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English Pages 471 [476] Year 1983
Modem Methods in Protein Chemistry Review Articles
Modern Methods in Protein Chemistry Review Articles following the Joint Meeting of the Nordic Biochemical Societies Damp/Kiel, F R. of Germany, September 27-29,1982 Editor Harald Tschesche
W G DE
Walter de Gruyter • Berlin • New York 1983
Editor Harald Tschesche, Dr. rer. nat. Professor für Biochemie Lehrstuhl für Biochemie Fakultät für Chemie Universität Bielefeld D - 4 8 0 0 Bielefeld, F R. of Germany
CIP-Kurztitelaufnahme
der Deutschen
Bibliothek
Modem Methods in Protein Chemistry: review articles; following the joint meeting of the Nordic biochem. soc., Damp/Kiel, FR of Germany, September 27 - 29,1982 / ed. Harald Tschesche. Berlin; New York: de Gruyter, 1983 ISBN 3-11-009514-9 NE: Tschesche, Harald [Hrsg.]
Library of Congress Cataloging in Publication Data Modern Methods in Protein Chemistry. Sponsored by Gesellschaft für Biologische Chemie. Bibliography: p. Includes index. I. Proteins—Analysis—Congresses. I. Tschesche, Harald II. Gesellschaft für Biologische Chemie. QP551.M58 1983 547.7'5 83-14009 ISBN 3-11-009514-9
Copyright © 1983 by Walter de Gruyter & Co., Berlin 30. All rights reserved, including those of translation into foreign languages. No part of this book may be reproduced in any form - by photoprint, microfilm or any other means - nor transmitted nor translated into a machine language without written permission from the publisher. Printing: Gerike GmbH, Berlin. - Binding: Dieter Mikolai, Berlin - Printed in Germany.
Preface
The intention of this volume is to attempt a survey of the present status in the different fields of analytical methods for the characterization and study of proteins. It is hoped, that the book will serve as a guideline for newcomers as well as for experienced scientists to become acquainted with the recent developments, trends and possibilities of the available analytical tools. The articles review the methodological developments up to the present most advanced applications. The references given should enable the reader to find his orientation among the literature and to adapt the method to his own problems. Most of the subjects have been reviewed during the Joint Meeting of the Nordic Biochemical Societies, Conference A, September 30 and October 1, 1982, Damp/Kiel, FRG. This meeting was kindly organized and supported by the Gesellschaft fur Biologische Chemie and the study group for chemical protein analysis. At this meeting, the general opinion was that there is a trend and demand for micro- and submicroscale analytical procedures in order to facilitate the solution of many interesting biochemical problems. This trend is clearly obvious from the efforts described in this book. It is the aim of the authors to extend knowledge and their analytical experience in order to stimulate progress in the field of protein research. Bielefeld, April 1983 Harald Tschesche
Contents
Protein Studies as Important Tools in Amplifying Different Characterizations of Biologically Active Macromolecules H. Jornvall, N. Kalkkinen, J. Luka, R. Kaiser, M. Carlquist, H. von Bahr-Lindstrom
1
High Resolution Analytical and Preparative Isoelectric Focusing of Proteins: Principles and Strategy B.J. Radola
21
High Resolution of Complex Protein Solutions by TwoDimensional Electrophoresis J. Klose
49
Some Recent Developments of the Electroimmunochemical Analysis of Membrane Proteins. Application of Zwittergent, Triton x-114 and Western Blotting Technique O.J. Bjerrum, K.P. Larsen, M. Wilken
79
Affinity Electrophoresis with Special Reference to the Microheterogeneity of Glycoproteins and Identification of Ligand-Binding Proteins T.C. B0g-Hansen, B. Teisner, J. Hau
125
Principles and Applications of Heterogeneous Enzyme Immunoassays G. Grenner
149
Immunological Methods for the Detection of Proteins. Application to Proteins Synthesized in Cell Free Systems in Rat Hepatocytes and by E. Coli Cells Transformed with Recombinant DNA K. Schneider, W. Northemann, E. Schmelzer, V. Gross, P.C. Heinrich
163
VIII Protein Quantification with Zone Immunoelectrophoresis Assay (ZIA) 0. Vesterberg
187
High Performance Liquid Chromatography of Peptides and Proteins H. Kratzin, C.Y. Yang, H. Götz, F.P. Thinnes, T. Kruse, G. Egert, E. Pauly, S. Kölbel, L. McLaughlin, N. Hilschmann
207
Advanced Automatic Microsequencing of Proteins and Peptides B. Wittmann-Liebold
229
The Current Status of Automated Solid-Phase Sequencing W. Machleidt
267
Microsequence Analysis of Peptides and Proteins K. Beyreuther, B. Bieseler, J. Bovens, R. Dildrop, K. Neifer, K. Stüber, S. Zaiss, R. Ehring, P. Zabel
303
Aminopeptidase M in the Sequence Analysis of Peptides and Proteins K.-D. Jany, J. Czech, G. Pfleiderer
327
Fast Atom Bombardment Mass Spectrometry. A New Technique for Peptide Sequencing. A Review W. Schäfer
337
Perspectives in the Circular Dichroic Analysis of Protein Main-Chain Conformation A. Wollmer, W. Straßburger, U. Glatter
361
IX Spin-Labelled Amino Acids, Peptides and Proteins Synthesis and Application
-
H . R . W e n z e l , H. T s c h e s c h e , E. v o n G o l d a m m e r
T h e U l t r a s t r u c t u r e of M a c r o m o l e c u l a r C o m p l e x e s with Antibodies
385
Studied
G. S t o f f l e r , M . S t o f f l e r - M e i l i c k e
409
S u b j e c t Index
457
L i s t of A u t h o r s
463
PROTEIN STUDIES AS IMPORTANT TOOLS IN AMPLIFYING DIFFERENT TIONS OF BIOLOGICALLY ACTIVE
CHARACTERIZA-
MACROMOLECULES
Hans Jörnvall, Nisse Kalkkinen, Janos Luka, Rudolf Kaiser, Mats Carlquist and Hedvig von Bahr-Lindström Departments of Physiological Chemistry I, Biochemistry II and Tumour Biology, Karolinska Institutet, S-104 01 Stockholm, Sweden, and Department of Biochemistry, University of Helsinki, SF-00170 Helsinki, Finland
Summary
Structures and functions of proteins and their genes require several
dif-
ferent types of investigation for complete characterization. Three kinds of protein study valuable in combined approaches, are discussed: radiosequence analysis and two applications of peptide
analysis.
-- Radiosequence analysis for correlation of proteins and their genes can be extended by use of multi-labelled proteins. This is exemplified by in vivo multi-labelled protein ns72 of Semiiki Forest virus. Results
illus-
trate factors of importance in the selection of labelled residues, and suggest that the spread of specific activities should be low. However, the total amount of label
is less critical, and the amount required is shown
to be smal1. -- Results from selected peptides can give information for subsequent synthesis of oligonucleotide probes intended for hybridizations with corresponding nucleic acid structures. This is exemplified by a cellular, probably transformation-associated protein ("p53^"). Utilization of CNBr-peptides facilitates fragment separation, gives knowledge of several
protein
regions, and ensures information on structures that include residues with little code-degeneracy. This enables subsequent synthesis of probes with few
alternatives.
-- Similarly, protein results for use in subsequent synthesis of peptide replicates to generate specific antibodies can be obtained by limited structural
studies. This has also been demonstrated on the
Modern Methods in Protein Chemistry - Review Articles © 1983 by Walter de Gruyter & Co. - Berlin • New York
above-mentioned
2 cellular protein utilizing results of direct sequence
analysis.
Introduction
Protein sequence studies, X-ray crystallography, enzymology and DNA sequence analyses are well-established methods that combined allow characterization of the structures and functions of proteins in great detail. In relation to the protein studies, one comparatively new aspect concerns radiosequence analyses where use of multi-labelled proteins (1) extends the methodology. Protein studies have also become especially important as steps in new approaches where oligonucleotide probes (f.ex. 2) and antibodies (3) may be produced on the basis of information from limited peptide analyses. These two approaches and radiosequence analysis are discussed in relation to some viral and cellular
proteins.
Methods
In vivo multi-labelling and radiosequence analysis of Semiiki Forest virus protein ns72 was performed by previously described methods (1). Another protein, cellular "p53^" (3) purified as described (4), was treated with CNBr and the peptides obtained were separated by reverse phase high performance liquid chromatography, HPLC (5). Amino acid sequences were determined by manual DABITC (dimethylaminoazobenzene
isothiocyanate)
dations using by-products to assist identifications
(6) degra-
(7), and by liquid-
phase sequencer degradations using polybrene and a 0.1 M peptide program (8).
Radiosequence Analysis
Background
Sequence analysis of biosynthetically labelled proteins is a standard procedure for establishing relationships between proteins and their genes,
3 and for investigating N-terminal protein processing. The protein is labelled with radioactive amino acids of known types during in vivo or in vitro synthesis. After isolation of the product, release of the radioactivity during degradations will residue(s)
identify the original position(s) of the labelled
in the polypeptide chain.
For single types of labelled residues, this approach is fast and sensitive, allowing sequence analysis down to below the picomole scale. This method has therefore also been used in "ordinary" sequence analysis of proteins that could only be obtained in small amounts (cf. 9). However, with increasing sensitivity of non-radioactive protein methods (10-13) and with fast methods for DNA analysis, the main use of radio-sequence
degradations
is not for complete investigations of fully unknown proteins, but for combined investigations of partly known proteins studied also at the DNA level In this way, it is possible to establish positions for initiation of protein synthesis, correct reading frames, and positions of post-translational processing (e.g. removal of signal sequences, cleavage of polyproteins, or glycosylations, cf. 14,15). Most residues have been fully utilized for label
success-
in such studies, and simultaneous degradation of
a cold carrier protein of known structure is standard practice to check yield and sequencer
performance.
In vivo multi-labelled proteins Several
labelled residues can be incorporated into a protein for analysis.
In this way, the positions of more than one type of residue can be determined in each sequencer run, increasing speed and amount of
information
obtained. However, radioactivity alone is then not sufficient for the identification of residues. Instead, ordinary amino acid
phenylthiohydantoin
(PTH) separations are also required, as shown schematically in Fig. 1. Another step in making radiosequence analysis generally applicable is use of in vivo rather than in vitro labelling. This avoids the limitations set by working with cell-free systems but adds the complexities of cellular amino acid transport/metabolism and of isolation of the labelled protein in a radiochemically pure form. A few extensive analyses of proteins multilabelled in vivo have been carried out (9), and one in vivo label of a Semiiki Forest virus protein with seven different types of radioactive amino
In vivo Single labelling x 5
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Acknowledgements T h a n k s due to M r s . L e n a B a r o n a n d M i s s Pia H j o r t O l s e n f o r t h e i r s k i l f u l t e c h n i c a l a s s i s t a n c e , a n d to M r s . P. P l o u g f e l t f o r t y p i n g . We a r e g r a t e f u l to D r s . A. G o e n n e , C a l b i o c h e m - B e h r i n g Corp. San D i e g o , C a l i f o r n i a f o r his g e n e r o u s s u p p l y of t h e Z w i t t e r g e n t s a n d M. D a n i e l s e n f o r p r o v i d i n g us w i t h pig i n t e s t i n a l b r u s h b o r d e r . T h e i n v e s t i g a t i o n w a s s u p p o r t e d by the D a n i s h M e d i c a l R e search Council (12-3228), L u n d b e c k f o n d e n and H a r b o e f o n d e n .
120 References la.
Albertsson, (1981 ).
1.
Allen,
2.
Andersson, D.R., Davis, 252, 6617-6627 (1977).
3.
A x e l s e n , N . H . : In H a n d b o o k of I m m u n o p r e c i p i t a t i o n - i n - g e l t e c h n i q u e s , B l a c k w e l l , O x f o r d ; a l s o S c a n d . J. I m m u n o l . 1 7 , Suppl . 10 (in p r e s s ) ( 1 9 8 3 ).
4.
A x e l s e n , N . H . , K r o l l , J . , W e e k e , B . : In A M a n u a l of Q u a n t i tative I m m u n o e l e c t r o p h o r e s i s . Methods and A p p l i c a t i o n s , Univ e r s i t e t s f o r l a g e t , O s l o ; a l s o S c a n d . J. I m m u n o l . 2, S u p p l . 1 , ( 1 973) .
5.
B a r o n , C., T h o m p s o n , 285 (1975).
6.
Bhakdi, A., B h a k d i - L e h n e n , B., phys. Acta 470, 35-44 (1977).
7.
Bhakdi, S., Knüfermann, phys. Acta 2ii> 505-557
H., W a l l a c h , (1975).
8.
Bjerrum,
O.J.:
Biochim.
Biophys.
9.
Bjerrum,
O.J.:
Anal.
10.
B j e r r u m , O . J . ( e d . ) : E l e c t r o i m m u n o c h e m i c a l A n a l y s i s of brane Preoteins, Elsevier Biomedical Press, Amsterdam, York (1983).
11.
B j e r r u m , O . J . : In E l e c t r o i m m u n o c h e m i c a l A n a l y s i s of ne P r o t e i n s ( B j e r r u m , O . J . , e d . ) pp. 3 - 4 4 . E l s e v i e r dical P r e s s , A m s t e r d a m , N e w Y o r k ( 1 9 8 3 ) .
12.
B j e r r u m , O . J . , B h a k d i , S . : In H a n d b o o k of I m m u n o p r e c i p i t a tion-in-qel Techniques (Axelsen, N.H., ed.) B l a c k w e l l , Oxf o r d ; a l s o S c a n d . J. I m m u n o l . 1_Z.> S u p p l . 10 (in p r e s s ) ( 1 9 8 3 )
for
J.C.,
P-Ä., Andersson, Humphries,
T.:
C.:
B.: J. FEBS
J.L.,
Lett.
57,
Carraway,
Biochim.
Biochem.
Chrom.
Acta
90,
D.F.H.:
331-348
J.
Acta
O.J.:
472,
131-141
158-162
K.L.:
Biophys.
Bjerrum,
21_5,
(1975).
Biol. Chem.
332,
276-
Biochim. Biochim.
135-195
BioBio-
(1977).
(1978). MemNew
MembraBiome-
13.
Bjerrum, O.J., Bog-Hansen, T.C.: M e m b r a n e s ( M a d d y , A . H . , e d . ) pp. London (1976).
In B i o c h e m i c a l A n a l y s i s of 378-426, Chapman and Hall,
14.
Bjerrum, O.J., 66-89 (1976).
Biochim.
15.
B j e r r u m , O . J . , G i a n a z z a , E . : In E l e c t r o i m m u n o c h e m i c a l A n a l y s i s of M e m b r a n e P r o t e i n s ( B j e r r u m , O . J . , e d . ) pp. 1 2 5 153. E l s e v i e r Biomedical P r e s s , A m s t e r d a m , New York, (1983).
16.
B j e r r u m , O . J . , Lundahl , P.: 139-143 (1973).
Scand.
17.
Bjerrum, O.J., 69-80 (1974).
Biochim.
B0g-Hansen,
Lundahl,
P.:
T.C.:
J.
Biophys
Immunol.,2, Biophys.
Acta
Acta
455,
Suppl. 342,
1,
121 18.
Bjerrum, Wallach,
O.J., B h a k d i , S., B o g - H a n s e n , T.C., D.F.H.: Biochim. Biophys. Acta 406,
19.
Bjerrum, O.J., Bhakdi, S., Rieneck, M e t h o d s 3, 3 5 5 - 3 6 6 ( 1 9 8 0 ) .
20.
Bjerrum, O.J., Bjerrum, P.J., Larsen, K.P., Norrild, B., B h a k d i , S . : In E l e c t r o i m m u n o c h e m i c a i A n a l y s i s of M e m b r a n e P r o t e i n s ( B j e r r u m , O . J . , e d . ) pp. 1 7 9 - 1 9 8 , E l s e v i e r B i o m e dical P r e s s , A m s t e r d a m , N e w Y o r k ( 1 9 8 3 ) .
21.
B j e r r u m , O . J . , B o g - H a n s e n , T . C . , P l e s n e r , T. , W i l k e n , M. : In L e e t i n s - B i o l o g y , B i o c h e m i s t r y , C l i n i c a l B i o c h e m i s t r y ( B o g - H a n s e n , T . C . , e d . ) V o l . 1, pp. 2 5 9 - 2 6 8 , W a l t e r de G r u y t e r , B e r l i n , New York (1981).
22.
Bjerrum, Biochim.
23.
Bjerrum, O.J., G e r l a c h , J., B o g - H a n s e n , E l e c t r o p h o r e s i s 3, 8 9 - 9 8 ( 1 9 8 2 ) .
24.
B j e r r u m , O.J., H a w k i n s , M., S w a n s o n , P., G r i f f i n , M., Lor a n d , L . : J. S u p r a m o l . S t r u c . C e l l . B i o c h e m . ]_6, 2 8 9 - 3 0 1 (1981 ).
25.
B j e r r u m , O . J . , R a m l a u , J . , B o c k , E . , B 0 g - H a n s e n , T . C . : In T e c h n i q u e s for M e m b r a n e R e c e p t o r C h a r a c t e r i z a t i o n and Pur i f i c a t i o n ( J a c o b s , S . J . , C u a t r e c a s a s , P . , e d s . ) pp. 1 1 6 156, Chapman and Hall, London (1980).
26.
Bonsai 1 , R.W., 280 (1 971 ) .
27.
Bordier,
28.
B r o d b e c k , V . , G e n t i n e t t a , R . , O t t , P . : In M e m b r a n e P r o t e ins. A L a b o r a t o r y M a n u a l ( A z z i , A . , B r o d b e c k , U . , Z a h l e r , P., e d s . ) pp. 8 5 - 9 6 , S p r i n g e r - V e r l a g , B e r l i n ( 1 9 8 1 ) .
29.
Burnette,
30.
B o g - H a n s e n , T . C . : In S o l i d P h a s e B i o c h e m i s t r y - A n a l y t i c a l a n d S y n t h e t i c A s p e c t s ( S c o u t e n , W . H . , e d s . ) J. W i l e y a n d S o n s , I n c . N e w Y o r k (in p r e s s ) ( 1 9 8 3 ) .
31.
B0g-Hansen, T.C., Brogren, S u p p l . 2, 37-51 ( 1 9 7 5 ) .
32.
B0g-Hansen, T.C., Bjerrum, O.J. Ramlau, m u n o l . 4, S u p p l . 2, 1 4 1 - 1 4 7 ( 1 9 7 5 ) .
33.
B 0 g - H a n s e n , T . C . , L o r e n c - K u b i s , I., B j e r r u m , O . J . : In E l e c t r o p h o r e s i s ' 79 ( R a d o l a , B . J . , e d . ) p p . 1 7 3 - 1 9 2 , W. de Gruyter, Berlin (1979).
34.
Calcagno, M., Zagoya, 73, 3 8 6 - 3 9 0 (1976).
J.C.D.,
35.
Chua, N.H., (1979).
F.:
O.J., Lundahl , P., B i o p h y s . A c t a 3JM>
C.:
J.
Hunt, Biol.
W.N. : Anal.
Blomberg,
S.:
K. : J.
Knlifermann, H . , 489-504 (1975).
Biochem.
Hjertén, S., Brogren, 1 73-1 81 (1 975 ).
Biochim.
Chem.
T.C.,
Biophys.
2j[6, 1 604-1 607
Biochem.
1_1_2 , 1 9 5 - 2 0 3
C.-H.:
J.
Scand.
Lozano, Biol.
J. J.:
A.G.:
Chem.
Biophys.
C.-H.:
Hertz,
Acta
249,
J.:
266-
( 1 981 ).
(1 981 ).
Immunol, Scand.
Anal.
25_4,
J.
4, Im-
Biochem.
215-233
36.
Converse, ( 1 975) .
C.A.,
Papermaster,
37.
Dako
38.
D a n i e l s e n , E . M . : In E l e c t r o i m m u n o e h e m i c a 1 A n a l y s i s of M e m brane Proteins ( B j e r r u m , O.J., ed.) pp. 1 5 5 - 1 6 7 , E l s e v i e r B i o m e d i c a i P r e s s , A m s t e r d a m , New Y o r k ( 1 9 8 3 ) .
39.
Dodge, J.T., Mitchel, Biophys. 100, 119-130
40.
Fairbanks, G., Steck, T.L., 10, 2 6 0 6 - 2 6 1 7 (1971).
41.
Förster, Seyler's
M., Kopp, F., R e i n a u e r , H., Z. P h y s i o l . C h e m . 3 6 3 , 1 0 1 0
42.
Gabriel,
0.: M e t h .
43.
Glass, 70-73
43a
G e r l a c h , J . H . : In E l e c t r o i m m u n o c h e m i c a l A n a l y s i s of M e m b r a ne P r o t e i n s ( B j e r r u m , O . J . , e d . ) p p . 2 9 9 - 3 1 7 , E l s e v i e r B i o m e d i c a l P r e s s , A m s t e r d a m , New Y o r k ( 1 9 8 3 ) .
44.
Gerlach, J.H., Bjerrum, 60, 6 5 9 - 6 6 6 (1982).
45.
Goenne,
46.
Grauballe, P.C., J. M e d . V i r o l o g y
47.
Graham, R.C., Lundholm, U., Karnovsky, C y t o c h e m . ]_3, 1 50-1 52 ( 1 962 ).
48.
H e l e n i u s , A. , S i m o n s , 79 ( 1 975 ) .
49.
H a g e n , L., B j e r r u m , O . J . , G o g s t a d , G . O . , K o r s m o , N . O . : B i o c h i m . B i o p h y s . A c t a 701_, 1 - 6 ( 1 982 ).
50.
H a g e n , I., N u r d e n , A . , B j e r r u m , O . J . , J. C l i n . I n v e s t . 6 5 , 7 2 2 - 7 3 1 (1980).
51.
H a r b o e , N . M . G . , I n g i l d , A . : In A H a n d b o o k of I m m u n o p r e c i p i t a t i o n - i n - g e l Techniques ( A x e l s e n , N . H . , e d . ) . B l a c k w e l l , O x f o r d , a l s o S c a n d . J. I m m u n o l . V 7 , S u p p l . 10 (in p r e s s ) 4 (1983).
51a
H e r t z , J . B . , P a r t o n , R . : In E 1 e c t r o i m m u n o e h e m i c a 1 Analysis of M e m b r a n e P r o t e i n s ( B j e r r u m , O . J . , e d . ) pp. 3 7 3 - 3 9 2 , E l s e v i e r B i o m e d i c a l P r e s s , A m s t e r d a m , New York (1983).
52.
H a w k e s , R., N i d a y , 147 ( 1 9 8 2 ) .
53.
H e e g a a r d , N . , C h r i s t e n s e n , U . , B j e r r u m , O . J . : In L e c t i n s Biology. Biochemistry, Clinical Biochemistry (Bog-Hansen, T . C . , S p e n g l e r , G . A . , e d s . ) V o l . 3, p p . 3 8 7 - 3 9 6 . W . de G r u y t e r , B e r l i n , New York (1983).
Immunoglobulins,
Ernst,
Pamphlet
pp.
C., Hanahan, (1963).
R.C.,
R.: Anal.
Rank,
D.J.:
Biochim.
E., G o r d o n ,
Arch.
D.F.H.:
(1975).
Biochem.
Biochemistry
S t a i b , W. : H o p p e (1982). ( 1 971 ).
L.S.:
G.H.:
Biochem.
Vestergaard, B.F., 7, 2 9 - 4 0 ( 1 9 8 1 ) .
469-472
5, C o p e n h a g e n
578-604
Huilica,
O.J.,
K.:
Science ^89,
Wallach,
Enzymol . VI,
W.F., Briggs, (1981).
P.,
D.S.:
Science
Can.
J.
8J7 , 2 8 - 3 8
Meyling, M.J.:
Biophys.
Solum,
J.: Anal.
211,
( 1 978).
A., J.
Biochem.
Genner,
J.:
Histochem.
Acta
415, R.,
N.O.,
Biochem.
29Solum,
Caen,
119,
J.:
142-
123 54.
Hjelmeland, L.M., Nebert, D.W., c h e m . 9_5, 201 - 2 0 8 ( 1 979 ).
55.
Hoek,
56.
K j a e r v i g , M . , I n g i l d , A . : In A H a n d b o o k of I m m u n o p r e c i p i tati o n - i n - g e l T e c h n i q u e s ( A x e l s e n , N . H . , e d . ) B l a c k w e l l , O x f o r d ; a l s o S c a n d . J. I m m u n o l . 1_7, S u p p l . 10 (in p r e s s ) ( 1 9 8 3 ).
57.
Kroll,
58.
Laemmli,
U.K.:
59.
Laurell,
C.-B.:
Anal.
60.
Laurell, (1981).
C.-B.,
McKay,
61.
Lester, R.L., ( 1 974 ) .
62.
L o r a n d , L., Proc. Natl.
63.
Lowry, O.M., Rosenbrough, N.J., Farr, A.L., J. B i o l . C h e m . ]_93 , 2 6 5 - 2 7 5 ( 1 951 ).
64.
Marchesi,
65.
Nielsen, C.S.: ( 1 975 ) .
Scand.
66.
Nielsen, C.S., ( 1 975 ) .
Bjerrum,
O.J.:
Scand.
67.
Nielsen, C.S., Bjerrum, 496-509 (1977).
