V.V., Guryev, S.O., Lipkin, V.M., Sverdlov, E.D.: Bioorg. Khim. 6, 1423-1426 (1980).
7.
Mindlin, S.S., Ilyina, T.S., Gorlenko, Ch.M., Hachikyan, N.A., Kovalev, Yu.N.: Genetika 12, 116-130 (1976).
8.
Kirschbaum, J.B., Konrad, B.E.: J. Bacteriology 116, 517526 (1973).
9.
Ovchinnikov, Yu.A., Monastyrskaya, G.S., Gubanov, V.V., Guryev, S.O., Chertov, O.Yu., Modyanov, N.N., Crinkevich, V.A., Makarova, I.A., Marchenko, T.V., Polovnikova, I.N., Lipkin, V.M., Sverdlov, E.D.: Dokl. Akad. Nauk SSSR 253,
11
994-999 (1980). 10.
Ovchinnikov, Yu.A., Monastyrskaya, G.S., Gubanov, V.V., Guryev, S.O., Chertov, O.Yu., Modyanov, N.N., Grinkevich, V.A., Makarova, I.A., Marchenko, T.V., Polovnikova, I.N., Lipkin, V.M., Sverdlov, E.D.: Eur. J. Biochem.116, 621-629 (1981) .
STUDY ON THE PRIMARY STRUCTURE OF THE ELONGATION FACTOR G FROM
E.ooli
Yuli B. Alakhov, Ludmila P. Motuz, Natalia V. Dovgas and Yuri A. Ovchinnikov Institute of Protein Research, Academy of Sciences of the USSR, 142292 Poustchino, Moscow Region, USSR
Introduction The bacterial protein-synthesizing system is known to contain three soluble proteins participating in synthesis of polypeptide chains on the ribosome at the elongation stage. One of them, the elongation factor G (EF-G), catalyzes the GTP-dependent translocation of the peptidyl-tRNA'mRNA complex from the A-site into the P-site on the ribosome. This is accompanied by the release of the deacylated tRNA from the P-site and the removal of the tRNA from the ribosome
(1).
EF-G represents a protein consisting of one polypeptide chain with M r of about 80,000. The use of traditional methods for the determination of the primary structure did not seem expedient for such a large protein. Therefore J choosing the strategy of structural analysis,we opted at the first stage for limited proteolysis which splits the protein molecule into a small number of large fragments relatively stable to further protease action. It has been shown earlier that mild tryptic hydrolysis splits the elongation factor G into five fragments (2-4), four of them
(T4-T7) [for the fragments nomenclature
see (3)] encompass the whole protein polypeptide chain. Thus, the study of the EF-G primary structure amounted to the determination of the structure of these four fragments and the search for the peptides which assemble the fragments of li-
C h e m i s t r y of P e p t i d e s a n d P r o t e i n s , V o l . 1 © 1982 by W a l t e r d e G r u y t e r &. C o . , B e r l i n • N e w Y o r k
14 mited trypsinolysis into one polypeptide chain. Results From the data of amino acid analysis and determination of the molecular mass of peptide fragments which are the products of tryptic hydrolysis it can be concluded that limited trypsinolysis does not result in splitting off of any notable regions of the polypeptide chain (3). At the same time, elucidation of the structure of peptides obtained during the study of the EF-G cyanogen bromide
cleavage
permitted us to assemble all
the fragments of limited trypsinolysis into one polypeptide chain. Hence it follows that there are really no insertions between the fragments of limited trypsinolysis, i.e. trypsin produces point disruptions of the EF-G polypeptide chain (4). Fragment Tg is N-terminal, it is followed along the chain by fragment T^ which contains the functionally important cysteine residue. The GTP-binding site is located within this fragment (5). Fragment T^ is followed by fragment T^ and, finally, comes fragment T^ representing the C-terminal part of the EF-G molecule. The study of the structure of fragments T^-T^ turned out to be simple enough because of their rather low molecular mass. The molecular mass of fragment T g is 6500, that of
- 7500
and that of T,- - 25,000. Using traditional chemical and enzymatic methods for cleavage of the polypeptide chain, we determined completely the primary structure of fragments Tg (4), T^ (6,7) and T,. which all together embrace more than 350 amino acid residues. We have shown earlier (3) that all the fragments of limited EF-G trypsinolysis have arginine as the C-terminal amino acid residue while in the G-factor lysine is the C-terminal amino acid residue. Studying the products of cyanogen bromide cleavage of the whole EF-G molecule we isolated a peptide having
15 the sequence analogous to that of the C-terminal cyanogen bromide peptide of fragment T^ but differing by two amino acid residues at the C-terminus: Gly-Lys. Therefore we concluded that limited trypsinolysis of EF-G resulted in splitting off the C-terminal di-peptide. To obtain overlapping between the fragments of limited trypsinolysis and to elucidate the structure of fragment T^ representing the middle part of the protein polypeptide chain with M r 41,000, we studied the products of cyanogen bromide cleavage of the whole EF-G molecule. As a result, all 24 cyanogen bromide peptides have been isolated, among which 13 peptides constituting the structure of fragment T^. Thus, the study of the structure of fragment T^ amounted to the elucidation of the amino acid sequence of 13 cyanogen bromide peptides and 1. L I M I T E D T R Y P T I C
I T
DIGEST
EF-G
I
T
T
EF-G
FRAGMENTS OF L I M I T E D
A
OF
RG
TRYPSINOLYSIS
RE
RQ
R K
Te
2.
CYANOGEN BROMIDE CLEAVAGE OF E F - G AND FRAGMENTS T ^ AND T5
CYANOGEN BROMIDE
PEPTIDES OVFRLAPPIHG
FRAGMENTS OF L I M I T E D
u 1=1
E
M V
TRYPSINOLYSIS
d
M
M
CYANOGEN BROMIDE P E P T I D E S C O N S T I T U T I N G
THE P O L Y P E P T I D E
E
C H A I N OF FRAGMENTS T(, AND T 5
MG MG \ MEMG M E
diaaauabdddddtiaat
3 MMGG M K M V M E O
SCHEME.
THE PATHWAY OF S T U D Y I N G
MG
ML
THE PRIMARY
STRUCTURE OF
To O B T A I N O V E R L A P P I N G BETWEEN CYANOGEN BROMIDE PRODUCTS OF T H E I R WERE
STUDIED
K
MY
MG
ÜÜ
MKMLMFMER
EF-G.
P E P T I D E S OF FRAGMENTS T^ AND T5
H Y D R O L Y S I S BY T R Y P S I N AND STAPHYI OCOCCUS AUREUS
PROTEASE
16
the search for overlapping between them. To obtain overlapping peptides, we used hydrolysis of fragment T 4 by trypsin and Staphylococcus
aureus protease.
These data pemitted us to represent the partial structure of the elongation factor G. Its polypeptide chain contains over 700 amino acid residues. Several regions of the obtained amino acid sequence have been recently confirmed by the study of the nucleotide sequence of the gene coding for EF-G. Thus, the study of sir operon of E.coli resulted in determination of the nucleotide sequence corresponding to 9 2 amino acid residues from the N-terminus of EF-G (8); elucidation of the nucleotide sequence of the tuf A gene coding for the elongation factor Tu gave the structure of the region of the fus gene coding for the C-terminal part of EF-G
consisting of twenty amino acid residues (9). In both
cases there is a coincidence between the amino acid sequences determined directly and those resulting from studies of the DNA structure. Since EF-G and EF-Tu perform similar functions on the ribosome, i.e. possess ribosome-dependent GTPase activity, it is interesting to compare their amino acid sequences forming the GTPbinding sites. Though the EF-G molecule is almost twice that of EF-Tu, it turned out that in both proteins these regions are located in the N-terminal part of the molecule. The cysteine residue located in close proximity to the GTP-binding site occupies a similar position in both proteins. It is difficult at first glance to find homology between the amino acid sequences of the GTP-binding sites in both proteins. However, if we take into account several insertions or deletions the homology is 30% and if we take into account conservative replacements the homology amounts to 45% (10). These calculations have been made taking into account deletions in 10 amino acid residues in EF-Tu (position 23-32 in the figure). Laursen
17
y
TRYPSIN l(G' (GTP) EF-G
H-N-L
(tRNA)S EF-Tu
1-COOH S(GTP)
VS///A
H-N-l
3 - COOH
TRYPSIN
TRYPSIN B
EF-G EF-Tu
TMD —
W M E Q E Q E R^G I T I
il
il
I II
- TSAATTAFWSGMAKQYE-PHR
II
I I
«
A F D Q I D N P E E K A R G I T I N T S H V 1 1 0 20
m
m
w
I ;
30
v w w w
- I N I
| | ;
I
!
EYDTPTRHYAHV 'tO
GTP-site EF-G
DTDGHVDFTIEVERSMRVLDGAVMV
EF-Tu
D©P
I
III
li
i
¡llliili
60
I t_ a - t uu r n tRNA-site
EF-Tu
VGGVQPQS-ETVWRQA
I
I
II:
I
i:
GHADYVKNMITGAAOMDGAILVVAATDGPMPQTREHLLLGR
Lf—J50
EF-G
y©A
70
VWVWWV/
80
NKYKVPRIAFVNKND
i
QVGVPYI 90
I
lilll
I V F L N Ku|ty»|St Pha Pro Qlu Val Val Gly|Ly»|Thr Val /UpGin •r
r
r
-tr*
z: —
-
r
z
H
Q
Z
H
n
H "
f^-^-
30 40 Arg Glu Tyr Ph« Thr Leu His Tyr Pro Gin Tyr A m Val Tyr Pha Lau Pro Glu Gly -T 4 n.: so •o >0Sar Pro Val Thr Lau Asp Lau|Arg|Tyr AMi|^]val^]val Plia Tyr Aan Pro Gly Thr -T7 -T6 T6T«-T4aCh170 Aan Val Val Aan Hi* Val Pro H ¡a Val Gly T7 __ • -Ch 1-
T1 - T7: tryptic peptides; Ch: chymotryptic peptide; ^ residue identified by automatic Edman degradation; —
residue identified after cleavage with carboxypeptidaseY.
Tryptic cleavage sites are indicated by the boxed amino acids (except T y r ^ ) ; the arrow denotes the chymotrypsin-reactive bond. The chymotryptic peptide Ch1 was obtained by incubation of eglin c with 50 mol % chymotrypsin and fractionation of the incubation mixture by gel chromatography in acidic medium.
Inhibition mechanism In preceding experiments it could be demonstrated that incubation of eglin with varying amounts of chymotrypsin and separation of the mixtures by SDS gel electrophoresis yields a low molecular weight peptide. Figure 2a shows the incubation of eglin c with 5 mol % chymo-
42
Figure 2. Incubation of eglin c with chymotrypsin and separation of the mixture by SDS gel chromatography (in the absence of reducing agents). a) Incubation with 5 mol % chymotrypsin 1
2
3
complex chymotrypsin
- native eglin c ^low molecular peptide
b) Incubation with 50 mol % chymotrypsin
complex chymotrypsin
native eglin c low molecular peptide
x
1 2 3
incubation mixture of eglin c with chymotrypsin native eglin c chymotrypsin
43 trypsin. Three bands appeared: the upper band with a molecular weight of about 30 000 corresponds to the eglin-chymotrypsin complex; the second band with a molecular weight of 8 000 corresponds to native eglin c; and the last band corresponds to the low molecular weight peptide. The same band pattern is obtained from the incubation mixture of eglin c with 50 mol % enzyme (Figure 2b). The only difference is that the intensity of the eglin band is decreased whereas the intensity of the complex and the low molecular weight peptide band is increased. From sequence data we could identify the low molecular weight peptide as the C-terminal fragment of eglin c comprising positions 46 - 70 (Ch1). From these results it seems likely that during complex formation of eglin c with chymotrypsin limited proteolysis occurs resulting in the release of a C-terminal peptide. The N-terminal part of the inhibitor molecule remains firmly bound to the enzyme in the complex. This complex might be covalently linked as it does not dissociate in SDS gel electrophoresis or during gel chromatography in acidic medium. Generally, proteinase inhibitor proteins do not form covalent complexes with proteinases. They react according to the following mechanism: E + I
kU
—1
L
k_ —2
k-3 C r ^ A -3
k. -4
L* ,
kr 3
» E + I*
-5
E - enzyme; I - native inhibitor; I* - modified inhibitor (reactive site peptide bond hydrolysed); L and L* loose complexes consisting of enzyme and native inhibitor or modified inhibitor, respectively; C - stable enzyme-inhibitor complex; A - acyl-enzyme-complex. Inhibitor and enzyme form via a loose intermediate (L) the noncovalent, catalytically inactive complex C (2). This complex is very stable as expressed by a low dissociation constant. Limited proteolysis, i.e. hydrolysis of the reactive
44 site peptide bond of the inhibitor may occur resulting in the formation of the modified inhibitor. The modified inhibitor is also inhibitory active, although the velocity of complex formation is normally reduced. It may be transformed again to native inhibitor by thermodynamically controlled resynthesis of the cleaved peptide bond. All inhibitors shown so far to obey the above given standard ii
mechanism are characterized by a reactive peptide bond which is encompassed in at least one disulfide loop. This disulfide loop ensures that during conversion of virgin to modified inhibitor the two peptide chains cannot dissociate" (3). However, the eglins do not contain a disulfide bridge, i.e. there are characteristic differences between the eglins and the "standard" proteinase inhibitor proteins: (i) The enzyme-inhibitor complex formed by the eglins seems to be a covalent complex, the one formed by the standard inhibitors is a noncovalent complex. (ii) Complex formation is reversible for standard inhibitors but obviously not for the eglins. (iii) The degree of limited proteolysis of the eglin reactive site peptide bond correlates with the applied enzyme concentration but depends on a true thermodynamic equilibrium between native and modified inhibitor for the standard inhibitors. Thus, the inhibition mechanism of the eglins resemble that of plasma inhibitor proteins, e.g. °Gal 3 ^0^
3Gal
3. 6Man
|3 4GlcN
6| 4GlcN
ASN
J Fuc
2Man ^
Structure of glycopeptides of the complex type NA
3 G a l — 4GlcN
NA
3Gal — 4 G l c N —
3. 6Man — 4GlcN — 4GlcN — ASN 2Man^
virus. Paramyxoviruses are efficiently propagated only in certain epidermal cells, but not in fibroblast
cells such as BHK-21
which apparently are unable to terminate the carbohydrate structure by acetalization. This terminal portion seems to be necessary for maturation of those viruses which contain a neuraminidase activity. The viral neuraminidase has been shown to function intracellularly (9) and may interfere with the release of the virus from those host cells which terminate the carbohydrate structure only by neuraminic acid and not by acetaldehyde. A scheme of paramyxovirus maturation is shown in Fig. 7. The viral polypeptides are synthesized in the endoplasmatic reticulum, glycosylated in the Golgi and terminated by acetaldehyde on their way to the cell membrane. The viruses are liberated by budding from the plasma membrane • The infectious cycle is again initiated by adsorption through the hemagglutinating activity of the HN protein to uninfected host cells presenting neuraminic acid residues on their surface.
59 viral neuraminidase
ù
ò
.
Golgi HN transferase
F
celi membrane
QCetQldehyde
Fig.7. Maturation of Paramyxovirus SV5.
References 1.
Choppin, P.W., Compans, R.W.: Comprehensive Virology (Fraenkel-Conrat,K., Wagner, R.R., eds.) Vol 4, 95-178 (1975).
2. 3.
Scheid,A. , Choppin, P . V I . : Virology 62., 125-133 (1974). Fukami, Y. Hosaka, Y. Yamamoto, K.: Febs. Lett. 114, 342-346 (1980). Prehm, P., Scheid, A., Choppin, P.W.: J. Biol. Chem.254, 9669-9677 (1979).
4. 5.
Laver, W.G.: Virology 45_, 275-288 (1971).
6. 7. 8. 9.
Klingenberg, M.: Nature 290, 449-454 (1981). Prehm, P. Scheid,A.: J. Chromatogr. 166, 461-457 (1978). Prehm, P.: Carbohydr. Res. 78, 372-374 (1980). Merz, D.C., Prehm, P., Scheid, A., Choppin, P.T'7.: Virology 11 2, 296-305 (1981).
HAEMOGLOBIN Primary
POLYMORPHISM
IN C H I R O N O M U S
Structure, Allergenic
(DIPTERA)
Determinants
and
Monomer-Dimer
Equilibrium
Heinz Aschauer, Traute Kleinschmidt, Wolfgang Steer, Braunitzer Max-Planck-Institut
Gerhard
für Biochemie, D-8033 Martinsried
b.München
Introduction
The
family
There
Chironomidae
are s o m e
in E u r o p e
75 000
alone
over
(midges)
species 1 500
stage. The These most
haemoglobin
upon
haemoglobins
approximately
electrophoresis
been c h a r a c t e r i z e d
species and
depending
population
interesting tionary
of one thummi
(4). This
a structural,
2-6 % d e -
high
factors.
in c o n t r a s t
species
12 d i f f e r e n t stage
form
can be
components
and
000
separated
(Fig.
1).
In
haemoglobins
is f o u n d
in all
environmental
fuctional, genetic
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter & Co., Berlin • N e w York
of
mono-
d e g r e e of p o l y m o r p h i s m
standpoint.
to
weights
16 000 a n d 32
polymorphism
upon developmental This
of
and
(1).
larval
between
haemoglobins
weights
into m a n y
thummi
conditions.
from
in the
have m o l e c u l a r
Chironomus
with molecular
the c a s e of C h i r o n o m u s
varies
described
and environmental
which
Diptera.
the w h o l e w o r l d been
low m o l e c u l a r w e i g h t s ,
haemoglobins
( 2 , 3 ) . The h a e m o g l o b i n
in d i s c gel have
concentration
10® d a l t o n s .
mers and dimers daltons
have
have
haemoglobin
s t a g e of d e v e l o p m e n t
invertebrate
to the o r d e r
spread over
species
M o s t of t h e m h a v e e x t r a c e l l u l a r pending
belongs
and
evolu-
is
62
IA Fig. 1 up HI.mo 7IIA IT YI "STUB YIII IX X
1 The
presence
of
giant
Chironomus
enabled,
structural
gene
sis
pattern
parent gene
localized
lized
to p a r t i c u l a r
existance
indicates through
of
that
the
gene
Chironomus
The
12
haemoglobins
in the
first
time,
Comparison with
of
polyare
haemoglobin
polymorphism
gel
chromosome that
structure III)
were
on o n e
o u t of a
even
loca-
chromosome.
single
of h a e m o g l o b i n
of
haemoglobin
of b a n d s o n t h a t
locus
of of a
electrophore-
the
(chromosome
components
or g r o u p s
glands
localization
disc
showed
chromosome
haemoglobin
salivary the
the
the
generations,
bands
the
the
of
thummi.
of
i ndi c a t e d .
on o n e
Single
electrophoresis
haemolymph
morphic
of h a e m o g l o b i n s
of f o u r .
gel
thummi
chromosomes
(5,6).
total The
the
for
and hybridized
was
Disc
chromosome
probalby
evolved
duplication.
Results The
sequences
thummi and
have
CTT
of all
been
IA a r e All
globins
represent
2,3
acids.
and
4.
determined.
identical
mersim. amino
12 h a e m o g l o b i n s
other
11 the
The
primary
and here we
haemoglobins partial
of
thummi
structures
suspect
are
determination
Significant
of C h i r o n o m u s
structural
different. the
sequences
of
The
sequence are
shown
12 of in
CTT I isohaemo1738 figures
64
65
Uí C •H m £ o C 3 t/1 eu c S- S-C 0) 1— 00 =3 0) ai JZ —i Q_ IO 3 i— ai _J c
>i CD c 5 ai
VI
>>
3 3 3 CD CD CD Í. i. i. aj ai a j oo 00 00 3 3 a> ai aj CL _j ai ai ai ai ai JZ JZ . c ^ CL es- O- CL o . 1- >> >1 s- tai aj a j CD oo 00 00 CD rl. ,-iIO IO IO IO IO > > > > >
(/I
3
>>
—I S- 1ai aj oo 00 a> ai jz .c a. a. 1 i/i >1 « ï CD "C eu CD ,-iIO aj i— « •— IO IO > i—i > > < rl à) ai —i i—i 1—1 > > 1 t/1 en t/1 OÌ t/1 >) >1 Î. >1 < —I > C c t/l 00 >> —I cd < 1 IO IO 10 io cd c «C c < m V) c oo co r e CD 31 n : >i to Q. s - ' a i IO 00 i— 1— 5 > (U 00 CD oo ,1 ai ai 0) ai io . c . e -C jz > a . CL O. Q. a. 3 o CL c r— t/1 r— s- t/1 CD a . < CD c IO o 10 18 10 l« t a .
3
CD CS L ai ai oo 00 3 IO ai >
aj *—i en en SC < >i s. •C 1— IO IO ai i—i
c oo m s. 1— 10 r— =c ai JC Cl. C CD
i—
ai
>. >.
CD 1
CD 1
> > t— 1— 1— 1— t— 1— 1— 1— c j (_> CJ CJ
ca. i—i »—« »—i > hhCJ
ai
Ol O) Oi s_ t- sc c < s_ > > i1— .c l'- 1— CD io 10 ia) «t < « t oo i/i t/1 00 •r— in • I n : a : Si. t. .c IO l'- 1— 1— > io 10 IO IO 1— i— r— 1— c 1 CD _i a) E •H Q
aj i—i
3
3
CD CD Sai co CD a> a; i— sz CL
>,
ai sz Cl >>
ai sz CL
>,
CD CD rl. ai IO i— >
1
ai
O) i. < >1 iai oo IO IO D1
hIO r— C ai QIO r—
JZ CL a. 00
>>
IO
1-1
rW ai
.c -p
o c ai 3 CT
•H fa
66 A comparison that
the
varies
of
sions
of
(Fig.
136
up to
insertions
20
positions
components.