O.J.:
Biochim.
68.
Norrild, B., Bjerrum, O.J., c h e m . 8J_, 4 3 2 - 4 4 1 ( 1 977 ) .
69.
N o r r i l d , B . : In A H a n d b o o k of I m m u n o p r e c i p i t a t i o n - i n - g e l T e c h n i q u e s (Axelsen, N.H., ed.) B l a c k w e l l , O x f o r d ; also S c a n d . J. I m m u n o l . V 7 , S u p p l . 10. (in p r e s s ) ( 1 9 8 3 ) .
70.
01 F a r r e l 1 , P . H . :
71.
O w e n , P . , S m y t h , C . J . : In I m m u n o c h e m i s t r y of E n z y m e s a n d t h e i r A n t i b o d i e s ( S a l t o n , M . R . J . , e d . ) pp. 1 4 7 - 2 0 2 , W i l e y a n d S o n s , New Y o r k ( 1 9 7 6 ) .
72.
Parkhouse, R.M.E., 280-281 (1980).
73.
Plesner, T.,Bjerrum, ( 1 980) .
74.
P l e s n e r , T . , W i l k e n , M . , A v n s t r o m , S . : In E l e c t r o i m m u n o c h e m i c a l A n a l y s i s of M e m b r a n e P r o t e i n s ( B j e r r u m , O . J . , e d . ) pp. 4 5 - 5 4 . E l s e v i e r B i o m e d i c a l P r e s s , A m s t e r d a m , New Y o r k ( 1 983) .
A.K.,
Zail,
J.: Meth.
S.S.:
Enzymol.
Nature
Smith,
J.
79,
7-14
Bio-
(1977).
(1981). (1970).
Meth.
J.
A.: Anal.
1_0, 3 5 8 " 3 6 1
Biochem. E.J.:
Acta
52-57
680-685
S.W.:
Meth.
Chim.
73,
227,
Weissmann, Acad. Sci.
V.T.:
Clin.
Chrambach,
(1 9 6 5 )
Enzymol.
Biol.
Chem.
73,
249,
338-339 3395-3405
L.B., Epel, D.L., Bunner-Lorand, U . S. A. 7 3 , 4 4 7 9 - 4 4 8 1 (1976).
Enzymol. J.
28,
Immunol.
Biol.
Lifter, O.J.:
252-254 4,
Suppl. J.
J.,
2,
Scand.
J.
101-105
Biophys. B.F.:
25J), 4 0 0 7 - 4 0 2 1
Choi,
Y.S.:
R.J.:
(1972).
Immunol.
Vestergaard,
Chem.
Randall,
J.:
2,
73-80
Acta
466 ,
Anal
( 1 975 ).
Nature
Immunol.
Bio-
11, —
284 , 341-351
124 75.
Plesner, T., Wilken, M., Bjerrum, O.J., C l i n . L a b . I m m u n o l . 8, 137-141 (1982).
76.
Reinhart, ( 1 982 ) .
77.
S i m o n s , K., H e l e n i u s , A . , M o r e in, B., B a l c o r o v a , J., S h a r p , M . : In N e w D e v e l o p m e n t s w i t h H u m a n a n d V e t e r i n a r y V a c c i n e s ( M i z r a k i , A . , e d . ) P r o g r e s s in C l i n i c a l a n d B i o l o g i c a l Res e a r c h , V o l . 4 7 , pp. 2 1 7 - 2 2 8 , A l a n R. L i s s , New Y o r k (1980).
78.
S j ö s t r ö m , H . , N o r é n , 0 . : In E 1 e c t r o i m m u n o e h e m i c a 1 Analysis of M e m b r a n e P r o t e i n s ( B j e r r u m , O . J . , ed.) pp. 2 4 1 - 2 5 5 , E l s e v i e r B i o m e d i c a l P r e s s , A m s t e r d a m , New York (1983).
79.
S k o v b j e r g , H., Norén, 0., S j ö s t r ö m , Lab. Invest. 38, 723-729 (1978).
H.:
80.
Smith, S.W., (1979).
Chem.
81.
Svendsen, ( 1 973) .
82.
S v e n d s e n , P . J . : In E l e c t r o p h o r e s i s . A S u r v e y o f T e c h n i q u e s and A p p l i c a t i o n s ( D e y l , Z., ed.) P a r t A. T e c h n i q u e s , pp. 349-350, Elsevier, Amsterdam (1979).
83.
Tanford, C., Reynolds, 133-170 (1976).
84.
Tanner, M.J.A., ( 1 976 ) .
85.
Towbin, S c i . U.
86.
U r i e l , J . : In M e t h o d s in I m m u n o l o g y a n d Immunochemistry (Williams, C . A . , C h a s e , M . W . , e d s . ) V o l . 3, pp. 2 9 4 - 3 2 6 , A c a d e m i c Press, New York (1971).
87.
Weeke,
88.
W i l k e n , M., B j e r r u m , O.J., G e i s l e r , C., P l e s n e r , T.: - S e y l e r ' s Z . P h y s i o l . C h e m . 36J3, 1 01 3 - 1 01 4 ( 1 9 8 2 ).
M.P.,
Malamud,
Lester,
P.J.:
D.:
K.L.:
Scand.
Anstee,
J.
J.
Anal.
Biol.
Immunol.
J.A.: D.J.:
Biochem.
2,
Biochim.
Scand.
J.
Clin.
Lab.
Scand. 249,
Biophys.
Biochem.
Invest.
J . ]_53, Proc.
25,
M.M.:
]_2_3,
S u p p l . 1,
H., S t a e h e l i n , T,, G o r d o n , J.: S. A. 7 5 , 4 3 5 0 - 4 3 5 4 (1979).
B.:
Hansen,
J.
229-235
J.
Clin.
3395-3405 69-70
Acta
457 ,
265-270
Natl.
Acad.
269-275
(1970). Hoppe-
AFFINITY
ELECTROPHORESIS
HETEROGENEITY BINDING
T.
C.
SPECIAL
GLYCOPROTEINS
AND
REFERENCE
TO
IDENTIFICATION
THE OF
MICRO-
LIGAND-
PROTEINS
B0g-Hansen
The P r o t e i n Sigurdsgade
B.
OF
WITH
Laboratory, 34, D K - 2 2 o o
University Copenhagen
of N,
Copenhagen Denmark
Teisner
Medical Microbiology, J. B . W i n s l 0 w s v e j 1 9 ,
U n i v e r s i t y of Odense D K - 5 o o o O d e n s e C, D e n m a r k
J . Hau B i o m e d i c a l L a b o r a t o r y , U n i v e r s i t y of J . B. W i n s l e w s v e j 2 1 , D K - 5 o o o O d e n s e
Odense C, D e n m a r k
Introduction
Affinity
electrophoresis
electrophoretic allowed
to
react
electrophoresis to
interact
resis,
23,
after
26).
jugates proach
As
this and can
during is
is in
the
term
which
which or
a system
the
in
which
(6).
used
Affinity
components
before
or
to
describe
components
are
during
are
Immuno-
allowed
electropho-
results
of
the
interaction
quantitatively
by
the
immunoprecipitation
a typical chapter
used
example
describes
lectins. be
commonly
interacting
electrophoresis
non-immunologically,
analytically
tion,
systems
However,
are
of the
are
1igand-macromo1ecu1e interaction
systems
summarized.
Modern Methods in Protein Chemistry - Review Articles © 1983 by Walter de Gruyter & Co. - Berlin • New York
in
between
which
revealed (6,
interacglycocon-
a similar
ap-
126 General The
Principles
analysis
tion
of
liqand
in a g a r o s e .
interaction
Compared
troimmunoprecipitation as p r o t e i n s
tend
to
biological
remain
activity
impaired.
Because
to
the
change
protein, resis.
well
complex
In t h i s in t h e
suited feature
free
migration
which
formation
the
of
their
of
be
gel.
these of e v e n
may it
can
be
utilized
in t h e
protein
reference
identification
of
native
The
be to
include
the
in the
are
not tends
of
the
Immunoelectropho-
that
crossed
Immuno-
m a c r o m o l e c u 1 ar matrix
pore
several
analysis (12,
offers
e-
is
size
li-
especially One
impor-
which
allows
m a c r o m o 1 e c u 1 ar c o m p l e x e s
has
mixtures gel
gel
an
their
complex
macromo1ecu1es. large
large
during
behaviour
by
elecmethod
retain
interactions
studied
agarose
is
very
they
antigenic
of n a t i v e
gels
state
Thus
is i m p o r t a n t
adapted
study
methods, reference
a protein-ligand and
Immunoelectrophoresis
multicomponent dies
in
protein-ligand
connection can
analytical
experiment.
formation
agarose to
tant
Crossed
and
electr•immunoprecipita-
to be a s u p e r i o r
e1ectrophoretic
electrophoresis gands
to o t h e r
seems
1ectroimmunoprecipitation
by
and 34).
unique
(29)
features
characterization The
use
the p o s s i b i l i t y
of
of
antibo-
for
specific
proteins.
Lectins For
developing
extensively
our
(6 - 1 6 ) .
bohydrate-binding blood
cells,
interacting
and
have
"phytohemagg1utinins" Several (2,
3,
reviews 39).
of
Lectins
chromatography 4o).
been as
lectins have
Several
separated types
of
are
They
to at
for
first
properties
and
been
e.g.
carred
"hemagglutinins" in
have for
characterization
have
lectins
cells,
extensively
glycoproteins label
used
or m u l t i v a l e n t
discovered
their used
and
have
divalent
were
and
been
we
agglutinate
referred
they
of p r o t e i n s
trophoretica11y 19,
Lectins
proteins.
systems
appeared
affinity of
elec-
g1ycopeptides
used,
or
plants.
these
(3,
include
127 fluorescein labels, been
or
i s o t h i o c y a n ate antibody
applied
(5).
to
to
led
form
Reactions
Fig.
with
1, F i g .
lectin
tin.
The
the p r o t e i n
the
prior
the
incubation
was
internal
protein
binds
to the
disappears
disappearance
2, or p a r t i a l , of
The
the
same
first
4b)
or w i t h
morphology If by tates
area
the
for
remain result
coupuncoup-
is b o u n d .
Other
mobility
4) or p r o f i l e
plates
(Fig.
lc).
This
(13) m e d i a t e d
unrelated
by
leclectin
that
by
bind
to
and
it
1).
When
that
the
in
a pre-
area.
for
Protein
in
only
could
may
immua
frac-
also
occur
several
lines
la,
Protein
4 - > 4a
(Protein
is u s e d ,
not
reduction
mobility
supernatant
identity
as s e e n
a change
lectin
the
analyzed
does
in
into
(Fig.
in t h e
immuincu-
immobilized was
patterns
split
by
shows
is r e d u c e d
The
dimension
accompanied
lb
1, F i g .
3 indicates
could
after
immobilized
is e i t h e r
or
3.
Crossed
unchanged
be c o m p l e t e ,
Protein
first
Fig.
(Protein
free
lectin
used free
schematically
with
mixing
pattern
Protein
dimension
by
complexes
in t h e
shown
If a p r o t e i n
the
either of
be
are
supernatant
will
the
precipitate
(Protein
nologically At low
may
could
contrast
as l e c t i n partial
and
lectin
different
This
techniques
been
obtained
plate.
performed
from
this protein
in t h e o r y .
5 + x).
control
reference
as s e e n
noprecipitation tion
have
in t h e i r
patterns
lectin
its p r e c i p i t a t e
as an
cipitate
lectins
electrophoresis.
Immunoelectrophoresis.
lectin,
have
or
of g l y c o p r o t e i n s
sample
be u s e d
The
to
with
reaction
with
crossed
enzyme
in b l o t t i n g
lectins
lectin)
precipitation
la b e i n g
after
labelled
labels,
lectin).
of g l y c o p r o t e i n
pattern
Moreover,
(immobilized
noelectrophoretic bation
radioactive
glycoproteins
electrophoresis
Sepharose (free
labels.
identify
In a f f i n i t y
led
labels,
some
as
result
lectin
+
5 ->
precipitate
5).
proteins
and
may
(Protein of
with
may
appear
immunoprecipiin
a pattern
cross-linking
of
of
immu-
proteins.
to g l y c o p r o t e i n
ratios,
the
pattern
is
affected
128 by
the
the
lectin
pattern
concentration,
is l i t t l e
but
changed
above
by
the
further
point1
'saturation
addition
of m o r e
lec-
tin.
Lectins lectin
in i n t e r m e d i a t e into
sis^ w a s
introduced
trophoresis'
(6).
fic a n t i b o d i e s
under
and
on of
interacting
sensitive
troduction, with
the
term
'crossed
is a n a l o g o u s
intermediate
gel,
to
the d e t e c t i o n antibodies
and
used
for
for p r e d i c t i o n
affinity
the
which
for been
incorporating
immuno
and
has
of
Immunoelectrophore-
method
the m e t h o d lectin
in c r o s s e d
antigens
glycoproteins
ments
The p r i n c i p l e
gel
The m e t h o d
in the
cific
many
gels.
an i n t e r m e d i a t e
affino use
of
speci-
is a h i g h l y and
(33).
spe-
identificatiSince
its
identification
of s e p a r a t i o n
chromatography
elec-
in-
of
experi-
of g l y c o p r o t e i n s
(8,
1,11).
Immobilized original tions
lectin
are p o s s i b l e .
or d i m i n u t i o n teristic
for
reasonable
simple
to
complex
tin.
Splitting same
that
compl exes
patterns gel
as
shown
dimension
seen
glycoproteins.
If s h o w s gel.
tins:
Protein
the
lectin,
formation
individual
to some
a limited reactions
(Fig.
Id a n d
may
the
with
of a f f i n i t y
glycoproteins.
with
reac-
are
e).
disappearance
This
free
charac-
it w o u l d would
in
precipitates
give
appear and
lecin
the of
precipitate
in the
changes
features
as
A - > 4a + 4b
is c h a r a c t e r i s t i c
lectin
be
such
reaction
(Protein
le
is
an i m m o b i l i z e d after
The c h a n g e
precipitate
notable
the
glycoproteins,
occur le
5 in F i g .
in of
glycoproteins,
reaction
in F i g .
gel
number
Theoretically
complex
mobility).
reactions
In a d d i t i o n
immobilized of
for
intermediate
containing
after
complex
Fig.
more
of p r e c i p i t a t e s
first
the only
glycoproteins.
profile
ate
to
Characteristic
expect
more
intermediate
added
However,
of p r e c i p i t a t e s
m a c r o m o l e c u 1ar
the
was
experiments.
for
intermedi-
mentioned with
free
with lec-
coprecipitation
129
F i g . 1 . S c h e m a t i c r e p r e s e n t a t i o n of v a r i o u s s y s t e m s of a g a r o s e g e l e l e c t r o p h o r e s i s w i t h a n t i b o d i e s for s t u d i e s of i n t e r a c t i o n b e t w e e n l e c t i n s and g l y c o p r o t e i n s : C r o s s e d I m m u n o e l e c t r o p h o r e s i s ( a - i ) a n d l i n e i m m u n o e l e c t r o p h o r e s i s (j). a - b - c : I n t e r a c t i o n b e f o r e e l e c t r o p h o r e s i s (a: c o n t r o l ) , d - e - f : L e c t i n in the i n t e r m e d i a t e gel (d: c o n t r o l ) , g - h - i : L e c t i n in t h e f i r s t d i m e n s i o n gel (g: c o n t r o l ) , j: L e c t i n in s m a l l w e l l s in an i n t e r m e d i a t e g e l . A n o d e to t h e r i g h t s i d e a n d on t o p . A b b r e v i a t i o n s u s e d : a = a f f i n i t y p r e c i p i t a t e , FL = f r e e l e c t i n , IMM = i m m o b i l i z e d l e c t i n . See the t e x t for f u r t h e r d e t a i l s . M o d i f i e d from (11).
130 Lectins
in
first
ting
lectin
1975
(9) a n d
the
first
first
into
dimension
gels.
the
dimension
first
is a n a l o g o u s
dimension
dimension
terization
and
prediction
of
gel
to
gel
(28).
has
been
outcome
(8,
Fig.
lh a n d
i shows
typical
trophorezed
through
a gel
respectively.
tin
concentration.
action Protein
can
tardation
that
action,
each
a well
Generally, cathodic
Lectins on of
a well the
component
each
with
peak
on
a low
the
very
Krall
and
If t h e r e
a change
of
to
for
dimension
with
and
the
inter-
an
affinity
gel.
In F i g .
to a p p e a r
from
to
a distinct
li the
as a re-
concentration.
respect
lectin
Many inter-
subpopu1 ation
structure. at pH 8 . 6
technique,
conservative
(25).
between
The the
is an i n t e r a c t i o n the p a t t e r n
which
amounts
may
A
lectin
between
a
2 and
3).
modificati-
has
the
of l e c t i n ,
antigen
be
induce
(Figs.
Immunoelectrophoresis.
gel
lectin
3 is l o s t
glycoproteins
Andersen
leclec-
a characteristic
lectin
with
the
position.
reflect
Protein
elec-
free
on
the
sometimes
mobility
reacting
in l i n e
bind
and
representing
intermediate
gel.
lectin,
as
are
and
dependent
cathodically
carbohydrate
of t h e
of u s i n g by
the
charac-
as w e l l
proteins
patterns
first
heterogeneity
defined
in an
antibody
in t h e
3 is s h i f t e d
lectins
introduced
in
in
chromatography
immobilized
not
the p a t t e r n .
immunoelectrophoretic
advantage
in
antibodies
lectins
of u n c h a n g e d
lectin
is d e p e n d e n t
in w e l l s
the
seen
when
is h i g h l y
1 does
with
from
show
shift
with
affinity
reactions
reference
precipitate,
glycoproteins
incorpora-
identification,
of g l y c o p r o t e i n s
containing
Protein
be
Protein
double-peak
for
immunoprecipitation
2 is l o s t
pattern.
of
introduced
of s p e c i f i c
The m e t h o d used
pattern
of t h e p r o t e i n
precipitate
with
The
as a n i n t e r n a l in
was
11).
tin
Alterations
principle gel
use
of l e c t i n
separations
is u s e d
the
quantification the
The
added was
is a d d e d gel
and
a protein
observed
as a
to the and
nega-
131 tive has
deflection been
tographic fast
and
extracts
used
in
for
media
the
(18,
sensitive (Fig.
i
1ine-preeipitate
evaluation 25).
assay
We for
of
binding
use
this
(Fig.
method
screening
lj).
properties
for
The of
routinely
lectins
in
method chromaas
a
plant
4) .
U
MMMm
c
y tt u
F i g . 2. C r o s s e d I m m u n o e l e c t r o p h o r e s i s w i t h l e c t i n s in the first dimension gel. Human serum proteins analyzed with antib o d i e s a g a i n s t h u m a n s e r u m p r o t e i n s ( s t a i n e d for p r o t e i n ) , a: C o n t r o l p l a t e . b: C o n A in the f i r s t d i m e n s i o n g e l . c : L e n t i l a g g l u t i n i n ( L C A ) in t h e f i r s t d i m e n s i o n g e l . d: W h e a t g e r m a g g l u t i n i n ( W G A ) in the f i r s t d i m e n s i o n g e l . A n a f f i n i t y p r e c i p i t a t e is v i s i b l e in t h e f i r s t d i m e n s i o n g e l w i t h all t h r e e l e c t i n s . E v e n t h o u g h c o n A and LCA is i n h i b i t e d by t h e s a m e m o n o s a c c h a r i d e s ( m a n n o s e a n d o t h e r s ) t h e i r r e a c t i o n w i t h g l y c o p r o t e i n s is d i s t i n c t l y d i f f e r e n t ( c o m p a r e b and c). The N - a c e t y 1 - g 1 u c o s a m i n e - b i n d i n g WGA e x h i b i t s a d i s t i n c t l y d i f f e r e n t b e h a v i o u r w i t h a s t r o n g b i n d i n g of o r o s o mucoid.
F i g . 3. As F i g . 2 b u t s t a i n e d for e s t e r a s e a c t i v i t y . Two ester a s e s a r e s e e n : C h o l i n e s t e r a s e (C) i s b o u n d s t r o n g l y i n t h e a f f i n i t y p r e c i p i t a t e by a l l t h r e e l e c t i n s , HDL-associated a r y l e s t e r a s e (A) is s h i f t e d c a t o d i c a l l y by t h e l e c t i n s .
132 Precipitation
It
is
important
cipitation tins.
In
No
to
with
note
there
lectin
interaction
non-binding. 2.
and
No
and
Microheterogeneity
here
are
the
and
distinction
affinity
three
between
immunopre-
precipitation
possible
reactions
with
lec-
between
a
glycoproteins:
with
the
change
Lectin-dependent pitating
and
antibodies
general
multimeric 1.
Patterns
glycoprotein: in
the
immunoprecipitate.
precipitation
binding
non-precipitating ,
of
the
glycoprotein.
glycoprotein:
Disappearance
preci-
of
the
im-
munoprecipitate. 3.
Interaction
without
formation
of
a lectin
non-precipitating , 1ectin-binding the
Characteristically,
may
described The ed
upon be
the
found
glycoproteins lectin
Change
in
as
used
a mixture
are
for of
microheterogeneous
analysis, two
or
a given
three
of
the
and
glycoproforms
above.
microheterogeneity by
glycoprotein.
immunoprecipitate.
depending tein
precipitate:
crossed
classes
can
Immunoelectrophoresis
most with
clearly free
be
distinguish-
lectin
incorpo-
F i g. 4. L i n e i m m u n o e 1 e c t r o p h o r e s is w i t h l e c t i n e x t r a c t s in s m a l l w e l l s for s c r e e n i n g of l e c t i n s , from l e f t s i d e e x t r a c t s of K e n n e d y a r u b i c u n d a , P s i d u m c a t t l e i a w u m , C a s s i a n o d o s a , E r y t h r i n a c r i s t a g a l l i , S c h o t i a a f f r a (T. C . B a g - H a n s e n a n d J. G. G r u d z i n s k a s , in p r e p a r a t i o n ) .
133 rated
into
protein
the
first
structure
In p r i n c i p l e and
the most
use
of b o t h
cipitating
both
dimension
previously
free
and
complete forms.
and
information
Free
lectin
fractions
ding.
lectin
and
non-binding
fractions
form
addition
this,
the
affinity
influences
the
pattern.
lectin
Quantification hods
may
with
free
a basis
lectin
for
Type For
into
sites,
three
Type
forms,
the
intermediate
out
lectin
third
three
Type
different
lectin
The
of
can
(the
simple
calculation
free the
be
will
Type of
the
of
2 (the
in the
the
relative
and
microhete-
required
the
is
with
with-
experiment gel
and
in-
the
intermediate
of e a c h
the
total
amount
of
of
glycoand
experiment).
content
gel.
precipitate amount
experiment)
third
of
without
site
of
are
second
second
2 (the
micro-
constitutes
experiment
area
met-
sites.
intermediate
for
In
the
forms
binding
types
first
experiment),
Type
give
three
enclosed
lec-
Precipitation
lectin
binding
lectin
obtained
first
1 plus
of g l y c o p r o t e i n
gel,
The
present
changes
ij^ v i v o .
experiments The
in the
includes
amount
(11).
these
intermediate
estimate
of
forms.
immobilized
technique.
planimetry
protein
of
The
non-bin-
for
one
By c a r e f u l
glycoprotein
glycoprotein
of m i c r o h e t e r o g e n e i t y
or m o r e
pre-
lectin-
with
a relative the
or
1 - molecules
of e a c h
immobilized experiment
fractions.
0 - molecules
gel
in the
between
Type
two
used
coordinated
between
quantitative
to
be
classes:
with
quantification
cludes
binding
(1).
or n o n - p r e c i p i t a t i n g .
of the
the
glyco-
of a g l y c o p r o t e i n .
of g l y c o p r o t e i n s
vs.
2 - molecules
rogeneity
assess
by
lectin-binding
be p r e c i p i t a t i n g
a classification
glycoproteins binding
to
forms
may
differentiate
of m i c r o h e t e r o g e n e i t y
be u s e d
heterogeneity
lectins
glycoprotein be
of
in d e t a i l
differentiate
tin-binding to
may
may
will
aspects
is o b t a i n e d
will
non-precipitating
Immobilized
These
discussed
immobilized
non-precipitating binding
gel.
were
of e a c h
the A form
134 Table
I.
Orosomucoid
Heterogeneity.
D i s t r i b u t i o n of O r o s o m u c o i d i n t o t h r e e C l a s s e s F o r m s C h a r a c t e r i z e d by t h e i r R e a c t i o n w i t h c o n Dimension
Peak(s ) 3
Source
Normal
serum
8
I 3
(+4)
Peak
43 a )
5 - 3
40
+ +
of M o l e c u l a r A in the F i r s t
2
Peak
3
49
4
55
+ +
1
Ref .