There
structures
relatively residues.
acids are
and
also
and deletions in w h i c h
If any
idenitiy. CD
are
- 151
6 amino
2).
as
in t h e
primary
differences
between
acids
50%
the
Despite
this
segment, which
large. There
high
chain
of
is the
up to
2
same
exten-
amino as
There
well
are
in all
there
variability
is p r a t i c a l l y
length
extensions
compared
shows
N-terminal
the c h a i n s .
acid
are
globins
The
are
deletions
within
chains
the
C-terminal
the amino
two
of
only
12
is a b o u t
there
is a
a
region,
constant:
CD
D
-Phe-Pro-Glu-Phe-Ala-Gly-Lys-Asp-LeuThe of
reason
for
this
the m o n o m e r
known
The
haem the
in the
show
has
tidine
normal
E7 on
the
globins,
does
the
in the
iron
pionic
acid
histidine
The
Chironomus
Allergic insect or
larvae,
(RAST)
Chironomus
180°
o u t of
the
around
The
histidine
up
present a salt distal
its
bulky
by
detect
thummi
How-
haemoof
the
is b o u n d
to
distal
in all
CTT
haemo-
position
side side
with is
hisof
a
pro-
residue
chain,
pushes
pocket.
is a p o t e n t
in p e o p l e the
IV
10%
bridge
the
very
known
axis.
F 8 . The
On
haem
to
haem
is
myoglobins.
and CTT
of
the
and
coordination
forms
is
t o the well
haem.
laboratories.
we c o u l d
(8,9).
sixth
but
III that
forms,
significant
the a,y meso
CTT
structure
structure are
haemoglobins
because
occur
either
compared
X-ray
liganded
there
indicates
the
The
tertiary
hand, although
haemoglobin
thummi
as
proximal
form
which,
reactions
in r e s e a r c h
Test
deoxy of
The
However,
orientation the
clear.
in v a r i o u s
on m o n o m e r i c
other
group
the
(7).
which
not occupy
isoleucine
III,
complex
is t u r n e d
through
not
vertebrate
a signal
its
protein
E11,
haem
of t h e
group
is
of m y o g l o b i n .
NMR m e a s u r e m e n t s
globins
CTT
A resoltuion
complexes haem
ever
o
to t h a t
differences haem
component
at a 1,4
similar
constance
antigen
who
have
preparation Using
a
specific
haemoglobins
in m a n
(10).
had contact
and
use
of
fish
with food
Radio-A11ergo-SorbentIg
E antibodies
(CTT
IA w a s
not
against investi-
67 gated). active
It w a s
also
shown
that
when
a larvae
extract
The
allergic
action
graphy. nents
was
also
dimer
CTT
VI, a region was
antigenic dues
63
vity. be
determinant
- 98
terminal
confirmed
(E11
One
in t h e
could
is
(F2)
separated
of the
test.
expect
of t h e
cleavage
of
F1
90
the
this
haemoglobins
dimers.
The
of
dimers
haemoglobin
Chironomus can
thummi
dissociate,
concentration
and
least
contains
region
loss and
chromato-
at t h e
the
form
monomers
upon
the
(Fig.
5)
(11,12).
• CO
o2 x Met "
Q. o 2,
u
Fig.
5-
Monomer-dimer component
X of
its d e p e n d e n c e
7.0
equilibrium Chironomus upon
pH and
S.O
of
to
.
thummi
ligand
6.0
acti-
depending
o.
5.0
C-
sequence:
• CAT
e.,0
resi-
determinant
have
the
one
of a n t i g e n i c
3.
1,
compo-
component, at
antigenic
point
Leu-Ala-Lys-Glu-Leu-AlaThe
In o n e
region
complete
gel
were
haemoglobin
in w h i c h
This
Cleavage
caused
fractions
using
separated
identified
present.
therefore
region
was
haemoglobin
by a s k i n
- FG2).
of Lys 89
the
the
thummi
pH
haemoglobin thummi
ligand.
and
pH
and
value,
68 Concerning different The
CTT
until 7.0. an
for
pH-dependence each
pH 8 - 9 , w h i l e The
further
the
all
other
in t h i s
a monomer
after
bridge
t h a t .forms a s a l t
IIB
they
are
should
Monod
(16).
as m o n o m e r s . all
of
lysine
and
glutamic This
from
acid
by
thereby
has an
This would
G7
suspicion
is the
identical, the
isologous
is s t r e n g t h e n e d
the monomer
components
no g l u t a m i c
acid
at
also
by
have
maleic
the
have as
anhy-
effect stability
t h e d i m e r s of C T T
we
in the
hae-
subunits,
as d e s c r i b e d believe
salt
the o b s e r v a t i o n histidine
po-
residue
numbered
structure,
partner
dimer
In
important
association
primary
a
dimers
is a
explain
even
of
11B e x i s t e d
with
(His, Lys)
isologous
comparing
other CTT
residues
G19
sites. role.
diethylas
present
position
be f o r m e d By
with
whereas
only
pH
gives
modified.
were
reaction.
formed
chains
remained
of the CTT II/3 d i m e r a t h i g h pH v a l u e s . A s moglobins
side
(15) w e r e
a lysine
bridge
dimerisation
up to
important
residues
CTT
form
the binding an
the
position.Conversely, that
cyanomet
equilibrium
of
play
of h i s t i d i n e
reaction
We believe
the
salt
that only
11B h a s
histidine
on
to t h e n a t u r e
compoenents
G19, CTT
dride.
found
is
is a d i m e r
(14) and a r g i n i n e
reaction we
in the
X component
interactions
the
it
component.
as a d i m e r
the m o n o m e r - d i m e r
as
ionic
investigate
selective
sition
CTT of
(13), lysine
pyrocarbonate, while
the
indication
that
histidine After
exists
pH d e p e n d e n c e
important
of t h e e q u i l i b r i u m ,
haemoglobin
11B c o m p o n e n t
We a s s u m e To
the
by that
bridge.
that
some
in p o s i t i o n
G19
of but
G7.
Discussion In o u r m o d e l , larities but
not
to
in the
ly, through units salt
one
the
in the bridges
inclination
can
see,
binding
tetramer in the the
regions.
formation,
direction of
in t h e q u a r t e r n a r y
6 - B or a - a s u b u n i t s
CTT
of
the
subunits
However in t h e
G helix
dimers and
structure,
of m a m m a l i a n
in t h i s
they
differ
inclination (17,18). region
therefore
simi-
haemoglobins, considerabof
the
Assuming are
tetramer
sub-
that
formed,
an
formation
69 is
impossible
Goodman, the They
Moore
heterotetramer further
ß chains
evolved
thought
that
of m a m m a l i a n
a chains can homodimers the
arid M a t s u d a
form
deduced via
a preceding homotetramer
homotetramers.
homotetramers
and
phylogenetic
the
haemoglobin
of C h i r o n o m u s
from
a still
homotetramer
as o n l y Have we
haemoglobins, earlier
data
was
(19).
similar
ß chains
to
and
discovered,
a further
that the
not
in
the
ancestor
developmental
form
of of
haemoglobi n ? The
phylogenetic
ration must
of
have
the
insect
taken
place
million 400 ship
million
dimers cestors
the
and ago.
sites.
thummi
of the m a m m a l i a n
binding
the
dimer
sites
binding
therefore
have sites
not able
others.
sepa-
s e p a r a t ion
years
of m y o g l o b i n s into
we
ago,
thummi
f i n d no
we
different into
that
500
ß chains
assume
haemoglobins
no p h y l o g e n e t i c to e v o l v e
about
a and
could
Therefore
heterotetramer have
early
This
650 m i l l i o n
separation
In o u r w o r k
binding
a very
f o r m a t i o n of h e m a t e t r a m e r s
separation the
shows
from
approximately
the
of C h i r o n o m u s
the were
ago
years
between
haemoglobins
the accepted
between
years
of h a e m o g l o b i n
place
t h a t is, b e f o r e took
tree
are
relationthat not
haemoglobins relationship,
the an-
and
that
Further
characteristics tetrameric
about
and
haemoglobins.
References 1.
T h i e n e m a n n , A . , in: Die m u s , S c h w e i z e r b a r t 1 sehe 1954
Binnengewässer, Vol. Verlagsbuchhandlung,
2.
Svedberg, T., 1700 ( 1 9 3 4 ) .
3.
Braunitzer, G., Braun, 3 4 0 , 80 ( 1 9 6 5 ) .
4.
Braun, V., Chrichton, R.R., Braunitzer, Z. P h y s i o l . C h e m . 3 4 9 , 197 ( 1 9 6 8 ) .
5.
Tichy,
H.:
Chromosoma
6.
Tichy,
H.:
J. M o l .
7.
Steigemann,
E r i k s o n - Q u e n s e l , I.B; J . A m . V.:
Hoppe-Sey1 er's
(Berlin)
Evol . 6 , 39
W., Weber,
29,
131
XX: C h i r o n o Stuttgart,
Chem. Z.
G.:
S o c , 5_6
Physiol.
Chem,
Hoppe-Sey1 er's
(1970).
( 1 975).
E.: J. M o l .
B i o l . J_27, 309
(1979).
70 8.
R i b b i n g , W. , K r ü m p e l m a n n , 9 2 , 105 (1978).
D.,
Rüterjans,
H.:
FEBS
9.
La M a r , G . N . , S m i t h , K . M . , G e r s o n d e , K . , S i c k , k a m p , M . : J. B i o l . C h e m . 2J55, 66 ( 1 9 7 9 ) .
Letters
H.,
Over-
10. B a u r , X . , Z i e g l e r , D . , R e i c h e n b a c h - K l i n k e , H . H . , H., B r a u n i t z e r , G.: Naturwiss. 365 (1980).
Aschauer,
11. B e h l k e ,
J., Scheler,
(1967).
12. B e h l k e , Müller, 34, 365
J., Pfeil, W., Blanck, J., Ristan, 0., Rein, H., K . , M ö h r , P . , S c h e l e r , W . : A c t a B i o l . M e d . Ger(1975).
W.:
Fahrney,
J. B i o c h e m .
3,
152
13. M e l c h i o r ,
W.B.,
D.:
Biochemistry
9 , 251
14.
D., Laskowski , M., Jr.:
Biochemistry
1 1 , 3451
Kowalski, ( 1 972 ) .
Jr.,
Eur.
15. D i e t l , T . , T s c h e s c h e , 357 , 6 5 7 ( 1 976 ). 16. M o n o d , J . , W y m a n , 88 (1965). 17. P e r u t z , 18.
M.F.:
H.:
H o p p e - S e y l e r ' s Z. P h y s i o l .
J., Changeux,
Nature
228,
726
J.P.:
J. M o l .
Biol.
Chem. 12, -'
(1970).
Perutz, M.F., Rossmann, M.G., Gullis, A.F., Muirhead, W i l l , G . , W o r t h , A . C . T . : N a t u r e J_85, 416 ( 1 960 ).
19. G o o d m a n , M . , M o o r e , (1975).
( 1 970).
G.W. Matsuda,
G.:
Nature
253,
603
H.,
HIGH
ALTITUDE
RESPIRATION
INDICUS)
AND
THE
IN A V I A N
HEMOGLOBINS
Investigations anser)
DIFFERENT
OF THE
on h e m o g l o b i n s
(1), Bar-headed
Goose
and
BAR-HEADED
EVOLUTION
of t h e (Anser
(Branta
canadensis)
Ostrich
Gerhard
Braunitzer
and
Walter
Max-Planck-Insitut D-8033 Martinsried
für bei
Biochemie München
GOOSE
OF THE a -
Grey-Lag indicus),
(Struthio
(ANSER
AND
g-CHAINS
Goose
(Anser
Canada
Goose
camel us)
Oberthür
Introduction
We
have
investigated
headed Goose
(Anser
structure
of
the
Lag
(Anser
Goose
Canada To and
Goose
determine g-chains
complete
were
amino
high
indicus)
altitude and
ma in c o m p o n e n t s anser),
(Branta the
the
fragmented
acid
sequences
and of
of
the
(Anser
Ostrich the
of t h e
the
hemoglobin
Goose
and
structure
described
the
Bar-headed
canadensis)
primary
have of
respiration
primary of t h e
products
Grey-
indicus),
(Struthio
hemoglobins,
the a - and
Bar-
isolated.
6-chains
camelus). the
a-
The
were
de-
A b b r e v i ati o n s : Q u a d r o l = N ,N ,N ' ,N ' - T e t r a k i s ( 2 - h y d r o x y p r o p y l ) e t h y l e n d i a m i n e , Reagent I = sodium 1 -(isothiocyanato)benzenesulphonate, R e a g e n t IV = t r i s o d i u m 7 - ( i s o t h i o c y a n a t o ) n a p h t h a i e n e - 1 ,3 ,5tri s u l p h o n a t e , IPP = m y o i n o s i t o i - 1 , 3 , 4 , 5 , 6 - p e n t a p h o s p h a t e , DPG = 2 , 3 - d i p h o s p h o g l y c e r a t e .
C h e m i s t r y of P e p t i d e s a n d P r o t e i n s , V o l . 1 © 1982 by W a l t e r d e G r u y t e r &. Co., B e r l i n • N e w Y o r k
72 termined
by a u t o m a t i c
sequencing
of the intact chains and
lated f r a g m e n t s . The d i f f e r e n t e v o l u t i o n and the problem of high a l t i t u d e Goose are d i s c u s s e d
of the a -
breathing
of the
and
iso-
B-chains
Bar-headed
(2,3).
Methods Crude h e m o g l o b i n moving
was p r e p a r e d by lysing e r y t h r o c y t e s
cell m e m b r a n e s
g r o u p , the a -
ion e x c h a n g e
CM-52
(2)).
using
chromatography
tic d i g e s t i o n
m e t h o d s as d e s c r i b e d e a r l i e r
maleic anhydride
the e - a m i n o - g r o u p s
(5); acid h y d r o l y s i s
d i g e s t i o n with S t a p h y l o c o c c u s Amino acid a n a l y s i s :
isolated
isolated (2,3):
cya-
(4); tryptic d i g e s t i o n and l i m i t e d
after blocking
aureus
of lysine
of A s p - P r o - b o n d s protease
V8
(6);
(Palo A l t o , C a l i f . ,
a Beckman USA).
Amino acid s e q u e n c e a n a l y s i s : amino acid s e q u e n c e s were mined automatically
in a Beckman
S e q u e n a t o r , Model
Lysin peptides
(0,5 pmol) were c o u p l e d with 8 pnol
(9) or r e a g e n t
IV
Arginine
minutes
using
3 M trifluoracetic
ti on HPLC
programme. Sequenator
acid at 80° C for
e i t h e r thin layer c h r o m a t o g r a p h y
(13).
of r e a g e n t I
from the
and the resulting p h e n y l t h i o h y d a n t o i n
tified using
(8).
a 1 M diethyl a m i n o p r o -
(11,12). Amino acid d e r i v a t i v e s
were c o n v e r t e d
deter-
890 C
(10) and s e q u e n c e d using a Quadrol
peptides were s e q u e n c e d using
pine buffer
trypwith
(7).
a n a l y s e s were c a r r i e d out using
121 C amino acid a n a l y s e r
heme-
CM-cellulose((Servacel
for s e q u e n c e a n a l y s i s were p r e p a r e d and
the following
nogen bromide c l e a v a g e
Model
on
re-
off the
and B - c h a i n s of the main c o m p o n e n t were
using
Fragments
and n u c l e i . After cleaving
and
amino acids
14 iden-
or g r a d i e n t el u -
73 Results
and
Discussion
Biology
of the G e e s e
The Grey-Lag
Goose
ser
belong
indicus)
da G o o s e the
family
portant geese The
place
of
Goose
northern
areas
breeds
Goose
African
ber
of t h e
on the
in
the
im-
(14)
of t h e
existing
areas
of the
Boreal
area
of the
Grey-
from
Iceland
In E u r o p e
they
breed mostly
In c o n t r a s t ,
in c e n t r a l
goose
Cana-
geese
stretching
cost.
They
(An-
period.
to w i n t e r
common
(see
to J o h n s o n
evolution
Goose
g e e s e ) , the
Branta
the breeding
lakes
Himalaya
(real
in the m i l d e r
Today zone
subspecies.
in
India
in A m e r i c a
inhabit,
the
Asia
in
Bar-headed
(4000-6000
(15-17).
and gives
like
through
The
Canada
rise
the G r e y - L a g
m) to
Goose,
Ostrich
(Struthio
camelus)
suborder
Ostriches
( S t r u t h i o n e s , f a m i 1y Struthionidae)
since
but
According
to S a l a c h i n . and
relatives
Africa
Anser
Bar-headed
the g e n u s
in the
lives
the
areas.
The
whose
(1)
a wide
is the m o s t
low-lying
steps
on h i g h l a n d the
of t h e
bird
Goose
covers
and crosses most
(ducks).
to
at the T e r t i a r y
Eurasia
low-lying Goose
and
the the genus
Palaearctic.
the
Ostrich
anser)
canadensis)
Anatidae
took
of the
(Anser
phylogenetic
Grey-Lag
Zone Lag
(Branta
and
have
the
its
inhabited
Eocene
position
period.
in the
large
areas
Today
family
is the o n l y of A s i a ,
it is the
tree
living Europe
largest
of b i r d s
is
memand
living
still
di s p u t e d .
Physiology In all
of
birds
hemoglobins
the A v i a n (18,19)
(ca.
IPP
5 pmol)
DPG a n d o t h e r o r g a n i c ty of o x y g e n Goose only
small
ween
the
is the m a j o r together
phosphates.
for h e m o g l o b i n s
and Canada
differences
Hemoglobins.
Goose
differences became
PcnO?
for
with
allosteric low
Investigations
in the G r e y - L a g
showed,
b u t on the
addition
significant
Canada
and Bar-headed
of A T P , on
Goose,
in t h e a b s e n c e
highly
effector
levels
of
of
ADP,
affini-
Bar-headed
phosphate,
phosphate
(20). The Goose
the
of
the
difference hemoglobins,
bet-
74 without phate
p h o s p h a t e , was
12 t o r r . T h e
a highland gen
bird,
affinity.
Grey-Lag
ca.
P5Q02
is 2 9 . 7
Geese
have
results
correlate
and C a m e l ,
Primary
with foetal
v a 1 u e s
lower
of
presence
of the
indicates
the b l o o d of the 39
oxygen
and adult
-
5
acid
of h e m o g l o b i n s
sequence
of the a - a n d
and Struthio
Comparing
the h o m o l o g y
including
chicken
a very
lowland
high
oxyand
torr
affinity
Goose,
Canada
(20).
respecThese
on h e m o g l o b i n s
from
the
(21).
from Anser camelus
g-chains
are g i v e n
of the h e m o g l o b i n
(22,23)
of the
anser, Anser
the f o l l o w i n g
in f i g u r e s chains
major
i n d i c u s , Branta 1 to
4.
of v a r i o u s birds,
differences
can
be
seen:
1: A
B
Amino acids
Nucleotides
a
ß
tx/0
a
ß
a/ß
GG/BG
3
1
3
3
1
3
CG/BG
5
3
1 .67
6
3
2
CG/GG
2
3
0 .67
3
3
1
OS/GG
15
4
3 .75
16
4
4
OS/BG
16
5
3 .2
1 7
5
3,.4
OS/CG
16
6
2 .67
1 7
6
2 .84 ,
CH/GG
30
6
5
39
6
6,.5
CH/BG
32
7
4 .71
41
7
5,.86
CH/CG
32
5
6 .4
41
5
8,.2
CH/OS
29
7
4 .15
39
7
5,.57
CH = CG =
phos-
Bar-headed
a n d
humans
of
Structures
component
Table
in the
blood
investigations
The amino canadensis
but
torr which
P5o°2
indicating a m u c h
The
for the
In c o n t r a s t ,
tively, Llama
2 torr
C h i c k e n , GG = G r e y - L a g G o o s e , C a n a d a G o o s e , OS = O s t r i c h
In A the n u m b e r corresponding
of a m i n o
number
BG
;
= Bar - h e a d e d G o o s e ,
acid exchanges
of n u c l e o t i d e
are
shown^.
exchanges,
in B the
assuming
a
mini-
75 mum
of b a s e
changes, and
exchanges.
the
For
relationship
3-chains
both
between
is c a l c u l a t e d
terminal
region,
In t h e
half
constant.
helices.
region.
Three
gions
and
total
mutations
the
Phosphate
the
and
of the m u t a t i o n s the
of the m u t a t i o n s
There
are
no s u b s t i t u t i o n s
are
present
Binding
found
Sites
in t h e
H helix.
in the
and
are
a-
in t h e
N-
C-terminal
is
contain
mutations are
in the
ex-
a/6.
of the a - c h a i n s
beginning of the
nucleotide
differences
of t h e c h a i n w h e r e a s None
IJ-chains, t h e m a j o r i t y
N-terminal
acid
as a f a c t o r
In the a - c h a i n s , the m a j o r i t y relatively
amino
tryptophan.
also
lie
in the
in
D to G
interhelical
Only
very
the
few
re-
of
the
the a -
and
G-chains.
Unequal
Evolution
of
S-Chains The
oxygen
(18),
in- b i r d s
paring amino all
now
of the
have
been
sites
human
exchange
was
was
somewhat
by c o m p a r i n g
of
rate
five
b i r d s , we
using
availability
this
the m u t a t i o n
higher
than
primary have
in t h e 6 - c h a i n s
one e x p l a i n
constructed
the
pal a e o n t o l o g i c a l
to be m a d e .
data
of
result? and
primary
enables
hemoglobin, been
finds
of b i r d s
very
rare,
paleontologists
family
tree.
The
example, million
are
the c h i c k e n years
old.
and
the
lower
common
muare
structural
data.
compa-
rate
( 2 5 ) . As
of
can
say
very
of,
for
to be
of 6 m i l l i o n
one
fossil
ancestor
is t h o u g h t
rate
trees
a mutation
calculated
goose,
By a m u t a t i o n
a-chain.
quantitative
T h u s , for
the
8-chain
the a - a n d 13-
Family
years
about
in the
a significantly
6-10 million
little
In
case
subtstitutions
of t h e
every
has
comthe
table).
surprising
of s e q u e n c e
in one
rate
that
by
hemoglobin.
no
structure
found
(see
phosphate
(24) w i t h
(except
reported)
that
by
determined
3 - c h a i n of c h i c k e n
investigated
thought
were
hemoglobin
it w a s
tation
risons
of
positions.
chains can
binding
is c o n t r o l l e d
fourid in t h e s e
hemoglobin
However,
The
The
sequence that
hemoglobins
analysis
a conservative been
Until
How
of
IPP.
X-ray
acid
where
of
the
birds
have
affinity
80-120
years,
this
76 would mean changes
a normal
a significantly rate.
site
stead
of 6 as
rates
of e v o l u t i o n
fixes
the
structure
(23).