4
41,,42
6
30
7
30
5
* * *
Pregnancy Maternal
serum
23
0 a )
3 - 4 0 Amniotic Chord
Abnormal Prostatic +
fluid
13
15 23
0
22
- 5
45
-
+ +
+
7
85
5
77
7
78
2
44
,42 +
+ + +
7 6
serum cancer
stilboestrol
Post
0
blood
t 0
77 +
b )
10
0 - 0
- 1
9 0 - 1
30
operative c)
cholecystectomy c)
24
Septicaemia
27
Acute
pancrea-
32
titis
C )
Advanced
>11
-
6
: i
a)
4 0 - 3
3 7 - 1 0
39 - 2
3 5 - 8
40
28 - 4
40
48
40
48
cancer
Rheumatoid arthritis c )
13
a)
- 13
a ) Sum of Peak 3 and p e a k 4, R a y n e s f i n d s a f o u r t h p e a k ( 3 o ) . b ) T o t a l a m o u n t of o r o s o m u c o i d , d o u b l e of n o r m a l . c ) T o t a l a m o u n t of o r o s o m u c o i d , four t i m e s n o r m a l . * T. C. B a g - H a n s e n and J. G. G r u d z i n s k a s , in p r e p a r a t i o n .
135 It
is
the
also
first
possible dimension
determined geneity are
is
plant
material
or
as
Table
I shows
how
(a-1
acid
technique.
forms
the
gel
in
affinity
formation
of
the
pH
shift in
the
have
to
immune an
of
of
is
each
and
component
The
in
there
reason
between
the
fractions
for the
preparation of
concentrations
is
microhetero-
Amazingly
differences
by
pro-
non-homogeneof
divalent
ca-
of
the
a
change
in
is
of
orosomucoid
an
in
strong
phoretic
shi ft.
be
added
to
the
first
first
methyl
antibody-con-
the
dimension
(1,
2o). we
dimen-
glycoprotein
the
specifically
precipitate
or
by
1ectin-binding
precipitate
crossed
affinity
in
the
protein gel
For
prior
release
have
used
from to of
1.5-3o
%
a-D-g1ucopyranoside.
lectins
a lectin
uniformly have
a low
(the
of
the may
glycoproteins. by
in
compared
a gel
veloin
dimension
at
the The
most
pH
8.6
common
interactions the
Higher
and
expressed
first
with
column.
chromatography
in
mobility
Immunoelectrophoresis)
gel
is
migration
electrophoresis
chromatography
binding
and
e1ectrophoretic
distributed
most
retardation
in
the
dimension
electrophoresis
sults
must
measured
a glycoprotein
first
Since
tions
of
release
affinity
between
the
been
forms
Affinity
lectin
the
technique). (the
used.
microheterogeneity
displacer
in
degree
during
which
the
a-D-mannopyra noside
affinity
city
inconsistent
order
the
Determination
by
in
different
precipitate
glycoproteins
The
of
detected
preparations.
lie
quantification
a specific
methyl
of
lectin
extraction
glycoprotein)
precise
taining
amount
forms
manganese.
sion
the
for
The
the
may
microheterogeneity
number
between
giving
by
The
upon
but
used
possibly
lectins,
For
technique.
depends
clear,
tions
quantify
planimetry.
differences
not
cedures, ous
by
forms
great
this
to
interacaffinity
a large
re-
electro-
136 Mathematically, ticular
ligand
the can
relative
be e x p r e s s e d
ents
by
of p r o t e i n s
the
for
retardation
a
par-
coeffici-
^ y2- - i r
R = where
1
(13).
and
r
mension
1
are
o
the
retardation
experiment
is p r e s e n t ,
according
to
ligand
their
differences
the
needs
may
listing
charge
to be p e r f o r m e d
of
with
from an
a
excess
glycoproteins
is i n d e p e n d e n t resulting
densities
method
di-
respectively
where
influences
this
first
be c a l c u l a t e d
coefficient
weights, of
ligand
of a g r o u p
assuming
advantage
in the
In c o n d i t i o n s
retardation
in m o l e c u l a r The
and without
ligand.
concentration,
disregarded. periment
with
distances
coefficient
with
of l i g a n d
{1}
m i qy r a t i o n
electrophoresis
The
single
the
affinity
is
lectin
that
etc. only
of
from can
be
one
ex-
in
the
incorporated
gel. With
several
tion
can
in t h e the
be
first
load
equilibrium tions
calculated (35)
gration
The
5o ng with
concentration
retardation
provided
to
conditions
between
as
the
there
per
retarda-
of
lectin
is i n d e p e n d e n t
is s u r p l u s
analysis
the n o r m a l l y
which
is a s i m p l e
velocity
K is the
in c o m p l e x ,
and
of
the
=
I T mo
constant
relation
did
used
of
not
lectin.
change
lectin
of the
concentra-
(1
+
from
between
a lectin a
may
be
Takeo-Nakamura
the
relative
mi-
i2>
-T>
constant
sites,
glycoprotein
and
concentration:
concentration
of b i n d i n g
the
protein
lectin
dissociation
c is the
concentration mobilily
a retarded
dissociation
TT" mi
where
gel.
amount
of up
concentration-dependent
increasing
(7) .
affinity
plot
the
using
dimension
glycoprotein
A protein
The
experiments, examined
of t h e
of l e c t i n
the
without
lectin
'normality', lectin,
glycoprote-
expressed RmQ
is
R , is t h e
as
the
the mobi-
137 lity
of
the
glycoprotein
mobility
of
internal
standard
albumin The on
or
the
the
lectin such
the
presence
as
plot
complex
component
is
ways
with
met
ferable
using to
involved the
the
difficulty
have
an
kidney
free
of
and in
on
this
non-linear
in
information
determination
of
the
it
is
pre-
of
con
e£
is
al-
pre-
effort
eliminates bound were
lectin. found
plots
(35)
A were
general
dissociation
met
but
the
and
lectins
is
often
saves
glycoprotein
with
an
situati-
not
Takeo-Nakamura
with
complex
is
it
amount
free
the
lectins,
lectins
exact
the
to
albumin,
to
which as
because
and
complex
glycoproteins
Based
the
is
components
However,
immobilized
glycoproteins
p h o s p h o r y 1 ase
trophoretic
lectins.
estimating
between
ligands
Rmc
relation
confined
interacting
lectins
the
e i g e n m o b i 1 ity
serum
(15).
with
preparing
and
in
orosomucoid.
a condition
macrorno 1 e c u 1 ar
immobilized
work
in
Complexes
man
free
lectin
of
implicitly
between
1 e c t r o p h o r e t i c a 11 y i m m o b i l e , priori
of
complex
bromphen o1b1ue-marked
non-reacting
Takeo-Nakamura where
in
glycoprotein
to
for
and
hu-
described
equation
constants
for was
elecde-
rived: 1 - R .
R mo where taken are
is in
as
the
those
(lectin
mo
mobility
used
line
of
the
in
equation
concentration)
^
is
the
(R
the
intercept
on
the
c-"*" i s
The
slope
where
the
of
{2}.
1 - R
R mo
This
(the
{ 3 }
mc
A glycoprotein
standard
the
line
mo
gives the
con
mobility
the
plotted
- R
complex
other
equation
symbols
represents
a
mc
mo
K - R
dissociation
the
is
(R m o (R
mo
-
R m i. ) ^ . R
mc
) ^
and
mc
A glycoprotein of
aqainst
J-"*" a x i s
-K-^.
is R
equation
1 c
when
on
The
con
internal
intercept
mobility
. mc
the
to
The
of
K - R
R
mi
relation
straight
"
con
constant complex.
A glycoprotein
K as In
the
well
as
simple
complex
is
the case
zero
138 (Rmc
= 0),
on of
equation
ligand
Subsequently, f i e d by
the
Horejsi
A prerequisite stant the
is t h a t
gel
with cause tes
the
the
exact
to
allow
.Chromatography A correlation nique
and
there
were
suggested
of
ligands
was
the
affinity
relation
was
milarly
between
veri-
the d i s s o c i a t i o n is not
con-
influenced
suited
large
for
by
work
complexes,
Prediction
found
When
the
be-
aggrega-
of
Affinity
for
affinity
chromatography,
strength,
prediction
the
by
by
three
various and were
above,
not we
of
and
gel
tech-
even
though
temperature
experiments results (13,
of 27).
A fractions
A
of
c o n A in
the
with
A
con
were correcoralpha
first
(4).
chromatography
The
was
si-
Immunoelectrophoresis.
lectins,
we
found
a
correlation
column
affinity
chromatography
bound
strongly
in
predict
use
an a n a l y t i c a l
con with
affinity
affino
glycoproteins
could
pH
experiments
chromatography
separated
with
intermediate
electrophoresis
in the
glycoproteins
as
been
of m a c r o m o l e c u l a r
affinity
separated
study
As m e n t i o n e d
of
forming
in e l e c t r o p h o r e s i s
and
we
has
especially
in t h e
in i o n i c
electrophoresis
trophoresis
lectins.
also
clearly
when
phoresis
column
of A F P
precipitate.
concentraticoncentration.
(22).
complex
chromatographic
(AFP)
gel
In a n o t h e r between
observed
analytical
sponding
forms
The
derivation
is
penetration
to be u s e f u l
dimension
the
gel
{2}.
monomer
(29).
differences
fetoprotein
the
Results
ordinary
Consequently
its
symbols
agarose
• lo7
2
as
determination
mobility
The
pores
and
other
Immunoelectrophoresis
Affino
only
equation
for
equation
calculated
macromolecular
of up
three
be
using
matrix.
free
{3} b e c o m e s
should
were
retarded
binding
interaction prediction
in
on
the
the
line
method
affinity
during
for
the
column
elec-
(27).
Immunoelectropreparation
of
139 Biomedical
Applications
We
the
propose
alternative used
analytical
to
is
when
available
or
in
specific
information
One
step
the
pattern on.
for
and of
This
the
was
ted
major
in
normal
of
five
Qrosomucoid
alpha-1 The
alpha-1
flammation rheumatic the
glycoprotein range
seen
ponents aemia
were
and
severity sponse, of
ins to
of and
with
in
the
disease
generally
proteins
the
disease
the
greatest
to
glycoprotein
highest
carbohydrate
Raynes.
These
of
the
Table
I.
the
each was
in
respon-
be
the
of
pattern
with
acute
phase
outside
a link
acute
that
the com-
septicto
the
phase
re-
in
the
pattern
which
are
the
of
are
after
in-
found
pancreatitis, may
content
forms
(3o).
A non-binding
observed
increases
relates
of
proteins
microheterogeneity Raynes
con
acute
were
=
aseptic
was
pro-
ceru-
associated it
of
orosomucoid
by
concentration
and
There
the
two
and
often
The
size
repor-
phase
(AGP),
pregnancy,
septic
pregnancy
in
the
and
remarkab-
HS-g1ycoprotein
cancer,
and
the
antitrypsin
components
changes
are
acute
surgery.
or
variati-
recently
alpha-1
diagthe
that
the
samples.
for
for
normal
serum
in
spe-
need
has
increased
major
be
establish
their
inflammation
serum
to
conclusion
acute
of
is
the
examined
amounts
may
biological
methodology
and
an
methods.
was
alpha-2
during
that
be
Raynes
metastatic
severe
normal
plasma
variation given
A was
to
proteins,
acid
and
antichymotrypsin
studied show
in
human
serum
chronic and
following
alpha-1
teins
the
in
in
con
wounding,
and
with
circulation.
major
inhibitor
disease
variation
of
= alpha-1
with
surgical
proteins
of
there
these
this
antichymotrypsin,
protease
variation to
by
of
approach
when
diseases
(21)
forms
a study
plasmin,
use
human
approach
amount
cases
offered
in
an
a small
other
serum
constant
teins:
se
of
reported
microheterogeneity ly
methods,
routinely
screening
Immunoelectrophoresis
e1ectrophoretic
only
the
nosis
Affino
preparative
conveniently
cimen
of
the also
five the
pro-
protefastest
a stimulus.
The
orosomucoid
is
of
orosomucoid
140 and
alpha-1
changes
of
lus
which
the
plasma
sylation before The
of
an
sin
has
42)
been
from
of
is
pattern
injury
in
con
of
of
stimurate
the
in
glyco-
antennary
sugars
seen
by
in
compared
by
Raynes
enzymes
(3o)
Raynes
with by
A binding
the
in
subse-
Also
at
the
antichymotryp-
a higher
and
that
the
(3o).
alpha-1
towards
Raynes
whether
from or
the
the
one
changes
whether during
these
blood
con
Wells
et
associated
explanation
may in
be
able
At of
to
A
non-
al.
(41,
with
deduce
carbohydrate
changes
reflect
circulation,
glycoprotein.
any
example
normal of
to
45%
serum
This
in
normalities, as
12
has
A affinity
valuable
alpha
this the
thus
point
a
chan-
microheterothe to
there
clearance reflect
is
no
microheterogeneity
of lead
fetoprotein between
of
has
proportion
32).
con
is
pregnancies
fetal
lower
such
addition
back
by
a
biosynthetic
a change
pancreatitis
change
to
the
reason of
the
glycoproteins.
whereas
of
to
significant
(3o).
explained
acute
of
levels.
alteration
consists
(31,
in
question
eliminate
for
in
glycosylating
reduction
forms,
Another
ly
a
in.synthesis
serum
were
the
found
is
hepatic
plasma
tissue
studied
main
an
to
proteins
function to
of
estrogen
the
lack
HS-g1ycoprotein
result
g1ycosy1 ation
(17).
there
geneity
the
proportion
the
higher The
the
response
attack
in to
responsible into
inflammation
binding With
in
induction
end
or
sequence
the
aIpha-2
a change
secretion
chronic
of
glycoproteins
phase
quent
pattern
causes
changes
acute
ge
a n t i c h y m o t r y p s i n , and the
the been
con to
variants
diagnosing
of
and
33.5
reported
the in
by
fetal
Amniotic
fluid
weeks
pregnancy
A non-reactive to
amniotic
a change serum
fluid
in
across
a
that is
(33). AFP
AFP
(32),
significant-
variants
demonstration
abnormalities
of
form
contain
A non-reactive
fetal
characterized
transudation
15
con
(AFP).
( 2 - 1 o ?£) the
pattern
potentially In
fetal
ab-
compartmentation
exposed
fetal
mem-
141 branes
in t h e p r e s e n c e
of n e u r a l
been
observed
in t h e p a t t e r n
nity
variants
to r e s e m b l e
measurements recently con
of c o n
been
A included
been
found
to
in the
The
affinity
comparison (16, be
24).
of
techniques
fetal
in h e p a t o m a
percentage
of
ra t h a n
fetal
in
C3c
and
LCA sera
have
physiological
role
ses.
as t h e
However,
C3 m o l e c u l e separation we
as w e l l of the
are c u r r e n t l y
procedures analysis
of
of
(36).
and
serum
a shift
has
AFP
A
con
(32,
33).
in a m n i o t i c This than
method the
of the
has
AFP con
and
has
with has
previous
also
lectin
been
used
affinity
A affinity
forms
fetal
sera.
However,
hepatoma
sera,
but
reactive
The
fluid
electrophoresis gel.
affi-
11).
system
among
fluid
reliable
form
is h i g h e r
for
patterns seem the
to LCA
generally
the
in h e p a t o m a
se-
(7). products
been the
complement
as t h e
molecules examining
prior the
third
system
to the
a crossed
of
the
on the
disea-
native
necessitate
specific of con
fac-
patho-
in v a r i o u s
products
usefulness
in a s e r u m
complement
in s t u d i e s
of e p i t o p e s
cleavage
5 shows
C3 m o l e c u l e s
of the
employed
distribution
Fig.
fetal
variants
hepatoma
of s p l i t
C3d,
defects,
affinity
(7,
sera
vary
the
Quantification tor
and
proportion
patterns
of
dimension
simple
electrophoresis
The
similar
affinity
using
first
be m o r e
chromatographic
that
A affinity
performed
tube
of a m n i o t i c
a
measurements A in
these
immunoelectrophoretic
sample
from
a
patient
F i g . 5. C r o s s e d I m m u n o e l e c t r o p h o r e s i s of s e r u m f r o m a p a t i e n t with c o m p l e m e n t a c t i v a t i o n . Anti C3c (lower part) and anti C 3 d ( u p p e r p a r t ) ; c o n A in the f i r s t d i m e n s i o n g e l in b.
142 with
complement
first
dimension
activation
and
gel
precipitation
on
antibody-containing whereas re
the
upper
suggests
acting
with
the
anti
the
lower
the
C3d
con
which
were
sults
are
in
This
C3d
of
in
reacting
addition
reacted
the
in four
differently two
precipitated. of
with
appeared
interaction,
being
figure-
con
forms These
A in
the
re-
direct
Immunoelectrophoresis
described with
e.g.
of
(38,
the
lectins
may
be
molecules, other
principles
as
of
ligands.
potential
hydrophobic
affinity
However, in
been
Immuno-
multitude electropho-
ligands,
metals,
has
a
this
charged
stains,
heparin
in
use
ligands,
dyes,
ligands
ions
used
in
spe-
(11).
As
recent
43). of
heparin
electrophoresis Fig. of
a serum
dimensional
human
serum
a
proteins
in
factor
seen
as
The
proteins
second
gel
B of an
the
the
of
(2o
Using
dimensional
contained
showed
no
system
interaction (anodic
was
is
the
seen
effect
with of
to
that
When
the
antibodies
velocity
shift
added against
mobility.
electrophoretic
Immunoelectrophoresis
it
affi-
been
Immunoelectro-
u/ml)
gel
in
have
antibodies
monospecific
complement
protein
crossed
electrophoretic
increased
which
Heparin H.
plasma
chromatography
results
marked
changed
with
affinity
sample.
gel
the
dimension
was
interaction and
6 shows
first
crossed
no
The
C3d.
ligands
effect
human
gel)
side:
Affinity
has
receptor
cond
upper
form
example
few
(the
anodic
the
lower
molecules
those
In
in
antibodies
antibodies.
from
experiments.
A
The
C3c
immunoprecipitate
utilization
cific
phoresis
A
con
anti
separate
the
Ligands
compared.
no
C3d
to
antibodies as
con
the
anti
used
one
system
The
C3c
be
for
resis
nity
contained
of
pattern.
5 received
and
chapter
years
Fig.
influence
retarded
various
an
of
the
promising
electrophoresis of
in
A can
the
from
quantification
Other
gel con
anti
forms A,
gel
antibodies
gel
molecular with
that
the
of of
heparin
the
total only se-
against heparin
factor
B.
in
migration)
all
143 appeared rose parin when was
in a s h a r p
chromatography. in c r o s s e d analyzed bound
by
tarded
(e.g.
lating
proteins,
Experimental
void
volume
proteins
plasma which
(e.g.
protein
B and
fell
chromatography
Sepharose C4)
showed
into
i.e.
two
A) a n d p r o t e i n s to
the
interaction
Sephawith
III
which
bulk
he-
groups
proteins
antithrombin
relative no
on h e p a r i n
interacting
which and were
of
pregre-
circu-
in e i t h e r
system.
Procedures
following
Our
experimental gel
affinity
factor
The rose
in t h e
By c o n t r a s t
Immunoelectrophoresis
to h e p a r i n
nancy-associated
peak
is a s h o r t
description
procedures
electroimmunoassays
are and
of m a t e r i a l s
essentially the
reader
those
and
methods.
used
is r e f e r r e d
in
aga-
to
F i g . 6. C r o s s e d I m m u n o e l e c t r o p h o r e s i s of s e r u m w i t h a n t i b o dies against serum p r o t e i n s (upper panels) and a n t i b o d i e s a g a i n s t f a c t o r B ( l o w e r p a n e l s ) . H e p a r i n in the f i r s t d i m e n s i o n g e l s m a r k e d H.
144 manuals tion
in e l e c t r o i m m u n o a s s a y s
(8, 9,
lo,
TRIS-barbital 22.4
water
TRIS-barbital 1 part
stock
% agarose
king
bath
ready
for
be
at use
The
solution,
pH 8.6,
tion
solution,
pH 8.6,
4 parts
distilled
(w/v):
1 g agarose,
The g e l C.
again
between of
is b o i l e d
The
gel
after
for
gel.
for
boiling. found
is p e r f o r m e d plate
paper
and
the
wicks
agarose
15 to buffer
(Whatman
employed
the
following
per
wicks
is u s e d :
8 layers
for
the
resis
(2
The
one
bromphenol front second 18
for
the
kept
C, a n d
in it
lectin
first
second
a is
may in
the
C.
vessel 1).
electrophoThe is
connecestablished
Depending
number
of
filter
dimension dimension
on pa-
electrophoelectropho-
V/cm).
first
about
5 layers
(wor-
suitable.
18°
No.
strength V/cm),
di-
0.02:
electroendosmosis
field (10
and
at 4 °
on w a t e r - c o o l e d of
g TRIS,
TRIS-barbital
immobilized
Litex
at a t e m p e r a t u r e
the gel
Low
0.1:
strength
5 minutes
the
resis
instruc-
water.
stored
with
44.3
ionic
100 ml
c a n be
experiments
We h a v e
filter
and
strength
(veronal),
working
apparatus
means
acid
solution,
56°
details
ionic
ml.
electrophoresis
resis
further
to l o o o
advantageous
intermediate
by
stock
solution).
water
for
34).
g 5,5-diethyl-barbituric
stilled
Gel
12,
dimension
electrophoresis
hour,
the
migration
blue
and
serum.
of the
bromphenol
dimension
may
The
blue
is n o r m a l l y
be c h e c k e d
free
albumin
electrophoresis
by
bromphenol
performed
for
a mixture
of
will
in t h e n o r m a l
is p e r f o r m e d
migrate buffer.
overnight
(15
in The to
hours).
Pressing,
washing
precipitated
and
proteins
drying:
It is n e c e s s a r y
in o r d e r
to g e t
low
to
remove
background
non-
staining.
145 This gel
is in
sheet
done
as
order
to
of
sorbant
filter paper
is p l a c e d
nutes
the
0.1 to
for
swell.
be
analyzed, for
5
is
Lectins: they
are
gel
plate.
and
the
gel
for
15 m i n u t e s
plate
may
hot
be
air.
should
be
before
with
then
5
is
The
cold
con-
the
air
in
gel
as
gel
activity
with
mi-
washed
10 m i n u t e s
in
abglass
After
causing
If e n z y m e dried
one
A thick
repeated.
staining
the
of
pressing is
for
over
layers
pressing.
is p r e s s e d
of
activity
gel for
covered many
The
swelling
plate
the
renewed
water
the
gel
is
performed
in
5 g Coomassie
4 5 0 ml
the
450
450
450
to
is and
ml
Coomassie
is
Normally in
aplate is
to
and
Coomassie
Brilliant
We free
ion to
filtered
96%,
1 0 0 ml water.
use
Blue
on
melted
lectins in
an
acid
immunoglobulin
by
salting
anion
agarose
98%
(techni-
may
be
After
rege-
destai-
fraction
from
immunoglobulin out
with
before
ammonium
The
antibo-
casting.
analogously
to
solution
immobilized
or
The
air.
exchanger.
gel
the
use.
hot
The
99%
overnight.
carbon. of
(Hop-
acid
mixing,
destainer
concentrations.
essentially
lectin
acetic
a stream
the
While
left
The
R 250
acetic
before
activated
in
exchange the
treat as
and
cooled
is
Blue
ml
C,
through
we
100
water.
dried
low
purified
added
60°
Brilliant
96%,
distilled
distilled
plate
by
ml
solution
filtration
gel
ethanol
ethanol
antiserum
are
tap
and
heated
day
Antibodies :
fraction
is
5 minutes.
grade),
by
sulfate
paper
the
is
poured
minutes.
grade),
rabbit
on
of
a stream
the
Destaining:
dies
in
placed
paper
solution:
following
the
top
this
& Williams),
nerated
then
on
Staining
for
solution
the
is
Blue.
(technical
ning
1 ) and
enzyme
Staining:
cal
gel
plain
dried
Brilliant
kin
The No.
pressing
then
Staining
well.
(Whatman
another or
is
R 250
fill paper
After
The
stained
water
absorbant
M NaCl
bove.
Distilled
are
plate
tinued
follows:
antibodies, on
whether partic-
146 les.
The
lectins
paration
and
problems
have
of
added
commercial
bility
buffer
trol
to
been
lectins
experiments for
agarose
as
We
an
gel
with
affinity-purified
before
casting.
stability
advise
may
displacer: include
the
be
next
to
(the
water
specific
to
to
test
or
heavy
affinity
cific
displacer
some
pre-
Numerous
and
solubility
the
reproduci-
the
first
totally
or
in
the
and
1.5
an
partially
(over
the
The
A we
to
5%
or in
For
take
the the
have
with
affinity
up
the
inter-
suc-
a-D-glyco-
dissolving
first
or
affini-
used
methyl
gel
the
experigel
electro-
will
gel
bound
con
agarose
overlayered
control
gel.
a-D-mannopyranoside.
been
con-
with
antibody
cathode)
dimension
with
for
washing
the
glycoproteins
containing
electrophore-
lectin
cofactors.
experiments
towards
the
with
repeated
displacer
precipitates, have
by
essential
experiments
gels
methyl
3 times
immobilized
1ectin-containing
into
For
agarose
pyranoside
of
flow
release
precipitate.
cessfully
either
the
displacer gel
produced
For
gel
2 to
Inactive
a specific
endosmosis
mediate
washed
use.
removal
Specific we
are
to
ments
ty
the
used
encountered
preparations.
prior
EDTA-buffer
in
normally
carefully.
Immobilized sis
are
to
3o
dimension
extra spegel
precipitate).
Acknowledgements This
work
Council
was
and
supported
the
Harboe
by
The
Danish
Medical
Research
Foundation.
References
1.
A n d e r s e n , M . M . , H a u , J . , B i a g - H a n s e n , T. C . : In T. C. BiagHansen (ed.) L e c t i n s - B i o 1 o g y , B i o c h e m i s t r y and Clinical B i o c h e m i s t r y . V o l . 2. W . d e G r u y t e r , B e r l i n , p . 7 7 9 (1982).
2.
B a r o n d e s , . S.
3.
B i t t i g e r , H., S c h n e b l i , Wiley, London, (1976).
H.:
Ann.
Rev.
4.
B a y a r d , B . , K e r c k a e r t , J. mun. 95, 7 7 7 - 7 8 4 , (198o).
H.
Biochem., P.:
P.:
5o,
2o7 - 231 , (1981 ) .
Concanavalin Biochem.
A as
Biophys.
a
Tool.
Res.
Com-
147 5.
B j e r r u m , 0. J . : In Protein Chemistry,
H. W.
6.
Bag-Hansen,
Anal.
7.
B o g - H a n s e n , T. C. ( e d . ) L e c t i n s - B i o l o g y , B i o c h e m i s t r y a n d C l i n i c a l B i o c h e m i s t r y . V o l . 1 a n d 2, W . de G r u y t e r , B e r l i n , (1981, 1982).
8.
Bag-Hansen,
T.
9.
Bag-Hansen, I m m u n o l . 4,
T. C . , Suppl.
10.
B a g - H a n s e n , T. C . , B r o g r e n , S u p p l . 2, 1 3 5 - 1 3 9 , ( 1 9 7 5 ) .
C.
11.
B a g - H a n s e n , T. C . , H a u , J . : L i b r a r y , V o l . 18 B , 2 1 9 - 2 5 2
In J o u r n a l (1982).
12.
B a g - H a n s e n , T. C . , L o r e n c - K u b i s , I . , B j e r r u m , 0. J . : In B. J . R a d o l a ( e d . ) E l e c t r o p h o r e s i s ' 7 9 . A d v a n c e d M e t h o d s . B i o c h e m i c a l a n d C l i n i c a l A p p l i c a t i o n s . W. de G r u y t e r , B e r lin, 173-192 ( 198o ) .
13.
Bag-Hansen, M e t h o d s 22,
14.
B o g - H a n s e n , T. C . , S p e n g l e r , G . A . ( e d . ) : Lectins-Biology, B i o c h e m i s t r y a n d C l i n i c a l B i o c h e m i s t r y , V o l . 3, W . d e Gruyter, Berlin (1983).
15.
Bog-Hansen, (198o ) .
16.
B r e b o r o w i c z , J . , B a g - H a n s e n , T. C . : In T. C. B a g - H a n s e n (ed.) L e c t i n s - B i o l o g y , B i o c h e m i s t r y and Clinical Biochem i s t r y , V o l . 2, W. d e G r u y t e r , B e r l i n , 4 4 5 - 4 5 6 (1982).
17.
B o w e n , M . : In T. C. B a g - H a n s e n ( e d . ) L e c t i n s - B i o l o g y , Bioc h e m i s t r y , C l i n i c a l B i o c h e m i s t r y , V o l . 2, W . d e G r u y t e r , Berlin, 4o3-411, (1982).
18.
B r o g r e n , C. H . , B i s a t t i , S . : In T. C. B a g - H a n s e n (ed.) L e c t i n s - B i o l o g y , B i o c h e m i s t r y and Clinical Biochemistry. V o l . 1, W. de G r u y t e r , B e r l i n , 3 7 5 - 3 8 6 , (1981).
19.
Dulaney,
T.
C.:
C.:
Tschesche (ed.) Modern M e t h o d s de G r u y t e r , B e r l i n (1983). Biochem.
Scand.
J.
J.
T.:
C.,
48o-488
Immunol.
Suppl.
B j e r r u m , 0. J . , R a m l a u , 2, 1 4 1 - 1 4 7 , ( 1 9 7 5 ) .
T. C . , P r a h l , P . , 2 9 3 - 3 o 7 , ( 1 9 7 8 ).
T.
56,
Takeo,
Mol.
Cell.
K.:
H.:
Scand. of
(1973).
lo.
J.: J.
press)
Scand.
J.
Immunol.
4,
H.:
Electrophoresis
21,
(In
Chromatography
Lawenstein,
Biochem.,
in
43-62
J.
1,
Immunol.
67-71,
(1979).
2o . F a y e , L . , S a l i e r , J . P . : In T. C. B a g - H a n s e n ( e d . ) L e c t i n s B i o l o g y , B i o c h e m i s t r y a n d C l i n i c a l B i o c h e m i s t r y . V o l . 2, W. de G r u y t e r , B e r l i n , p. 6 o 5 , ( 1 9 8 2 ) . 21.
Hinnérfeldt, D. S t a t a c h o s lin (1983).
F., A l b r e c h t s e n , J., B a g - H a n s e n , ( e d . ) E l e c t r o p h o r e s i s '82, W. de
22.
Horejsi,
V.:
J.
23.
Horejsi, (1979).
V.,
Ticha,
24.
Kerckaert, phys. Acta
Chromatography M.,
178,
Kocourek,
1-13,
J.:
J. P., B a y a r d , B . , B i s e r t e , 576, 99-loB, (1979).
TIBS G.:
T. C . : In G r u y t e r , Ber-ì
(1979b). 4,
1,
N6-N7,
Biochim.
Bio-
148 25 .
Krall, J., (1975) .
Andersen,
26 . N a k a m u r a , S . : Applications. (1966) . 27 .
Cross Igaku
M.
M.:
J.
Electrophoresis. Shoin, Tokyo and
29.
P l u z e k , K. : In T. L e v r i n g S y m p o s i u m . 7 1 1 - 7 1 8 , W. d e
30 .
R a y n e s , J. : B i o m e d i c i n e
Ruoslahti , E 31 . J . C a n c e r 22 S m i t h , C. J . 32 . 1 - 3 2 , ( 1 9 8 o )
34.
Methods
9,
141-146,
Its P r i n c i p l e and Elsevier, Amsterdam,
N i l s s o n , M . , B a g - H a n s e n , T. C . : In H . P e e t e r s ( e d . ) P r o t i d e s of the B i o l o g i c a l E l u i d s , P r o c e e d i n g s of the X X V I I C o l l o q u i m , Vol. 27, P e r g a m o n P r e s s , O x f o r d , (1979).
28 . P i a t t , H. S . , S e w e l l , B. M . , Clin. Chim. Acta 46, 419-429
33 .
Immunol.
S m i t h , C. J . Brit. Med. J
Eeldman, (1973).
T.
Souhami , R . L . :
(ed.) Xth I n t e r n a t i o n a l Seaweed Gruyter, Berlin, (1981).
36,
77-86
(1982).
, E n g v a l l , E. P e k k a l a , 515-520 , (1978 ) . C.:
Kelleher.
A.,
Seppälä,
M.:
Int,
Biochem,
Biophys.
Acta
6o5,
K e l l e h e r , P . C . , B e l a n g e r , L. , D a l l a i r e , L. : 1, 9 2 0 - 9 2 1 , (1979).
S v e n d s e n , P. J . : In D e y l , Z . , E v e r a e r t s E. M . , P r u s i k , Z., S v e n d s e n , P. J. ( e d s . ) , Electrophoresis A S u r v e y of T e c h n i q u e s a n d A p p l i c a t i o n s , P a r t A : T e c h n i q u e s . J. C h r o m a t . L i b r a r y , V o l . 18 A , E l s e v i e r S c i e n t i f i c P u b l i s h i n g C o . , A m s t e r d a m , 13 3 - 1 5 4 , ( 1 9 7 9 ) .
33 .
Takeo, K., (1972).
36 .
Teisner, B., Hau, Svehag , S.-E.:(To
Nakamura,
S.:
Arch.
Biochem.
J., B r a n d s l u n d , be p u b l i s h e d ) .
I.,
Biophys.
Bag-Hansen,
37 . T e i s n e r , B . , B r a n d s l u n d , I . , H a u , J . , S v e h a g , P a t h . M i c r o b i o l . I m m u n o l . S c a n d . (In p r e s s ) . 38 . T e i s n e r , A c t a (In
B., Davey, press).
39.
Tobiska, (1964).
J.:
40 .
Turkova, J.: A f f i n i t y Library (1978).
41 .
W e l l s , C . , C o o p e r , E . ( G l a s s , R. M . , Clin. Chem. Acta lo9, 59, (1981).
Die
M.
W.,
Grudzinskas,
Phytohamagg1utine.
J.
G.:
1-7 ,
153,
T. C . ,
S.-E, Clin.
Acta Chim.
Akademie-Ver1ag-Ber1in,
Chromatography.
J.
Chromatography
Bag-Hansen.
T.
C.:
4 2 . W e l l s , C . , C o o p e r , E . , B a g - H a n s e n , T. C . : In T. C . B a g Hansen (ed.) L e c t i n s - B i o 1 o g y , Biochemistry and Clinical B i o c h e m i s t r y . V o l . 1. W. de G r u y t e r , B e r l i n , 3 3 9 - 3 4 6 (1981). 43 . W e s t e r g a a r d , G.: P l a c e n t a
J. G . , (1983)
Teisner, H a u , 3., (In p r e s s ) .
B .
Grudzinskas,
J.
PRINCIPLES AND APPLICATIONS OF HETEROGENEOUS ENZYME IMMUNOASSAYS
Gerd Grenner Research Laboratories, Behringwerke AG D-3550 Marburg
Introduction The l a b e l l i n g of antigens and antibodies with radioactive substances in s e n s i t i v e immunoassays has been the method of choice for many years. In 1971, two research groups (1, 2) independently described immunoassays following conventional separation techniques but using enzymes f o r l a b e l l i n g instead of radioactive isotopes (heterogeneous enzyme immunoa s s a y s ) . One year l a t e r an enzyme immunoassay not requiring a separation step (3) was reported (homogeneous enzyme immunoassay). The heterogeneous ®
method has been called ELISA (enzyme-linked immunosorbent a s s a y ) . EMIT (enzyme multiplied immunoassay technique) i s used f o r homogeneous procedures. Enzyme immunoassay has been extensively reviewed (4-8). The f i r s t part of t h i s paper deals with the p r i n c i p l e s of heterogeneous enzyme immunoassays with special reference to protein determinations. In a second part some developments of ELISAs f o r protein determinations from our own laboratory are described.
Assay p r i n c i p l e s D i f f e r e n t assay types f o r the determination of antigens and antibodies have been developed. The main p r i n c i p l e s for antigen assays are shown in f i g . 1.
Modern Methods in Protein Chemistry - Review Articles © 1983 by Walter de Gruyter & Co. - Berlin • New York
150 Competitive enzyme immunoassay
O.D.
O - E
o
antigen concentration
Immuno enzymometrlcal assay
-o
O > E
Sandwich assay •P k
o
>
E
= solid phase F i g u r e 1:
0 =
A s s a y principles
antigen
for antigen
- Q = antibody
E = enzyme
determinations
In t h e c o m p e t i t i v e type the enzyme-label led a n t i g e n competes w i t h the sample antigen for the binding sites of a n t i b o d i e s bound to a solid (9). A f t e r phase s e p a r a t i o n
the free or the bound phase is d e t e r m i n e d . T h e e n z y m e activity is proportional
phase
(see b e l o w ) the e n z y m a t i c a c t i v i t y in e i t h e r
to t h e s a m p l e a n t i g e n
inversely
concentration.
T h e sample antigen inhibits the binding of an e n z y m e - l a b e l l e d a n t i b o d y to a s o l i d - p h a s e bound a n t i g e n in the i m m u n o e n z y m o m e t r i c t i t i v e and a sequential
procedure is
assay
(10). A c o m p e -
possible.
The s a n d w i c h assay is r e s t r i c t e d to antigens w i t h h i g h e r m o l e c u l a r
weight,
s i n c e it requires antigens b e a r i n g at least two b i n d i n g sites for antibody. T h e sample a n t i g e n is reacted w i t h excess s o l i d - p h a s e a n t i b o d i e s .
After
s e p a r a t i o n , e n z y m e - l a b e l l e d a n t i b o d i e s are added to c o m b i n e w i t h the remaining antigenic determinants
(11). T h e o n e - s t e p v e r s i o n o f the
assay is c h a r a c t e r i z e d by the s i m u l t a n e o u s
reaction of the sample
sandwich antigen
w i t h the s o l i d - p h a s e and the labelled a n t i b o d y . This assay t y p e is m a i n l y a p p l i c a t e d w h e n monoclonal
a n t i b o d i e s a r e used
(12).
151 Phase separation A f t e r completion of the immunochemical reaction steps a separation of the immune complexes from the excess reagents i s required. Most of the c l a s s i cal methods of phase separation employed in radioimmunoassays, e.g. precip i t a t i o n by s a l t , a l c o h o l , polyethylene g l y c o l , second antibody etc. were found to be inconvenient in enzyme immunoassay due to problems with determination of enzyme a c t i v i t y in sediments. Therefore solid-phase matrices are most commonly used f o r separation (8). In table 1 some solid-phase materials are l i s t e d . Table 1:
Solid-phase matrices for phase separation
Material
Immobilisation of antigen
Separation by
Cel 1 ulose Agarose Latex
covalent linkage (e.g. BrCN a c t i v a t i o n )
centrifugation
magnetic f i e l d
magnetic p a r t i c l e s p l a s t i c tubes, bead, d i s c s (polystyrene, PVC, s i l i c o n rubber)
physical
paper d i s c s
covalent linkage
adsorption
décantation or aspiration
Antigens and antibodies can e a s i l y becovalentlylinked to c e l l u l o s e , agarose or latex p a r t i c l e s but c e n t r i f u g a t i o n steps and long washing cycles are required. The separation of magnetic p a r t i c l e s i s quite simple but f o r complete separation washing i s also necessary. Most widely used i s the physical adsorption of antigens and antibodies to p l a s t i c materials (tubes, m i c r o t i t e r p l a t e s , macro beads e t c . ) , mainly made from polystyrene (8). Phase separation i s achieved by simple decantation or a s p i r a t i o n . Because of the plane surface washing i s not complicated by d i f f u s i o n problems. Very e f f i c i e n t phase separation i s possible by adding and d i r e c t l y a s p i r a t i n g a s u i t a b l e washing s o l u t i o n containing a detergent.
152
The mechanism of adsorption of proteins to p l a s t i c surfaces i s not complet e l y understood. Both electronic charge differences between p l a s t i c s u r face and protein and hydrophobic i n t e r a c t i o n s may be responsible f o r the binding. Therefore d i f f e r e n t proteins do not bind with the same efficiency to the same s o l i d phase. The binding i s not t o t a l l y i r r e v e r s i b l e (13) but f o r most a p p l i c a t i o n s the release of proteins from the s o l i d phase during the incubations can be neglected. No general rules e x i s t for highly e f f i c i e n t and reproducible coating. Good solid-phase bio-reactants r e s u l t in most cases from a time consuming t r i a l and error process. Polystyrene m i c r o t i t e r p l a t e s and beads e s p e c i a l l y made f o r ELISA a p p l i c a t i o n s are a v a i l a b l e from d i f f e r e n t manufacturers.
Marker enzymes Enzymes for l a b e l l i n g in enzyme immunoassays must f u l l f i l l the following c r i t e r i a : As the enzyme i s used as an amplifier only those with very high s p e c i f i c a c t i v i t y can be used. Simple and reproducible procedures for the covalent coupling to antigens or antibodies must be p o s s i b l e . Another requirement i s an excellent s t a b i l i t y of the enzymatic a c t i v i t y during the assay procedure and during storage of the reagent. The enzyme of choice should be absent in the t e s t sample and should not be influenced in i t s a c t i v i t y by sample components. In
heterogeneous enzyme immunoassays horse-radish peroxidase
(E.C.
1.11.1.7), a l k a l i n e phosphatase (E.C. 3 . 1 . 3 . 1 ) , 6-galactosidase (E.C. 3.2.1.23) and glucose oxidase (E.C. 1.1.3.4) are most often used (8). No one enzyme i s i d e a l l y s u i t e d , the choice depending on the requirements of an p a r t i c u l a r assay, e.g. high s e n s i t i v i t y , stable s u b s t r a t e , simple l i n k i n g procedure etc.
153
Conjugates Conjugates are obtained by covalent linkage of the antigen or the antibody to the marker enzyme. The ideal conjugation procedure does not reduce the biological a c t i v i t i e s
(enzymatic a c t i v i t y and immunoreactivity) and has a
high y i e l d of a very stable product. No c r o s s - l i n k i n g between the same proteins (enzyme-enzyme conjugates) should occur. The reaction should be s t o i c h i m e t r i c a l and give conjugates of small s i z e (no polymerisation). None of the e x i s t i n g methods can achieve a l l these c r i t e r i a .
G1utaraldehyde method G1utaraldehyde has been widely a c r o s s - l i n k e r of proteins. In the one-step method (14) enzyme and antigen or antibody are mixed and glutaraldehyde i s added. Conjugates have very high molecular weight and are heterogeneous. Extensive homopolymerisation of the antibody has been described in the case of peroxidase-antibody conjugates (15). Immunoreactivity i s considerably diminished. Despite these drawbacks the method has been very often used because of i t s
simplicity.
The two-step method i s limited to peroxidase-conjugates
(15). Peroxidase i s
reacted with an excess of the aldehyde, the unreacted aldehyde i s removed by gel f i l t r a t i o n and the activated enzyme i s added to the protein to produce the conjugate. Homogeneous populations of conjugates are obtainable, but with low y i e l d .
Periodate method (16) The carbohydrate moiety of peroxidase can be oxidized to aldehyde groups. F i g . 2 shows the procedure in d e t a i l . After blocking the small number of free amino groups and p a r t i a l oxidation of the carbohydrates, the excess of reagents i s removed by d i a l y s i s or gel f i l t r a t i o n . The activated peroxidase i s then reacted with the protein followed by borohydride reduction of the S c h i f f bases. The method has a high y i e l d and the b i o l o g i c a l
154 NO 2
/' "V-NH—/ V - N02
( POD )
Figure 2:
\==/
Periodate method
activities are sufficiently retained. The degree of polymerization can be controlled by the concentration of periodate and the conditions
(pH, dura-
tion) of the coupling step. Glucose oxidase can be coupled using the same procedure
(17).
Diamaleimide
procedure
N,N'-0-phenylendimaleimide
has been used in a one-step procedure to couple
[3-galactosidase to proteins via the sulfhydryl and the protein
(18). In a two-step method
groups of both the enzyme
m-maleimidobenzoyl-N-hydroxy-
succinimidate acetylates the free aminogroups of the protein, the maleimide function is then reacted with sulfhydryl
groups of the enzyme.
N-Succinimidyl-3(2-pyridylthio)propionate method
In this two-step method (fig. 3)
(19)
N-succinimidyl-3(2-pyridylthio)propionate
(SPDP) is reacted firstly with free aminogroups of the protein. In the
155
Figure 3:
N-succinimidyl-3(2-pyridylthio)propionate
procedure
second step the activated d i s u l f i d e groups reacts with the s u l f h y d r y l groups of the enzyme to form a s t a b l e d i s u l f i d e bridge. The reagent can be used to introduce SH-groups to antigens and enzymes.
P u r i f i c a t i o n of conjugates P u r i f i c a t i o n of conjugates has been achieved by gel f i l t r a t i o n (14), ion exchange chromatography ( 2 0 ) , density gradient c e n t r i f u g a t i o n (21) and a f f i n i t y chromatography (22). In the case of antibody-enzyme conjugates simple gel f i l t r a t i o n i s s u f f i c i e n t , although the p u r i f i e d conjugate may contain free antibody. P u r i f i c a t i o n of antigen-enzyme conjugates i s
inmost
cases morecomplicated, i f high immunoreactivity i s necessary. The coupling procedure may have dramatic effects on the r e a c t i v i t y of antigens, e.g. i f the linkage i s via a functional group at or near to an antigenic determinant.
156 Applications Heterogeneous enzyme immunoassays have been described f o r the detection and quantitation of numerous parameters during the l a s t ten years. In the f o l lowing some appl i c a t i o n s for the determinations of c l i n i c a l l y relevant prot e i n s are described.
Alpha-fetoprotein
(AFP)
A1 pha-fetoprotein, a glycoprotein with a molecular weight of 70,000 Dalton, i s synthesized in the yolk sac and in the fetal l i v e r (23). Being a fetal protein i t proved useful in monitoring pregnancy, e s p e c i a l l y in screening for neural tube defects (24). Diagnosis and follow-up of l i v e r carcinoma i s another use for AFP determination (25). Both a p p l i c a t i o n s require very s e n s i t i v e assays which must be able to measure l e s s
than
10 pg/1. To achieve t h i s requirement, we selected the sandwich assay p r i n c i p l e for the development of an enzyme immunoassay (26). Fig. 4 shows the procedure in d e t a i l . 2 ml-polystyrene tubes are used for s o l i d - p h a s e , coated with antibodies s p e c i f i c f o r AFP. The sample (serum or plasma) i s d i l u t e d 1+ 10. After reaching the equilibrium of the f i r s t r e a c t i o n , the tube i s emptied by a s p i r a t i o n of the sample and then f i l l e d with phosphate-buffered saline, followed by immediate a s p i r a t i o n . This washing process i s repeated. This separation step i s necessary to remove excess, unbound antigen otherwise would react with the antibody in the conjugate preventing a reaction with the solid-phase bound antigen. This would r e s u l t in a low s i g n a l at very high concentrations of the analyte ("high-dose hook e f f e c t " ) (27). The addition of the conjugate i s followed by a s u f f i c i e n t incubation time and the second washing. This second phase separation i s c r i t i c a l , as a l l remaining excess conjugates molecules w i l l contribute to the solid-phase enzyme a c t i v i t y g i v i n g f a l s e l y elevated r e s u l t s of the antigen concent r a t i o n . The chromogen/substrate s o l u t i o n i s incubated for 30 min. Diluted acid i s then added to stop the reaction by destroying the enzymatic a c t i v i t y . The colour i n t e n s i t y of the s o l u t i o n i s measured in a photometer.
157 solid-phase antibodies (anti-AFP from sheep)
antibodies peroxidaseconjugate (anti-AFP from rabbit)
anti gen (AFP)
—
€
V . pipette incubate diluted sample* wash
substrate (o-phenylendiaminedihydrochloride, H2O2)
incubate wash 3*2 ml
200 pi
oo o o o oo
«»ti
oo o o o oo
€*|
pipette substrate/ chromogen
incubate
pipette stopping solution
photometry
200 pi
1/2"
1000 pi
492 nm
•diluted 1:10 with incubation medium
Figure 4:
Assay procedure of the enzyme immunoassay f o r AFP determination
F i g . 5 shows a typical c a l i b r a t i o n curve for the AFP assay. As in most immunoassays the nonlinear r e l a t i o n s h i p between antigen concentration and s i g n a l necessiates the use of a multipoint c a l i b r a t i o n . We use f i v e d i f f e r e n t c a l i b r a t o r concentrations to cover a range from 3 to 300 IU/ml (1 IU AFP i s approx. 1.6 ng).
2,0- A/.92r
1.0-
0,3-
0,1-
0.03-
-1— 10
—r30
AFP
Figure 5:
C a l i b r a t i o n curve of the AFP enzyme immunoassay
100
300
C o n c e n t r a t i o n (I.U./ml)
158 Lower concentrations can be measured d i l u t i n g the sample 1 + 1 . In t h i s case we determined a detection l i m i t of 0.4 Mg/1- The assay has a good precision. Intraassay c o e f f i c i e n t of v a r i a t i o n i s in the range of 4 - 6 %, and day to day c o e f f i c i e n t s of v a r i a t i o n are between 6 and 10 % (26).
Pancreatic
lipase
Pancreatic l i p a s e ( t r i a c y l g l y c e r o l l i p a s e , E.C. 3 . 1 . 1 . 3 ) i s an important marker in pancreatic d i s e a s e s . The glycoprotein has a molecular weight of 46,000 to 48,000 Dalton (28). The routine methods in the c l i n i c a l
labora-
tory measure i t s enzymatic a c t i v i t y . To overcome the problems of low s p e c i f i c i t y or low s e n s i t i v i t y of most of these methods, we developed a procedure measuring the protein concentration of the enzyme immunochemically
(29).
This enzyme immunoassay follows exactly the same protocol as the AFP t e s t . The measuring range i s 3 to 300 pg/l- Results from c l i n i c a l samples i n d i cate the usefulness of the assay in the diagnosis and monitoring of chronic
pancreatitis.
B2"microglobulin Determinations of B^-microglobulin, a protein with a molecular weight of 11,800 Dalton, are requested in kidney diseases and can be useful in the monitoring of some tumours (30). The c l i n i c a l l y relevant concentration range from 1 to 25 mg/1 would require an extremely high d i l u t i o n
(e.g.
1 + 1000) of the sample for a sandwich assay procedure. Therefore we decided to apply a competitive procedure ( f i g . 6). P u r i f i e d ^ - m i c r o g l o b u l i n conjugated to peroxidase i s used. Diluted sample (e.g. 1 +25 for serum samples) and antigen-enzyme conjugate are incubated in an antibody-coated p l a s t i c tube. After a 2 h incubation and a s i n g l e washing step, the solid-phase linked enzyme a c t i v i t y i s determined as in the other assays.