The
rate
therefore
The can
normally
oxygen
compared
the m o s t This
surprising
with
M.
structure
there
these its
Bar-headed
different for
IPP
which
12 b i n d i n g
sites
be r e d u c e d sites
and
in
will
alteration
birds. is no
exchange
The
the
room
of the to the
E12
Val
hemo-
side
found)
alanine
in t h e
chain
therefore
dis-
occupied
Ser w a s
of t h i s
as
Goose
of
is
it
ex-
of a w r i t t e n
a63
B2 so t h a t
a longer
for
Goose as
the
Bar-headed structure
group
a21
Canada sites,
and H b A / H b F ,
rabbit where
B-methyl for
and
binding
Bar-headed
the m u t a t i o n s
position
of a l a n i n e
of A l a
Goose
is a r e s u l t
"The
of t h e
Llama/Camel Of all
finding
Goose
hemoglobin
phosphate
in t h e
(except
C=0 c a r b o n
The
increased
(12 m o l e c u l e s i n -
requirement
Grey-Lag
found.
F. P e r u t z .
mammals
other
the
that
ex-
mutation
be t h e
no b i n d i n g
in t h e a - c h a i n
drastic
cussion
sition.
of the
were
globin.
in all
could
B - c h a i n will
has
of t h e
by d i f f e r e n t
(E1 2 ) Val
in all
an a b n o r m a l
through
of the
of t h e
case, for e x a m p l e , a63
the
B-chain
affinity
no d i f f e r e n c e s
touches
by
(2 x 15 however,
evolve.
to t h o s e
causes
this
B-chain,
hemoglobins
We b e l i e v e
of t h e
Respiration
change
and
for
caused
of e v o l u t i o n
n o t be c a u s e d
by A l a
therefore
in a v i a n
are
for the a - c h a i n
for the
to t h e a - c h a i n w h i c h
higher
is the here
and
in m a m m a l s ) .
Altitude
Goose
rate but
explanation
binding
comparison
years)
reduced,
A possible
phosphate
High
mutation
= 90 m i l l i o n
normal
in t h i s
causes
the
po-
heli-
o
ces a
E andB
large
to
be
pushed
alteration
at
in t h e
be n o t e d
histidine
of t h e heme c o m p l e x .
B binding
above,
probably
hemoglobin pretation Goose.
sites,
when of
the
IPP
the
E-helix
a different
is b o u n d
high
with and
altitude
represents
structure." in E7 c a r r i e s
Additional
together
cause
1.5 A a p a r t w h i c h
tertiary
It s h o u l d and
that
least
the
mutations
allows
respiration
distal
at the
substitution
conformational
thus
the
change
a molecular
of t h e
a
described in inter-
Bar-headed
77
i/t
r—
0>
«— r— ^
_Q O CD O
— < < o
< Ü3 U
>
ai t. CD "O e C - Q
+
80 z
377
—C=0I m/e 346
6
Ph-C-Ph Ph m/e 243
(- 60
^ ^
378
346
& 40
243 244
20
200
250
400 m/e
350
300
Figure 2. F.d. mass spectrum of H-Cys(Trt)-OCH^ and interpreted fragmentation at 6 mA e.h.c.; solvent: DMSO.
CH3(
m/e 309 ( M H * = 310)
NH-CH-C0(0H
m/e 210 +
nhj°\J
nu OH
nu OH II
Fig. 5.
0
HOOC-CH2-CHJ-CH-COOH NH
J
I H2N4H
nu OH
.0 T
h
° ! OH
' OH
III
I: nucleoside of nikkomycin X; II: peptidenucleoside (nikkomycin N) of n i k k o m y c i n J; III: peptide-nucleoside (nikkomycin M) of n i k k o m y c i n I.
F i n a l l y nikkomycin B was isolated (5) in w h i c h the pyridine ring of nikkomycin X is replaced lay a phenyl ring. The fungicide activity of this compound is rather low compared to n i k k o m y c i n X. Since nikkomycin X and Z are p r o d u c e d in amounts up to culture filtrate
kg/l
and due to their h i g h fungicide and insec-
ticide activity they are promising compounds for practical application in pest control.
References 1.
Dahn, U., Hagenmaier, H. , Höhne, H., König, W . A . , W o l f , G . , Zähner,H.: Arch. Microhiol. 107, 1^3 (1976).
2.
Ishikawa, K., Achiwa, K., Yamada, S.I.: Chem. Pharm. Bull. 19, 926 (1971).
3.
König, V.A., Pfaff, K.P., Bartsch, H . H . , Schmalle, H., Hagenmaier, H.: Liehigs Ann. Chem. 1980, 1728.
k.
Hagenmaier, H., Keckeisen, A . , Dehler, W . , Fiedler, H.P., Zähner, H., König, W.A.: Liehigs Ann. Chem. 1981, 1018.
5.
König, W . A . , Hass, W . , Dehler, W . , Fiedler, H.P., Zähner, H.: Liehigs Ann. Chem. 1980, 6 2 2 .
Peptide Syntheses. Biological Activity A n a l y t i c a l P r o b l e m s of S y n t h e t i c
and
Peptides
ELECTROCHEMICAL INTRODUCTION AND SELECTIVE REMOVAL OF A NEW TYPE OF AMINO- AND CARBOXY-PROTECTING GROUP
FOR PEPTIDE SYN-
THESIS
Günther Jung, Mohamed Hassen Khalifa and Anton Rieker Institut für Organische Chemie der Universität Tübingen, D-7400 Tübingen, Germany
Introduction of protecting groups The electrochemical oxidation of sterically hindered 2,6-ditert-butyl-4-aryl (or alkyl)-phenols U/2) yields phenoxenium cations These aryloxenium ions are formed via a homogeneous redox reaction between the intermediate cation radical 2 and the neutral radical 3, respectively via a two-electron process including the deprotonation of cation 2. Nucleophiles (NuH) react with the phenoxenium cation £ yielding para-substituted quinol derivatives ^ (R=aryl or alkyl).
0
R
Nu
5
0
R 4
C h e m i s t r y of P e p t i d e s a n d P r o t e i n s , V o l . 1 © 1982 by W a l t e r d e G r u y t e r &. C o . , B e r l i n • N e w Y o r k
194
This reaction can be carried out in neutral electrolyte systems in the presence of amino acid derivatives as nucleophiles yielding either N—protected or C—protected intermediates useful for peptide synthesis (3,4,5). a) Amino acid esters as nucleophiles The anodic oxidation of 2,6-di-tert-butyl-4-phenyl-phenol (3,5-di-tert^butyl-4-biphenylol) (1,2) in the presence of amino acid esters in dichloromethane followed by a saponification step gives N- [3 ,5-di-tert-butyl-4-oxo-1-phenyl-2,5-cyclohexadienyl] amino acids 7 (R3=H) in 80-95% preparative yields (3,4) .
'6 5
£
1
As shown on more than 10 different derivatives synthesized so far N-PChd amino acids are readily crystallizable compounds free of racemate. b) N-protected amino acids as nucleophiles Another application of the anodic oxidation of sterically hindered phenols is the preparation of quinol esters 8 from 2,6-di-tert-butyl-4-phenyl-phenol 6 and Z-resp.Boc-amino acids as nucleophiles. Quinol esters, e.g. Z-amino acid-^3,5di-tert-butyl-4-oxo-1-phenyl-1,5-cyclohexadienyl^ esters 8 corresponding peptide derivatives
or
constitute a new class of
carboxy protected intermediates. Via CF^COOH catalysis cleaving one of the tert-butyl groups they can be transformed into
the ether soluble pyrocatechol esters 9. These isolable
activated esters 9 couple to amino groups of amino acid and peptide esters often in more than 80 % yield.
195
6
• Z-NH-CR1R2-C00H -2e° • 2 H ® CH2CI2j (EtJ^NBF^
0
0
iH
0-fc-CR1R2-NH-Z
0 o-£-cr1r2-nh-z
cf3cooh^ch2ci2 -h
2
c=c(ch
3
)
2
Removal of N-PChd group The cleavage conditions for the N-PChd group are either mild acidolysis, e.g. 10-50 % CF 3 COOH in CH 2 C1 2 within about 15 min, or hydrogenolysis, e.g. H 2 /Pd-C (10 %) in CH 3 OH/HCl within
ca.1h. Therefore the PChd protection is selectively
applicable in combination with the Z, Bzl and the Boc, Bu*" groups.
• 2CFoC00H
2. resP-
ch2ci2
• CF3C00H x H2N-CR1R2-COOR3
N-PChd-Peptides H^/Pd-C
4
• hci x h 2 n - c r ' r 2 - c o o r ^
hci/ch3oh
The pyrocatechol trifluoroacetate J_0 is easily separated from the peptide trifluoroacetates by extraction with diethyl ether. In the same way the regenerated phenol 6 can be isolated from peptide hydrochlorides, and it is reusable. Recent experiments have shown the electrochemical reduction to be a third alternative way for deblocking N-PChd protected peptides. The NPChd group is completely stable towards the alkaline conditions used for saponification of peptide esters and the aminolytic conditions used for removal of the Fmoc group. Due to the simultaneous hydrogenolytic and acidolytic sensitivity of the PChd group and its electrochemical oxidative intro-
196
duction and reductive removal a variety of orthogonal combinations of protecting groups is possible in particular, when we have side chain protected PChd amino acids available. Furthermore, the different sensitivities of the PChd group can still be modified, e.g. by introducing suitable substituents on the phenyl ring. Moreover, by substituting the 4-phenyl for the 4-tert-butyl group on phenol 6 one can obtain N-(1,3,5tri-tert-butyl-4-oxo-2,5-cyclohexadienyl) amino acids, which can be transformed into further interesting derivatives (6). It is interesting that the rate of trifluoroacetolysis of N-PChd amino acids is much faster for «:,cC-dialkyl than for the protein amino acids. Thus, PChd-Aib-OH is cleaved quantitatively within 1 min and PChd-Ala(Gly or Leu)-OH within 5-10 min to about 70 % using 3 % trifluoroacetic acid in dichloromethane. Peptide synthesis with N-PChd protection The applicability of this new amino and carboxy protection and the acid -catalyzed carboxy activation is shown so far on the synthesis of a number of oligopeptides containing only difunctional residues. The extension of the new protective principle to combinations of protecting groups for the trifunctional amino acids is in progress. Representative examples of synthesis revealed readily crystallizable N-PChd oligopeptides with excellent solubilities in common organic solvents, complete retention of configuration and the possibility of monitoring reactions by UV detection. So far we prepared more than 20 N-PChd-protected oligopeptide esters, amides and acids, including 1 tetrapeptide, 1 hexapeptide and 1 heptapeptide. As a first example the wellknown C-terminal tripeptide of oxytocin, H-L-Pro-Leu-Gly-NI^ was synthesized. In a second test synthesis we built up by fragment condensation the lipophilic heptapeptide segment 14-20 of human lymphoblastoid interferon HuIFN-o£(Ly)
Ala-
Leu-Ile-Leu-Leu-Ala-G-ln.The same peptide had been prepared in our laboratory using Z- and Boc-protection.
197
H
N m s o
ñ I-i Ct!
H
N w
9
+J c a> e C P «j M
w (D S o M
(31 •H >1 O ÍN
W Q
l-l
-a ni tf o O O Ph FM Ph
I S fa H ¡E -P a a> e tn d)
CÖ H 1
a) h -p c 0) o a o o
6'¿-0-PM3d
a
0 " 0Jd l-O-PMOd
>i iH 0 1 3 O) J I
0 u cu 1 h-q i T3 XI U & m O N
.T-3-PMOd ,7-0-PM0d X-O-PWOd
.l-O-PMOd s'e-0-PM0d
a
UZl UZl 5821
a
8 a t i - i — 9'Z-O-WCtí — r m re7tJ —rrsvt L ¿ 671
o . = -9.65 ppm
(20 RSS) M-D-Ala-Phe-OMe (20 RRS)
6(CF3> = -10.1 ppm Scheme 4
References 1. 2. 3.
4.
5.
Urban, R., Marquarding, D,, Ugi, I.: Hoppe Seyler's Z. Physiol. Chem. ¿59, 1541 - 1552 (1978). Urban, R.: Tetrahedron 35, 1841 - 1843 (1979). Urban, R. (unpubl. results) see also: Urban, R., Marquarding, D., Ugi, I.: Proceedings of the American Peptide Symposium 1979. Ugi, I., Marquarding, D., Urban, R,, in: Chemistry and Biochemistry of Amino Acids, Peptides and Proteines. Vol. 6 (Weinstein, B., edit.). Marcel Dekker, New York (1981, in print). Brandt, J., Jochum, C,, Ugi, I,, Jochum, P.: Tetrahedron 33, 1353 - 1363 (1977).
208
6.
Dugundji, J., Kopp, R., Marquarding, D., Ugi, I.: Top. Cürr. Chem. 75, 1 65 - 1 80 (1 978) .
7.
Ugi, I., in: The Peptides. Vol. 2 (Meienhofer, J., edit.). Academic Press, New York 1979, p. 365 - 381.
8.
Marquarding, D., Burghard, H., Ugi, I., Urban, R., Klusacek, H.: J. Chem. Res. (S), 82 - 83 (1977); J. Chem. Res. (M), 091 5 - 0958 (1 977) .
9.
Eberle, G., Lagerlund, I., Ugi, I., Urban, R.: Tetrahedron ¿4 , 977 - 980 (1 978) .
10.
Herrmann, R., Ugi, I.: Tetrahedron 37, 1001 - 1009 (1981).
11.
Giesemann, G., v. Hinrichs, E., Ugi, I. (unpubl. results).
12.
Gieren, A., Dederer, B., George, G., Marquarding, D., Ugi, I.: Tetrahedron Lett., 1503 - 1506 (1977).
13. 14.
Falou, S., Ugi, I. (unpubl. results; see also ref. 4). Waki, M. , Meienhofer, J.: J. Amer. Chem. Soc. 9j), 6075 6082 (1977). Waki, M,, Minematsu, Y., Meienhofer, J., Izumiya, N.: Chem. Lett., 823 - 824 (1979),
15.
16.
(a) Bukall, P., Ugi, I.; Heterocycles (Sendai) 11, 467 470 (1978). (b) Bukall, P., Ugi, I.: Heterocycles (Sendai) 381 390 (1 981 ) . v. Zychlinski, Ugi, I,, Marquarding, D.: Angew. Chem. 86, 517 - 518 (1974); Angew. Chem. Internat. Ed. 13, 473 - 474 (1974).
17.
Bukall, P.: Dissertation, T. U. München (1980).
18.
Gil-Av, E., Charles, R., Bukall, P., Ugi, I. (unpubl. results) . Giesemann, G.: Dissertation, T. U. München (1981, in preparation) .
19. 20.
21. 22.
23.
Eckert, H., Breuer, W, , Geller, J., Lagerlund, I., Listl, M., Marquarding, D., Seidel, P., Stüber, S., Ugi, I., Zahr, S., v. Zychlinski, H.: Pure Appl. Chem. 51, 1219 - 1233 (1 979) . Sullivan, G. R., Dale, J. A., Mosher, H. S.: J. Org. Chem. ¿8, 2143 - 2147 (1973), Aigner, H., Koch, G., Marquarding, D,, in: Chemistry of Peptides and Proteins. Ill USSR - FRG Symposium. Makhachkala, October 2 - 6 , 1980. (Voelter, W. , Wünsch, E., Ovchinnikov, Yu. A., Ivanov, V. T., edit.). Walter de Gruyter, Berlin, New York 1981. Breuer, W.: Dissertation, T. U. München (1981, in preparation) .
ISOCYANIDES AS ACTIVATING REAGENTS IN PEPTIDE SYNTHESIS
Helmut Aigner, Gertraud Koch
and Dieter Marquarding
Organisch-Chemisches Institut der Technischen Universität München, D-8046 Garching, Germany
Dicyclohexylcarbodiimide
(DCCI) plays a major role as reagent
for a one-pot coupling of properly protected amino acids yielding peptide derivatives^. The wide application of this reagent is due to the fact that it is readily available and easy to apply. The real breakthrough in its use, however, originates from the discovery that racemization during the coupling in many cases can be totally suppressed, or at least remarkably decreased, if the carbodiimide is employed in combination with certain additives, such as hydroxysuccinimide (HOSu) or hydroxybenzotriazole (HOBt)1. The effectiveness of DCCI in amino acid coupling has been the impulse for numerous attempts to use in an analogous manner other compounds containing a similar "reactive moiety" as carbodiimides, namely the C=N double bond. These investigations have been undertaken not only to get informations about the behaviour of those compounds in condensation reactions, but also possibly to find a reagent which could replace DCCI, i. e. to find a coupling reagent that avoids the two major shortcomings of DCCI, namely its skin irritating property and the low solubility of its product dicyclohexylurea, which very often makes the purification of the desired peptide product so difficult. Up to now, however, in practice none of the compounds in the literature seems to be able to compete with DCCI. Attempts to introduce simple alkyl and aryl isocyanides as coupling reagents have not been satisfactory with respect to the
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by Walter de Gruyter &. Co., Berlin • New York
210
2 3 4 yields of the desired peptides ' ' . The yields are particularly low, when as the acid component amino acids are used whose amino group is protected through a t-butoxycarbonyl or benzyloxycarbonyl group, i. e. those protecting groups which are usually employed in peptide chemistry"^. It is noteworthy, however, that after the normal work-up procedure the desired peptide derivatives usually are obtained in analytically pure form, even in those cases in which the yields are extremely low. When DCCI is used as coupling reagent, very often the yield of the condensation product is remarkably increased, if HOSu is 1
added to the reaction mixture . We have found that addition of HOSu, or HOBt, has almost no influence on the yields of the peptides, if simple alkyl or aryl isocyanides serve as condensation reagents. However, a large effect is observed, when isocyanides with tertiary amino groups are used. The best results have been obtained in the case of those isocyanides, in which the distance between the tertiary amino group and the isocyanide group is determined by an ethyl or propyl moiety. A very effective condensation reagent is N-(2-isocyanoethyl)-morpholine
(MAI) which has
not yet been described in the literature. It is prepared by wellknown procedures in two steps from the inexpensive chemical N-(2-aminoethyl)-morpholine. Most important with respect to the application of MAI is the fact that it does not have the customary smell of isocyanides. Preparation of MAI O
^
N-CH n -CH 0 -NH_ + HCOOH
/
z
Z
z
0
^
N-CHo-CH_-NH-CH0
^
¿.
Z
0.7 mole of N-(2-aminoethyl)-morpholine and 30 ml of formic acid in 300 ml of toluene are refluxed with a water separator. After the removal of the water the mixture is concentrated i. vac. and subsequently dissolved in dichloromethane. The solution is satu-
211
rated with ammonia (gas), filtered, and again evaporated i. vac.. The residue is distilled i. vac., N-(2-N1-formylaminoethyl)morpholine (b, p. 122 - 124°, 0.05 torr) is obtained in 90% yield. H-NMR (CDC13): -CHO 8.0 ppm (s) [TMS as internal standard] IR (neat): C=0
/ 0
1670 cm -1 .
\ N-CH-,—CH--NH-CHO + COCln 2
2
2
2
Et^N
- 2 HC1 - C0 2
•
/ \ O N-CH--CH..-NC 2 2 \_/ MAI
1 mole of N-(2-N1-formylaminoethyl)-morpholine, 320 ml of triethyl amine and 450 ml of dichloromethane are the starting materials. 1 mole of phosgene is introduced while stirring and cooling with ice. The mixture is allowed to reach room temperature and is stirred for 3 hours. Within 1 hour 40 g of ammonia (gas) are introduced (until saturation) while cooling with ice, and the mixture is filtered and concentrated. The residue is distilled i. vac., MAI (b. p. 70°, 6.05 torr) is obtained in 76% yield. IR (neat): isocyanide 2160 cm ^
From numerous experiments the following general procedure for the preparation of peptide derivatives has emerged. Procedure for preparing peptide derivatives The acid component (10 mmole);together with the additive, HOSu (20 mmole) or HOBt (10 mmole), is dissolved or suspended by stirring in a suitable solvent (dichloromethane, ethyl acetate, dioxane, isopropanol, t-butanol, tetrahydrofurane, or dimethyl formamide). After adding MAI (12 mmole) the reaction mixture is stirred for half an hour, then the amine component as hydrochloride (10 mmole) and a suitable tertiary amine (10 mmole) are added (triethyl amine, 4-dimethylaminopyridine (DMAP)).
212
In general, the reaction mixture is stirred for 24 hours and then after evaporation i. vac. the residue is distributed between ethyl acetate/1 N hydrochloric acid. The ethyl acetate phase is washed with 1 N hydrochloric acid, water, twice with 7.5% NaHCO^-solution, and once again with water. After drying over sodium sulfate the solution is evaporated i. vac. Note that it is necessary to let the acid component, the additive, and the isocyanide react over a suitable period of time before the amine component is added.