159 o OIo
f<
H fl) >H r-H
u
in IN
oo
r-v o O Osi o o o o o o o S) N ^ ^ CVi
+ + +
o o
co
n T—
n
o
O
o
• 0) c •H IH 3 C •H z 1—1 LU 1— o Di
CL
c •H E 3 -Q i—1
+-> 00 IO i—i — ta "Cl E o c to c c O o s- ai a; •— I IO a) •E i ai 00 s_ IO IO -O uo o c o . +-> +-> ai c ai un o "O sz a; ai S• to 0) ai +-> 3 +-> en .—t s- c c CT" O—i 1 0) • r-4 >, ai Í - ta LL. CO 3 E 00 00 cx en 4O SO 00
00
00
o t= aj • í - •rt c .—. +-I O m e o +-> —i > o S - CM C a . . to C • I—( CTIi—1 -CT 4- ai LL. co o +-> to c • t/l C : - H cn • I—to • .—! t/1 •^H 0 0 L I S-.+-I
UJ cj
);
m/e
no 120
indicates Phe at the amino end of the peptide chain and this is confirmed by the ion m/e 796 (3)
Interpretation:
( =
943-147(Phe)).
a) W i t h the a s s u m p t i o n
Phe
amino end of the peptide one can establish the with h e l p of ACO ions: Phe = 148 ( ^ 9 9 ) , Phe-Val-Pro = 344
457
(A 113), P h e - V a l - P r o - I l e - P h e = 604
(a97),
ions AA, AlkC, AC and
the above sequence. Signals m/e ( = 340 -101
sequence
Phe-Val-Pro-Ile
722
=
(A 147).
ACO
for
the
sequence - ions m/e 796, 697, 487, 474 and 621 [Thr]) and m/e 239
the
(not found), Phe-Val =
247
Calculating
at
(
=
above confirm
621
+
101
[Thr]) allow to add Thr
to the sequence. The sequence at the c a r b o x y l e n d of the peptide chain - T y r , G l y - remains (4)
unclear.
The FAB-MS of this neutral peptide shows some ACO
ions,
and ions of type AA and AC but no ion of type AlkC.
128
y r —- - Ala — -H 2 N -—T Tyr Q b
(181)
c d
(164) 1 136
- - Leu —- OH Gly —- - Phe — 309
(252)
(456)
¡392:
(321
(264)
(117)
407
336
279
132
235 1 207
292
439 1 411
MG 569 M - H 570
552
H2N — A l a - - Tyr - - Gly — P Phe h e — Leu —•OH MG569 a ]89) (252) 309 (256) M+H 570 1454) (321; b (264) (117) c (499) 336 279 132 d
(72)
235
I
207
292
439
I
411
552
353 Example 4 (1)
A m i n o acid a n a l y s i s : A l a , G l y , Leu, P h e , T y r , MG
(2)
I n s p e c t i o n of the m a s s s p e c t r u m : M + H 570; and 107 p r o v e the p r e s e n c e of Phe 86), Phe
(m/e 120) and Tyr
on the amino
(3)
and
(m/e acids
end of the p e p t i d e . D i f f e r e n c e s
411, 336 — >
the p r e s e n c e of ACO and AI
308, 235 — >
Interpretation:
In
several
for
candidates
this
207,
the
205
to
increments
of
has
of
the
peptide
construct
the
peptide
M+H
570
allows
to
all
amino
552.
Now
acids
present
f r a g m e n t 439 = 5 5 2 - 1 1 3
(Leu/Ile)
e s t a b l i s h e s Leu to
at
of
peptide;
the
carboxylside
increments not
(57-Gly, 7 1 - A l a , 147-Phe
verified
Proceeding
the
in
sequence
by
fragments
the
same
in
way
for
all are
mass
can
possible no
good
Ala-Tyr-Gly-Phe-Leu,
sequence
spectrum.
one
the the
the amino
masses
finds
Tyr-Ala-Gly-Phe-Leu.
arguments because
are
establish
Calculating
fragmentations
the
against
the
end.
good But
sequence
ion m/e 136 c a n n o t
t a k e n as a proof for Tyr at the amino
be
other
163-Tyr)
G l y - P h e - L e u . The s e q u e n c e of
a g r e e m e n t w i t h the there
the
and
the
one
end A l a , Tyr r e m a i n s u n c l e a r .
28
177)
one
the h e a v i e s t ACO ion to 570 - 18 =
the
^
—>
where
aminoend
it seems a d v a n t a g e o u s
of
ions.
situation
b e g i n n i n g w i t h the c a r b o x y l g r o u p . testing
91
Leu
(439 — >
calculate
Tyr.
m/e
(m/e 136) may be amino
indicate
chain
ions
569
be
354 1 1 2 1 20
h2n — Arg - - Pro - -Pro -- Gly - - Phe --Sér- -Pro 174
Q b c d
-- Phe -- Arg -
X25> S7? iés?) 903 421 — 3Q7 ¿z. ¿35 m 160 827 710 653 sai (5061 419 322 175 1157) 1254) (3511 14061 15551 1642] (739) 18661 11042) I I t 1 858 1014 MG 1059
—
ja
M. H 1060
167 ] 30
1 0-
1060 1 061
1 062
1 058 1000 90-4 960
800 2 0 -NO V - S 1 1 6 : 5 8
BRRDYKIN1N
850
950
g 7 3
ggg
1 0 1 5
1000
355 Example
5
B r a d i k i n i n ; this w a s one of the first
studied with (1)
Amino acid analysis: A r g 2 , G l y , P r o 3 , P h e 2 , S e r
(2)
I n s p e c t i o n of the mass s p e c t r u m : two p a i r s of s i g n a l s w i t h a observed,
t h e r e f o r e one
has
no
Only ACO
remember
indicating
AC
the p r e s e n c e
that a m i n o - a m i d
the c a r b o x y l s i d e
and
of
three
ions
1059. Only
A
of
chance
s e q u e n c e w i t h h e l p of ACO ions. A 15
MG
M + H 1060.
difference
with
Concerning
to
a
28
are
find
the
few
dubletts
ions
are
found.
prolin
one
should
(AA) are not p o s s i b l e
and A l k y l - c a r b o x y l - i o n s
not
p o s s i b l e on the a m i n o s i d e of p r o l i n ; also m i g r a t i o n
of
ion is
sometimes
F r a g m e n t m/e 120 c o u l d be r e s p o n s i b l e amino
end but all c a l c u l a t i o n s
acid met with
not
for
Phe
found. at
s t a r t i n g w i t h this
the amino
failure.
Interpretation:
A favourable
s e q u e n c e may be c o m p a r i n g acids
(AlkC)
on
are
a p r o t o n to the f r a g m e n t
(3)
peptides
FAB-MS.
present
in
the
s e a r c h for the
integral peptide
peptide
i n c r e m e n t s of with
amino
differences
p r o m i n e n t p e a k s of the m a s s s p e c t r u m s t a r t i n g w i t h molecular
ion: 1060 - 1043 = 17
(OH?)
(result n e g . ) , 1060 - 995 = 101
(Thr,
acid
is m i s s i n g
(Pro), 710 - 653 = 57
(Pro),
807
(Gly). This r e s u l t .... or
=
61
amino 155
-
847
=
58
-
710
=
97
inciates
the
Gly-Pro-Pro-Arg.
(653 - 1_5) tell us that
the
former
f r a g m e n t s are those of type A C and t h e r e f o r e
the
above
sequence
expected
(710 - 15) and 638
....
=
this
905
(result n e g . ) , 905
905 - 807 = 98
sequence Arg-Pro-Pro-Gly Ions 695
but
in the p e p t i d e ) , 1060 -
(Arg), 905 - 858 = 47 (result neg.)
1060 - 999
of the
is
indeed
Arg-Pro-Pro-Gly
there are no f r a g m e n t s of type AC and A l k C
As for
356 the A r g - P r o - and the P r o - P r o - b o n d .
Proceeding
further
in the same w a y w i t h the a m i n o - c a r b o x y l - i o n m/e 653 the a l k y l - c a r b o x y - i o n
638
(
15)
reveals
Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe, the
carboxyl
possible
end
of
fragments
the
the
Arg
for
Calculating
all
ions for the p r o p o s e d
s o m e more p r o o f s for
the
sequence
leaving only
peptide. postulated
and
sequence
and
shows
well
known
sequence. As
Barber
and
biological
coworkers
a c t i v i t y of
have
demonstrated
bradykinin
is
not
s i g n i f i c a n t l y d u r i n g F A B - M S , those a n a l y s e s considered
to be
conditions with
carried
out
under
"could
non
r e s p e c t to b i o l o g i c a l
the
diminished be
destructive
activity"
^^.
Conclusion
FAB-MS represents of p e p t i d e s without
an i m p o r t a n t a d v a n c e
for several
derivatization
reasons: peptides by
chemical
n e c e s s a r y to have the p e p t i d e Nevertheless derivatization g r e a t h e l p for
Molecular high
by
volatile
be
enough
for
are EI-MS.
is s o m e t i m e s n e c e s s a r y and/or
integral
compounds. mellitin
observed
The
ions. Lys and
increment
and
molecular
Molecular
(128) are
amino
reactions
ions
for
insulin / ^ - c h a i n ion
b e t w e e n G l n - A s n and G l u / A s p . F A B / M S d e t e c t novel
measured
which
ions are of r e l a t i v e l y h i g h i n t e n s i t y ,
molecular
analysis
of Gin
easily
acetylation.
somastotatin, 211
chemical
can
methods,
i d e n t i f i c a t i o n of s e q u e n c e
w h i c h both have the same distinguished
in s e q u e n c e
allows has
a c i d s w h i c h are d i f f i c u l t
with
glucagon, have
the the
even
been
distinction potential
to d e t e c t
that m i g h t c h a n g e the u n k n o w n
to
after
structure.
357 A t the p r e s e n t
state
of
development
e a s i l y d e t e c t e d , also w i t h small fragment clear
molecular
a m o u n t s of
ions are not a l w a y s of s u f f i c i e n t i n f l u e n c e d by
the
peptide
are But
intensity
cut s e q u e n c e d e t e r m i n a t i o n . M o r e o v e r
greatly
ions
substance. fragmentation
structure
and
d e t a i l e d s t u d i e s are n e c e s s a r y to find out how has to be h a n d l e d conditions
before
have
fragmentation.
to
be
ms
analysis
tuned
to
and
get
the m e a s u r e m e n t
Further
is
from
peptide of
important
each
the r e m a i n i n g
e a s i l y be r e i s o l a t e d and p u r i f i e d
is
operating
optimum
The a m o u n t of p e p t i d e a v a i l a b l e
a
further
the how
an
in this r e s p e c t . As o n l y a small a m o u n t of destroyed during
for
sample peptide
is can
glycerol.
technical development, perhaps with
more
efficient
22)
ionization
techniques
', should e n h a n c e
the
sensitivity;
the m e t h o d s e e m s to be s u i t e d for L C - M S c o u p l i n g high
field
magnet
technology
opens
the
and the new
possibility
to
a n a l y z e m o l e c u l e s of MW > 2000. Literature 1) B i e m a n n , K. in B i o c h e m i c a l Spectrometry,
Ed.
A p p l i c a t i o n s of
Waller,
G.R.,
W i l e y - I n t e r - S c i e n c e , N e w York 1972 p
Mass Chapter
405
-
428
15, and
1982, p 469 - 525. 2) M o r r i s , H . R . , N a t u r e 286, 447 3) A p r i n o , P . J . and M c L a f f e r t y , of O r g a n i c S t r u c t u r e s
by
A c a d e m i c P r e s s , N e w York
(1980). in N a c h o d . Physical
Determination Methods,
Vol.
1976.
4) B e c k e y , H . D . , H o f f m a n n , G . , M a u r e r , K . H . and
Winkler,
6,
358 H . U . , A d v . M a s s S p e c t r o m . j>, 626
(1971).
5) W i n k l e r , H.U. and B e c k e y , H . D . , B i o c h e m . B i o p h y s . C o m m u n . £ 6 , 391
6) M a c f a r l a n e , R . D . and T o r g e r s o n , D . F . , Science 920
Res.
(1970). 191
(1976).
7) B u r l i n g a m e , A . L . , D e l l , A. and R u s s e l l , D . H . , C h e m . 54., 363R
Anal.
(1982) .
8) B e n n i n g h o v e n , A., S i c h t e r m a n n , W . , Org. M a s s S p e c t r o m . 12,
595
(1977).
9) B a r b e r , M., B o r d o l i , R . S . , S e d g w i c k , R.D. and A . N . , J. C h e m . Soc. C h e m . C o m m u n .
1981,
325
10) D e v i e n n e , F.M. and R o u s t a n , I., Org. M a s s 17 173
Tyler,
Spectrom.
(1982) .
11) F r a n k s , I. and G h a n d e r , A . M . , V a c u u m 2A, 489 (1979) . 12) M a r t i n , S.A., C o s t e l l o , C.E. and B i e m a n n , K., C h e m . 54^, 2362
Anal.
(1982) .
13) W i l l i a m s , D . H . , B r a d l e y , C . V . , S a n t i k a r n , S. and B o j e s e n , G., B i o c h e m . J. 201, 105
(1982).
14) B a r b e r , M., B o r d o l i , R . S . , S e d g w i c k , R.D., T y l e r , and
Whalley,
E.T.,
Biomed.
Mass.
Spectrom.
A.N. 8^
337
(1981) . 15) B a r b e r , M., B o r d o l i , R . S . , G a r n e r , G . V . , G o r d o n ,
D.B.,
359 S e d g w i c k , R . D . , T e t l e r , L.W. and T y l e r , A . N . , J. 197, 401
Biochem.
(1981).
16) K ö n i g , W . A . , A y d i n , M. S c h u l z e , V . , R a p p , U., H o h n , M. P e s c h , R. and K a i i k h e w i t c h , S p e c t r o m . 46, 403
V.N.,
Int.
J.
of
(1983).
17) R i n e h a r t J r . , K . L . , G a u d i s o , L.A., M o o r e , M . L . , R . C . and C a r t e r Cook J r . , I. J. A m e r . C h e m . 6517
Mass.
Pandy,
Soc.
103,
(1981).
18) M o r r i s , H . R . , P a n i c o , M. B a r b e r , M., B o r d o l i ,
R.S.,
S e d g w i c k , R.D. and T y l e r , A . N . , B i o c h e m . B i o p h y s . C o m m u n 101, 623
Res.
(1983).
19) W i l l i a m s , D . H . , B r a d l e y , C., B o j e s e n , G . , S a n t i k a r n , and T a y l o r , L . C . E . ,
J.
Amer.
Chem.
Soc.
103,
S. 5700
(1981). 20) K a m b a r a , H., Org. M a s s . S p e c t r o m . r7, 29
(1982).
21) B a r b e r , M., B o r d o l i , R . S . , S e d g w i c k , R . D . , T y l e r , Garner, G.V., Gordon, D.B.,
Tetler,
R . C . , B i o m e d . M a s s . S p e c t r o m . 9, 265
L.W.
and
Hider,
(1982).
22) A b e r t h , W . , S t r a u b , K.M. and B u r l i n g a m e , A . L . , C h e m . 54, 2029
A.N.,
Anal.
(1982).
23) W i e l a n d , F., H e i t z e r , R. and S c h ä f e r , W. , s u b m i t t e d P r o c . N a t . A c a d . Sei.
1983.
to
PERSPECTIVES MAIN-CHAIN
Axel
IN T H E
CIRCULAR
DICHROIC
ANALYSIS
OF
PROTEIN
CONFORMATION
Wollmer,
Wolfgang
Straßburger,
and
Uwe
Glatter
L e h r - und F o r s c h u n g s g e b i e t S t r u k t u r und F u n k t i o n der Abteilung Physiologische Chemie Rheinisch-Westfälische Technische Hochschule Aachen Schneebergweg 211, D-5100 Aachen
Proteine
I n t r o d u c t i on
In a v o l u m e chapter
on
on m o d e r n circular
As
a method,
CD
spectroscopy
well
CD
protein
tion
to
most
routinely
which,
however,
troscopy protein tions,
is
an
and
Where
in
7)
this
would
also
by
the
It
may
a more The
the
widely
find
the
frame
of
instrumentation, The
rather
critical
to
chapter for
is
workers
applying
CD
to
be
there
article
even
results
Modern Methods in Protein Chemistry - Review Articles © 1983 by Walter de Gruyter & Co. - Berlin • New York
the
contem-
much
atten-
is
now
al-
structure As
CD
for
is
circular
the
however,
familiar
of
new
spec-
studying of
a
condi-
certain
context.
specializing
of
a
place
nor
in
range
ecological
this or
gives
a wide
of
its
of
is o n e used
technique
spectroscopy
interpretation
assumed
this
not,
it
secondary
used,
landscape
going
in
out
it r e c e n t ,
experiment.
under
reviewed
the
of
by
well
exceed
is
most
analysis
determination
convenient
solution
one
that
volume
Sequence
it
envisage
reader
present
verified
is
currently
prediction
and
protein slightly
nor
sense
treating
dichroism. is m e a n t
be
in
appear
for
chapter
far
phenomenon,
who
to
conformation
justification
is
has
the
The
by
adequate
may
techniques
sequencing. followed
chemical
chemical, in
physical
research.
protein
of
dichroism neither
is m o d e r n
established
porary
lar
is
methods
with
dichroism niche?
to
outline
theory meant in
of
for
other
themselves reported
by
absorption
(1-
It the
circuexperts.
fields, or
want
others. spectro-
362 ai .e +J
!
ai t/1 o 1/1 T - E t E O Sd
iaj "O
LO CM • O r-H
co
1 CL so c l/l o J D •.IO - P
aj sz +-> c
10 S-P 1 -C (_> " O - P O) c e Q . IO •!«1X1 ï
u a)
O) û£
CO CO CO PO
o
o
o
o
—t E c —i
o
o
o
o
LO 1—1
LO LO LO LO LO
"3-
0) .¡r 4->
CTÌ CO LO LO LO O
r-H r - t H
.-H
SO +-> IO i— "O o E
Í. io ai >> x> CD +J ra o -a c i—i co ci o -1— +-> •1— "O c o o
-p c aj E rj s-p 00 c
CM CM CM CM
rtHH
t—1 t—t r—( «-H
C M H H H r H
so 1
c — i
o o
-Q IO
o
sai s-
+-> 10 o
ü
t/1 Saj +J aj E O s+J o ai O00
aj o c IO E So M— s_ ai a.
1— 1 — C O C O O O H
o
co IO
4o
LO CO LO • CO i—1 o o
— ,
-o
t/l
o. o
CM oo CTI I—I
o o LO 1 •n
S0) •P ai E -rs10 1— o o. o í. +-> o cu O. 00
o O t/i (0 o •"3 C_)
N re
o lo
lo o co o rH N
o o o o PO < í
1 O -P L0
>
1 c •r-O O
ai a)
o IO
>
» >
10 u
1
¿í iIO s
u cu o. oo
363 scopy ism.
in g e n e r a l
given
enough
treatment
the
far
chain
by
the only
l i s t of
lection cited
i s , of
important
CD
and
tion
Lakewood,
of
puter
assistance)
identical
the
re-
with
proteins
secondary cover
and
the
se-
literature
the m a j o r i t y
Jersey,
ago.
under
of
same
modern cell.
CD
on and
the
(in
conditions basis
of
in
of
idea
manufac-
of
field,
the
per-
Table I
the a b s e n c e
comparison
the Asso-
moderniza-
to be
indicated.
cannot
Spec-
the A v i v
i ns t r u m e n t s
for
the m a n u f a c t u r e r s
an
in the
noise
the d i f f e r e n t fair
ceased
to g i v e
Japan
Devision
specialized
spectrometers (rms)
the
Recently
which
In o r d e r
square
from
Jobin-Yvon
USA,
samples
specifications
Pockels
and
New
as a p r a g m a t i c
In all
be d e a l t
complete
available France.
root mean
the
presently
Tokyo,
standard
the
exactly
can
at-
latter
Aspects
Longjumeau,
years
lists
used
The
been
CD. The
to
main-
indirectly.
spectropolarimeters
several
formance
of
are
S.A.,
of C a r y
tured
being
hopefully
Experimental
Company,
Instruments ciates,
least
or
spectrometers
spectrometers
troscopic
will
is r e s t r i c t e d
and
individual
from
not
performance.
structure
side-chain
subjective.
however, at
of
dichro-
sometimes
a u t h o r s .have, a l w a y s
of
is far
course,
dichroism
structures
level
are
better
secondary
the
specific
a t the
papers
Instrumental Modern
of
of c i r c u l a r
that
procure
hence,
although
references
therein,
that
circular
and,
idea
touched
potentialities
to d e t a i l s
adequately
a rough
are
and
protein
conformation
lates
CD
of
ultraviolet
tracted
to h a v e
aspects
attention
The
The
and
Experimental
of
com-
Measurements should since
be the
be n o r m a l i z e d
to
conditions.
instruments The main
hygroscopic
nature
and
or a m m o n i u m
dideuterium
photoelastic
disadvantages optical
of
modulators the
imperfection
phosphate
crystal,
replace
latter
lie
of
potassium
its
the
coating
in
the the
with
364 transparent voltages the
foil
and
electrodes,
low m o d u l a t i o n
low f r e q u e n c y
ty of flat
circular
level. time
Operation
to
Higher
square-wave
polarization.
baseline.
ceptability
lamp
IV,V
in
turn
methods
The a n a l y s i s
of
are
protein
wavelength
limit
of
Vacuum u l t r a v i o l e t research yet.
a superior
modulators in
speed
have a
lower
shorter
noise
response
IV,V
0.5
Stopped
in detail was
flow
by B a y l e y
shown
to b e n e f i t
CD s p e c t r o m e t e r s
( A > 185
were d e v e l o p e d
not commercially
involving
the
in
outlined
in
subshort-
nm). several
available
m a g n e s i u m and c a l c i u m
is
Mark
(8).
standard
and m o d u l a t o r s ,
ms)
CD
beyond
but are
sus-
( J - 5 0 0 < 8 nm/s,
studies.
CD s p e c t r o m e t e r s
quali-
reduced
the m e a s u r e m e n t s
construction,
polarizers
scanning
hand,
of
laboratories,
Their
oride
means
conformation
from e x t e n s i o n
yields
0 . 2 5 ms, Mark
discussed
stantially
operating
and a somewhat
J-500
kinetic
high
On the o t h e r
kHz r e s u l t s
course,
constant high
the
Photoelastic 20-50
of
and f a s t
as
voltage
instabilities
allows
< 40 nm/s)
and r e l a t e d
at
frequency,
(minimum time
which
as well
frequencies.
as flu-
references
9-12. Circular
dichroic
Depending
on t h e
difference AA
(i.e.
should the
in
due to =
M
signal or
preference
underlying
unfortunate
a;
displayed
polarized
the
since choice exists
however,
definition
in
it
for
a lot
M
molecular
weight
1
optical
c
concentration
pathlength
[g-mol_1J [dm] [g-cm~3]
the
The It
9.
AA
reflects literamay
appear
ellipticity
of c o n f u s i o n
traditional -1
the
absorption,
directly
though.
[deg • cm 2 • d e c i mol
R
as
ellipticity,
the m e a s u r e m e n t .
by the o p p o s i t e rotation
is
circularly
a common f o r m a l i s m
the o p t i c a l its
the
ellipticity.
dichroism),
be g i v e n
that
and
and r i g h t
process
dominated
attractive 9 and
left
clearly
is
instrument
the c i r c u l a r
physical
ture
absorption
]
units.
is
365
Ae
[103-cm2-mol -1]
=
1
optical
pathlength
c
concentration
[cm] [mol-l"1]
[0] = 3300•Ae Main-chain
conformations
of p o l y p e p t i d e s
and proteins are
pared on the basis of the m o l a r c o n c e n t r a t i o n mophores which
is c a l c u l a t e d
of p e p t i d e
from the mean m o l e c u l a r w e i g h t of
c o n s t i t u e n t r e s i d u e s . For c o m p a r i s o n s with r e s p e c t to c h a i n or p r o s t h e t i c c h r o m o p h o r e s the a n a l y t i c a l empirical
data are lacking
value
hardly e x c e e d
Factors affecting Calibration.
accuracy
of
reported
from d i f f e r e n t
calibration.
the CD
test s o l u t i o n s
involving
(III)
(CSA) as a s t a n d a r d . A of (+)-tris
17 i n s t r u m e n t s
(13 J a s c o , all
2 Jouan
up to 30% at 220 and 490 nm d e p e n d i n g calibrating
(13). This o b s e r v a t i o n
(or third) w a v e l e n g t h
r e q u i r e m e n t of a c o n t i n u o u s additional
calibration
longer w a v e l e n g t h s
(later
Jobinwhich
deviations in
calibration
at
investiga-
it c a n n o t m e e t the
calibration
f u n c t i o n . For
in the far u.v. is a d v i s a b l e
for p r o t e i n s with c e r t a i n
of
the risk
in the range under
that r i s k ; h o w e v e r ,
D-pantolac-
on the type and age demonstrates
at a single w a v e l e n g t h . A d d i t i o n a l
tion may reduce
scale
compara-
over the w o r l d
c a l i b r a t e d with CSA at 290 nm, r e v e a l e d
the m o d u l a t o r
rathattri-
(ethylene-
iodide m o n o h y d r a t e , CSA, and
Y v o n ) , 1 C a r y , and 1 n o n - c o m m e r c i a l )
a second
laboratories
less
This is c o m m o n l y a c h i e v e d at 290 nm with
tive study on identical
were all
will
( A A ) or e l l i p t i c i t y
acid
tone
by an
d i f f e r e n c e s , w h i c h are m o s t l y
(+)-camphor-10-sulfonic cobalt
If
measurement.
to the sample. H o w e v e r ,
diamine)
introduced
CD spectra of the same p r o t e i n under more or
the same c o n d i t i o n s
requires
the error
side-
is i n a d e q u a t e .
cent.
er o f t e n show d i s q u i e t i n g buted
this basis
(mean residue w e i g h t , MRW s 115 g/mol)
10 per
comchro-
basic proteins
(and
at
prosthetic
g r o u p s ) . This could be a c h i e v e d w i t h D - p a n t o l a c t o n e at 220 a wavelength
nearly
coincident with
the n-ir* band of the a -
nm,
366 helix; nm
or a d d i t i o n a l l y
(14),
a wavelength
larized |0
9 2 9 0. 5
/
| =
carefully
purified
its
hygroscopic
of
the
concentration
reliable
puted with ORD
[ e ] 2 9 0 .5
However,
since
terest
that
lution
can
the
normal
used
226.
rule out
ranges
calibrated Protein errors
at
can
itself
mounts
of
of CD
and from
analysis
and
1.1.
pendent the
The on
protein
sated
in
the
field
it is of
in-
inconsistencies
of
the
sensi -
the
spectrometer
used
for
differences
is
increases be are
cent
so-
in the
Increases
by a d e c r e a s e
Very
known with
of
sample.
substantial
to be a
optically
three
a-
active
proteins
seem
are
of
the
prove
composition to and
for
of 0 . 9 ,
fractions
in g - s t r u c t u r e
or
difficulty.
a factor
structural
De-
problem
decreasing
by a n a l y s i s
resulting in h e l i x
be
in c o n c e n t r a t i o n
derived
secondary
actual
a related
with
should
in c o n c e n t r a t i o n .
they
error
below)
were
the
factors.
multiplication
analyzed.
(15).
CSA
(see
II. T h e y
the a b s o l u t e
for m a i n l y
standardized
the
water,
conformation
after
its
The com-
of
Contaminants,
adherent
the
spectra
from
as
absorbance
concentration
of a 10 p e r
three
desirable.
CD of CSA
spectrometers
uncertainties
exponentially
Table
the
spectrum
related
consequences from
highly
because
determination
(14);
The
visible
problematic
spectropolarimeters,
setting
protein
or e v e n
on
(isotropic)
same
of m a t e r i a l .
inactive,
po-
0.77.
instrument
originate which
192.5
perpendicularly
an a c c u r a t e
transform
eventual
the
the
at
or
concentration
termination in
of
-
instead
9
290.5 / E285 =
CSA
2.33-10-\
of O R D
0.068
to
solutions
is b a s e d
number
A E 2 9 o . 5 / E 2 85 = In o r d e r
the
remains makes
dispersion)
2 70
that
the be
(14)
Kronig-Kramers
[M] 3 0 6 "
exceeds
with
with
a-helix:
This
of CSA
rotatory
vastly
tivity
CSA
[M] 3 0 6 - [M]270 = /
the
nature.
calibration
the
(optical
A e 2 9 0. 5 /
of
also
2.00.
of
most
preferably,
coinciding
77-7t* t r a n s i t i o n
1 9 2.5
Even
and
be
1.0, deof
compen-
vice
versa.
367
Table
II:
Dependence of C i r c u l a r D i c h r o i c S e c o n d a r y D e t e r m i n a t i o n * on E r r o r i n C o n c e n t r a t i o n error i n concentration
protein
helix [«1 84
-10% myoglobin
pancreatic trypsin inhibitor
ribonuclease A
Structure
g-structure m
B-turn [%1
unordered m
0
3
13
± 0
79
0
5
16
+10%
70
10
4
16
-10%
31
27
4
38
± 0
28
33
3
36
+10%
24
40
2
34
-10%
26
34
15
25
± 0
23
40
13
24
+10%
20
46
11
23
*)Least-squares a n a l y s i s with the reference data of Chang et a l . under the c o n s t r a i n t s Ef. = 1 and f . > 0. i If
the f r a c t i o n s
low)
their
are
error
is
not c o n s t r a i n e d directly
to
sum to u n i t y
proportional
to
(38)
(see
the e r r o r
be-
in
con-
centration. There
still
is
another
important
experimental
parameter:
of a p r o t e i n
should
dence: wide
changes
range
libria. should teins
in
are
be n o t i c e d
of d i f f e r e n t in
a defined
state
lengths
are
solvent.
of
concentration
depen-
of
concentration
over a
of a s s o c i a t i o n / d i s s o c i a t i o n reflect
derivatives
an
investigation
a study
equi-
quaternary
structure.
It
studies
homologous
pro-
of
of
one
protein
structure,
are
reasonable
concentration
from lyg/ml
5 cm to is
as
which
are
only
for
association.
protein
extends
lationship the
of
CD s p e c t r o s c o p i c
comparative
a quaternary
The m e a s u r a b l e u.v.
that
to c o n c e n t r a t i o n
variation
CD c a n a l s o
organized
far
include
CD w i t h
indicative
Hence,
or
Every
aspect
to
range
10 mg/ml;
for
studies
corresponding
10 pm. The p a t h l e n g t h / c o n c e n t r a t i o n
substantially
determined
by t h e
in
the
pathre-
transparency
of
368 The
less
small
pathlengths
tions. can
transparent
Phosphate
be u s e d
down
to
small ror.
185
and,
the m o r e
consequently,
buffers
are
high
and
0.5 mm
nm.
are
suitable
Fluorides
cells,
Nominal
optical
pathlengths
absorption
one
should
be
to r e s o r t
as
at
neutral
may
with
rotation
Tris
wavelengths salts.
be a s o u r c e
checked
to
concentra-
transparency;
pathlength
pathlength
(16), or o p t i c a l
has
protein
of a c c e p t a b l e
at 0.02 mol/1
sample
infrared
a solvent,
For
of
er-
standards
by
(17), or
inter-
is p a i d
to
ferometri cally. Artefacts.
In g e n e r a l
possibility important corded
same
for
the
come
a cell
cell
that
tests
the
absorption.
optically
sample
are
such
absence
as
not mean
are
that
the most
baseline compound
reof
from
Artefacts
liposomes
in t h i s
of a r t e f a c t s
does
The
the
on o r i e n t e d ,
films,
treated
of
not deviate
solvent.
in m e a s u r e m e n t s not
One
inactive
should
a transparent
in p u b l i c a t i o n s
collection
In r e s e a r c h any
its
proved lows
by
the
that
may
be-
scattering or
membrane
article). normally
they were
The not
fact men-
a matter
solvent
processing
the
always
than
of
improvements
be
operated
under
optimum
detectabi1ity
at
of a s i g n a l
at fixed w a v e l e n g t h
the
technique"
cell are
"step
to be w i t h d r a w n position.
referred
graphically
peak-to-peak
(18): from
noise
the and
instrumentationlimits
The
and can
of
Without
the
its
per-
computer
reproducibili-
be c o n s i d e r a b l y
A special
the
Measurements
to a i r p a t h . as
in the
conditions.
recording
identical
obtained
will
rather
assistance ty of
and
-irrespective
technique
formance
the
the
samples
(which
for
isotropic an
attention
of a r t e f a c t s .
course.
Data
an
as
concern
reflecting
tioned
is
holding
holding
preparations
insufficient
occurrence
absorbance
a primary
and/or
of
the
artefacts
for
the
of
cell
holder*
beam
and
re-inserted
of b o t h
the
sample
height
difference is r e f e r r e d
im-
and
of
the
signal
between
the
centres
to as a s t e p .
At
alin the
is of
signal/
369 noise
(s/n)
ducible
ratios
with
Modern
commercial
digital
computer
provement,
as
data
CD
facilities.
takes
into
play.
of
sample
the
kind
same the time
These
time
can
described has
separation
proportional baseline
of
to
$ 1 m°/day;
data.
The m a i n
Mark
in the
lies
of m a g n i t u d e .
tween
the
operator for
of
IV,V
of c o l l e c t i n g
order
the
cell
and
with
and
small
and
(Cary
order
increased
experiment
which
the
is
the
manual
within
is
saves
m°/day;
rather
remains
the
like
affect over
of p r o c e s s i n g
of
however,
61 ^ 2
will
come
in
baseline
assistance
measurements,
Solvent scanning
the d a t a w h i c h the
may
instabilities
+ +
IO O ^ CCL CCL + + +
+ + + + +
+ + + + + C O
cytochrome c
+
+ +
+ + +
+ +
+
+
+ +
+
+
+
triosephosphate i somerase
subtil i si n Novo
+
hemog1 obi n
+
prea1bumi n
glyceraldehyde-3-P-DH
+
dehydrogenase
+
f1 avodoxi n
+
alcohol
¡3
carbonic anhydrase B
CO
thermolysin
+
tryps in i nhi b i tor
+ +
ribonuclease S
+
parva 1bumi n
+
insulin
+
nuclease
1981
-H h»
el as tase
1980
Hennessey S Siegel et al.(40) !johnson*(41)
+ •*•
concanava1 i n A
ko m N N Ö «icCL
ca rboxypepti dase A
r\
+
a-chymotrypsi n
+
-*- +
adenylate kinase
1979
Bo loti na et al.(39)
+
subtil i si n BPN'
+
lactate dehydrogenase,
1978
1974
+• +
papa i n
Chang et al.(38)
Chen et al.(37)
+
lysozyme
— +
ribonuc1 ease A
to in
myoglobi n
Saxena S Mitläufer (35) 1971
Table
protei n
374
I V : P r o t e i n s w i t h Kn wn X - R a y S t r u c t u r e U s e d f o r E x t r a c t i o n o f CD R e f e r e n c e S p e c t r a f o r S e e o n dary Structures
+ +
375 real
from
the
tain margin extreme
in
the
by d i f f e r e n t
et al.(38)
the
(42) of
criteria
utilized
Bolotina
which
were
g-bends ments
were
are
Microfiche stereo
(AMSOM
pictures
necessarily use al.
of
for
leaving
a few
of
the
the
Hennessey's
a
cer-
examples same
for
protein
& Greer
of
analysis
crystal-
and,
for
g-turns,
and
Glockner
bonds
the
criteria
were
helices two
and
central
criteria
(44)
reference such
which
as
(41)
of
assign-
Structure
for
helices
on and
discrepancies
data
the
were
g-structure, residues
Johnson's
Classification the
procedure
Levitt
the
Provencher
and
H-bond
in
by
o f M a c r o m o 1 e c u 1ar
g-bends.
reflected
given
structures
defining Only
(43)) p l u s
for
the
Hydrogen
the A t l a s
of a s t a n d a r d i z e d
rithms
and
call
automatic
applied
will
for
algo-
by S i e g e l
et
(40).
Execution The
actual
search* by a the
for
linear
the
analysis the
usually f,>0 1
to
of
number
of
their
and/or
*)Computer
consists
in a
fit of
the
of
reference
the
spectrum
least-mean-squares
uninterpretable
out with
the
computer-mediated under
spectra
investigation according
to
deviation:
solutions
following
calculations
obvious
are
constraints:
n i f. = 1 i=l 1
unconstrained
viation
optimum
exclude
carried
and
normally
combination
criterion
In o r d e r
In
be
set.
(39)
on
thus
gives
fractions
e t al „ ( 3 4 )
priority.
counted.
based
the
solved
same
et al. given
types, IV
interpretations
on
of Lewis
the
Table
authors.
relied
1 o g r a p h e r s who a c t u a l l y on
structural
subjectivity.
differences
structure Chang
theoretical
for
analyses, sum
nature
programs
from
negative unity
are
signs
of
fractions
indicative
of
reference
spectra.
are
available
upon
request.
of
and
de-
inadequate
376 Least-mean-squares curacy
fitting
is based on the a s s u m p t i o n
is limited by random e r r o r s .
uncertainties
and s h o r t c o m i n g s
h o w e v e r , c o n s i s t e n t rather portant.
Furthermore,
that ac-
remaining
parameters
than random errors are more can still
for curve fitting
(45) p r e s e n t e d a m e t h o d e m p l o y i n g
spectral was
of the s t a n d a r d
very poor p a r a m e t e r s
good fits. As an a l t e r n a t i v e berg
In view of the
Baker and
integrals
over
data instead of the data t h e m s e l v e s w h i c h ,
later shown to be e q u i v a l e n t
im-
yield Isen-
the
however,
to a l e a s t - s q u a r e s
fit
(38,
46). Alternative Extraction tures
approaches of s t a n d a r d
is not the only
tion e m b o d i e d reference
spectra for the single s e c o n d a r y possibility
for u t i l i z i n g
informa-
in the c i r c u l a r d i c h r o i s m and X-ray s t r u c t u r e
proteins.
Provencher
and G l o c k n e r
s p e c t r u m d i r e c t l y as a linear c o m b i n a t i o n spectra
the
struc-
|X(A)| of m r e f e r e n c e
of
(42) a n a l y z e a CD
of the
original
proteins,
m [9(A)]= I Y , [ X ( A ) ] J j=l J The f r a c t i o n s
f^ of s e c o n d a r y
the known c o m p o s i t i o n s
structure
of the r e f e r e n c e
can be d e t e r m i n e d proteins F^^
from
as
m f,= I Yy .F. . i j=1 J U Because of the high number m of c o e f f i c i e n t s y the squares a n a l y s i s propriate
needs s t a b i l i z a t i o n .
11 m m i n j ^ O G U , ) ] - ^ Hennessey "basis
(41)
calculated
Y
= 1
is a c h i e v e d by ap-
term: , 21 ( V i ) |
the use of
orthogonal
from the CD spectra of suffice
inal CD s p e c t r a of the r e f e r e n c e independent
+
suggested
Five basis spectra
there are five
m
2
Yj[X(Xk)].)
and J o h n s o n
spectra"
proteins.
This
choice of a in a r e g u l a r i z i n g
least-
reference
to re c o n s t r u c t
proteins.
the
orig-
Correspondingly,
"superstructures",
each
consisting
377 of a s p e c i f i c are
capable
reference
under
How many
of
ambiguity curve
on
how
On
are.
co, Woody,
and
supercoiling t w i s t of
of
calculations.
stance
a and
whereas The
in b r o a d e r 310
helix
diversity
of
types. Attempts have
been made
spectra
of
type
conformational each of
type
the
occur of
as m i r r o r
their
CD
I, II a n d
which ones
the
into
these III
hand
for
should
the
in the
it will of
the
case depend
single
work
as
be
of
Tino-
(49-56). related
length
of s t r a n d s
or
and
the
by q u a n t u m
mechanical
categories
have
not
account
(56)
on
closely
such
should
types
Woody
finally
depend
helical
be r e d u c e d
in
reasonably class,
for
a be in-
distinguished, by C h a n g
et al.
terms
spectral
using
of
synthetic
predicted
be r a t h e r
that
(38).
models the
similar.
specific
the o t h e r
using
an overall
representation
similar
Brahms
found
very
complication
images
with
in a s t r u c t u r e
contributions.
Thus
Chang
and
preferred
to c o n s i d e r
part
the
unordered
form.
the
by
g-turns leading et al.
data
for
using
were
reference
Two
one
g-turns of
uncon-
importance
number
generally
can
above).
analyses,
types
In
are
to c o n f i r m
(11). An additional
the
predictable
is t a k e n
will
theoretical
greatest
and which
g-turns
(see
the
indicate
helices
of b e n d ,
three
of
classes.
length
the
for
spectra.
particularly other
of f e a t u r e s
are
will
to be d i s c e r n e d
combined
of
structures
by an
characteristics
is of
or
sheets
which
structures
basis
number will
or d i s s i m i l a r i t i e s
helices
These
the
elements
the
aspect
the e f f e c t s
pleated
On
spectral
Schellman
and
determined
techniques,
this
similarities
geometries,
chance
the
X-ray
secondary
with
the
procedures. For
are
structures,
categories
hand
of e v a l u a t i o n
different
of
structural
the o n e
fitting
Spectral
of
secondary
original
analysis
structural
categories
the
fractions
investigation
categories
discernible? of
The
least-squares
Resolution
of e i g h t
to r e c o n s t r u c t
proteins.
a protein strained
combination
&
Brahms
is
that
to
cancellation
(38)
cancelling
they
counted residues
may "net" as
378
special features
Q--U CI o n o "5 C i -h •-h -t> O-h o 0) in a o OO -s fD < -S-S T c 01 c+ Q. 3 ui n oi 3 3 o o fD' -s -s c -s fD — o w a c o CL CL » -s on 3 3 fD fD -s -! Ol Ol C c+ C fD fD -S —Q. CL 0) • 3 fD 3• 01 3 Qio 01 -J Q-•• s
Ol 1—-a (0 o i/i •— I -C •— i o +-> (/i O) CL) >i cle: i— cn rO -a C "O QJ C c: +-> to o i— cu CL>o t 3 i/i •— o 4-> a. 4- (O OE CTI Sc (/I o •1 — a) 4— > S- c 1— 3 o o 00 CD fD fD fD >TOfD ' I r+ I- XI t —' L &f> D I c+ r fD I a. 3" fD fD
authors 1969 Greenfield & Fasman (23) 1971 Rosenkranz & Scholtan (24) 1971 Saxena & Wetlaufer (35) 1971 Chen & Yang (36) 1972 Chen et a l . (47) 1974 Chen et a l .
(37)
1978 Chang et a l .
(38)
1979 Brahms & Brahms (48) 1979 Bolotina et a l . (39) 1980 Siegel et a l .
(40)
1980 Brahms & Brahms (11) 1981 Provencher & Glöckner (42) 1981 Hennessey & Johnson (41)
379 Inclusion
of
the
178-195
portance
for
cernible
structural
analytical
the m e a s u r e m e n t s sized
by B r a h m s
show minima
nm.
Surprisingly of
this
tiation
baseline
the
(41).
is
Brahms
to
the
Their
do
of
is a l s o
of
emphaspec-
168 a n d
not affected
in the
im-
dis-
reference
between
were
data
great
number
0-turn
intersections
& Brahms
be of
of an e x t e n s i o n
ultraviolet
48).
g-turn categories
190
by
Hennessey/John-
not describe
employed
of
Tests
the
on
of
a study
of
vacuum
analytical
formation the
procedure analysis the
the
of one
permits
from
the m e t h o d
and
removed
was
15 w a s
actually
of
various
differen&
Johnson
a special
used
eigen-
of
noticed
that
carried
X-ray
the
The
the
Permutation of
out:
structure
at a time.
to a n a l y z e
separated.
deviation
been
known
characterization
X-ray
the
have
protein
methods
in-
spectrum
of
this
quality
of
the
and
correlation
coefficient
structural
composition
and
structure.
numerical
The
performances
analysis
are
that
of
compared
three
in
VI. be
coefficient category
to
frequency
the
approaches
sey
& Johnson
et al.
of
secondary
lation in the
data
with
the
It m a y tural
degree
by H e n n e s s e y
16 p r o t e i n s
of r m s
resulting
different
ultraviolet
remaining
protein
in t e r m s
manifest Table
on
one
highest
in
approaches
reliability
spectrum,
V. T h e
is a t t e m p t e d
achieved
evaluation.
a collective CD
differentiation
in T a b l e
8 categories
method
Accuracy
From
structural
given
with
(41) w h o vector
for
vacuum (11,
i.e. value
shortest wavelength
of t h e
analyses
of
the
The
found
kind.
A survey
and
into and
the
son a n a l y s i s
specificity,
categories.
& Brahms
tra
omission
nm r a n g e w a s
ratio
the
other.
(41)
Provencher have seems
of r m s
varies This
of o c c u r r e n c e
of
(38) w h i c h
the
strongly
of
and
certain
from
deviation one
is d u e the
to
advantages
comparatively
weak
correstruc-
large
single
Glockner
and
secondary
differences
categories.
(42) over
and
of
Both
Hennes-
t h a t of
Chang
in q u a n t i f y i n g
g-
380 Table
VI:
Root-Mean-Square Deviations and Correlation Coeffic i e n t s b e t w e e n CD E s t i m a t e s a n d X - R a y V a l u e s f o r the F r a c t i o n s of S e c o n d a r y S t r u c t u r e s in 16 P r o t e i n s rms
secondary structure
Chang et al.(38)
d e v i a t i o n [Xj
Provencher & Glbckner(42)
11
hel i x
5
anti para 11 el B-structure p a r a 11 el 8-s tructure
21
6
8-turn
15
10
r e m a i nder
15
11
The
the
how
spectral
structure
(see T a b l e
range and
can
nm, whereas the
facile
to
bounds
they
produced
studied
been
200
nm.
nm - w e r e
Notably,
categories,
0.25
10
0 46
0.49
0.72
while the
for
none
helix
of
and
non-ideality limitations
for
of
the
on
the
of
It b e c a m e
above
the
16
of
apparent
proteins
fraction
between
inves-
restrictions
of
only
that
helical
210
and
240
deny
the
significance
of
g-structure
and
random
This
fact
that
because
the
of
affected
large
waveerror
Hennessey
at
178,
first
&
184,
- by
"other"
truncations
coil.
shorter
the
fit.
cut-offs
$-sheet and
Johnson 190,
cut-off
and at
(irregular)
caused
substantial
the
neglected
chromophores
of m a i n - c h a i n for
the
side
create
dichroic
complications
transitions
and
In n e a r l y
they
(1). due
the
dif-
analysis
originate
chains
contributions because
geometry
circular
Additional
peptide
cystinyl
of CD a n a l y s i s
to
analysis.
(40)
side-chain
conformation.
are
should
respond
the
fractions.
and
and
that one
the
ficulties
overlap
I) s u g g e s t s
the
the
Diversity
of a r o m a t i c
towards
of d a t a
from
protein
problems
the e s t i m a t e s
those
0.51
in a p r e l i m i n a r y
Interferences
ods
0.31
of n o i s e
discarded
the e f f e c t
190
mophores
- 0 31
from data
for
had
in the
8
0.95 0.66
statisties
to be d u e
data
of
0. 94
estimation
resulting
length
in
e t al.
be o b t a i n e d
seems
changes
0 25
results
utilized
unfavorable
fractions
(41)
Hennessey & Johnson(41)
0.96
7
increase
by S i e g e l
accurate
finding
(38)
0 85
8
the a n a l y t i c a l
in a s t u d y an
steep
ultraviolet
tigate
coefficient
Provencher & G18ckner(42)
10
structure. far
correlation Chang e t al
Hennessey & Johnson(41)
absorption all
meth-
to n o n - p e p t i d e
chro-
are a s s u m e d
to be
small.
381 While as
contributions
a "background"
in r e f e r e n c e known
X-ray
spectra ed
will,
data
structure,
from model
to c o r r e c t
sentatives.
for
between positive density
of
lation has
of
proteins tional out
for
they
the
(61).
than
handle
and
being
Spectra
from
the of
of
unexpectedly
detailed
a
also
u.v.
near
increase
two excep(58,
tyrosyl
the of
con-
destructive
is e x c e p t i o n a l deserve
sometimes
insights
two
side
dichroic
a truly
59)
with-
case
interaction two
iso-
spectrum of
u.v.
In o n e
in-
high
Clearcut
smoothly
features
protein
generate
there were
that
chromophores
unusual
least
in a
to
spectra
circular
not analyzing
Their
repre-
simultaneously
case
indication
side-chain
far
affected.
success
is an
at
(57),
(6).
in the
abolished
attempt-
chromophores, nm
the
because
in the o t h e r
relative
attention. to a t t a i n
far
and
structure
from
normal.
ticular
in the
reference
interactions
should
in the
o u t to o r i g i n a t e
The
222
For
with
spectral
expected
contributions
included
(11)
occurs
tyrosyl
hand,
present
lysyl-phenylalanine, as
Though
cancellation (1).
with
acids
possible
both
analysis
interference
other
be
corrections
around
be
proteins
& Brahms
always
be q u a n t i f i e d
(58, 60),
formational
the
influenced
turned
tryptophyl chains
be
secondary
phenomena
er
could
phenomena could
on
or
are
at wavelengths
been
of
case
bands.
phenylalanyl
always
other,
using
amino
peptide
compensatory
ever
the
Brahms
applying
geometry,
side-chain
hardly
which
the
of a r o m a t i c s ,
the
glutamyl-tryptophan
of a r o m a t i c
and
less,
spectra
contributions
and
their
or or
the
is n o t
recommended
effects
chances
from
this
such
low CD of
peptide
dependent
in o n e w a y
polypeptides.
a high content
displaying
the
They
may, more
derived
glutamyl-tyrosine, when
which
rathpar-
offer
into
a
a
struc-
ture . This tural
article
restricted
composition.
function used.
is
of CD
One
has
to d e t e r m i n a t i o n
Although
this
spectroscopy, to
realize
principle.
However,
it a p p e a r s
in o u t l i n e s
from
it is
that the
that
cannot the
be
of s e c o n d a r y considered
one m o s t
growing
l i s t of
solved
architecture
best
extensively
it is an a p p r o x i m a t e
protein
the
struc-
is
method
in
structures achieved
382 with
a limited
(62). make
(though
Utilization the
method
of
more
large)
these
set
of
basic
back-bone
for
CD a n a l y s i s
will
reading
text
structures
and more
patterns
reliable.
Acknowledgements We a r e to ing
Mrs.
indepted Renate
to
Dr.