In Table 1 the yields of a number of peptide derivatives are given, which have been prepared according to the above procedure. It contains di-, tri-, and tetra-peptides. However, larger peptide segments have also been combined successfully^. Table 1: Peptide derivatives which have been synthesized according to the above general procedure. Peptide derivative
additive
base
solvent
Z-Val i Gly-OMe
HOSu
Et 3 N
AcOEt
81
Z-Val*Gly-OMe
HOBt
DMAP
t-BuOH
82
BOC-Aib^Aib-OMe
HOBt
DMAP
C
60
TCBOC-Val^Aib-OBzl
HOBt
TCBOC-Aib*Pro-OBzl
—
TCBOC-Aib*Ala-OBzl
HOSu
BOC-Gly-Ala-tVal-OtBu
HOSu
yield [%]
DMAP
6H6+) CH 2 CI 2
81
Et
CH 2 CI 2
69
N
3 DMAP —
CH 2 CI 2
80
CH 2 CI 2
95
BOC-Gly-Ala-^Leu-OEt
HOSu
Et^N
AcOEt
93
TCBOC-Aib*Val-Aib-OBzl
HOSu
DMAP
CH 2 CI 2
64
BOC-Gly-Leu±Ala-Gly-OEt
HOSu
Et 3 N
CH 2 CI 2
72
BOC-Gly-Ala-tLeu—Gly-OEt
HOSu
Et 3 N
CH 2 CI 2
70
TCBOC-Aib-Ala*Aib-Ala-OBzl TCBOC-Aib-Pro*.Val-Aib-OBzl
HOBt
DMAP
CH 2 C1 2
55
HOSu
Et N
CH 2 C1 2
61
boiling after 3 h of reaction time
213
The critical issue in peptide synthesis is the racemization of the acid component during the coupling step. MAI as well as DCCI have been applied in the synthesis of TFA-Phe-Phe-OtBu from the racemization prone TFA-Phe-OH and H-Phe-OtBu. The racemization of the phenylalanine moieties has been measured according to the method developed by Gil-Av et al. 6 Preliminary results 7 are most promising (see Table 2). It is very surprising that the additise HOSu suppresses racemization only in those cases completely in which MAI is employed as coupling reagent. Table 2 : Racemization of TFA-Phe-OH [1 mmole] during the formation of TFA-PKe-Phe-OtBu. additive
coupling reagent
[mmole]
[mmole]
HOSu [2]
MAI [1.2]
HOSu [2]
MAI [1.2]
HOSu [2]
DCCI [1.1] MAI [1.2]
phenylalanine D and L [%] D 0 L 1 00 D 0 L 100 D 0 L 100 D 3 L 97 D L
remarks starting material H-Phe-OH
addition of a catalytical amount of DMAP
T7 83
If the condensation reaction with isocyanides is performed in absence of any additive, then the mechanism of the amide bond formation may be described by a scheme which is given below. The main step in this scheme is the a-addition of the acid component at a formally divalent isocyanide carbon. All of the consecutive steps represent nucleophilic substitutions, in which the various nucleophiles that are present in the reaction mixture attack the carbonyl carbon of the acid component. The ability of isocyanides to undergo a-additions is well-documented in the g
literature . The intermediate products VII and VIII have been detected; the diacylamine derivative IX, which originates from a
214
g Mumm rearrangement , has, however, not yet been found. Compound IX corresponds to the diacylurea derivative which is often a byproduct in condensation reactions performed with carbodiimides in the absence of HOSu. A nucleophilic attack at the carbon atom of the imine leads ultimately to compounds which already belong to the scheme. +r3-nh R -CO-O-CO-R
VII
IV
f
• •>
V
+ 1 -VI R^ —COOH + C N - R 2
II
Hv \
2
R 1 -CONH-R 3 + OCH-NH-R2
R —CO —0
VI
[R1 = -CH-NH-CO-R4] -VI
OCH-N-R
I
IX
CO-OR
N-CH-R 4 // \ R -C
+ IV
V
C=0 VIII
The presence of additives such as HOSu may change the reaction mechanism considerably, in particular, when MAI is the condensation reagent. We have observed that in a solution of 1.2 moles of MAI and 2 moles of HOSu in dichloromethane no isocyanide is detectable any more according to IR. This ratio depends strongly on the nature of the solvent as well as on the acidity of the additive. For example, in order to achieve this effect in DMF, a larger amount of HOSu must be added. In the case of HOBt, which is more acidic than HOSu, the corresponding ratio is given by 1,2 moles HOBt and 1 mole MAI in dichloromethane. A protonation of MAI according to the next scheme explains these observations. Isocyanides are known to form strong hydrogen bonds
In the case of unsubstituted isocyanides a very large
excess of HOSu is needed, in order to protonate the isocyanide
215
such that it cannot be detected in the infrared. Note that the propyl analog of MAI is also not as easy to protonate as MAI itself.
/
CH,-CH9
IN \
C=N-CH0-CH~-N 2 Z \
0
/
^
\^ .N
CI
®IÔ-Su —
H
I
\
0
V U /
CH_-CH. 2 / 2 \X
\
C—H-Furthermore, when an excess of MAI (or a basic solvent such as pyridine) is used in the reaction, then very often the HOSu or HOBt ester, resp., of the acid component can be isolated in high yields. It is noteworthy that this is possible even in the presence of the amine component! The formation of these so-called "active" esters can be rationalized according to the following reaction scheme. Here the hydroxysuccinimide anion serves as the nucleophile which reacts with the a-adduct of the isocyanide and the acid component.
C=N-CH2-CH2-N
(excess) + HOSu + R 1 -COOH (+
3
R -NH2)
,CH0-CH.
/
IN.
CI
CH--CH-
.AN H"
/ p
2
+ IN
\N
\ - H
® lÔ-Su
R 1 -C0-0
R -CO-OSu (+
+
/—\ 0CH-NH-CH_-CH 2 2o-N \ /0
RJ-NH2)
216
It has been assumed that in condensation reactions with DCCI the additive HOSu reacts with the DCCI-adduct of the acid component to form the HOSu ester of the latter. This reaction is supposed to take place before the DCCI-adduct can decompose into the racemization prone oxazolinone derivative of the acid component'' ^ . Our observations are evidence against such a reaction mechanism.
References 1.
Wünsch, E.(edit.): Synthese von Peptiden. Teil II. Methoden der organischen Chemie. (Müller, E., edit.). Band 15/2, Georg Thieme Verlag, Stuttgart 1974, p. 103 - 119.
2.
Yasuda, N., Ariyoshi, Y., Toi, K,: United States Patent, 3,933,783. Jan. 20, 1976.
3.
Aigner, H., Marquarding, D.: Tetrahedron Lett., 3325 - 3326 (1 978) .
4.
Wackerle, L.: Synthesis, 197 - 198 (1979).
5.
Wünsch, E., Moroder, L, et al, (unpubl, results).
6.
Gil-Av, E., Feibush, B,, Charles-Sigler, R., in: Gas Chromatography. (Littlewood, A. B., edit.). Institute of Petroleum, London 1967, p. 227. Gil-Av, E., Feibush, B., Charles-Sigler, R,: Tetrahedron Lett., 1009 - 1015 (1966).
7.
Charles, R., Gil-Av, E., Aigner, H., Koch, G., Marquarding, D. (unpubl. results).
8.
Ugi, I. (edit.): Isonitrile Chemistry. Academic Press, New York and London 1971, p. 65 - 92,
9.
Mumm, 0., Hesse, H., Volquartz, H.: Chem. Ber. 48, 379 391 (1915).
10.
Schleyer, P. von R., Allerhand, A,: J, Amer. Chem. Soc. 84, 1 322 - 1 323 (1 962) . Ferstandig, L. L.: J. Amer. Chem. Soc. 84, 1323 - 1324 (1962). Ferstandig, L. L.: J. Amer. Chem. Soc, 8£, 3553 - 3557 (1962) . Allerhand, A., Schleyer, P. von R.: J, Amer, Chem. Soc. 85, 866 - 870 (1965).
11.
Rich, D. H., Singh, J,, in: The Peptides. Analysis, Synthesis, Biology. (Gross, E., Meienhofer, J,, edit.). Vol, 1. Academic Press, New York 1979, p, 249.
IMPACT
OF
CONFORMATION
ON
THE
SYNTHETIC
STRATEGIES
FOR
PEPTIDE
SEQUENCES
Manfred Mutter, Hermann Anzinger, V . N . R a j a s e k h a r a n P i l l a i (+) Institute of Organic C h e m i s t r y , D-6500 Mainz, Germany
Karsten
Bode,
University
of
Franz
M a s e r and
Mainz,
Introduction
The
physicochemical
rate
of
wise
and
coupling segment
peptides.
The
influence
upon
wise are
the
synthesis.
In
sequence,
and
physical of
the
length
of
the
peptide
and
coupling
a
growing
nature
of
environment concerned
peptide
by
the
decide
interdependence
of
properties
peptide
and
protein
we
sequences.
solubility
On leave Calicut,
of
chain
observed
a
their
to
kinetics
pre-
knowledge
of
influence
on
would for
permit
the
desired these
with
between
con-
the
and
respect on
of
The
groups
solvation
Chemistry,
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by Walter de Gruyter &. Co., Berlin • New York
properties
delineate
correlation
f r o m t h e D e p a r t m e n t of Kerala-67635, India
step-
oligopeptides
and
of
transitions.
preferences
coupling
during
conformational
model
the step-
significant
these
peptides
length
and the
synthesis
rates
strategies
of
in
protecting
and
In o r d e r
a number
and
has
thorough
the
conformational
The
the A
factors
synthetic
sequence,
structure.
formation,
(+) of
their
composition,
condary
of
synthesized
investigated to
planning
role the
chain,
involved
peptides.
these
solubility
conformational
physicochemical
aspects,
the
solubility
the
effective
as
important
approaches for
the
an
such
extremely
influenced
primary the
an
condensation
chain
drastically
ferences
properties
play
se-
growing
University
218 peptide
chain
specific ful
synthesis the
of
proved
be h i g h l y
to
The
analysis
peptides
peptides
ficant This
high
Chain
on
of
characterized and
suitable
using
experimental
influence
property
out
could
since
the the
POE
CD,
Elongation
and
been
its
success-
phase
conformational
under for
the
applied
conformational to t h e
to h a v e
of the
bound
structure
on
different
conformational
coil
a
NMR m e a s u r e m e n t s
shown
conformations to
liquid
the
IR a n d
peptides
has
for
the
peptides. the
techniques
POE
is d u e
to d e l i n e a t e followed
be d i r e c t l y
by a s t a t i s t i c a l
segmental
be
oligopeptides
(POE)-bound
conditions. of
the
carried
to
to m e d i u m - s i z e d
of
was
helped
strategies
short
polyoxyethylene
bound
studies
synthesis
analysis the
these
experimental
For
method^
from
POE-
no
siqni? peptides .
behaviour
with
low
density
mobility.
and
Physicochemical
Properties
of
Homo-
oli g o p e p t i d e s The of
stepwise
synthesis
homooligopeptides
oxyethylene,
reveals
transitions
of the
properties.
The
of the
and
on
the
growing
amino
group
oligopeptides
exhibiting
homooligomers
of
aggregate drastic
at
example,
when
derivatives of
10%
the
very
decrease
valine short
viscosity
like
structure
ween
the
is
peptide
on
lengths with
viscous
chains.
by
Thus the
and
the
reduced
the
to
from
peptide at
in
POE-bound
tendency
the
chain.
For
tetrapeptide
concentrations
concentrations
polar
reactivity
in the
chloride
{ aggregated
be a g e n e r a l
certain
this
n = 6-8.
of
solvents change
development
by c o n f o r m a t i o n a l
conformational
1. The o c c u r e n c e
peptides
in
conformation
o f the
of
peptide
n >12,
that
(n 5)
in
these
behaviour
in t h i s
lengths),
synthesis.
result
due
. Then,
of
(5-conformation
insertion
segments
segments
'
this
of a 13-structure,
peptide
preferences
longer
a minimum
tendency
and
than
must
chain.
be e n v i s i o n e d
Pg-potentials
sequence
chain
by
various possible 9 10
to a v o i d
with
of
product
peptide
conformational
other
present
show
the
described
be o f c o n s i d e r a b l e
chains
aspects,an
to
be
solubility.
of the
is p o s s i b l e ,
the
examples
formation
f o r (3-structure of
peptides
is r e l a t e d
to
to
in
elongation
strategies
larger
by a d e c r e a s e
further
of m e d i u m - s i z e d
middle
chain
structures
densation
it
The
synthesis
ventional
Whenever
of peptides.
in p e p t i d e
at
help
strategies
of a p e p t i d e
peptide
can
cooligopeptides
experimental
of
conformational
stage
condensation,
prevents
These
and
interdependence and
(3-1 i ke s t r u c t u r e s
(a)
where
on the
synthesis
The
critical
either
more
form
Peptides
elongation
paralleled
general.
in c a s e s
the
that medium-sized
this
segment
the
reactivity
segments
show
by
be
observation
solubility short
extent,
for
properties
of h o m o o l i g o p e p t i d e s to
suggest
appears
investigations
physicochemical
not necessarily The
Strategies
pre a way
residues and when
in a
the
central
227 position these the
of
total
which ions
the
segments
should
the
sequence
gives and
concerned by
due
the
help
synthesis,
by
segment
reactivity
chain
1ength.
the of
to the
two
low
the
to the
and
main
Such
a
properties
obstacles
solubility
terminal
synthesis
finally
of
amino
in
of
establish procedure
conformational
physicochemical
to o v e r c o m e namely
proceed
approach
condensation.
consideration
dependent
duced
segment;
stepwise
transit-
of
peptides
peptide
segments groups
and
with
the
re-
increasing
Acknowledgement We
thank
the
support
of
"Chemie
und
Deutsche
this
work
Physik
Forschungsgemeinschaft through
der
the
for
the
financial
Sonderforschungsbereich
41,
Makromoleküle".
References 1.
M u t t e r , M . , B a y e r , E.: in " T h e P e p t i d e s : A n a l y s i s , S y n t h e sis a n d B i o l o g y " , V o l . II, G r o s s , E . , Me i en ho f e r , J.: Eds., A c a d e m i c P r e s s , N e w Y o r k , 1 9 8 0 , p. 286
2.
Mutter,
3.
M u t t e r , M., M u t t e r , H., m e r s , 15^, 917 ( 1976 ).
Uhmann,
4.
Rahman, S.A., 173 ( 1 9 8 0 ) .
H.,
5.
von D r e e l e , P . H . , L o t a n , Andreatta, R.H., Poland, c u l e s 4 , 4 0 8 ( 1971 ) .
6.
Ribeiro, A., Goodman, 100, 3903 (1978).
7.
Toniolo, C., Bonora, G.M., M a k r o m o l . C h e m . , 1J52 , 1997
Mutter, M., ( 1981 ).
8.
Toniolo,
Mutter,
M.:
C.,
Macromolecules, ^0,
Anzinger,
Bonora,
1413 R.,
Mutter,
(1977). Bayer, M.:
E.:
Biopoly-
Biopolymers,
19,
N., A n a n t h a n a r a y a n a n , V.S., D., S c h e r a g a , H.A.: M a c r o m o l e -
M.,
G.M.,
Naider,
F.:
J. A m .
Chem.
Soc.,
Pillai,
V.N.R.:
M., Pillai,
V.N.R.:
228 Makromol. 9.
C h e m . , ¿ 8 2 , 2007
(1981).
T a n a k a , S., S c h e r a g a , H.A.: M a c r o m o l e c u ! e s , 9, 142
10. C h o u , P.Y. (1978).
F a s m a n , G.D.: Ann. Rev. B i o c h e m . , 47, —
(1976).
251
SYNTHETIC STUDIES OF NEUROTOXIN II FROM VENOM OF CENTRAL ASIAN COBRA Naja naja ox-Lana
Vladislav Deigin, Victor Ulyashin, Inessa Mikhaleva, Vadim Ivanov Shemyakin Institute of Bioorganic Chemistry, USSR Academy of Sciences, Moscow, USSR
At the previous FRG-USSR Symposium and at the 15th European Peptide Symposium we reported some results of our investigation aimed at total synthesis of neurotoxin from the venom of Central Asian cobra Naja naja oxiana (Fig. 1) (1). Synthesis of neurotoxin II is a component part of the structure-functional investigation of polypeptide neurotoxins and the development of methodology for synthesis of large peptides and proteins. NT-II is a 61-membered polypeptide with 4 disulfide bridges.
Fig. 1. Amino acid sequence of neurotoxin II from the venom of Central Asian cobra Naja naja oxiana.
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by Walter de Gruyter & Co., Berlin • New York
230 The synthesis was elaborated in such a manner so that we could employ the strategy of maximal protection of the trifunctional residues with the help of hydrophobic groupings of the benzyl type as was described in an earlier paper for the case of obungarotoxin
(2). In view of the fact that we encountered
some difficulties in synthesizing a-bungarotoxin, for instance, side reactions involving the liberating cysteine SH group due to HF treatment, we utilized the acetamidomethyl protection instead of
p-methoxybenzyl. Such a combination of the protec-
ting groups allows the purification of the resulting product following HF deblocking to be carried out without any risk of oxidation of the cysteine residues. The glutamine carboxamide groups
and tryptophan
indole remained unprotected. The fol-
lowing protections were used for the remaining amino acids: benzhydryl for asparagine,benzyl esters for aspartic and glutamic acids, benzyl ethers for serine and threonine, 2,6-dichlorobenzyl for tyrosine and the tosyl groups for the arginine guanidine group. Tos, Boc and Dnp groups were used to protect the histidine imidazole.
The a-amino group was protected either
by Boc- or Z-group. Stepwise synthesis was the method used to obtain all the short fragments corresponding to the total amino acid sequence of the NT-IX molecule (Fig. 2), namely 1-3, 4-8, 9-12, 13-15, 16-19, 20-26, 27-33, 34-47, 48-51 and 51- 61. Each fragment was synthesized in more than one way that allowed us to optimize the yield and facilitate the purification of the final product. The present paper is devoted to further studies on condensation of the fragments, as well as on methods of their-, purification. Several attempts have been made to purify the protected peptides by gel-filtration on soft strongly swelling sorbents, as for example, enzacryl K-2 (3), Sephadex LH-20 and LH-60 (4) or Bio-Beads Sxl (5) . However,under these
conditions
it appeared difficult to realize the separation of peptides as they differ in molecular mass by less than twofold. Besides, difficulties connected with their purification
increased
with a rise in the molecular mass of the peptides.
231
Acm
Bzh
Fig. 2. Molecule fragment scheme for neurotoxin II.
Moreover, we encountered other difficulties in the process of purification of the intermediate protected NT-II fragments, especially when using the conventional gel-filtration methods (1) .
Analytical and preparative size-exclusion HPLC methods were employed in the case of the protected hydrophobic peptides in organic solvents. But in order to optimize these procedures we had to investigate various types of gels - soft, semirigid and rigid. Among the investigated soft gels, Sephadex LH-20 is in virtue of its properties the most suitable for separation and analysis of synthetic protected peptides with a molecular mass below 2000 dalton (Fig. 3). The mechanical properties of Sephadex LH-20 favour a rise in the efficiency of the column and linear flow rate.
232
Fig. 3. Chromatogram of the protected peptides and naphthalene mixture: M M M.M. 1. Aoc-56-61-OBzl 1963 2. Aoc-58-61-OBzl 1265 3. Boc-60-61-0Bzl 768 4. Boc-Asn(Bzh)-OBzl 488 5. Naphtalene 130 8 x 600 mm column, Sephadex LH-20 gel, eluent DMF . Flow rate 0.4 ml/min, refractive index detector.
With the help of narrow fractions of sorbent particles (40 50 u)
we managed to obtain an efficient column operation
(about 8000 t.p. per meter). A more detailed investigation of the soft and semirigid gels was carried out in (6). We used silica gels of different types to separate and analyze peptides with a molecular mass above 2000 dalton. The application of rigid sorbents in size-exclusion chromatography has opened the way for new opportunities for performing separation and analysis of peptides. Thus, for example, the accessibility of silica gel with small-size particles makes it possible to obtain an extremely high efficient column (about 100000 t.p. per meter). Additionally, the mechanical properties allow
operating at high flow rates. One can select
silica gels for working in any molecular mass range. By modifying the silica gel surface one can obtain a sorbent suitable for the separation of substances of any class, including labile
233
Fig. 4. Calibration curves for the studied sorbents with synthetic protected peptides in DMF. 1. o 2 . -4 3. £ 4.—A—
Sephadex LH-20 Silica gel "L" Silasorb 600 Spherical silica gel
5.—« 6. • 7. •
Si-40 PSM-60S Zorbax Sil
Synthetic peptides indicated in Fig. 4 caption as well as a Boc-52-61-OBzl fragment (M.M.=2575) and naphtalene were used for calibration. Void volume was determined using high molecular impurities.
biopolymers. Therefore,silica gels can be applied for analysis and separation in preparative quantities of practically any substance. With the help of different modifications it is also possible to prepare sorbents oh which the separation proceeds" according to a purely size-exclusion mechanism. We investigated the selectivity of different silica gels and the behaviour of peptides on them, with the aim to choose an optimal form for size-exclusion chromatography of protected peptides in organic solvents (Fig. 4). As is seen in Fig. 4 Zorbax Sil and PSM-60S have practically a linear calibration curve but their selectivity value is relatively low. Silica gel Si-40(Merck) also has the same linear calibration curve, although its selectivity is apparently less and the operating range narrower, most likely due to the larger
234 6
mln. 5
4
3
2
1 0
Fig. 5. Chromatogram of artificial peptide mixture:
M.M.
1. High molecular weight impurities . . 2. Boc-34-61-OBzl 5417 3. Boc-48-61'-OBzl 3125 4. Aoc-55-61-OBzl 1962 5. Aoc-58-61-OBzl 1265 6. Boc-60-61-0Bzl 768 7. Boc-Asn(Bzh)-OBzl 488 8. DMSO 78 8 x 250 mm column, Silasorb 600 sorbent, eluent DMF. Flow rate 2 ml/min, refractive index detector.
yolume of the micropores. The silica gel prepared according to Unger's methods (7) appeared to have the best selectivity, especially in the high molecular
weight region. The calibration curve of this sili-
ca gel has a non-linear shape. Besides, the nature of the silica gel surface also plays an essential role in achieving a suitable separation of the protected peptides.
For instance, only totally protected pep-
tides were eluted from the column with a non-modified surface by the pure size-exclusion mechanism (Fig. 5). Peptides containing free imidazole, guanidino or amino groups sorbed on a gel
235
1-12 13-19
20-26
mna .(H )»c« XCACBT XC/HOP*
27-33
3i-39 ¿0-47 ¿S-51 52-6i
B«c4 XL7I«
Fig. 6. Preparation scheme for fragments 1-33 and 34-61.
matrix and eluted a little later then the protected peptides of the same molecular mass. In the course of synthesis and condensation of the fragments we observed the formation of high molecular weight impurities
Fig. 7. Analytical (A) and preparative (B) chromatography of synthetic peptide of 34-61 sequence on a silica gel "L" column, 25 x 330 mm in DMF. Flow rate 10 ml/min. 1. High molecular impurities 2. Boc-34-61-OBzl 3. Initial fragments UV-detector,respect.refractive index detector. Loading under preparative conditions 50 mg per 20 ml.
236
of peptide nature whose amount increased with reaction time. Not always is it possible to successfully remove these polymer products by standard methods, especially on large peptides. According to our data these polymers are not products of peptide association, for their retention times do not change with rechromatography. The fragments were condensed mostly by DCC/HOBT method (Fig.6). Fragments 1-33 were obtained by the condensation of two blocks, that of 1-19 and 20-33. The C-terminal part of the molecule sequence was obtained by the same DCC/HOBT, as well as by DCC in the presence of pentafluorophenol. In both cases the yield varied within the range of 25-30%. The reaction product was separated by size-exclusion chromatography on a silica gel column. An example of the analytical (A) and preparative (B) separation of the condensation reaction products of fragments 34-37 and 48-61 is given in Fig. 7. The individuality of all the resulting fragments was also controlled chromatographically and by determining the N-terminal amino acids and was confirmed by amino acid analysis data. Thus, two large molecule fragments were obtained, those of 1-33 and 34-61 (Fig. 2).A search for optimal conditions for condensation of these blocks into a uniform polypeptide chain is still in progress.
References 1. 2.
3. 4.
Mikhaleva, I.I., Deigin, V.I., Ulyashin, V.V., Ivanov, V.T.: "Peptides 1978", Proceedings of the 15-th European Peptide Symposium, Poland, 391-395 , 1979 Ivanov, V.T., Mikhaleva, I.I., Volpina, O.M., Myagkova, M.A., Deigin, V.I.: "Peptides 1976" (ed. A.Loffet), Proceedings of the 14-th European Peptide Symposium, Belgium 219-229, 1976 Galpin, I.J., Handa, B.K., Kenner, G.W., Moore, S., Ramage, R.: J. Chromatogr. 123, 237-242 (1976). Danho, W., Fohles, T.: Hoppe-Seyler's Z. Physiol. Chem. 36, 839-847 (1980).
237
5. 6. 7.
Volpina, O.M., Deshko, T.N., Mikhaleva, I.I., Ivanov, V.T.: Bioorg. Khim. 6, 1155-1162 (1980). Deigin, V.l., Ulyashin, V.V., Nefedev, P.P., Zhmakina, T.P., Belen'ky, B.G., Ivanov, V.T.: Bioorg. Khim. (USSR) 8, in press Unger, K., Check-Kalb, J., Straube, B.: J. Polym. Col. Sci. 253, 658 (1974) .
I N V E S T I G A T I O N O N T H E S Y N T H E S I S O F S A L M O N C A L C I T O N I N II F R A G MENTS Gennadij Vlasov, Valentina Glushenkova, Valerij Lashkov, talija Kozhevnikova, Lidija Nadezhdina, Leonid Irina Ditkovskaja, Oskana Glinskaja and Tatjana
Na-
Krasnikov, Komogorova
I n s t i t u t e of M a c r o m o l e c u l a r C o m p o u n d s of the A c a d e m y of ces of the U S S R , L e n i n g r a d , U S S R
Scien-
Introduction S y n t h e s i s of the s a l m o n c a l c i t o n i n II f r a g m e n t s w a s
investi-
g a t e d u s i n g a c l a s s i c a p p r o a c h . A n u m b e r of b y - r e a c t i o n s the c o u r s e of the s y n t h e s i s w a s
in
investigated.
Results C a l c i t o n i n s are 3 2 - m e m b e r e d p o l y p e p t i d e h o r m o n e s w i t h a d i s u l f i d e b o n d b e t w e e n the f i r s t a n d the s e v e n t h a m i n o a c i d
(1).
T h e y r e g u l a t e the c a l c i u m a n d p h o s p h o r u s l e v e l s in the b l o o d (2). S a l m o n c a l c i t o n i n is m o r e a c t i v e t h a n o t h e r h o r m o n e s c e p t eal
calcitonin
ex-
(3).
In o r d e r to d e v e l o p a s a l m o n c a l c i t o n i n s y n t h e s i s the
in-
v e s t i g a t i o n of the s y n t h e s i s of its f r a g m e n t s w a s c a r r i e d
out
in s o l u t i o n by u s i n g a m i n i m u m a m o u n t of b l o c k i n g g r o u p s .
The
fragments
1-5, 6-10, 11-15, 16-21, 22-24,
s y n t h e s i z e d a c c o r d i n g to s c h e m e s
25-28 a n d 29-32 w e r e
1-7.
T h e s y n t h e s i s of f r a g m e n t 1-5 w a s c a r r i e d o u t by the use of the N P S b l o c k i n g g r o u p for the a m i n o f u n c t i o n s a n d D C C a n d (scheme 1). The s y n t h e s i s of f r a g 8 9 m e n t 6-10 w a s c a r r i e d o u t w i t h N P S (Leu , Val ) a n d Boc PFP m e t h o d s for c o u p l i n g
(AcmCys^, Thr^)
b l o c k i n g g r o u p s a n d D C C as the c o u p l i n g
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter &. Co., Berlin • N e w York
rea-
240
gent (scheme 2), Scheme 1 Cys1
Asn"
Ser
NPS-
Leu NPS-
-OMe
NPS-
-OMe
H-
-OMe
PFP
-OMe
NPSNPSAcm Boow^-OPFP
-OPFP
Ser"
H-
-OMe
NPS-
-OMe
H-
-OMe
Boc- ,Acm
-OMe
Boc- ,Acm
-NHNH,
Scheme 2 Thr
Cys
Boo BocH-
-OPFP
Val
-OH
^Acm —OPFP
H-
Leu'
Gly
10
Z- -OH
-OMe
Z-
-OMe
H-
-OMe -OMe
H ,Acm
-OMe
-Acm
-OMe
The pentapeptide 11-15 was synthesized from two fragments: 11-13 and 14-15. The carbobenzoxy blocking group was used for the protection of the c< -amino function and the tertbutyloxycarbonyl group for blocking the
¿-amino function
241
of lysine^. Condensation of fragments was carried out by Rudinger's modification of the azide method (scheme 3). The hexapeptide 16-21 was synthesized from two fragments (16-17 and 18-21) by the DCC/HOSu coupling method. The dipeptide 16-17 was prepared by the reaction of the N-hydroxysuccinimide ester of Z-leucine with histidine. The tetrapeptide 18-21 was synthesized according to the scheme 4. The carbobenzoxy and tert18
butyloxycarbonyl blocking groups were used for lysine The condensation of the acylamino acids and peptide fragments was carried out with the PFP, NP ester and DCC/HOSu method. Scheme 3 Lys 11
12 Leu NPS-j-OH
Boc Z — hQH
NPSH-
^Boc ffoc
Ser 13 -OMe
Gin 14 -OPFP
Asp 1' 5 OBut H— ^-OH ,
-OMe -OMe -OMe -NHNH, -N-
,Boc
The synthesis of the fragment 22-24 (scheme 5) was carried 24 out without blocking the guanidino group of arginine with the help of the activated ester method. The tetrapeptide 25-28 was prepared according to scheme 6 from the azide of the tripeptide 25-27 and glycine. The tetrapeptide 29-32 was synthesized according to scheme 7 from two dipeptides by the DCC/PFP method. Crystallization, gel chromatography and adsorption chromatography were used for the preparation of the calcitonin fragments in pure form. Many by-reactions were investigated. Dipeptide 31-32 can be prepared only with the use of prolin-
242
Scheme 4. Leu
16
17
His
Leu
Lys
19
Gin
20
21
Z- 3Np Z-OPFP
H-
Boc Z—-OH -OSu
H OH
^Boc J3oc
Scheme 5. Phe 22 -OSu
Pro
23
Arg 24
-OH "OH -OSu
-OH -OH
amide but not from the methyl ester. All attempts to transform the carbobenzoxy dipeptide ester into the amide were unsuccessful. The reaction of acylation of the methyl ester 25 of threonine or the methyl ester of threonyl-asparaginylthreonine (25-27) by acyl-(Z or Boc)nitroarginine with the help of DCC yield only N-acyl-urea (70-80 %). Only the 2.5-diketo-piperazine of valine and proline was found during the catalytic hydrogénation of carbobenzoxyvalyl-prolinamide in the absence of strong acid. However, in the presence of p-toluenesulfonic acid hydrogénation yields the dipeptide amide.
243 S c h e m e 6. Thr
25
Asn Z-
-OPCP
26 DNp
Thr
27
Gly
-OMe
Z-
-OMe
H-
-OMe -OMe -NHNH, -NH-
-OH -OH
S c h e m e 7. Ala
29
Gly
30
Z -+OSU
-OH
z-
-OH
A t t e m p t s to s y n t h e s i z e m o r e c o m p l e x p e p t i d e f r a g m e n t s w e r e m a d e a n d the d e c a p e p t i d e peptide
1 —10, p e n t a d e c a p e p t i d e
25-32 a n d h e p t a d e c a p e p t i d e
16-32 w e r e
1-15, octa-
prepared.
O p t i m a l c o n d i t i o n s of c o u p l i n g b u l k y f r a g m e n t s to ^he p e p t i de of the s a l m o n c a l c i t o n i n s e q u e n c e a r e u n d e r tion .
investiga-
244 References 1. Niall, H.D., Keutmann, H.T., Copp, D.H., Potts, Y,T.:Proc. Natl.Acad.Sei.64, 771 (1969), 2. Riniker, B., Reher, R., Maier, R., Byfield, P.G.H., Gudmundsson, T.V., Maclntyre, J.: Nature 220, 984 (1968). 3. Keutmann, H.T., Passons, J.A., Potts, J.T.: J.Biol.Chem. 245, 1491 (1970).
TOTAL SYNTHESIS OF SOMATOSTATIN WITHOUT HYDROXYL GROUP PROTECTION OF HYDROXYL AMINO ACID RESIDUES
Yu.P.Shvachkin, S.K.Girin, A.P.Smirnova, A.A.Shishkina, N.M. Ermak Institute of Experimental Endocrinology and Hormone Chemistry, Academy of Medical Sciences of the USSR, Moscow
Introduction The hormone somatostatin is a tetradecapeptide of structure (I) (all asymmetric amino acids have L-configuration) (1). 1 5 10 14 H-Ala-Gly-Cys-Lys-Asn-Phe-Phe-Trp-Lys-Thr-Phe-Thr-Ser-Cys-OH I
I (I)
At present this hormone is of interest for peptide chemists as well as for clinicians. In spite of a number of published papers concerning the synthesis of somatostatin in solution and on polymeric carriers the problem of preparative methods for somatostatin remains nevertheless an actual one.
Results In pursuit of a research study on somatostatin derivatives we have performed a total chemical synthesis of this hormone according to a new scheme whose specific features are: 1) The possibility to use amino acid derivatives (Thr and Ser ) without hydroxyl group protection;
Thr
2) the application of the tetrahydropyranyl protection for masking mercapto groups in the Cys"^ and Cys ^ residues at intermediate stages of the synthesis.
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by Walter de Gruyter &. Co., Berlin • New York
246
Preparation of the protected linear tetradecapeptide was performed by a fragment condensation starting from the previously synthesized 1-7 and 8-14 fragments. From the point of view of the tactics of the peptide synthesis this variant which makes allowance for "a docking" of the mentioned heptapeptide fragments is the most preferable one since in this case properties of the final desirable product differ maximally from those of the initial materials. This would facilitate the separation of the conceived tetradecapeptide from the reaction mixture. All condensation reactions were carried out under conditions which reduced racemization of the individual amino acid residues to a minimum. The key stages of the fragment docking were performed by the azide method or by the method of activated (pentafluorphenyl) esters. The tert-butyloxycarbonyl group or the o-nitrophenylsulfenyl group were used to protect the o-OSUp3] . H-1>«BOO-OKU] Z-Aij^LysBOa-OH^-U^ jtywci Z-G>uPeuhOSU [ l j •
H-AnlHCH-LyHBOC)-OH|a-Klj
Z-GMCI8u)-Afg(HQ)-Lys(B0C)-0H[l2-U^
1
'
2-ATA-QSU[9] . H-Pto-OH[Kg
Z-*t»IZj-OSU[l j
Z-Alo-Pre-OH [ 9 - I O j
.
H
mjluCCul-AtglHCIHyiaOCHOH[tt-Hlj
Z-Arg(Z2l-Glu(OISu)-Arg-LyslSOCI-OH§l-U^
IDCC/NOIU
j^Mff*
Z-Ala-Pnt-OSUfo-lOlj
.
K-Alj(Har)-OUl(Oeu>-Arg|Hei)- L»»(BOCI-OH [ l t - U ^
Z-Alo-Pio-Aig(HBt)-GlulOeu)-ArglHB>)-LyslBOC)-OH[9-U^
Ln
NPS-M»I-CHP[»]
.
H-AlQ-Pro-Af9lHBf)-Gtu(01Bu)-AnlHBfHy»lB0C)-0H[9-Ub|
N P S - M t t - A l a - P R O - A r g ( H B f ) - G I I I O ® u ) - A f g IHBrl-LyslBOC) -OH [ i - U o ]
Scheme 4. Synthetic route to fragment III corresponding to sequence 8-14 of somatostatin-28; for analytical data see Ref. 14; overall yield calcd. from Z-Arg(Z 2 >-OSU [ 13]: 29%. Z-Pro-05u[6] •
H-Alo-OCu[7]
Z - P r o - A t a - O f i u fc-la]
Z-Asn-0WP[5] • H-Pro-Aln-OIBu fS-7b]
Z - A s n - P r o - A l o - O C u ¡S-Tqj MJ/IW
H-Asn-Pro-Alo-OtBu [ 5 - 7 ^
|tfa
Z-S«flBu>-OSU[NH't>Cs+>Rb+>K+>Na+>Li+. Of considerable interest are the mean life-time and conductance values of these channels. As seen in Table 3 all bis-gramicidins,regardless of their bridge position and spatial structure form channels with similar conductance but with the mean life-time by 1-2 orders of magnitude longer than with the channels formed by gramicidin A. In addition to the long-living channels the head-to-tail and tail-to-tail analogs also form short-living channels. It are these channels which are responsible for the observed conductance in the noise experiments. Bearing in mind the aggregation tendency of these analogs revealed by spectral measurements in solution, and their high concentrations at noise experiments we assume that the shortliving channels are formed by bis-gramicidin associates (possibly, by + + TTTT double helices) . The head-to-head derivatives do not seem to form short-living channels at the great variety of membrane modifications. So, the covalent crosslinking applied to gramicidin A in this work failed to produce a conformationally homogenous species. Nonetheless the data obtained clearly indicate that the channel-forming capacity in the gramicidin series should not be considered as a prerogative of a single molecular structure. In particular, a whole family of ^D^LD' ^LD^LD anc^ ^LD^LD helices are efficient channel formers. As for the double helices, their channel forming capacity still requires further study.
267
References 1. 2. 3. 4. 5. 6. 7. 8. 9.
Veatch, W.R., Blout, E.R.: Biochemistry 13, 5257-5264 (1974). Urry, D.W.: Proc. Nat. Acad. Sei. USA 68, 672-676 (1971). Urry, D.W., Goodall, M.C., Glickson, J.D., Mayers, D.F.: Proc. Nat. Acad. Sei. USA 68, 1907-1911 (1971). Ramachandran, G.N., Chandrasekaran, R.: "Progress in Peptide Research" (S. Lande, ed.), Gordon and Breach, New York, p. 195 (1972). Ramachandran, G.N., Chandrasekaran, R.: Ind. J. Biochem. Biophys. 9, 1-11 (1972). Veatch, W.R., Fossel, E.T., Blout, E.R.: Biochemistry 13, 5249-5256 (1974). Shepel," E.N., Jordanov, St., Ryabova, I.D., Miroshnikov, A.I., Ivanov, V.T., Ovchinnikov, Yu.A.: Bioorg. Khim. 2, 581-593 (1976). Ovchinnikov, Yu.A., Ivanov, V.T.: "Biochemistry of Membrane Transport" FEBS-Symp. No. 42 (G. Semenza, E. Carafoli, eds) Springer-Verlag, Berlin, pp. 123-146, 1977 Sychev, S.V., Nevskaya, N.A., Jordanov, St., Shepel, E.N., Miroshnikov, A.I., Ivanov, V.T.: Bioorg. Chem. 121-151 (1980).
CYCLIC ANALOGUES OF BRADYKININ AND KALLIDIN
Gunars Chipens, Felikss Mutulis, Natalia Mishlyakova Division of Peptide and Protein Bioregulators, Institute of Organic Synthesis, Latvian SSR Academy of Sciences, 226006, Riga, USSR
Introduction Total semi-empirical space structure calculations for bradykinin have shown that energetically preferable are the bent, quasi-cyclic structures (1) characterized by ionic bonding between the guanidyl group of arginine in position 1 within the common fragment (2) and the carboxyl group of arginine in position 9. Experimental evidence in favour of the existence of bent structures in aqueous solution was obtained by Ovchinnikov, Ivanov and co-workers investigating labelled analogues of bradykinin by EPR and fluorescence spectroscopy (3,4). However, further analysis of NMR spectra of bradykinin (5) and titration data (6) have shown that there is no ionic bonding between the terminal arginine residues of the bradykinin molecule in aqueous solution. In our view, this fact can be easily explained by the existence of a hydration layer, screening the electromagnetic fields of ions. However, quasi-cyclic structures are possibly formed in apolar biophase during hormone-receptor interaction after the dehydratation of ionogenic groups. This assumption is supported by the fact that dehydratation of the contacting surfaces is the first step during substrate-enzyme interaction(7).
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by Walter de Gruyter &. Co., Berlin • New York
270
u • H *
CM*
o a n o •P -H O -P •H U S H)
KO
CO » N (N m •
a)
a)
•H -P Ü
G
•H
O
_ O CM M o 10* M C 0) o H -H ft-p a) o a i rH O 1J
> •H -P O a) m m
en
,—.
j - i Ol M
rn
oo O
\
\
(U > •H -P O i H O (M O M CM CO >1-1
en
o>
a &
i rH U CM O M CM Cn M
1.
i -a «o m a
u >. o
-H o >1 rH Ol
r—i I rH
11)
G
>1
•H CO >1 1 (J
r
o -a o G -H
C •»H -a
(0 ¥ u I O rH U
>1
O
I
I 3 —
O
a
> —
C "ri C l-rl
i A: O >1 rH -O U (0 (H Ü
>1
-Ü (U N ~ • H CI) - P a) ai - P 3 •P fi M -H
>1.«
O c 10 o a)
S3
(0 o ai -a o T> 0 a •h
>1 n (0 n jq i ~ H >i o c
A
a) (0
(0 - H
G
1 3
(U -a o i—iiq
-P U w > o MH o ~
KAUC14,
K2PT(N02C1)2,
PB(CH3COO)2,
and
HgCl 2 as well as measurement and processing of experimental data were described in detail elsewhere (3, 4). The total numo ber of reflections from the 2.5 A range for each derivative used in the calculations was 3,43 3. The heavy atom binding sites were located by X-ray "direct" methods
(5). The selec-
tion of correct enantiomorph has been done using anomalous scattering data. The mean figure of merit < m > after last cycle of phase refinement was 0.80.
C h e m i s t r y of P e p t i d e s a n d P r o t e i n s , V o l . 1 © 1 9 8 2 b y W a l t e r d e G r u y t e r &. C o . , B e r l i n • N e w Y o r k
430 Results The actinoxanthin backbone folding drawn from C a atom coordinates is shown in Fig. 1. A distinctive feature of the actinoxanthin structure is the absence of a-helices and the presence of enhanced content of antiparallel B-structure (-55%). The three-dimensional architecture of the molecule has a double part appearance with the two lobes of different sizes (70 and 30%) being separated by a well-defined cavity. The larger lobe is a regular g-supersecondary structure containing the N- and C-termini.
Fig. 1. Topology of actinoxanthin spatial folding. The arrows indicate 6-strands, the strings indicate non-regular protein parts.
431 It is a slightly flattened cylinder formed by two layers of antiparallel g-sheets. The first external layer consists of three strands S^, S^ and S,- and the second one, bounding the molecular cavity, consists of four strands S^, S^, Sg and S^. g-Strands arrangement in protein architecture has topology of so called "Greek key" (6). The g-sheets exhibit a right twist when viewed along, and a left twist when viewed across the sheet. The two neighboring g-strands form an angle of 15-20° when looking across the sheet. The fragments of sharp chain reversal (g-turns) positioned between the g-strands are rich in Ser, Ala and Gly residues. The inner part of the g-cylindrical barrel is tightly packed with hydrophobic side chains oriented towards the axis: Ala(92), Val (6, 18, 20, 64), Phe(4, 51, 61, 63, 106), Leu(90, 99, 104), Ile(31); the Gln(33) side chain is also inside the cylinder. Hydrophilic side chains are arranged mainly on the external surface; the largest group among them is formed of Ser and Thr residues, which are located along the chain alternately with hydrophobic residues. They mainly populate the external threestrands g-sheet S, S3 c and strand S„. L ,A 4 The cylinder is bounded from one end by turns S2-S.J, S^-S^, Sg-S^ and the N-terminal and on the other end by turn disulfide bond Cys (83)-Cys (-88) , residue Lys(66) and the C-terminal. The smaller and less regular lobe of the molecule includes two closely spaced deca- and hexapeptide cycles 34-43 and 83-88 closed by disulfide bonds, curved fragment 43-47 and a g-hairpin shaped part 66-82 on the elongated loop between g-strands S r and S,. d o The internal area of the molecular cavity separating the two structural units contains a large number of Gly and Ala residues and disulfide bond Cys(34)-Cys(43). The peripheral part of the cavity is lined by the side chains of Tyr(30), Thr(49, 72), Asn(89 , 94 ), Gln(71), Ser (95) and His(101). The relative arrangement of the seven g-strands of the super-
432 secondary actinoxanthin structure shows strong topological similarity with the arrangement of g-strands in C and V domains of immunoglobulins IgG (7), in Bence Jones protein REI (8), in superoxide dismutase subunits (9), and in azurin (10). Despite the fact that these protein units consist of about the same number of residues and show close resemblance of the spatial folding pattern, the proteins themselves are functionally unrelated and have no evident sequence homology. Estimation of topological similarity of the actinoxanthin cylindrical subunit with those of immunoglobulin and superoxide dismutase has been performed on a computer by least squares method superimposing of their C a -frames. Pairwise comparison of the three-dimensional structures shows that the arrangement of practically half of amino acid residues in actinoxanthin and in the two other proteins are topologically equivalent; the root mean-square distances between the residues o were less than 2.5 A. The mean value of base change per codon for comparable protein ranges was about 1.31. It is unclear whether the observed structural similarity is indicative of divergent evolution of these proteins from a common ancestor or convergent evolution of independent precursors to energetically favorable topological state. The characteristic cavity found in the actinoxanthin structure undoubtedly has a direct relation to its biological activity. It is the probahle binding site for the chromophore in the active complex.
References 1.