Kehren
a manuscript
Derek
Saunders
who m u s t e r e d
ready
for
the
for
care
the
required
for
and typ-
reproduction.
References 1.
S e a r s , D. & Beychok, S . : i n P h y s i c a l P r i n c i p l e s and Techniques of P r o t e i n C h e m i s t r y , P a r t C, Leach, S . , E d . , Academic P r e s s , New Y o r k , p. 445 (1973).
2.
A d l e r , A . J . , G r e e n f i e l d , N . , Fasman, G.D.: i n Methods i n Enzymology, H i r s , C.H.W., E d . , V o l . 27, Academic P r e s s , New Y o r k , p. 675 (1973).
3.
Woody, R.W.: J . Polym. S e i . , Macromol. Rev. 12, 181 (1977).
4.
Bewley, T . A . & Yang, J . T . : i n Hormonal P r o t e i n s and P e p t i d e s , V o l . Academic P r e s s , New Y o r k , p. 175 (1980).
5.
Simons, E . R . :
6.
Strickland,
7.
Kahn, P . C . : i n Methods i n Enzymology, H i r s , C.H.W., E d . , V o l . 61, Academic P r e s s , New Y o r k , p. 339 (1979).
9,
i n CRC Handbook o f B i o c h e m i s t r y , p. 63 (1980).
E . H . : i n CRC C r i t i c a l
Reviews i n B i o c h e m i s t r y ,
8.
B a y l e y , P . M . : Prog. B i o p h y s . molec. B i o l .
9.
Johnson, W.C.: Rev. S e i .
p. 113 (1974).
37, 149 (1981).
Instrum. 42, 1283 (1971).
10. Brahms, S. & Brahms, J . : P r o c . Nat. Acad. S e i . USA 74, 3208 (1977). 11. Brahms, S. & Brahms, J . : J . Mol. B i o l .
138, 149 (1980).
12. Düben, J . A . & Bush, C . A . : A n a l . Chem. 52, 635 (1980). 13. Tuzimura, K . , Konno, T . , Meguro, H . , Hatano, M., Murakami, T . , wabara, K . , S a i t o , K . , Kondo, Y . , S u z u k i , T . M . : A n a l y t . Biochem. 81, 167 (1977). 14. Chen, G.C. & Yang, J . T . : A n a l y t . L e t t e r s 10, 1195 (1977). 15. Cassini, J . Y . & Yang, J . T . : B i o c h e m i s t r y 8, 1947 ( 1 9 6 9 ) . 16. Bree, A. & Lyons, L . E . : J . Chem. S o c . , 2658 (1956). 17. Samejima, T. & Yang, J . T . : B i o c h e m i s t r y
613 (1964).
Kashi-
383 18. Wood, S.P., Blundel1, T.L., Wollmer, A., Lazarus, N.R., Neville, R.W.J.: Eur. J. Biochem. 55, 531 (1975). 19. Tinoco, I. & Cantor, C.R.: Methods Biochem. Anal. 18, 81 (1970). 20. Savitsky, A. & Golau, M.J.E.: Anal. Chem. 36, 1627 (1964). 21. Bush, C.A.: Anal. Chem. 46, 890 (1974). 22. Glatter, U., Straßburger, W., Wollmer, A.: Biophys. Struct. Mech. 7, 258 (1981). 23. Greenfield, N. & Fasman, G.D.: Biochemistry 8, 4108 (1969). 24. Rosenkranz, H. & Scholtan, W.: Hoppe-Seyler's Z. Physiol. Chem. 352, 896 (1971). 25. Li, L.K. & Spector, A.: J. Amer. Chem. Soc. 91, 220 (1969). 26. Quadrifoglio, F. & Urry, D.W.: J. Amer. Chem. Soc. 90, 2760 (1968). 27. Urry, D.W., Long, M.M., Ohnishi, T., Jacobs, M.: Biochem. Biophys. Res. Comm. 61, 1427 (1974). 28. Brahms, S., Brahms, J., Spach, G., Brack, A.: Biochemistry 74, 3208 (1977). 29. Kawai, M. & Fasman, G.: J. Amer. Chem. Soc. 100, 3630 (1978). 30. Bush, C.A., Sarkar, S.K., Kopple, K.D.: Biochemistry 17, 4951 (1978). 31. Ananthanarayanan, V.S. & Shyamasundar, N.; Biochem. Biophys. Res. Comm.'102, 295 (1981). 32. Gierasch, L.M., Deber, C.M., Madison, V., Niu, C.-H., Blout, E.R.; Biochemistry 20, 4730 (1981). 33. Venkatachalam, C.M.: Biopolymers 6, 1425 (1968). 34. Lewis, P.N., Momany, F.A., Scheraga, H.A.: Biochim. Biophys. Acta 303, 221 (1973). 35. Saxena, V.P. & Wetlaufer, D.B.: Proc. Nat. Acad. Sei. USA 68, 969 (1971). 36. Chen, Y.-H. & Yang, J.T.: Biochem. Biophys. Res. Comm. 44, 1285 (1971). 37. Chen, Y.-H., Yang, J.T., Chau, K.H.: Biochemistry 13, 3350 (1974). 38. Chang, C.T., Wu, C.-S.C., Yang, J.T.: Analyt. Biochem. 91, 13 (1978). 39. Bolotina, J.A., Chekhow, V.O., Lugauskas, V.Yu.: Internat. J. Quant. Chem. 16, 819 (1979). 40. Siegel, J.B., Steinmetz, W.E., Long, G.L.: Analyt. Biochem. 104, 160 (1980). 41. Hennessey, J.P. & Johnson, W.C.Jr.: Biochemistry 20, 1085 (1981). 42. Provencher, S.W. & Glöckner, J.: Biochemistry 20, 33 (1981). 43. AMS0M, Feldman, R.J. Ed., Tracor Jitco Inc., 1776 East Jefferson Street, Rockville, Md. 20852, USA. 44. Levitt, M. & Greer, J.: J. Mol. Biol. 114, 181 (1977).
384 45. Baker, C.C. & Isenberg, J . : Biochemistry 15, 629 (1976). 46. W i l l i c k , G. & Zuker, M.: Biophys. Chem. 7, 223 (1977). 47. Chen, Y.-H., Yang, J . T . , Martinez, H.M.: Biochemistry
4120 (1972).
48. Brahms, S. & Brahms, J.G.: J. Chim. Phys. 76, 841 (1979). 49. Woody, R.W. & Tinoco, J . : J. Chem. Phys. 46, 4927 (1967). 50. Woody, R.W.: J. Chem. Phys. 49, 4797 (1968). 51. Woody, R.W.: Biopolymers 8, 669 (1969). 52. Johnson, W.C. & Tinoco, J . J r . : Biopolymers ]_, I I I
(1969).
53. Pysh, E . S . : J. Chem. Phys. 52, 4723 (1970). 54. Vournakis, J . N . , Yan, J . F . , Scheraga, H.A.: Biopolymers 6, 1531 (1968). 55. Madison, 0. & Schellman, J . : Biopolymers 11, 1041 (1972). 56. Woody, R.W.: in Peptides, Polypeptides and P r o t e i n s , Blout, E.R. et a l . , Eds., John Wiley & Sons I n c . , New York, p. 338 (1974). 57. Woody, R.W.: Biopolymers 17, 1451 (1978). 58. Wollmer, A. & Buse, G.: FEBS Letters 16, 307 (1971). 59. Straßburger, W., G l a t t e r , U., Wollmer, A . , Fleischhauer, J . , Mersola, D.A., Blundel1, T . L . , Glover, I . , P i t t s , J . E . , T i c k l e , I . J . , Wood. S . P . : FEBS Letters 139, 295 (1982). 60. Wollmer, A.: paper presented at the Advanced Study I n s t i t u t e on ORD and CD at T i r r e n i a , P i s a , I t a l y , Sept. 5-18 (1971). 61. Wollmer, A., Straßburger, W., P i t t s , J . E . : to be published. 62. Schulz, G.E.: Angew. Chem. 93, 143 (1981).
Note a d d e d
in
An a r t i c l e
on " e x p e r i m e n t a l
lyzing after It
has
proof:
CD s p e c t r a the d e a d l i n e still
of
errors
proteins"
for
this
been p o s s i b l e
and t h e i r
appeared
in
effect
the
on
ana-
literature
chapter. to a t
least
Hennessey, J . P . , J r . and Johnson, W.C., J r . Analyt. Biochem. 125, 177 (1982).
give
the
reference:
SPIN-LABELLED AMINO ACIDS, PEPTIDES AND PROTEINS - SYNTHESIS AND APPLICATION
Herbert R. Wenzel and Harald Tschesche U n i v e r s i t ä t B i e l e f e l d , Fakultät für Chemie, D-4800 B i e l e f e l d 1
Eberhard von Goldammer R u h r - U n i v e r s i t ä t , I n s t i t u t für B i o p h y s i k , D-4630 Bochum 1
Contents Introduction 1.
Spin-Label Modification Reagents Dinitrofluorobenzene d e r i v a t i v e s Acylating agents Imidoesters Alkyl a l k a n e t h i o l s u l f o n a t e s C r o s s - l i n k i n g reagents I s o t o p i c a l l y labelled reagents
2.
S p i n - L a b e l l i n g of Amino Acids and Peptides Amino group s p i n - l a b e l l e d amino acids Carboxyl group s p i n - l a b e l l e d amino acids Side chain s p i n - l a b e l l e d amino acids N-Terminal s p i n - l a b e l l e d peptides C-Terminal s p i n - l a b e l l e d peptides Side chain s p i n - l a b e l l e d peptides
3.
Minimum Perturbation Spin-Label Amino Acids Nitronyl n i t r o x i d e amino acids Pyrrolidine-oxyl derivatives Pyrroline-oxyl d e r i v a t i v e s Piperidine-oxyl d e r i v a t i v e s Peptides with integrated s p i n - l a b e l s References
Introduction Since i t s introduction as a reporter group technique by McConnell almost twenty years ago, s p i n - l a b e l l i n g has become a well established powerful tool to study structure and function of biological systems on the molecular
Modern Methods in Protein Chemistry - Review Articles © 1983 by Walter de Gruyter & Co. - Berlin • New York
386 level. The method requires a stable paramagnetic nitroxide group to be placed in the system of interest either by covalent attachment label') or by introduction as a »suitably tailored radical
('spin-
('spin-probe')
which may interact with the system through hydrophobic, ionic, or hydrogen bonds. As the electron spin resonance of the nitroxide moiety is sensitive to orientation, molecular motion, and electric and magnetic environment, it potentially offers the ability to study these features in the biological Thus, many biochemical spin-label
and biophysical
system.
problems have been the subject of
experiments, e.g. molecular architecture of membranes, orienta-
tion or tumbling of macromolecules, structural
or conformational
proteins upon ligand binding, protein-protein interactions,
changes of
interconversion
among molecular species, distances between distinct sites in a macromolecule, rates and mechanisms of denaturation, active site geometry of enzymes, and rates of reactions catalyzed by them. The rapid development and the broad scope of spin-labelling are well
docu-
mented by three books entirely devoted to the various aspects of this method (1-3). Important advances have recently been achieved and can certainly be expected for the future in many respects: new instrumental ches such as the use of the saturation transfer ESR spectroscopic
approa-
technique
(4), improvement of computer programs for the simulation of ESR spectra, and the development of new nitroxide spin-labels, new methods o f attachment of these labels to molecules of interest, and new chemistry of the nitroxide grouping as it pertains to the spin-label method. Up to now a great variety of biologically important compounds have been spin-labelled including m e m brane components (5-8), nucleic acids (9-11), coenzymes (12-14), and carbohydrates (15,16). Since the very beginning of the technique, proteins and especially enzymes have ranked among the most prominent targets of spinlabelling. The vast literature which has accumulated up to about 1978 is thoroughly discussed in numerous reviews, wherein detailed synthetic
proce-
dures for spin-labels and representative examples for their covalent attachment to proteins can be found (1-3, 17-34). The focus of this present paper is threefold. The first chapter will some additions to the arsenal of spin-label
protein modification
present
reagents
made during the last four years. A review on the use of spin-labelled amino acid derivatives and peptides as spin-probes and methods for their
synthesis
387 will
follow in the second chapter. Finally, the third chapter will
discuss
the synthesis of amino acid analogues containing a nitroxide moiety as integral
part and their potential
applications.
1. Spin-Label Modification Reagents (Chart 1)
Dinitrofluorobenzene The spin-label
derivatives
reagents I, II and III combine in a single rather hydro-
phobic molecule the paramagnetic nitroxide function, a means to attach the radical
to proteins by an aromatic nucleophilic substitution re-
action, and a chromophoric group which facilitates quantitating the extent of reaction. Reagent I has been mentioned in an early review article (17) and is now commercially available
(Syva, Palo Alto, USA),
the syntheses of reagents II (35, 36) and III (37) have been described recently. Histone HI from calf thymus (38), human serum albumin
(36)
and phosphorylase b (37) were the targets of labelling. A general drawback of the aryl fluorides is their low specificity. They not only react with amino groups but also with sulfhydryl
and
imidazole
groups and with the phenolic hydroxyl of tyrosine. Modification of the latter three groups can be reversed, however, by thiolysis (37, 39). Moreover, the different substitution products can be distinguished
by
their ultraviolet spectra (36, 39).
Acylating
agents
The three acid chlorides of the pyrrolidine series IV (40, 41), the pyrroline series V (22, 38, 41, 42), and the piperidine series VI (41) respectively have been standard reagents e.g. for the spin-labelling of steroids. They may, however, also be suitable for the labelling of rather stable peptides and proteins, since the hydroxyl
groups of serine,
threonine and tyrosine can be esterified by these agents in the presence o f trifluoroacetic acid without affecting amino groups
(38).
The N-hydroxysuccinimide derivatives VII (available from Serva, Heidelberg) and VIII are convenient reagents to label
proteins at their amino
groups. VII was first used to attach a nitroxide moiety to the a-amino
388 Chart 1. Spin-label
reagents for protein modification
NO 2 OH/~Y-
N H - / > N O 11
2
F
NO 2 x
O — N \ — O — — N O ILL
C—CI
c-ci
2
F 0
iv
"N I. 0 0.
Y/ - \. Oii QR-N^ Y - C H 2 - C - 0 - N viii
0
H 3 CO
0
K I
¿7 I.
IX
0
^
^
XVCH
x
2
- S - S - CH 3 XI
NH-C- U CH 2 I xiii
ICH2-C-NH
CH2-NH-C-CH2I
D3C
CD 3
Q
O=-15N I. 0
XII
D3C
CD 3
0
XIV
group of valyl-tRNA (43), recently l a b e l l i n g of snake neurotoxins 45) and of a t r y p s i n i n h i b i t o r (Kunitz) d e r i v a t i v e in which a l l
(44,
e-amino
groups had been guanidinated (Wenzel, H.R. unpublished) was achieved with V I I and V I I I . The p y r r o l i d i n e d e r i v a t i v e I X was prepared in the course of developing a reagent which could be used to s e l e c t i v e l y attach a n i t r o x i d e group to t y r o s i n e residues of proteins (46). I t seems to be more stable than the corresponding pyrrol ine d e r i v a t i v e prepared e a r l i e r (47). Reagent IX has recently served to spin-label
histone HI from c a l f thymus (38)
and both the nucleosome core p a r t i c l e s and histone core extracted from chicken erythrocytes
(48).
Imidoesters The imidoester X ( a v a i l a b l e from Pierce, Rockford, USA) was recently syn thesized and used to spin-label cytochrome c in order to study the inter actions of cytochrome c with l i p i d and protein preparations ( 4 9 ) . The spin-label reagent shares the advantages of other imidoesters (50) such as high water s o l u b i l i t y , l y s i n e s p e c i f i c i t y , rapid modification at moderate temperature and pH, and retention of p o s i t i v e charge at the reaction s i t e . Alkyl al kanethiol sul fonates In an e f f o r t to render the advantages of alkyl a l k a n e t h i o l s u l f o n a t e s as r e v e r s i b l e t h i o l - b l o c k i n g agents (51) accessible to the spin-label
tech-
nique, compound XI was prepared (52). I t s unique s p e c i f i c i t y was demonstrated with the thiol proteinase papain, which was r a p i d l y and s t o i c h i o m e t r i c a l l y inhibited r e s u l t i n g from the formation of a mixed d i s u l f i d e between the active s i t e cysteine residue and the methyl pyrrol ine-oxyl moiety of X I . The radical was r a p i d l y and completely released from the protein by d i t h i o t h r e i t o l . Thus the spin-label
i s useful not only as a
s p e c i f i c conformational reporter group for t h i o l s i t e structures but a l s o as a s e n s i t i v e t h i o l t i t r a t i n g agent.
390 C r o s s - l i n k i n g reagents I f one i s interested in a f a i t h f u l r e f l e c t i o n of the motion of a protein by the ESR spectrum of a covalently attached s p i n - l a b e l , i t must be ascertained that the label i s r i g i d l y bound, that i t undergoes
little
or no motion r e l a t i v e to the protein structure (53). I t i s obvious that a radical anchored to several s i t e s would most l i k e l y meet t h i s r e q u i r e ment . With t h i s in mind n i t r o x i d e X I I of the p y r r o l i d i n e s e r i e s with two functional iodoacetamido groups was synthesized (54). I t appears to be useful for c r o s s - l i n k i n g of cysteine residues which are not more than 1.3 nm d i s t a n t from each other; other potential reaction partners are the side chains of h i s t i d i n e and l y s i n e . Very recently, progress in the development of several new hetero- and homobifunctional
n i t r o x i d e s has been reported (55, 56).
I s o t o p i c a l l y l a b e l l e d reagents Synthesis of i s o t o p i c a l l y labelled spin-label modification reagents has been carried out for two purposes. The use of radioactive reagents such as the iodo[2-
14 C]acetamide d e r i v a -
t i v e X I I I (57) allows c a l c u l a t i o n of the extent of protein l a b e l l i n g d i r e c t l y from the r a d i o a c t i v i t y incorporated and determination of the s i t e s of reaction by peptide mapping methods. Recently the maleimide d e r i v a t i v e XIV with deuterium and nitrogen-15 subs t i t u t i o n s in the n i t r o x i d e part was synthesized (58, 59) and used to label glyceraldehyde-3-phosphate dehydrogenase (60). Compared with conventional unlabelled reagents, XIV showed a considerable gain in s e n s i t i v i t y and a marked sharpening of spectral features. These improvements are due to a reduction in the spectral linewidths r e s u l t i n g from the r e l a t i v e l y weak i n t e r a c t i o n s of the unpaired electron with the deuterium nuclei and to spectral s i m p l i f i c a t i o n because of the reduction 14 In the15 number of nuclear manifolds from three to two in replacing N with N.
391 2. S p i n - L a b e l l i n g of Amino Acids and Peptides (Charts 2 and 3) Considering the extensive l i t e r a t u r e on s p i n - l a b e l l e d p r o t e i n s , papers dealing with the l a b e l l i n g of peptides and amino acids have been rather scarce. Amino acids or d e r i v a t i v e s thereof have served as model compounds to test properties of protein modification reagents. Moreover, s p i n - l a b e l l e d amino acid d e r i v a t i v e s or small peptides have been used as spin-probes. The synthesis of labelled peptides s t a r t s either from s u i t a b l y protected peptides using n i t r o x i d e reagents, part of which was presented in the previous chapter, or from s p i n - l a b e l l e d amino acid d e r i v a t i v e s , which are elongated by standard coupling procedures. Amino group s p i n - l a b e l l e d amino acids Acylation of amino acid esters to y i e l d the highly v e r s a t i l e
spin-label-
led d e r i v a t i v e s XX can be accomplished by several synthetic routes. A key s t a r t i n g compound i s
3-carboxy-2,2,5,5-tetramethylpyrroline-l-oxyl
XV (22). Either the free carboxylic acid in the presence of d i c y l o h e x y l carbodiimide and 1-hydroxybenzotriazole (61) or s u i t a b l e active d e r i v a t i v e s such as active e s t e r s , e.g. V I I (43, 61), mixed anhydrides (61 63) or the corresponding azide (61, 63) acylate amino acid e s t e r s . Compound XXb was also prepared by reaction of ethyl glycinate and reagent XVI (64, 65). A l k a l i n e h y d r o l y s i s of XX leads to N-acylamino acids X X I , which can a l s o be obtained in good y i e l d by reacting the acid azide of XV with the free amino a c i d s . Compounds XXI can be converted to the active esters X X I I with N-hydroxysuccinimide/dicyclohexylcarbodiimide and further to the azides X X I I I with sodium azide in aqueous acetone. An a l t e r n a t i v e pathway to X X I I I leads from the esters XX or the active esters X X I I via the acid hydrazides XXIV. The general procedures mentioned above and c h a r a c t e r i z a t i o n of the c o r responding individual compounds of chart 2 can be found in the l i t e r a ture (61). The isocyanate X V I I , prepared from the azide of XV by Curtius
reaction(63),
392 Chart 2. Spin-labelling of amino acids
COOH
0
N = C = 0
>d< O
xv
i
0
XVI
xvii
„
XVIII
SL1 — C O — G l y — O C H 3
xxa
SL1—CO—Gl y — OC2H5
xxb
SL1—CO—His — O C H 3
xxc
S L 1 — C O — G l y
xxia
S L 1 — C O — A l a
xxi b
SL1—CO — P h e
xxic
SL1—CO—Gly — O S u
XXlla
SL1 — C O — G l y — N 3
xxilla
S L 1 — C O — A l a — O S u
xxiib
S L 1 - C O - P h e - N
xxnib
SL1—CO — P h e — O S u
xxnc
SL1 — C O — G l y — N H N H 2
xxiva
Phe—NHNH2
xxivb
SL1 — C O —
SL1 — N H — C O — G l y — O C H 3
xxva
SL1 — N H — C O — T r p — O C H 3
xxvb
3
0 /7~\ II (' V - 0 - P - G l y - 0 C \ = / | 0-SL3
2
H
xxviia
" \ = J
° " P ~
A l a _ 0 C H
3 xxvi I b
0-SL3 S L 3 — 0 — C O — P h e
xxvia
SL3—0—CO—Trp
xxvib
SL3—0—CO—Gly—OC2H5
xxvic
5
0 0 - P - L e u - 0 C 0-SL3
2
H
5
xxviic
393 Chart 2.
(Continued)
N0
2
NO 2
SL3-NH
Glu
XXVIIIb
XXVII la
NH
2
Gly—NH—SL3
XXX
XXIX
H
2
N - ( C H
2
)
n
xxxi
- C O - N H - S L 2
Thr — N H — S L 2 I
n = 1,5,10
xxxiia-c
P h e — N H — S L 2
XXXIIIa
xxxnib
Bu*
A c — L y s — N H
CH 2 -O-S-CH 3
Tyr—OC2H5 I CH2 I SL1 xxxvi
2
O2N.
8
NH-SL3 0
N0
XXXIV
Abbreviations: - SL1,
Ac, acetyl; Bu
T
; - SL2,
2
XXXV
'» " SL3,
, tert-butyl; OSu, N-hydroxysuccinimide
ester.
—
;
394 adds to amino acid esters to y i e l d a-ureido acid esters XXV (61). The alkoxycarbonyl azide X V I I I was designed to label amino groups.
It
proved to be a convenient reagent for the preparation of s p i n - l a b e l l e d amino a c i d s , e.g. XXVIa, b and t h e i r e s t e r s , e.g. XXVIc under conditions generally used in N-protection with tert-butyloxycarbonyl
azide (66).
N-Labelling procedures for amino acids or d e r i v a t i v e s thereof, which, in addition to the n i t r o x i d e moiety, introduce a rather bulky group, make use of reagents XIX leading to the phosphorylated s p i n - l a b e l l e d amino acid esters XXVIIa-c (67) or reagent I I y i e l d i n g compounds X X V I I I a and XXVII lb
(36)
(68-70).
Carboxyl group s p i n - l a b e l l e d amino acids Amide bond formation using amino n i t r o x i d e s XXIX (22, 71) or XXX (22) has been found to be the method of choice for carboxyl group l a b e l l i n g of amino acid d e r i v a t i v e s . N-protecting groups have to be chosen which can be s p l i t o f f again without destruction of the n i t r o x i d e group. The glycine d e r i v a t i v e XXXI was prepared from XXIX and t r i f l u o r o a c e t y l glycine anhydride, followed by a l k a l i n e deprotection (72). The t r i f l u o r o acetyl protecting group was also s u c c e s s f u l l y used in the s y n t h e s i s of the s p i n - l a b e l l e d amino acids XXXIIa-c ( 7 3 ) . Coupling of N - t r i f l u o r o a c e t y l amino acids and XXX was achieved by dicyclohexylcarbodiimide,
deprotection
by ammonia. 2-Nitrophenyl sul fenyl amino acid N-hydroxysuccinimidesters were reacted with XXX to y i e l d after mild deprotection r a d i c a l s X X X I I I a and b ( 7 4 ) . Cleavage of the 2-nitrophenylsulfenyl
group was carried out in methanol/
acetic acid with rhodanide and 2-methylindole without i n v o l v i n g the nitroxide group. Side chain s p i n - l a b e l l e d amino acids Derivatives of l y s i n e and t y r o s i n e have been l a b e l l e d at t h e i r side c h a i n s . The spin-label reagent used in the preparation of XXXV was compound I I ( 3 6 ) , XXXVI was synthesized by reacting t y r o s i n e ethyl ester with the spin-label
s u l f o n i c ester XXXIV (75).