Khokhlov, A.S., Cherches, B.Z., Reshetov, P.D., Smirnova, G.M., Sorokina, I.B., Koloditskaya, T.A., Smirnov, V.V. , Navashin, S.M., Fomina, J.P.: J. Antibiotics 22, 541-544 (1969) .
2.
Khokhlov, A.S., Cherches, B.Z., Reshetov, P.D., Smirnova, G.M., Koloditskaya, T.A., Sorokina, I.B., Prokoptseva, T.A., Ryabova, I.D., Smirnov, V.V., Navashin, S.M., Fomina, I.P.: Izvestiya AN SSSR (ser. biol.) (Bull. Acad. Aci. USSR,
433 Russ. ser. biol.) 755-763 (1970). 3. 4. 5. 6. 7. 8. 9.
Pletnev, V.Z., Kuzin, A.P., Trakhanov, S.D., Kostetsky, P.V., Popovich, V.A., Tsigannik, I.N.: Biopolymers 20, 679-694 (1981). Pletnev, V.Z., Trakhanov, S.D., Tsigannik, I.N.: Bioorgan. Khim. (Soviet J. Bioorgan. Chem) 5, 1605-1608 (19 79) . Pletnev, V.Z., Kuzin, A.P., Trakhanov, S.D., Popovich, V.A., Tsigannik, I.N.: Bioorgan. Khim. (Soviet J. Bioorgan. Chem.) 6, 563-569 (1980). Richardson, J.S.: Nature 268, 495-500 (1977). Amzel, L.M., Poljak, R.J.: Annu. Rev. Biochem. £8, 961-997 (1979) . E£>p, 0., Colman, P., Fehlhammer, H. , Bode, W. , Schiffer, M. , Huber, R.: Eur. J. Biochem. £5, 513-524 (1974). Richardson, J.S., Richardson, D.C., Thomas, K.A.: J. Mol. Biol. 102, 221-235 (1976).
10. Adman, E.T., Stenkamp, R.E., Sieker, L.C., Jensen, L.H.: J. Mol. Biol. 123, 35-47 (1978).
ALDIMINE BOND MIGRATION IN THE PHOTOCHEMICAL CYCLE OF BACTERIORHODOPSIN
Najmutin Abdulaev, Victor Tsetlin, Alexandr Kiselev, Valdis Zakis, Yuri Ovchinnikov Shemyakin Institute of Bioorganic Chemistry, USSR Academy of Sciences,Moscow, USSR
Introduction We found that a migration of the aldimine bond takes place in the course of the bacteriorhodopsin
(BR) photochemical
cycle.
It was also shown that, depending on the NaBH^ reduction of BR or its modified derivatives in the light or in the dark, the retinyl moiety is attached to e-amino groups of different lysine residues. Such a phenomenon is not an artifact of the reduction conditions, but is a conseguence of the photochemically aldimine migration
induced
(Fig. 1, 2).
Our experimental approach relies upon analysis of the products formed on limited proteolysis of native
(1) or reduced BR cata-
lyzed by chymotrypsin or papain. By polyacrylamide gel electrophoresis two fragments are obtained in both cases: 1-71 and 72-247
(248)-chymotryptic
papainic ones according to
fragments, or 3-65 and
(numbering according to
73-230(231)-
(2), in parenthesis -
(3)); these fragments are termed as a small and a
large one, respectively. Intense fluorescence of the retinyl residue enabled its facile detection in electrophoregrams in retinyl-bacterioopsin
and in the above-mentioned
After NaBH^ reduction of BR in the light
both
fragments.
(in all experiments
a 250 W halogen lamp was used along with 3 cm layer of 10% C u S 0 4 and yellow-orange glass filter) at pH 9.5 and 20°C retinyl moiety was found in the small and large
(4),
fragments.
Noteworthy, the proton transport across the purple membrane is
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter & Co., Berlin • N e w York
436
direction of
the
SDS-electrophoresis
+
Fig. 1. PAAG-electrophoresis of bacteriorhodopsin fragments obtained by reduction at various conditions followed by chymotryptic hydrolysis. 1) Reduction in the light followed by cleavage; 2) cleavage followed by reduction in the light; 3) cleavage followed by reduction in the dark. correlated with sequential protonation and deprotonation of the aldimine bond between retinal aldehyde and Lys 41 (see review (5)). The data obtained indicate that the e-amino group of this residue is not the only site for covalent attachment of retinal to the BR polypeptide chain and that aldimine bond may be formed by a lysine residue in small fragment (apparently Lys 41), or by large fragment residue (s) (designated as Lys x) in position 130, 159, 171(172), or 215(216). After cleavage with chymotrypsin or papain, BR preparations
437 1
< v o c 0 u) o
D
01 c £ a >s C
ffl o in c
£c
_
d i r e c t i o n of t h e
SDS-electrophoresis
+
Fig. 2. PAAG-electrophoresis of bacteriorhodopsin fragments obtained by reduction at various conditions followed by chy.motryptic hydrolysis. 1) Reduction in the presence of gramicidiri S; 2) reduction in the light at 0° and pH 10; 3) reduction in the light at 0° and pH 10. essentially preserve the spectral and functional properties of the native molecule, however acquire the NaBH^ reducibility. We capitalized on this fact to obtain information about the aldimine localization in dark conditions. In dark preparations the retinyl moiety is associated exclusively with a small fragment. After reduction of native or proteolyzed BR in the light, fluorescence was detected in both fragments. These data testify the N N retinal migration in the course of photochemical transformations of bacteriorhodopsin.
438 After dark reduction of proteolyzed BR, preliminary adapted to light or dark, or after dark reduction of preparations regenerated from proteolyzed BR with 13-cis- or all-trans retinal, all the fluorescence was found only in the small fragment. This fact means that in the dark, whatever is the double bond configuration, retinal is attached to Lys 41, and aldimine formation with a new lysine residue (Lys x) in the light is not caused by retinal isomerization during the photocycle. The BR reduction in the light was also carried out under the conditions wherein an intermediate of the photocycle (so-called M412 form or its congeners) having deprotonated aldimine bond is predominant. Stabilization of such a form is achieved by adding gramicidin S (6) OJ; by lowering the temperature (5, 7). In both cases reduction proceeds at a considerably higher rate and results in exclusive localization of retinyl on Lys x. It might be possible that under these conditions both Lys 41 and Lys x aldimines are present, but only the latter is reducible by NaBH^. However, since Lys 41-aldimine in proteolyzed BR is accessible for NaBH^ in the dark as well as in the light, localization of retinyl moiety only in large fragment when reduction is carried out in the light under the conditions favoring M412 stabilization, is indicative of the absence of Lys 41-aldimine and of complete migration of aldimine onto Lys x. Thus, a correlation exists between the aldimine bond deprotonation and its migration. The migration may proceed via aldimine hydrolysis and subsequent reaction of released retinal with another lysine amino group (earlier a photoinduced hydrolysis of aldimine bond was discovered and a hypothesis about possible migration was discussed (8)),or via a direct attack of aldimine by a spatially proximal amino group leading to tetrahedral intermediate. We found that trifluoroacetylation or succinylation of the exposed amino groups in BR fails to prevent the aldimine migration, thus allowing a conclusion to be made that Lys x amino group, inaccessible for modification, is a suitable acceptor for migrating retinal, probably being in a hydrophobic environment
439 and having a low pK. Collectively, the data on reduction of BR and its modified derivatives clearly show that migration is not a random formation of aldimines with any of accessible amino groups induced by the pH of the medium or by presence of NaBH^. The retinyl residue occupies a chromophoric site in BR when it is bound either to Lys 41 or Lys x, since none of the reduced preparations regenerates with added all-trans retinal. However, marked differences exist in microenvironment of retinyl residues attached to different lysines: a characteristic fine structure and bathochromic shift of the absorption band are seen only for Lys x -retinyl. A preference for aldimine localization on Lys 41 in the dark and a capability of photoinduced migration onto Lys x are characteristic of native BR and may be lost under certain conditions affecting the relative stability of corresponding aldimines. For example, both,after light and dark reduction retinyl is bound only to Lys 41, when analogs modified at retinal C(4) position are reduced, and only to Lys x when proteolyzed BR is reduced at acidic pH with NaBH^CN. Aldimine bond migration reported in this communication provides evidence that at least two amino groups, separated in the amino acid sequence and belonging to two different a-helical segments are involved in the BR photocycle. (Localization of these lysines is under way). This finding should be taken into consideration when interpreting the data of physico-chemical studies of BR or mechanisms of its functioning, wherein retinal aldimine is given a key role. A possibility of protonating and deprotonating different aldimines, formed by amino groups of different residues and having different microenvironment, seems very advantageous for realization of a proton transfer across the purple membrane. A photoinduced migration of aldimine bond may be a component part of the mechanism of BR functioning as a proton pump.
440 References 1. 2. 3. 4. 5.
Abdulaev, N.G., Feigina, M.Yu., Kiselev, A.V., Ovchinnikov, Yu.A., Drachev, L.A., Kaulen, A.D., Khitrina, L.V., Skulachev, V.P.: FEBS Letters 90, 190-194 (1978). Ovchinnikov, Yu.A., Abdulaev, N.G., Feigina, M.Yu., Kiselev, A.V., Lobanov, N.A.: FEBS Letters 100, 219-224 (1979) . Khorana, H.G., Gerber, G.E., Herlihy, W.G., Gray, C.P., Anderegg, R.J., Nihei, K., Biemann, K.: Proc. Nat. Acad. Sei. USA 76, 5046-5050 (1980). Schreckenbach, T., Walckhoff, B., Oesterhelt, D.: Eur. J. Biochem. 76, 499-511 (1977). Stoeckenius, W., Lozier, R.H., Bogomolni, R.A.:Biöchim . et Biophys.Acta 505, 215-278 (1979).
6.
Melnik, E.I., Chizhov, I.V., Skopinskaya, S.N., Snezhkova, L.G., Miroshnikov, A.I.: Abstracts of the I SovietSwiss Symposium "Biological membranes: structure and function" Tbilisi, p. 75 (1979) .
7.
Peters, I., Peters, R., Stoeckenius, W.: FEBS Letters 61, 128-134 (1976).
8.
Shkrob, A.M., Rodionov, A.V., Ovchinnikov, Yu.A.: Bioorgan. Khim. (Russian) 4, 354-359 (1978).
CHEMICAL MODIFICATION T o p o g r a p h y of
Horst-Dieter
OF PURPLE
MEMBRANE
Bacteriorhodopsin
Lemke, Jürgen B e r g m e y e r
Max-Planck-Institut D-8033 Martinsried,
and Dieter
Oesterhelt
für B i o c h e m i e Germany
Introduction The primary membrane
s t r u c t u r e of b a c t e r i o r h o d o p s i n
(PM) is known
The d i s p o s i t i o n was m a i n l y
(bR) in the
purple
(1,2).
of the p o l y p e p t i d e
chain first p u b l i s h e d
based on s u r f a c e c l e a v a g e sites by p r o t e a s e s
in (1) (Fig.1).
F a v o r e d by the c r y s t a l l i n e array of bR in the m e m b r a n e an ron d e n s i t y map of 7 A r e s o l u t i o n was o b t a i n e d s e q u e n c e of the p o l y p e p t i d e
chain fitted
the nonhelical density Chemical
is one a p p r o p r i a t e
p r o p o s e d a r r a n g e m e n t of the p o l y p e p t i d e by retinal
and total
insight
scattering
a p p r o a c h to test
and the amino acids near by the model
structure,
its binding
The t r i m e r i c s t r u c t u r e
in Fig.
in general
was already
(5). H o w e v e r , the sites of
were not d e t e r m i n e d ,
a l t h o u g h the knowledge of
ural
information.
chemical
represent extremely
In this article we will
modification
site, as well features
proven by
cross-
modification neighbouring valuable
summarize
of bR and the m e t h o d s
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by Walter de Gruyter &. Co., Berlin • New York
it
formed
1 and 2.
linking e x p e r i m e n t s
ami no acid residues w o u l d
the
chain. A d d i t i o n a l l y
into the c h r o m o p h o r e
as into the p r o t e i n ' s f u n c t i o n as a proton pump. Both are not e x p l a i n e d
of
(4).
modification
may give more
The
(A-G in
based on the c r i t e r i a of c o n n e c t i v i t y
links, charge s e p a r a t i o n
per helix
density
elect-
the
into this map.
a r r a n g e m e n t s of the seven regions of helical Fig.2) w e r e e v a l u a t e d
(3) and
struct-
results
used for the
of
iden-
442
Fig.
1: P r i m a r y s t r u c t u r e of b a c t e r i o r h o d o p s i n and i t s arrangement i n the membrane. P r o t e o l y t i c c l e a v a g e s i t e s of the n a t i v e p u r p l e membrane w i t h d i f f e r e n t p r o t e a s e s are marked (Ch: C h y m o t r y p s i n , P: P a p a i n , T: T r y p s i n ) ( 1 ) .
f i c a t i o n of modified
residues
i n the
sequence.
Results As a f i r s t tyrosine
reaction
residues
f o r chemical
modification
the n i t r a t i o n
by t e t r a n i t r o m e t h a n e was u s e d . A f t e r
of
subti-
443
Fig.
lisin
2: S u g g e s t e d a r r a n g e m e n t ( a c c o r d i n g to t h e m o d e l in (5)) of t h e s e v e n h e l i c e s in t h e p r o t e i n ' s t r i m e r i c unit.
digestion
complex
mixture
of t h e of
high-performance (absorbing sine
and
Tyr(N02) 3e).
nm)
nitrated
(Fig.3c),
Gly-Tyr
according
to
small
liquid
at 360
the
protein's
sequence
131
(0.6 m o l )
and
(Fig.
3f)
and
(6).
For
of
133
of
was
with of
the
of t h e the
derived,fragments
(Fig.3b),
Gly-
are 64
(1
acid
extent
integration found
hydrolysate
positions,
obtained
in
mol),
3-Nitrotyrosine
protein's
and
unique
The molar by
(Fig.
130-131)
132-133)
obtained
nitrated
3-Ni t r o t y r o -
(positions
3 moles
3f a
peptides
with
the tyrosines
was
a
Leu-Tyr(N02)
as n i t r a t e d .
tyrosine
analysis
and
(positions
(0.4 m o l )
identification
Leu-Tyr(N0?)
Ser-Tyr(N02) Val-Tyr
In F i g .
nitrated
is c o m p a r e d
identifying
each
in s u s p e n s i o n
obtained. of
(Fig.3d)
63-64),
Ser-Tyr
comparison acid
was
a digest
dipeptides
(positions (2) a l s o
of m o d i f i c a t i o n
peptides
protein
chromatogram
Val-Tyr(N02)
the
in t h e a m i n o
delipidated
from
which
by C N B r - c l e a v a g e
of
444
F i g . 3: C o m p a r i s o n of h i g h p e r f o r mance liquid chromatograms of 3 - N i t r o t y r o s i n e , nitrated d i p e p t i d e s and the s u b t i l i s i n d i g e s t of n i t r a t e d p u r p l e m e m b r a n e (6). The following samples were i n j e c t e d s e p a r a t e l y i n t o an isocratic high p e r f o r m a n c e liquid chromatography system: a) 3 - N i t r o t y r o s i n e b) S e r - T y r ( N 0 ? ) c) G l y - T y r ( N O p ) d) V a l - T y r ( N O , ) e) L e u - T y r ( N O ^ ) f) s u b t i 1 i s i n - d i g e s t of nitrated purple membrane. P e a k 6 c o u l d be r e l a t e d to a s e q u e n c e a r o u n d t y r o s i n e 26 by a m i n o a c i d c o m p o s i t i o n .
the delipidated tion
21-32
Gly-Tyr64)
protein
including a n d VII
were
analysed.
Leu-Tyr26),
(positions
V
Only
f r a g m e n t s II
(positions
118-145
61-68
including
absorption
a t 360 nm
tion
including
Leu-Tyr.47-I1e-Leu-Tyr,Rn).
146-163,
not
including
Va 1 - T y r 1 3 1 - S e r -
T y r -j 3 3 ) s h o w
but
(posi-
fragment
VIII
(posi-
445
Fig.
After
4:
reaction
soluble nm
reagent
except
longer less
S p e c t r a l c h a n g e s of p u r p l e m e m b r a n e upon nitration a) p u r p l e m e m b r a n e b) n i t r a t e d m e m b r a n e c) n i t r a t e d a n d s u b s e q u e n t l y r e d u c e d m e m b r a n e .
those
of
the n i t r a t e d
sodium
dithionite
derived
indicating
from
a reduction
3-Aminotyrosine.
membrane
As
of
accessible
to t h e
reducing
agent.
conditions
reacts
to a b o u t
20
tion
subsequent
and
spectral
changes
reduction
ionic,
absorbing
water at
detectable
3-Nitrotyrosine
to l i e o n
the
26 w e r e
a consequence surface
the
peptides
tyrosine
be a s s u m e d
In F i g . 4
the
no
with
to t h e
Tyr64,131
of t h e m e m b r a n e
and
colour-
133
therefore
3-Nitrotyrosine2g
360
any
under
can being these
%. of t h e are
purple
shown.
membrane
Nitration
upon
shifts
nitrathe
446 absorption
maximum
mum
nm.
at
360
at 3 6 0 a form does 26
absorbing show
in the
Reaction reagent mation sulting
HPLC
Reaction
of
exclusive all
64 a n d the
and
The
at 532
acid
residues
the
CNBr-cleavage Lys
phase
30
V as
and
and
of
the
subsequent
re-
ion
26
(0.25
tyrosine
64
(0.75
vesicles
of
tyrosine
64. This
oriented
identically
30 are
infor-
membrane.
tyrosine
are
26/lysine
further
of t h e
mo-
sites.
membrane-containing
modification
tyrosine
separation
II a n d
reactive
of
produce
(0.5 m o l e s ) ,
in C N B r - f r a g m e n t
trans-
(6,8).
surface
HPLC
with
strongly h y d r o p h i 1 i c
should
at t h e
remains
3-Nitrotyrosine,,g
proposed
with
nm
pK of t h i s
because
maxi-
absorption
chromophore
was
reversed
bR m o l e c u l e s
tyrosine
specific
mation
about
membrane. under
modification the
protein. the
of
located
relative therefore
lead
clearly and
to
the
demonstrates that
on o p p o s i t e
with
with
afterwards
papain
activity weight
should
upon
by t h e
S-diazotized were
be f o u n d
tyrosine
sites
of
on S D S
gels
if t y r o s i n e
on t h e
same
side
s i des.
carry
the
label
64 a n d
prepared.
amino
the
As
acids
the off
different-
carboxyterminus
64 a n d
lower the
Vesic-
(DSA) and treated
a prediction
in t h e
are
in
cleaves
experiment:
acid
of t h e m e m b r a n e if t h e y
chain
papain
infor-
electrophoresis.
following
exclusively
further
chain migrates
gel
sulfanilic
band should
with
terminal
SDS
located
chain
to o b t a i n
polypeptide
of t y r o s i n e
be d e t e r m i n e d
les c o u p l e d
the
polypeptide
chain
orientation 35
of
used
the c a r b o x y
The shortened
can
be
purple membranes
conditions
uncleaved
The
can
arrangement
Treatment
certain
1y f r o m
are
is o b s e r v e d .
the
structure
in C N B r
purple
of
a new
membrane.
This
the
located
absorption
participation
revealed
located
influences
nm,
acid by
only
creates
a t 360
at pH 8 . 8 ,
fragments
both
les)
nm
9. T h e r e f o r e
sulfanilic
amino
nm a n d
equilibrium
purple membrane
diazotized
exchange
510
pH
532
chromophore
absorption
the
Modification
that
at
chromophore of
about
moles)
the
to
reduction
A pH d e p e n d e n t
is at a b o u t not
5 6 8 nm
Dithionite
nm, w h e r e a s
unchanged. ition
from
radio-
molecular
carboxyterminus
but
located
the on
uncleaved opposite
447
1 2
3
4
Fig.5: SDS gel electrophoresis after modification of PM-vesicles with 3 %-DSA at pH 10 and subsequent treatment with papain (autoradiogram) 1) 3 5 s - m e t h i o n i n e PM.,,-
2) PM modified with S-DSA 3 5 3) PM-vesicles modified with S-DSA 4) 35S-methionine PM without papain treatment Samples 1-3 were treated with papain for 6 hours. 3S Fig.5
shows
the
result
methionine
PM s e r v e s
tide
(trace
chain
Beside
the main
lower m o l e c u l a r action of
are
3
tact
^S-DSA
containing This
the
proves
on o p p o s i t e
the
A same
to
located
the
bands
be on t h e
cytoplasmic
Unmodified
the
cleaved
(bR m i n u s
as a r e s u l t
chain
(trace
of f u r t h e r papain
2).
In c o n t r a s t ,
are
found
of
treated
tyrosine
64 a n d
the
the
the
side
in-
(trace
3).
carboxyterminus
carboxyterminus
s i d e of t h e m e m b r a n e
extracellular of
Since
sample
only
bacteriorhodopsin
papain
cytoplasmic side
if the
treated
and
of t h e m e m b r a n e .
1).
papain
and
chains
polypep-
carboxyterminus )
pattern
(trace
S-
uncleaved
S-DSA modified
are m o d i f i e d
on t h e
for
papain
product
location
sides
64
on t h e
w e i gohct
modified
shown is
4) a n d
vesicles
experiment.
as a r e f e r e n c e
reaction
seen.
PM s h o w s
of t h a t
(7),
and t y r o s i n e
was
tyrosine
26/lysine
PM.
Discussion The bR
results located
of c h e m i c a l at the
modification
surface
of a m i n o
of t h e m e m b r a n e
acid
support
residues fully
the
in
30
448 arrangement rations
gents
64,
results
reaction
reaction has
Another
light-dark could
Proteases
like
cleave
loops
reactions Tyrosine close
to
the
function
intermediate
the
nitrated to y i e l d
based
to
on
30,
rea-
the
these
exception
revealed
from the
of
by a
(6). T h i s of t h e
the
reliable
non-stoimembranes
access
to
some
heterogeneous
by e x t e n s i v e problem
in
reactivity.
sonication
membrane modification
conformational
cis-trans
reasonable
on t h e 30
states
In t h e
of
case
isomerisation
with
basis
only
It c o u l d
well
of
the
reacts
retinaloximes
for
of
reti-
the
with
soluble
26
cycle.
hydroxy 1 amine
to
be
borohydride
or
change
has
in t h e d a r k
apomembrane.
small
models.
is a s s u m e d
tyrosine
bond
sites
these
a structural
photochemical
with and
within
proposed
which
reacts
be t h a t
active
react with water
induces
for the C=N d o u b l e of
surface
of t h e
chromophore,
light which
buried
explanation
(partially)
2"6, h o w e v e r ,
membrane
to
to t h e m e m b r a n e
stages
hydrophilic
be c l o s e
non-stoichiometric
(i.e.
lysine phase.
differences.
No
lysine
in t h e
the dark
due
different
retinyliden
chromophore.
tective
close
tyrosine
hydroxy 1 amine the
such
be f o u n d
26 a n d
reagents,
reagent
of d i f f e r e n t
with
in F i g . 1 .
can
the
papain o r c h y m o t r y p s i n
very
shown
as
as a g e n e r a l
adaptation
provoke
(with the
in p a r t o v e r c o m e
be t h e e x i s t e n c e
to
However,
of m o d i f i c a t i o n
for
get
alte-
arise.
complication
reason
protein
to
little
the aqueous
be d u e to a s t a c k i n g
be c o n s i d e r e d
the membrane nal)
be
necessary with
is c o m p l e t e
excluding
This
can only to
chemistry. might
thus
may
Only
itself may
reactions
64)
in F i g . 1 .
accessible
questions
the e x t e n t
sites.
are
of t h e m e m b r a n e .
at t y r o s i n e
in s u s p e n s i o n reactive
chain
in c o n t a c t
chromophore
general
of
shown
is p a r t i a l l y
surface
several
chiometric
can
26
133
of t h e m o d i f i c a t i o n
nitration
bR
and
retinyliden
quantitation
and
polypeptide
p a t h of t h e
131
tyrosine
the
cytoplasmic None
the
of t h e
tyrosine Because
of
a
but In
already
of
pronot
at
fact, in
the
449 References 1.
Ovchinnikov, Yu.A., Abdulaev, Kiselev, A.V., Lobanov, N.A.: (1979).
2.
Khorana, H.G., Gerber, G.E., Herlihy, W.C., Gray, C.P., A n d e r e g g , R . J . , N i e h e i , K. , B i e m a n n , K.: P r o c . N a t l . A c a d . Sei. USA 76, 5046-5050 (1979).
3.
Henderson,
4.
E n g e l m a n , D.M., H e n d e r s o n , R., M c L a c h l a n , A.D., W a l l a c e , B . A . : P r o c . N a t l . A c a d . S e i . USA 7^» 2 0 2 3 - 2 0 2 7 ( 1 9 8 0 ) .
5.
Dellweg,
6.
Lemke, H.-D., 604 ( 1 9 8 1 ) .
7.
Gerber, G.E., Gray, Ch.P., Wildenauer, D., Khorana, Proc. N a t l . A c a d . Sei. USA 74, 5 4 2 6 - 5 4 3 0 (1977).
8.
Fischer,
R., Unwin,
H.G.,
N.T.:
Sumper, M.: Oesterhelt,
U., O e s t e r h e l t ,
N.G., Feigina, M.Yu., FEBS Lett. 100, 219-224
Nature
FEBS D.:
D.:
252, 28-32
Lett.
Eur.
J.
Biophys.
90,
(1975).
123-125
Biochem.
(1978).
115,
J. 2 8 , 2 1 1 - 2 3 0
595H.G.: (1979).
FORMATION AND UNUSUAL PROPERTIES OF BACTERIOOPSIN - A g + - 4DiMETHYLAMINOCHALCONE TRIPLE COMPLEX
Almaz Aldashev, Alexander Rodionov, Eugenii Efremov, Alexander Shkrob Shemyakin Institute of Bioorganic Chemistry, USSR Academy of Sciences, Moscow, USSR
Introduction Bacteriorhodopsin
(BRh) is the main component of purple mem-
branes from Halobaoterium
Halobium
(1). Removing of the pros-
thetic group (retinal aldimine) from BRh transforms the purple membrane into colourless apomembranes containing bacterioopsin (BO) (2). Recombination of BO with,both;retinal and some of its analogs results in formation of aldimine - containing chromoproteins (3). Retinal analogs not only of aldehyde competitively inhibit BO-aldehyde recombination
nature,
(4). The Ag + -
ions are also the competitive inhibitors of the recombination and destroy the noncovalent complexes formed by BO with retinal analogs (5).
Results Apomembrane-bound 4-dimethylaminochalcone (DMCh)
(CH^)2 N _ C 6 H 4~
CH=CH-CO-CgHj. has the bands in the excitation and emission spectra (Fig. 1) at 435 nm and 500 nm, respectively
(lifetime
in the excited state ca. 2.1 nsec). The binding of the probe results in a large enhance of the quantum yield of fluorescence: this effect enabled us to calculate apomanbrane -DMCh dissociation con-7 stant (K,=3-10 M, see Fig. 2). The bound probe reveals relai i 3 2 tlvely low ellipticity in CD-spectra (|9|=4,58*10 grad-sm /
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r d e G r u y t e r &. C o . , B e r l i n • N e w Y o r k
452
Fig. 1. Excitation and emission fluorescence spectra of DMChBO complex before and after Ag + -ions were added.
Fig. 2, 3. Determination of equilibrium constant of DMCh-apomembrane binding (C B0 =10 - 7 M) and CD-spectra of DMCh in apomembrane without Ag+ and in presence of Ag+ (C b 0 =10"5 M).
453 decimole, see Fig. 3). K^ calculated from CD data appeared to be lower than the value obtained fluorometrically. Taking into account
that spectral properties of DMCh in apo-
membrane are very similar to those of the probe, included in lipid vesicles,we can explain
the differences in K^ values
obtained by both methods so, that the main contribution in fluorescence enhancement gives the lipid-bound probe, and in CD
the protein-bound DMCh. DMCh does not inhibit the forma-
tion of BRh from BO and all-trans retinal but suppresses the recombination of BO with 13-cis-retinal (1(^=2,1-10
5
M) as well
as with tetraenal p-CH 3 0-C g H 4 -(CH=CH) 4 CH0 (K i =l,4-10 -5 M, Fig. 4). These data demonstrate the differences in the binding sites of isomeric retinals on the stage of the formation of noncovalent complexes.
Fig. 4, 5. Competitive inhibition by DMCh of binding to BO (C b0 =10 _ 6 M) of 13-cis-retinal and tetraenal (left) and all-trans retinal in presence of various concentrations of Ag + -ions (right).
454
When Ag+-ions are present even in negligible concentration, DMCh competitively inhibits the recombination of BO with alltrans retinal (Fig. 5). The Ag + -ions induce also the large bathochromic shift (40 nm) of the bands in absorption, CD and fluorescence spectra (see Fig. 1, 3). The halfwidth of the emission band
of the B0-DMCh-Ag+ complex
(AA=78+2 nm) is similar to that of DMCh in organic solvents. It means that all molecules of the probe are in the homogeneous environment. In addition to the spectral shift, Ag + -ions induce also the marked rise of DMCh ellipticity (up to |e|=16,5-10 2
grad.sm /decimole, Fig. 3), which could be due to increase of asymmetry of the probe environment. Equilibrium constant for reaction B0-DMCh-Ag+ t B0-Ag + + DMCh (Kd=3,5-10~7 M) is independent of whether it was obtained from CD or from fluorescence data (Fig. 6).vThus, Ag + -ions in small concentrations
Fig. 6, 7. Determination of equilibrium constant of binding of DMCh to B0-Ag + complex (left) . Removal of DMCh from BO by large concentrations of Ag + -ions (right), C B0 =10~7 M, MES 0,02 M, pH 6,4.
455 apparently induce not only the migration of DMCh from lipid to protein, but also modify the intraprotein binding site in such a way, that it can overlap the binding site of all-trans retinal. No other investigated metal ions cause such an effect. When the Ag + concentration is further increased, DMCh,like other retinal analogs is forced out of BO-DMCh-Ag+ complex (Kd=8-10~3 M, Fig. 7).
References 1.
Oesterhelt, D., Stoeckenius, W.: Proc. Natl. Acad. Sci. U.S.A. 70, 2853 (1973).
2.
Oesterhelt, D., Schuhmann, L.: FEBS Lett. £4, 262-265 (1974) .
3.
Schreckenbach, Th., Walckhoff, B., Oesterhelt, D.: Eur. J. Biochem. 76 , 499-511 (1977) .
4.
Ovchinnikov, Yu.A., Shkrob, A.M., Rodionov, A.V., Mitzner, B.I.: FEBS Lett. 97, 15-19 (1978).
5.
Shkrob, A.M., Rodionov, A.V.: Bioorg. Chem. 5, 376-393 (1979).
PEPTIDE FROM BEEF HEART MITOCHONDRIA INDUCING ION-SELECTIVE CHANNELS ON PLANAR BILAYER MEMBRANE
L.A. Pronevich, G.P. Mironov, G.D. Mironova Institute of Biological Physics of the USSR Academy of Sciences, Pushchino
Introduction Essential steps in studying the molecular mechanism of calcium transport regulation in mitochondria are isolation, identification and reconstruction of ion-transporting systems (1-6). This article is dealing with a new efficient method of isolation of beef heart mitochondrial peptide (P) which induces the 2+
selective Ca ranes (BLM).
-transport through artificial bilayer lipid memb-
Results 1)
Isolation of peptide. The mitochondrial fraction of beef heart tissue was extracted with 96% ethanol (200 ml per 1 g of mitochondrial protein; pH 7.0; 1 h under stirring; 4°C) and centrifuged at 5.000 x g for 15 min; 4°C. The pellet was resuspended in 50% ethanol and then extracted and centrifuged under the same conditions. The supernatants of two centrifugations were combined and evaporated to dryness in vacuum at 30°C, then dissolved in bidistilled water (1 ml per' 2 g of wet tissue) and treated with 3-fold volume of chloroform: methanol (2:1, v/v) in order to remove lipids. The lipid-free extract was evaporated to dryness in vacuum at 30°C and dissolved in bidistilled water, 1.5 ml of this solution which corresponded to 100 mg of the dry pre-
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter & Co., Berlin • New York
458 paration were applied to a Sephadex G-15 column (2.8x78 cm). The profile obtained after elution with bidistilled water (60 ml/h) is presented in Fig.l. As has been shown earlier (2), fraction
as identified by its ability to induce BLM
conductance>corresponded to the membrane-active peptide.
Fig.l. Elution profile of beef heart mitochondria,defatted water extract from Sephadex G-15 column (2.8x75 cm). Elution was carried out by bidistilled water at the rate of 60 ml/h. 2) Purification of P. Since we have shown earlier the presence of sulfhydryl groups in the peptide, further purification was conducted by means of affinity chromatography with reversible coupling of thiol-containing peptides. 150 mg of fraction 3 were applied onto an activated Thiol-Sepharose 4B column (4 ml). The non-coupling components of fraction 3 were eluted with 25 ml of 0.02 M ammonium formate
buffer (pH 8.0; 5 ml/h).
The coupled P was eluted for 4 h with 20 mM mercaptoethanol in the same buffer. The eluate was evaporated until complete removal of mercaptoethanol and ammonium formate , then the dry preparation of P was brought onto Sephadex G-15 column (2.8x60 cm) and eluted with bidistilled water (60ml/h). The 140-170 ml fraction contained P. The homogeneity of P was analyzed by paper chromatography as described elsewhere (2).
459 3)
Properties of P. The molecular weight of P as determined by gel filtration on Sephadex columns was about 2 r 000. After affinity chromatography purification the specific activity of P increases about 1000 fold. The acid hydrolysis revealed 7-8 amino acids (Fig.2). P is water- and ethanol- (70%) soluble. In water solution the Ca2+-transporting activity of P decreases at room temperature in 26 h and at 100°C in 3 min. The yield of P depended on the season as in the case of glycoprotein (3) and was 2-5 vg from 100 g wet tissue.
Fig.2. Ascending paper chromatography (Filtrak FN-1) in the butanol: acetic acid:water (4:1:5) system at room temperature: I - peptide before hydrolysis in 6 N HC1; II - peptide after hydrolysis in 6 N HC1: 1 - Leu; 2 - Phe; 3 - Ala; 4 - Pro; 5 - Glu,Gly; 6 - His,Lys; 7 - Cys 2+
4)
2+
P-induced Ca -selective conductance of BLM. Ca -transporting activity of P was tested using BLM (beef brain lipids in n-decane, 20 mg/ml) which were formed on a hole (1 mm diameter) in a teflon wall separating two chambers each containing 2.5 ml of magnetically stirred buffer solution (20 ml Tris-HCl, pH 7.5; 5-20 mM CaCl 2 ). Adding P ( final concentration!.0-5-0,ug/ml) to one or two bathing solutions of BLM one could observe in 1-5 min keeping membrane voltage constant, step-wise increases of current which were interpreted as due to formation of channels. The smallest
460 amplitudes of these steps corresponded to an increase in BLM conductance of about 20 pS (Fig.3).
C^O'ug/ml). Buffer solution contains 20 mM Tris-HCl and 20 mM CaCl2 . Besides, large jumps of conductance up to 0.5-1.0 nS were registered which persisted for tens of minutes and resembled the increase of integral BLM conductance.The higher the concentration of P, the more probable was the opening of the channels and the longer the channels remained open. Increasing the concentration of C a C ^ makes the conductance of the channels rise proportionally with the increase of the concentration of this salt. The generation of the transmembrane gradients of C a C ^ gives rise to the potential difference on the membrane (21-25 mV per 10-fold gradient at pH 6.0-8.0) that corresponds to Ca2+-selectivity of the channel. The selectivity for Ca^ + is also observed in case of large channels, which probably indicates their sieve structure, determined, in particular, by incorporation of whole P-aggregates. 2+
5)
Inhibition of Ca
-transporting properties of P by specific
agents: a) sulfhydryl groups intrinsic in P proved to be
461 essential for its ability to induce the Ca^ + transport through BLM. Addition of fluorescein mercury acetate (FMA) binding sulfhydryl groups into the BLM bathing solution results in suppressing
the ion-transporting properties of
P; b) the specific inhibitor of Ca 2 + transport in mitochondria ruthenium red (Rr) induces complete inhibition of the Ca2+-conductance of BLM in the presence of P. When one or several Ca2+ -selective channels are open, the addition of Rr (5-10~6M) results in a 100% inhibition of the effect. The
inhibition
may proceed
either jump-wise
(abrupt
closing of all or a few channels) or gradually. The inhibition rate depends on concentration of Rr. The results obtained enable the assumption that P isolated from beef heart mitochondria is involved in transport of Ca 2 + through the mitochondrial membrane. The proposal is also made that P in mitochondria functions in a complex with the glycoprotein.
References 1. 2.
3. 4.
Carafoli, E., Sottocasa G.: Dyn. Energ. Transducing membranes, Amsterdam, 455-465 (1974). Mironova, G.D., Pronevich, L.A., Fedotcheva, N.I., Sirota, T.V., Trofimenko, N.V., Mironov, G.P.: Mitochondrial processes in time organization, Pushchino, 126-140 (1978). Mironova, G.D., Sirota, T.V., Pronevich, L.A., Trofimenko, N.V., Mironov, G.P., Kondrashova, M.N.: Biofizika, 2_5, 276-280 (1980). Azarashvili, T.S., Lukjanenko, A.I., Evtodienko, Yu.V.: Biochimia, 47, 1139-1142 (1978).
5.
Lunevsky, v., Zherelova, 0., Alexandrov, A., Vinokurov, M., Berestovsky, G.: Biofizika, 25, 685-691 (1980).
6.
Sottocasa, G., Sandri, G., Panfili, E., de Bernard B., Gazzotti, P., Vasington, F., Carafoli, E.: Biochem. Biophys. Res. Commun. 47, 808-813 (1972).
FUNCTIONAL ROLE OF THE PROTEIN COMPONENT OF THE Ca 2 + TRANSPORTING GLYCOPROTEIN FROM BEEF HEART HOMOGENATE AND MITOCHONDRIA
T.V.Sirota, L.A.Pronevich, G.D.Mironova Institute of Biological Physics of the Academy of Sciences of the USSR, Pushchino, Moscow Region, USSR
Introduction 2+
Recent investigations have shown that the Ca -transporting system of mitochondria contains substances of glycoprotein origin (1,2). A confirmation of this statement is provided by our data that mitochondria contain a glycoprotein (GP) with a molecular mass 40 kD, which, when reconstructed on a bilayer lipid membrane (BLM), activates a selective transport of calcium ions (3). There is some evidence in literature showing 2+
that Ca
-transporting activity may be due to phospholipids
(4). The aim of the present work was to elucidate whether the phospholipids enter into composition of GP and what part of the GP molecule is responsible for its ionoforic properties. Results The attempt to identify the lipid component in the fraction of GP after electrophoresis in polyacrylamide gel (PAGE) by means of sudan black has not given positive results. At the same time our experiments have shown that the amount of inorganic phosphorus (P^) in GP is 13.6 yg/mg of the protein whereas the preparations of GP isolated by the other authors (1,4) contain up to 300 yg of P^ per 1 mg of protein. The disparity in the results may be probably accounted for by the fact that in our experiments the partially purified preparation was treated
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter &. Co., Berlin • N e w York
464
with chloroform-methanol (2:1). After additional special treatment of GP we managed to isolate some amount of lipids using the method of thin-layer chromatography (TLC). At the first stage of extraction conducted by the method of Folch (8) negligible amount of neutral lipids was found: fatty acids, mono-, di-, triglycerides, cholesterol as well as the phospholipids phosphatidylserine and lysophosphatides. Following the second stage of GP treatment conducted by the method of Blondin (9) much less amount of the same neutral lipids and phospholipids was isolated. GP obtained after the two-stage treatment with organic solvents does not contain any lipids. Simultaneously with determination of the lipid composition, at 2+ each stage of lipid extraction the Ca -transporting activity of GP and the effect of ruthenium red (Rr) was studied by reconstruction on BLM. The results are presented in Table 1. As 2 + seen from the Table, after removal of lipids from GP its Ca -transporting activity does not change, the inhibiting effect of Rr, the specific inhibitor of calcium transport in mitochondria, being retained. The data obtained by PAGE indicated that after all stages of treatment GP contains, both, the protein and carbohydrate components. As shown by PAGE GP does not change prior and after treatment with organic solvents. This indicates that removal of lipids does not result in denaturation of the protein and that the contribution of the lipid component to the molecular mass of GP is insignificant. The data that treating with 2+the mixture butanol:acetic a,cid:water does not affect the Ca transporting activity have been obtained earlier (3) when using the method of ascending paper chromatography in the same solvent system. The obtained results indicate that lipids are not essential for functioning of GP. It is likely that lipids, namely the phospholipids prevent a fast incorporation of GP into a model membrane, since GP from beef heart mitochondria containing minor amount of lipids starts to affect BLM conductance in 2-5 rain (3), whereas GP from rat liver mitochondria containing a great amount of lipids in 40-50 min (4).
465
Table I. Ca extraction.
2+
-transporting activity of GP after lipid
Preparation
GP,pg/ml
BLM conductance -1
(Ohm Control (without GP) GP initial
20
GP after Folch procedure
20
GP after Folch and Blonding procedures
20
Rr inhibition,
-2
-cm
)
per cent
(8.2+1.0)-10 (7.3+2.0)-10~7
100
(6.2+2.5)-10~7
100
(7.1+3.1)-lo"7
100
Media - tris-HCl pH 7,5 - 10 mM, CaCl2 - 10 mM, Rr - 5-10~6M 2+
Table 2. Proteinase treatment effect on Ca activity of GP . Preparation
GP yg/ml
-transporting BLM conductance (Ohm- 1 'cm - 2)
Control (without GP) GP initial GP after proteinase
20
(6,8+1.4)•10-9 (5.5+2.0)•10~7
treatment
20
(8.8+3.2)•10~9
without proteinase
20
(5.4+4.2)•10~7
Proteinase after incuba,tion
-
(6.5+1.5)-10-9
GP after incubation
Medici as in Ta,ble 1.
466
Further evidence for the essential role of the protein component in the function of GP are the experiments with proteinase (Table 2) . As seen f;rom the Table, proteinase-treated GP loos2+ es completely its Ca -transporting activity. Thus, it follows from the results presented in the paper that the main functional role in GP is played by its protein component, When reconstructed on BLM by means of lipid-free GP the 2+
Ca -transporting system is inhibited by Rr. This enables the assumption that it is GP (its protein moiety) that is the main component in the system of electrogenic influx of calcium into mitochondria. The phospholipid isolated from rat liver GP whose Ca 2+ -transporting activity is not inhibited by Rr is pro2+
bably involved in the system of Ca
efflux from the mitochond-
ria which exists in the mitochondrial membrane.
References
1. Carafoli,E., Sottocasa,G: Dyn.Energ.Transducing membranes, Amsterdam, 455-465 (1974). 2. Moore,C.: Biochem.Biophys.Res.Commun., 42^ 298-305 (1971). 3. Mironova,G.D., Sirota,T.V., Pronevich,L.A,, Trofimenko,N.V., Mironov,G.P., Kondrashova,M.N.: Biofizika, 25, 276-280 (1980). 4. Evtodienko,Yu.V., Medvedev,B,I. , Yaguzingsky,L.S., Azarashvili,T,S., Lukjanenko,A.I., Kuzin,A,M.: DAN SSSR, 249, 1235-1238 (1979), 5. Reynafarje,B., Lehninger,A.; J,Biol.Chem., 244, 584-593 (1969). 6. Jeng,A., Ryan,E., Shamoo,A.: Proc.Nat.Acad.Sci.USA, 75, 2125-2129 (1978). 7. Tyson,C.A., Lande,A.V., Green,D.E.: J.Biol.Chem., 25, 1326-1329 (1976). 8. Folch,J., Lees,M,, Stanley,J.: J.Biol.Chem., 226, 497-509 (1957). 9. Blondin,G.: Biochem. Biophys, Res. Commun., ¡56, 97-105 (1974),
OPTICAL SPECTROSCOPY STUDY OF SUBSTRATE BINDING BY LEUCINE SPECIFIC AND LEUCINE - ISOLEUCINE - VALINE BINDING PROTEINS FROM
E. eoli
Igor Nabiev, Sergey Trakhanov, Alexandr Surin, Tatyana Vorotyntseva, Evgenii Efremov, Vladimir Pletnev Shemyakin Institute of Bioorganic Chemistry, USSR Academy of Sciences, Moscow, USSR
Introduction Leucine - isoleucine - valine-binding
(LIV) and leucine speci-
fic (LS) proteins are the components of high affinity transport systems for branched chain amino acids in E. aoli K12. These proteins are located in the periplasmatic space being released on cold osmotic shock procedure (1). The polypeptide chain of the LIV protein consists of 344 amino acid residues including 3 Trp, 13 Tyr, 9 Phe and one S-S bridge (2). The homogeneous LIV protein contains tightly bound substrates as L-leucine, L-isoleucine and in less amount L-valine which might be released by reversible denaturation treatment in urea solution with subsequent urea removal. In contrast to LIV, the LS protein can be obtained in crystalline form
free of L-Leu
without the treatment mentioned above. The primary structure of the LS protein which is not completely determined yet (the most probable number of amino acid residues is 346, including 4 Trp, 13 Tyr
and 9 Phe residues) revealed a high degree of
homology with the primary structure of the LIV protein (3).
Results Recently it has been shown that binding L-Leu, L-Ile and L-Val
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter & Co., Berlin • N e w York
468 causes changes in optical spectra of the LXV protein (4). The positions of the maxima and fluorescence band shapes of LIV and LS proteins point to differences in polarity of Trp environment with at least one Trp buried in the protein interiorThe changes of the fluorescence spectra of LIV and LS proteins upon substrate addition (Fig. 1) reflect different environments of the Trp residues in the complexed with respect to the free forms of the proteins. In case of LIV the shape of the differential spectra depends on the type of substrate (4). The ions I and Cs + quench significantly the fluorescence of the Trp residue (-s) in the Ls protein but do not influence the fluorescence of the protein. In the L-Leu complex of LS the fluorescence quenching is less pronounced. It was suggest-
Fig. 1. Fluorescence spectra (F) LIV (1) and LS (2) and relative changes in fluorescence (AF) LIV (3) and LS (4) upon L-Leu complex formation. ^ e x c = 2 9 5 nm, protein concentration 5 yM, L-Leu concentration 10 yM.
469 ed that a Trp residue (-s) on the surface of the LS globule becomes less accessible to the solvent environment as a result of complex formation. Differential UV spectra obtained upon substrate binding by LIV and LS proteins reveal changes in the aromatic residue environment due to complex formation. The common feature of differential spectra of LIV and LS proteins is the presence of bands corresponding to Tyr and Phe chromophores which might be interpreted as a transfer of the side chains of these residues into a more hydrophobic environment. Contrary to LIV in LS protein the bands at 290 and 300ratiassociated with Trp residue (-s) are clearly revealed. These bands are not observed in the LIV protein spectra. Probably the
Fig. 2. Differential UV spectra of LS (1) and LIV (2) after L-Leu addition. Protein and substrate concentrations are 5 yM and 10 pM.
470 Table 1. The amount of Trp and Tyr residues accessible for solvent in LIV and LS proteins and in the L-Leu - protein complexes.
Protein/Perturbant LIV LIV+L-Leu LS Ls+L-Leu
Ethylene glycol 20% v/v
Sucrose 20% w/v
Tyr
Trp
Tyr
Trp
7 5-6 9
2 2
7 5-6
2 2
5-6
3 1-2
charge alteration in the vicinity of the chromophore causes the appearence of a minimum at 300 nm. The solvent perturbation differential UV spectroscopy has been applied for quantitative estimation of the effect of substrate binding on the solvent accessibility of the aromatic amino acid residues (Table 1). In comparison with LIV the number of accessible Trp residues of LS protein is diminished of at least one residue. In the CD and Raman spectra practically no changes are observed upon substrate binding. Complex formation does not obviously affect the secondary structure of the polypeptide chain in the LIV and LS proteins. Comparison of differential UV, fluorescence, CD and Raman spectra with the data of primary structure of these proteins enables us to suggest that Trp-18 (for the LS protein) and Tyr—18 (for the LS protein) participate in the formation of a substrate binding center. A model of the binding was also proposed (4). The confirmation about participation of Tyr, Trp, Phe residues in complex formation has been obtained from the comparison of surface - enhanced Raman spectra of the free and complexed LS protein adsorbed on a silver electrode. The changes of the
471
Q.
Fig. 3. Surface - enhanced Raman spectrum of LS protein (B) and LS+L-Leu (A) adsorbed on a silver electrode. Protein concentration 0.5 mg/ml, X = 632.8 rati.
surface - enhanced Raman spectrum on substrate binding suggest that the LS protein maintains its ability for substrate binding even after adsorption on the electrode surface (Fig. 3).
References 1. 2.
Oxender, D.L.: In Biomembranes chap. 2 (Manson, L.A., ed.), New York, Plenum Press 25-79, 1974 Ovchinnikov, Yu.A., Aldanova, N.A., Grinkevich, V.A., Arzamazova, N.M., Moroz, I.N.: FEBS Letters 7^, 313 (1977).
3.
Soldatova, L.N., Shakhparonov, M.I., Chertova, E.N., Aldanova, N.: In Abstracts of 5th Ail-Union Symposium on Chemistry and Physics of Peptides and Proteins. Baku, 124,
4.
Vorotyntseva, T.I., Surin, A.M., Trakhanov, S.D., Nabiev, I.R., Antonov, V.K.: Bioorg. Khim. 7, 45 (1981).
1 980
INVESTIGATIONS OP IMMUNOGLOBULIN STRUCTURE IN SOLUTION
Vladimir Zav'yalov,Vyacheslav Abramov,01ga Loaeva,Vladimir Tishchenko,Elena Dudich,Igor Dudich All-Union Research Institute of Applied Microbiology, 142200 Serpuckov,Moscow Region,USSR Frantisek Franek Institute of Molecular Genetics Prague 6,Czechoslovakia George Medgyesi Institute of Haematology H-1502 Budapest,Hungary
Introduction The available data on the three-dimensional immunoglobulin structure have been obtained as a result of X-ray structural analysis of some human myeloma immunoglobulins G belonging to the first subclass (IgG1 Dob,Col,Meg) and of immunoglobulin A produced by murine plasmacytoma (M 603) (1).These data give a reason to conclude only - the most general regularities of the spatial arrangement of polypeptide chains of immunoglobulins G.In particular,these data manifest the conformational mobility in the so-called "switch" and "hinge" regions. It is likely that during crystallization only one of the possible dynamic conformational states is fixed.The equilibrium in solution may be shifted towards the other conformer,and it may appear to be the decisive factor to understand the functional immunoglobulin differences and the mechanism of activation of their effector functions.Besides,it is known that even immunoglobulins G of different subclasses differ significantly in their functional properties (2).The conformatio-
Chemistry of Peptides and Proteins, Vol. 1 © 1982 by W a l t e r de Gruyter &. Co., Berlin • New York
474
nal basis of these differences is still unclear,though the main differences in the primary structure of immunoglobulin G subclasses are known to be concentrated in the "hinge region" (3).One may suppose that the structure of this region can affect the functional properties of immunoglobulin G subclasses ,both, by influencing the degree of relatively independent motions of Fab and Pc subunits in solution and by influencing the structure of Pc subunit
and,correspondingly,the
conformation of effector sites.In order to verify this supposition, we have investigated in the present paper the normal rabbit immunoglobulin G,the homogeneous rabbit antibodies to pneumococcus polysaccharides,precipitating (early) and nonprecipitating (late) pig antibodies to dinitrophenyl derivatives and homogeneous human myeloma immunoglobulins G of 4 subclasses.The investigations were carried out with the help of the complex of physical methods allowing to estimate the conformational properties of proteins in solution (differential temperature- and solvent-perturbâtion spectrophotometry, adiabatic scanning microcalorimetry,polarization of fluorescence, spin label method of EPR,method of proton relaxation of NMR,circular dichroism) and also the electronic microscopy.
Results 1) Immunoglobulins G of different species origin and of different subclasses differ significantly not only in the character of interactions between Pab and Pc subunits H pppG • ppVJ • POpA jh» f+0+^pppGp"Up*UpGpA(iUpApGpAp*U RINA - polymerase ^l »
cvm
I,« in5
Fig. 1. Crosslinking of the RNA polymerase with photoreactive RNA in transcribing complex. (1)-after irradiation. (2)-without irradiation. (3)-the complex was destroyed before the irradiation.'
active label covalently bound to RNA polymerase upon illumination at X >290 nm may be due only to the oligonucleotides synthesized in the system, rather than to initial substrates, because the y-azidoanilide of GTP is not radioactive, whereas 32 the pp pU is not photoreactive. After synthesis and irradiation the reaction mixtures were subjected to SDS electrophoresis. The slabs were stained with Coomassie and autoradiographed. After photoaffinity labeling (two triphosphates are present) the B,B' and a-subunits become radioactive (Fig. 1 left-hand side), but in the case of three substrates (right-hand side) radioactivity predominates in g,B'-subunits, which presumably reflects the shift of the 5'-end of the nascent oligonucleotide within the transcribing complex when its length grows continuously up to decanucleotide. A similar methodology was employed to establish the subunits contacting with the 3'-0H end of the growing RNA. Affinity modification was made by the oligonucleotides being synthesized
487 in situ. They contained photoreactive 5-halogenopyrimidine residues in the vicinity of 3'-OH end. In the presence of GpU (the primer), 5-IU or 5-BrU and |a-32p| GTP (substrates) and the above-mentioned X imm DNA fragment (template) only cr-subunit incorporated the radioactive label upon UV-irradiation (3) . During primary structure determination of B-subunit (see V.M. Lipkin et al., this volume) the limited tryptic hydrolysis was made. Separation and sequencing of low molecular weight peptides
together with their yields
enabled to find regions of
polypeptide chain easily accessible for the protease. Two regions in the middle part of the polypeptide chain (amino acid residues 528-548 and 678-758) and C-terminal part of the molecule (residues 1105-1342)are evidently on the surface of the B-subunit and possibly represent flexible connections between stable domains. A topographic study of the RNA polymerase a-subunits was made by modifications of RNA polymerase with iodoacetate, iodoacetamide, mercury ions and K^lFeiCNjgl. The results are summarized in the model (Fig. 2). jyftiCNy
Fig. 2. Scheme of actions of different chemical agents on sulfhydryl groups of the RNA polymerase a-subunits.
488 2*
IHg
V 6-W
>
2+
IHg 2.DTT HCHjCOOH 2.Hg UCHjCONHj 2.Hg
* ¥
t -
• »
I.KgtPefCNIg]
* *
Fig. 3. SDS electrophoresis of the modified RNA polymerase. The order of modifications indicated. Buffer: 0.05 M Naphosphate pH 7.0, 0.1% SDS.
The assignment of the alkylations to definite residues of the a-subunit polypeptide chain was made by the analysis of the a-subunit sequence (4) and electrophoretic mobilities of labeled peptides of tryptic digest on thin-layer peptide maps. 2+ Formations of intrasubunit (Hg ) and intersubunit (disulfate bridge) crosslinks were shown with the aid of SDS electrophoresis (Fig. 3).
References 1.
Ovchinnikov, Yu.A., Efimov, V.A. , Chakhmakhcheva, O.G., Skiba, N.P., Lipkin, V.M., Modyanov, N.N.: Bioorg. Khim. 5, 1410-1421 (1979) .
2.
Sverdlov, E.D., Tsarev, S.A., Kuznetsova, N.F.: FEBS Letters 112, 296-298 (1980).
3.
Sverdlov, E.D., Tsarev, S.A., Begar, V.A.: FEBS Letters 114, 111-114 (1980).
4.
Ovchinnikov, Yu.A., Lipkin, V.M., Modyanov, N.N., Chertov, 0.Yu. , Smirnov, Yu.V.: FEBS Letters 76_, 108-111 (1977).
STRUCTURE
Jürgen
OF
THE
PROTEOLIPID
Hoppe
and
Walter
SUBUNIT
OF
THE
ATP
SYNTHASE
Sebald
G e s e l l s c h a f t für B i o t e c h n o l o g i s e h e D-3300 Braunschweig, Germany
Forschung
mbH.
Introduction
Membrane show are
bound
common
of
activity
+
H -conduction energy from
the
fied of
about
protein and
ATPase
is
was
referred
The
inhibited some
rum
[11,13] .
which
to
found
as
lead
to
and
from
of
the
exists
be
subunit
antibiotics activity
numerous
been
as
inhibitor
of
to
be
synthases e.g.
resistancy
or
to
C h e m i s t r y of P e p t i d e s a n d P r o t e i n s , V o l . 1 © 1982 by W a l t e r d e G r u y t e r & C o . , B e r l i n • N e w Y o r k
acid
butanol
cow.
a
[10] the
ATP
But
from
proteolipid synthase target
from
of
se-
oligomycin mitochondria
R h o d o s p i r i 1 1 urn
subunits
p.4-20 ]. A m i n o
and
the
oligomycin.
as
identi-
protein
hydrophobic
to
appeared
ATP
a
was
inhibited
The
bound the
proteolipid
sequenced
Beechey
of
bacteria,
were
is
or w i t h
(DCCD)
a subunit
e.g.
[5-8] .
a h e x a m e r [9 1. T h i s
a6
mitochondria. covalently
for
isolated
subunits
chloroform/methanol
heart to
catalyzing
E. coli
part
the
necessary
subunits F^
They
bears
F^,
been
different
different
[1-4].
are
has
organisms
which
part
parts
part
a proteolipid.
identified
the
years
have
two
likely
with
photosynthetic
recent
three
most
proteolipid
and
PS-3
of
constituent
in b e e f
hydrophobic
ganisms
coli
Both F^
dicyclohexylcarbodiimide
was
later
membrane.
bacterium
F^,
integrated
functional
composition
which
that
membrane
the A
major
activity
j1—4].
In
the
extractable
carbodiimide
only
part
In E .
8000d is
thus
veral
properties
subunit
discovered
which
functional
and
The
various
associated
across
in P S - 3 .
from
and
thermophilic
[6-8],
isolated
a membrane
transduction.
A minimum found
synthases
structural
composed
ATPase
ATP
rub-
various
or-
substitutions
a nonfunctional
enzyme
490 have been
determined Jl4,17,18,20,21].This
fore concentrate this protein, carboxyl
on the description
especially
residue which
based
to be intimately
for the conformation
on C D - m e a s u r e m e n t s
will be
of the primary
on the identification
seems
ton c o n d u c t a n c e . A model
article will
and secondary
there-
structure
of an
involved of the
structure
of
invariant in
pro-
protein
prediction
discussed.
Results General
properties.
by extraction graphy
The p r o t e o l i p i d s
with c h l o r o f o r m / m e t h a n o l
on c a r b o x y m e t h y l - c e l l u l o s e
acid
degradation
{14-21] .
residues which
weights
determined
containing lubility
only
at the N - t e r m i n u s Long found of the
both
the
25 amino
as well
hydrophobic their
so-
clustered
of the protein
s t r e t c h e s of about
amino
molecular
explain are
of the N e u r o s p o r a
of the s e q u e n c e s
the numerous conserved be i n d i s p e n s a b l e
ance of certain
structure
(residues
crassa acid
sequence).
residues
as in the C - t e r m i n a l
of these h o m o l o g o u s amino
acid
are part
the middle
of the N - t e r m i n a l
gln^g, p r o ^
residues
localized
found
to be invariant.
basic
amino
dic amino
acid
acid
for the function
hydrophobic
subunit
hydrophobic
in the h y d r o p h i l i c (arg^)
stretch
(position
maintainhomologies
(residues arg^»
segment were The only one
In 27
asn/
also
conserved invariant
in the middle of the 65). With
re-
resi-
were found.
the single
occurs.
is observed
stretch
These
or the
are c o n s e r v e d . G l y ^ »
In this segment
residue
residue
proteins
residues.
of the protein. E x t e n s i v e
the s e q u e n c e s of the proteolipid
- 3 3 ) four glycine
minal
residues
in the middle
in the N - t e r m i n a l
dues might among
and
residues which Polar
phase
72 - 82
sequence.
A comparison vealed
is in a g r e e m e n t with
solvents.
chromato-
solid
contain
on S D S g e l s . They are extremely
the numbering
hydrophobic
subsequent
by automated
The proteins
16 - 25% polar
in organic
40 - 50 using
number
and
purified
in c h l o r o f o r m / m e t h a n o l [14-21].
All the s e q u e n c e s were determined Edman
can be generally
aci-
C-ter-
exception
491
Ni'urospora cniyüu
r"i i — lyi -Sei-'jc'i-Glu-l h -Aki-Llii-rtla-Mrt-V^i-Lju-\Jul-bL'i^Lys-lAi,N-Leuilily .Het-JClyjbtir-Ala-Ala-Ile-jGly
Aup-l li'-Asp-lhr-Ala-AlaiLys
GlylAla-Ala-Thr-Val-JUy.
Cly
t -McL-Uln-L tiu-Vul-Lcu-Ala-Alo-Lys. lyr-Ile Cly Ala-tly-I le-Ser-Thr-lle*ly.
I ' Ala-tly'Leu-Ala-Ala-Ue-'ClyJMett-Mi-t-Aiip-Ala-Glu-Alu-Ala-L ys-Mot-l li --J I I L..I ! I
HMuduspu'i i lum l ubru
1 I I t -Met -Asn-l'iu-l l'u-I le-Ala-Ala-Ala-Scr-Vul-l lelAla.Alo-Cly-Leu-Ala-ValJGly-Leu-Ala-SerI i I I I I
Spinach
r-nct-Asp-l'io-Li-u-Ilc-SiT-Alo-Ala-Scr-Val-Lcu-All Alo-«la-Lcu-A]a-Ile-iCly-LiHjÍAla-AlaI >
Mast njocladus l m m n u s u s
i f-Net-i;iu-Asn-Leu-Asn-Mi't-Asp-Leu-Lcu-Tyr-Met.»All
Acidu caldarius
I I « , i r--> Val-Met-HetJCly-LeujAJa-IA]«I I
I I
I
I I
Ala-
f-MeL-Gln-Lcu-Asp-Met-Val-Lys-Ala-1le-Tyr-Asp-Ile-Ala. 1
Ile-Ala-Val-Cly-LeuÍGiy AI«.; J
f"-Het-Ser-Leu-Gly-Val-Leu-»Ala
Ncuruspora crassa
SO r—i Tyr-Gly Ala- Gly lie.Gly Ile. :iy L eu-Va1-Phe-A1a-AlaJL euM. eu-Asn-ily- Val-Ala- Arg-Aan-Pro iAla-Leu^Arg^ I I Ala-Cly. •Ser- Cly -Ala. Gly lie. Cly Thr-Val-Phe-Cly-Ser-lLeuille-lle- Gly. Tyr-Ala- Arg-Aan-Pro !Ser-Leu4.ya* I
Saccharnmyces cerevisiae
Leu-Gly
Gly lie. Gly
Rhudospirillum rubrun
lie Gly
Gly
lie Gly Pro. Cly.
Ile-Val-Phe-Ala-Ala.
Ile-Asn- Gly. Val-Ser Arg-Aim-Pro ! .Ser-lle^Lya.
Gly. .Val. Gly Asn-lle-Trp-Ala-Asn-Leu-1le-5cr.
Val-Cly. -Arg-Aao-Pro. Ala-Ala-Lys
Gly. -Gin Gly Thr-Ala-Ala-Gly-Gln.Ala-Val-IClu.lGly lleJAla. Arg-Gln-Pro Clu-Ala-GluI I I I
Mastigocladus laminosus
I le-Gly Pro Gly lie Gly •Gin- Cly Asn-Ala-Ala-Gly-Gln-Ala-Val-Glu-jCly.
Gly
lie.Gly
Cly
I - Cly..Ala-lAla. Arg-Gln-Pro. Asp-lLeu-lleI I I
Acido co Idarius
Gly •Ser Gly Val Cly. Asp. Gly Met-Val-Met-Ser. Lyallyr-ValJClu-i- Gly Val-Ala- Arg-Gln-Pro. Clu-Ala-ArgI I I I I Leu Gly Ala- Gly 1 le. Cly
Cly. Leu-Ile-Val-Ser-lArgiThr-Ile-Clu. i- Gly. J
Arg-Gln-Pro- Glu-Leu-ArgI
492 60 I" • i r-i r * •> Gly-Gln-Leu-Ptic-Scr-Tyr-Ala-I lc-LeujGly-Phc •I'he-Val- Glu-Ala .LeutMet'Vel I i i I i i I Uovine C ln-i; ]n-( ru-l'lii'-Sur-1 y r-A]a-1 le-L eu-fi 1 y-Phc :iu-Alafj'let-GlyiLcu-PhejCys Leu-iMet-'l/allAlaI I I I < Saccharomyces ccrevisiau Asp-Thr-Vul-l'hr-Pro-Mut-Ala-llc-Lcuiciy-Phe Ihr-GlyJleu-PheACys1 1 I I Rhodospirilium rubrum 5er-lhr-Vul-i;iu-l cu-Tyr-Uly-Trp-l li^fiì 1>-IMie Ile-AlaJLeu-Phe-Ala-Leu-Val-W 1 L-J c -
Ncurospora crassa
Spinach
lily-l.yu-l li'-Anj-(;iy-Ihr-lru-Lc'u-Lru-SL»r-Leu
Mast Kjocluduii 1 aminosuu
Acido caldarius
Lcu-Thr-Ile-Tyr-Gly-Leu-Val-Val-Ala-
Gly-Lys-I le—Ari)—ti]y—Ihr—Lcu—Lcu—Leu— Ihr—I cui
Leu-Thr-Ile-Tyr-Gly-Leu-Val-Ile-Ala-
Pro-Leu-lcu-Arg-Thr-Cln-Phc-Phe-1lc-Val-Met •CI»
r-T |--1 Asp-Ala I le-jProiMet-fl leAla-Uol-Gly-Leu-Cly-
Gly-Ser-Ilc-Phe-Gly-Scr-Ala-Lcu-Leu-Gly-Ual
•Valille.Ala-Leu-Ala-Phe-GlyI I Ile-Ile-Gly-Val-Val-Phe-Ser-
Pro-Val-Leu-Cln-Thr-Thr-Mel-Phe-Ile-Gly-Val
Neurospora crassa
l .J
-J
Leu-Met-Ala-Lys Phe-Leu-Ile-Leu-
Saccharomyces cerevisiae Phe-Leu-Leu-Leu