395 N-Terminal s p i n - l a b e l l e d peptides Peptides l a b e l l e d at t h e i r amino group have been prepared using two s t r a t e g i e s : The s y n t h e s i s s t a r t s either from active d e r i v a t i v e s of N - l a b e l l e d amino acids or from the complete peptide, which i s s u i t a b l y C-protected i f necessary. S p i n - l a b e l l e d N-acylpeptide esters such as XXXIXa or b were obtained by coupling amino acid esters to N-hydroxysuccinimide esters X X I I , to azides X X I I I or to acylamino acids XXI in the presence of dicyclohexylcarbodiimide and 1-hydroxybenzotriazole (61). The second strategy was followed using d i f f e r e n t spin-label
reagents.
Dipeptide XL, exerting a strong binding to the proteinase papain (76), was prepared by dicyclohexylcarbodiimide-coupling of Phe-Leu-OCH^ and c a r b o x y l i c acid XV followed by a l k a l i n e ester h y d r o l y s i s
(77).
Application of the N-hydroxysuccinimide ester procedure using V I I I or V I I yielded the labelled tetrapeptide ester XLI (78) and the oxidized g l u t a thion d e r i v a t i v e X L I I with two n i t r o x i d e groups (Wenzel, H.R. unpublished). The ESR spectrum of X L I I revealed a strong i n t e r a c t i o n between the two paramagnetic centers. The s p i n - l a b e l l e d p e n i c i l l i n X L I I I was synthesized by the mixed carbonic anhydride method using the mixed anhydride from XXXVII (79) and e t h y l chloroformate (80). Reagent X X X V I I I was employed in the synthesis of compound XLIV, a s p i n l a b e l l e d analogue of pepstatin used to probe the active s i t e of porcine pepsin (81). C-Terminal s p i n - l a b e l l e d peptides Again, elongation of carboxyl group s p i n - l a b e l l e d amino acids and l a b e l l i n g of s u i t a b l y protected peptides have been employed. N-Hydroxysuccinimide-coupling led from X X X I l i b to dipeptide XLVI, a z i d e coupling with XXX to t r i p e p t i d e X L V I I . In both cases the amino group which should not react was intermediately protected with the 2 - n i t r o p h e n y l sulfenyl group (74). XLVI and XLVII were used as substrate-analogous
in-
h i b i t o r s for leucine aminopeptidase (74, 82). Amine XXIX and dicyclohexylcarbodiimide were used to synthesize the s p i n l a b e l l e d pepstatin X L V I I I (81) and, with intermediate N-terminal
trifluoro-
396 Chart 3. S p i n - l a b e l l i n g of peptides
COOH
N=C=S
SL3-CH
2
XXXlXa
SL1—CO—Gly—His—OCH3
xxxixb
SL1—CO—Phe —Leu
XXXVIII
XXXVII
SL1—CO—Gly—Gly—OC2H5
-C0-Gly-Gly-Leu-Gly-0C
H
XLI
5
r
SL3-CO-NH
S H - C O - G l u L
2
XL
Cys-Gly I S XLir
S I |-Cys—Gly
XLII
COOH
SL3 —NH—C—Val—Sta—Ala—Iaa
SLI-CO-Glu
Thr—Phe—NH—SL2
xliv
xlvi
But Thr—Phe—Phe—NH—SL2
xlvii
But
Iva—Val—Val—Sta—Ala—Sta—NH—SL3 Gly—Gly—Leu—Gly—NH—SL3
XLVHI
XLIX
SL3—CH2—CO—Gly—Gly—Leu—Gly—NH—SL3
Gly—Phe—NH—SL3
n
L
lie—Val—NH—SL3
HI
397 Chart 3. (Continued)
0
rA 0
CH 2 -COOH I
NH-C-CH2I
LV
LI 11
COOH /—( 0
LVI
Cys—Tyr—NH2 I
S-CH2-CO-NH-SL2
LIV
acetylation, the tetrapeptide XLIX (78). The latter could be converted to the biradical L by the amino group-labelling procedures discussed above (78). The spin-labelled dipeptide LI, capable of binding to the hormone-binding site of neurophysin (83-86), was synthesized by a route which circumvents problems associated with nitroxide instability under standard conditions of peptide deblocking (86): The N-carbobenzoxy derivative of GlyPhe was coupled with 4-amino-2,2,6,6-tetramethylpiperidine XLV using dicyclohexyl carbodiimide / 1-hydroxybenzotriazole. The carbobenzoxy group was removed by catalytic hydrogénation and replaced by the citraconyl group. After oxidation of the piperidine to the nitroxide, the citraconyl group could be split off at pH 3 to yield LI without destroying the paramagnetic center. The same route was followed from N-carbobenzoxy-Ile-Val to the spin-labelled dipeptide L U
(Wenzel, H.R. unpublished). LII was found to bind
398 Chart 3.
(Continued) LVII
Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg
a
SL3-CH 2 -C0-Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg
b
SL3-CH 2 -CO-Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg CH 2 -C0-SL3
c
SL2 -CO-Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg CH 2 -SL2
d
SL3-CH 2 -CO-Arg-Pro-Pro-Gly-Tyr-Gly-Pro-Phe-Arg CH 2 -C0-SL3
e
SL3-CH 2 -C0-Arg-Pro-Pro-Gly-Phe-Gly-Pro-Tyr-Arg CH 2 -C0-SL3
f
Boc-Arg-Pro-Pro-Gly-Tyr-Gly-Pro-Tyr-Arg CH 2 -C0-SL3 CH 2 -C0-SL3
g
Boc-Gly-Pro-Pro-Gly-Tyr-Gly-Pro-Tyr-Arg CH2-C 0-SL3 CH 2 -CO-SL3
h
SL3-CH 2 -CO-Pro-Pro-Gly-Tyr-Gly-Pro-Phe-Arg
1
CH 2 -C0-SL3 SL3-CH 2 -C0-Pro-Pro-Gly-Phe-Gly-Pro-Tyr-Arg CH 2 -CO-SL3
j
Boc-Pro-Pro-Gly-Tyr-Gly-Pro-Tyr-Arg CH 2 -C0-SL3 CH 2 -C0-SL3
k
Boc-Tyr-Gly-Pro-Tyr-Arg CH 2 -C0-SL3 CH 2 -C0-SL3
i
Abbreviations:
- SL1,
"T
Boc, t e r t - b u t y l o x y c a r b o n y l ; B u \ Iva, i s o v a l e r y l ; Sta,
statine.
; - SL2,
—/*T
; - SL3, — /
t e r t - b u t y l ; I a a , i soamyl amide ;
N-0
;
399 strongly to the complex of trypsinogen and bovine trypsin inhibitor
(Ku-
nitz). This corroborates the proposed mechanism of trypsinogen activation (87, 88).
Side chain spin-labelled The standard spin-label
peptides reagent LI 11 (89) with high affinity for sulfhydryl
groups was used to prepare the labelled dipeptide amide LIV (86), which found application along with LI in studies on neurophysin complexes (83 86). Bradykinin LVIIa is a pharmacologically highly active nonapeptide
(90),
which has often served as model to study peptide conformations in solution. A series of mono spin-labelled, LVIIb, and bis-spin-labelled,
LVIIc-1,
bradykinins or bradykinin analogues have been prepared (91-93). The syntheses were carried out using activated derivatives of the carboxylic acids LV (94) or LVI (22), such as 4-nitrophenyl mide ester, 2,4,5-trichlorophenyl symmetrical
ester, N-hydroxysuccini-
ester, pentachlorophenyl
anhydride (95). The 4-nitrophenyl
ester and
ester proved to be most
satisfactory especially for labelling the hydroxyl
groups of serine or
tyrosine residues. On the basis of distance measurements between the paramagnetic centers of the biradicals in vitrified solutions it was proposed that conformers having a bent or pseudocyclic structure with closely adjacent N - and C-termini predominate in the conformational
equi-
librium of bradykinin (93). This hypothesis has, however, been questioned as a result of
13
C nuclear magnetic resonance studies
3. Minimum Perturbation Spin-Label
(96).
Amino Acids (Chart 4)
A continuing concern in the study of biological
systems by the spin-label
technique has been the extent to which the system under investigation is perturbed by the steric bulk of the nitroxide moiety. This is a crucial question especially when a nitroxide group is attached to a rather small molecule like a membrane component or a peptide. In an effort to minimize the perturbation of the nitroxide group on the labelled molecule, azethoxyl
spin-labelled lipids have recently been in-
400 Chart 4. Minimum s t e r i c perturbation spin-label amino acids
H 2 N ^ ^COOH CH
H2N
COOH
H
2
N ^
/COOH
CH I
I
CH2
CH2 O ^Nr +JW N O
I. 0
f Y -
LIX
LVIII
LX
C-NH HNL
X -
"N' I. 0
H2Nv/COOH "N' I.
0
LXII
H
H 2 C0H
C=N
2
N \
LX I I I
/COOH
CH
LXVI
COOBIR
LXVI I
LXVIII
LXIX
401 Chart 4. (Continued)
Ac—NNAla—Pro—Phe
LXXa
Ac—NNAla—Phe
LXXb
Ac—NNAla—Phe—Phe
LXXc
NNAla—Pro—Phe
LXXd
Abbreviations: Ac, a c e t y l ; Bu1*, tert-butyl ; NNAla, nitronyl n i t r o x i d e amino acid L V I I I . troduced (97 - 99), which have three of the f i v e atoms of the p y r r o l i d i n e ring integrated into t h e i r hydrocarbon chains. A straightforward t r a n s f e r of t h i s concept of 'minimum s t e r i c perturbation spin-labels'
to amino acids would aim at analogues which contain a
stable radical as integral part of t h e i r side c h a i n s . E f f o r t s in t h i s d i r e c t i o n w i l l be presented in the following s e c t i o n s . Nitronyl n i t r o x i d e amino acids Amino acid L V I I I , i t s acetyl and carbobenzoxy d e r i v a t i v e s and i t s a c e t y l a ted ethyl ester were prepared s t a r t i n g from N- or C-protected L - a s p a r t i c (J-semi aldehyde (100). The nitronyl n i t r o x i d e amino acid i s an e f f e c t i v e analogue of h i s t i d i n e . I t approximates the s i z e and shape of the natural amino acid and p a r a l l e l s the ion-dipole interactions observed in h i s t i d i n e d e r i v a t i v e s (100). Drawbacks in comparison with simple n i t r o x i d e s are the reduced s t a b i l i t y of nitronyl n i t r o x i d e s and t h e i r more complex ESR spectra due to s p l i t t i n g by the two r i n g nitrogens and the p-methylene protons Pyrrolidine-oxyl
derivatives
The only representative of p y r r o l i d i n e - d e r i v e d spin-label amino acids
is
p-amino acid LIX (101). I t shares a high structural r i g i d i t y with prol i n e and may become i n t e r e s t i n g in c r o s s - l i n k i n g studies or as ligand for metal
ions.
402
Pyrroline-oxyl
derivatives
Derivatives of the spin-label a-amino acid LX have been described very recently (102). S t a r t i n g from the mesylate XXXIV or the corresponding bromomethyl compound ( 7 5 ) , three d i f f e r e n t preparative methods were s u c c e s s f u l l y employed. Because of i t s structural resemblance to the natural aromatic amino a c i d s , LX i s a very promising paramagnetic amino acid synthon for studies of peptides and proteins. Piperidine-oxyl
derivatives
S t a r t i n g from ketone LXI the f i r s t member of a homologous s e r i e s of p i p e r i dine-oxyl-derived a-amino acids LXI11 can e a s i l y be prepared in two steps (101). LXI i s f i r s t converted by conventional methods (103) to the s p i r o hydantoin L X I I , which i s then hydrolyzed to y i e l d LXI11. This spin-label amino acid was used in proton NMR r e l a x a t i o n studies y i e l ding structural and dynamical parameters such as the number and l i f e t i m e of water protons in the f i r s t hydration sphere around the paramagnetic center (104). Moreover, a s e r i e s of complexes between t r a n s i t i o n metal ions and LXI11 were prepared and studied by d i f f e r e n t techniques 105, 106). Recently the ESR spectra of LXI11 and the N-acetyl
(101,
derivative
were studied as a function of pH. The pH-dependence found both for the i s o t r o p i c hyperfine s p l i t t i n g and the g value should enable these compounds to be used as pH-indicators in model and b i o l o g i c a l
systems
(107). Due to i t s r i g i d structure and the lack of an a-hydrogen, radical
LXIII
would probably not make a promising s u b s t i t u t e of natural amino acids in peptides or proteins. The next homologue, amino acid LXVI, i s c e r t a i n l y a more s u i t a b l e candidate for such an approach. I t possesses an a-hydrogen atom and shares the p-branching of i t s side chain with v a l i n e and i s o l e u cine. The synthesis of LXVI has been carried out using standard reactions (Wenzel, H.R. unpublished). Treatment of ketone LXI with tosylmethyl isocyanide in the presence of base (108) yielded the n i t r i l e LXIV (79). A l k a l i n e h y d r o l y s i s gave the corresponding carboxylic acid ( 7 9 ) , which
403 was reduced by lithium aluminum hydride to the primary alcohol Pyridinium dichromate in methylene chloride
LXV
(109).
(110) allowed the oxidation
of LXV to the corresponding a-ldehyde, which had previously been prepared by a more laborious procedure (111). Conversion to the hydantoin
followed
by alkaline hydrolysis yielded the amino acid LXVI. The homologous amino acid LXIX closely approaches the requirements for an ideal spin-label
reporter group, as its structure and dimensions
favourably compare with those of the natural amino acids and tyrosine
phenylalanine
(112).
The last steps of its synthesis (Wenzel, H.R. unpublished) parallel
those
of the two amino acids described above. A suitable intermediate was the unsaturated ester LXVII, which could be prepared from ketone LXI and tert-butyl
trimethylsilylacetate
(113). Reduction of the ester group
with lithium aluminum hydride and subsequent catalytic hydrogenation of the exo double bond yielded the primary alcohol
LXVI11, whose
synthesis
involving a Wittig reaction was mentioned in a short note (114). Pyridinium dichromate oxidation to the aldehyde, hydantoin formation and alkaline hydrolysis led to the amino acid LXIX.
Peptides with integrated
spin-labels
The paramagnetic analogues LXXa-d of angiotensin fragments have been prepared by solid-phase methods using suitably N-protected derivatives of the nitronyl
nitroxide amino acid LVIII (115). The ESR spectra of these
peptides changed with pH in a way which indicated the existence of an ion-dipole bond between the phenylalanine carboxylate group and the nitronyl nitroxide ring system. Solid-phase peptide synthesis also yielded the dipeptide LXXI with the piperidine-oxyl
amino acid LXIII incorporated
(107).
It can certainly be expected that this short list will soon be substantially enlarged. Incorporation of minimum steric perturbation amino acids into a peptide or protein can be achieved by total
spin-label synthesis
(116, 117) or by semisynthetic methods using naturally occurring
peptide
fragments (118). Situated at a well chosen site of a peptide chain the spin-label
could
'report the news in its environment and not make the
news (1)', as it is to be postulated from an ideal reporter group.
404 The literature has been reviewed up to June 1982. Acknowl edgement Our own spin-label work has been supported by the Deutsche Forschungsgemeinschaft .
References 1.
Berliner, L.J., ed.: Spin Labeling Theory and Applications, Academic Press, New York 1976.
2.
Berliner, L.J., ed.: Spin Labeling II Academic Press, New York 1979.
3.
Likhtenshtein, G.I.: Spin Labeling Wiley-Interscience, New York 1976.
4.
Hyde, J.S.: Meth. Enzymol. 49, 480-511 (1978).
5.
Jost, P., Waggoner, A.S., Griffith, O.H.: in Structure and Function of Biological Membranes, Rothfield, L.I., ed., Academic Press, New York 1971, pp. 83-144.
6.
Keith, A.D., Sharnoff, M., Cohn, G.E. : Biochim. Biophys. Acta 300, 379-419 (1973).
7.
Gaffney, B.J.: Meth. Enzymol. 32, 161-197 (1974).
8.
Cafiso, D.S., Hubbell, W.L.: Ann. Rev. Biophys. Bioeng. 10, 217-244 (1981).
9.
Caspary, W.J., Greene, J.J., Stempel, L.M., Ts'o, P.O.P.: Nucleic Acids Res. 3, 847-861 (1976).
10.
Dugas, H.: Acc. Chem. Res. 10, 47-54 (1977).
11.
Kamzolova, S.G., Postnikova, G.B.: Quart. Rev. Biophys. 14, 223-288 (1981),
12.
Wenzel, H.R., Pfleiderer, G., Trommer, W.E., Paschenda, K., Redhardt Biochim. Biophys. Acta 452, 292-301 (1976).
Theory and Applications,
Methods in Molecular Biology,
13.
Sinha, B.K., Chignell, C.F.: Meth. Enzymol. 62, 295-308 (1979).
14.
Misharin, A.Yu., Polyanovsky, O.L., Timofeev, V.P.: Meth. Enzymol. 62, 495-510 (1979).
15.
Darcy, R., McGeeney, K.F.: Experientia 32, 1129-1131 (1976).
16.
Adam, M.J., Hall, L.D.: Carbohydrate Res. 68, C17-C20 (1979).
17.
Hamilton, C.L., McConnell, H.M.: in Structural Chemistry and Molecul Biology, Rich, A., Davidson, N., eds., W.H. Freeman and Co., San Francisco 1968, pp. 115-149.
405 18.
Ingham, J.D.: J. Macromol . Sei.-Revs. Macromol. Chem. C2, 279-302 (1968).
19.
Griffith, O.H., Waggoner, A.S.: Acc. Chem. Res. 2, 17-24 (1969).
20.
Feher, G.: Electron Paramagnetic Resonance with Applications to Selected Problems in Biology, Gordon and Breach, New York 1970.
21.
McConnell, H.M., McFarland, B.G.: Quart. Rev. Biophys. 3, 91-136 (1970).
22.
Rozantsev, E.G.: Free Nitroxyl Radicals, Plenum Press, New York 1970.
23.
Jost, P., Griffith, O.H.: Meth. Pharmacol. 2, 223-276 (1972).
24.
Smith, I.C.P.: in Biological Applications of Electron Spin Resonance, Swartz, H.M., Bolton, J.R., Borg, D.C., eds., Wiley-Interscience, New York 1972, pp. 483-539.
25.
Dugas, H.: Can. J. Spectrosc. 18, 110-118 (1973).
26.
Dwek, R.A.: Nuclear Magnetic Resonance in Biochemistry: Applications to Enzyme Systems, Clarendon Press, Oxford 1973.
27.
Kalmanson, A.E., Grigoryan, G.L.: in Experimental Methods in Biophysical Chemistry, Nicolau, C., ed., J. Wiley & Sons, London 1973, pp. 589-612.
28.
Lassmann, G.: in ESR und andere spektroskopische Methoden in Biologie und Medizin, Wyard, S.J., ed., Akademie-Verlag, Berlin 1973, pp. 381-403.
29.
Berliner, L.J.: Prog. Bioorg. Chem. 3, 1-80 (1974).
30.
Axel, F.S.: Biophys. Struct. Mechanism 2, 181-218 (1976).
31.
Smith, I.C.P., Schreier-Muccillo, S., Marsh, D.: in Free Radicals in Biology, Vol. 1, Pryor, W.A., ed., Academic Press, New York 1976, pp. 149-197.
32.
Berliner, L.J.: Meth. Enzymol. 49, 418-480 (1978).
33.
Jost, P.C., Griffith, O.H.: Meth. Enzymol. 49, 369-418 (1978).
34.
Keana, J.F.W.: Chem. Rev. 78, 37-64 (1978).
35.
Hsia, J.C.: Ph.D. Thesis, University of Hawaii (1969).
36.
Gerig, J.T., Reinheimer, J.D., Robinson, R.H.: Biochim. Biophys. Acta 579, 409-420 (1979).
37.
Cazianis, C.T., Sotiroudis, T.G., Evangelopoulos, A.E.: Biochim. Biophys. Acta 621, 117-129 (1980).
38.
Lawrence, J.-J., Berne, L., Ouvrier-Buffet, J.L., Piette, L.H.: Eur. J. Biochem. 107, 263-269 (1980).
39.
Shaltiel, S.: Biochem. Biophys. Res. Commun. 29, 178-183 (1967).
40.
Benson, W.R., Maienthal, M., Yang, G.C., Sheinin, E.B., Chung, C.W.: J. Med. Chem. 20, 1308-1312 (1977).
41.
Defaye, G., Basset, M., Chambaz, E.M.: Bull. Soc. Chim. Fr. 1978 II, 471-473.
42.
Cor.vaja, C., Giacometti, G., Kopple, K.D., Ziauddin: J. Am. Chem. Soc. 92, 3919-3924 (1970).
406 43.
Hoffman, B.M., Schofield, P., Rich, A.: Proc. Natl. Acad. Sci. USA 62, 1195-1202 (1969).
44.
Tsetlin, V.I., Karlsson, E., Arseniev, A.S., Utkin, Yu.N., Surin, A.M., Pashkov, V.S., Pluzhnikov, K.A., Ivanov, V.T., Bystrov, V.F., Ovchinnikov, Yu. A.: FEBS Lett. 106, 47-52 (1979).
45.
Ellena, J.F., McNamee, M.G.: FEBS Lett. 110, 301-304 (1980).
46.
Adackaparayil, M., Smith, J.H.: J. Org. Chem. 42, 1655-1656 (1977).
47.
Barratt, M.D., Dodd, G.H., Chapman, D.: Biochim. Biophys. Acta 194, 600-602 (1969).
48.
Chan, D.C.F., Piette, L.H.: Biochim. Biophys. Acta 623, 32-45 (1980).
49.
Mehlhorn, R., Swanson, M., Packer, L., Smith, P.: Arch. Biochem. Biophys. 204, 471-476 (1980).
50.
Hunter, M.J., Ludwig, M.L.: Meth. Enzymol. 25, 585-596 (1972).
51.
Kenyon, G.L., Bruice, T.W.: Meth. Enzymol. 47^, 407-430 (1977).
52.
Berliner, L.J., Grunwald, J., Hankovszky, H.O., Hideg, K.: Anal. Biochem. 119, 450-455 (1982).
53.
McCalley, R.C., Shimshick, E.J., McConnell, H.M.: Chem. Phys. Lett. 13_, 115-119 (1972).
54.
Wenzel, H.R., Becker, G., von Goldammer, E.: Chem. Ber. Ill, 2453-2454 (1978).
55.
Hankovszky, H.O., Hideg, K., Lex, L., KulcsSr, G., Halasz, H.A.: Can. J. Chem. 60, 1432-1438 (1982).
56.
Keana, J.F.W., Hideg, K., Birrell , G.B., Hankovszky, O.H., Ferguson, G., Parvez, M.: Can. J. Chem. 60, 1439-1447 (1982).
57.
Price, N.C.: FEBS Lett. 36, 351-354 (1973).
58.
Venkataramu, S.D., Pearson, D.E., Beth, A.H., Perkins, R.C., Park, C.R., Park, J.H.: J. Labelled Compd. 18, 371-383 (1979).
59.
Beth, A.H., Venkataramu, S.D., Balasubramanian, K., Dalton, L.R., Robinson, B.H., Pearson, D.E., Park, C.R., Park, J.H.: Proc. Natl. Acad. Sci. USA 78, 967-971 (1981).
60.
Beth, A.H., Balasubramanian, K., Wilder, R.T., Venkataramu, S.D., Robinson, B.H., Dalton, L.R., Pearson, D.E., Park, J.H.: Proc. Natl. Acad. Sci. USA 78, 4955-4959 (1981).
61.
Hideg, K., Lex, L., Hankovszky, H.O., Tigyi, J.: Synthesis 1978, 914-917.
62.
Griffith, O.H., Keana, J.F.W., Noall , D.L., Ivey, J.L.: Biochim. Biophys. Acta 148, 583-585 (1967).
63.
Hankovszky, H.O., Hideg, K., Tigyi, J.: Acta Chim. Acad. Sci. Hung. 98, 339-348 (1978).
64.
Golding, B.T., Ioannou, P.V., O'Brien, M.M.: Synthesis 1975, 462-463.
65.
Alcock, N.W., Golding, B.T., Ioannou, P.V., Sawyer, J.F.: Tetrahedron 33, 2969-2980 (1977).
407 66.
Hankovszky, H.O., Hideg, K . , L e x , L . , T i g y i , S y n t h e s i s 1979, 530-531.
J.:
67.
S o s n o v s k y , G., Konieczny, M.: S y n t h e s i s 1976, 537-539.
68.
S o l t i s , B . J . , H s i a , J . C . : J . B i o l . Chem. 253, 3029-3034
(1978).
69.
S o l t i s , B . J . , H s i a , J . C . : J. B i o l . Chem. 253, 4266-4269
(1978).
70.
H s i a , J . C . , E r , S . S . , Tan, C . T . , T i n k e r , D.O.: J . B i o l . Chem. 257, 1724-1729 ( 1 9 8 2 ) .
71.
Rosen, G.M.: J . Med. Chem. 17_, 358-360
72.
Misharin, A.Yu., Vinokurov, L.M., Polyanovskii, O.L.: I z v . Akad. Nauk SSSR, S e r . Khim. 1974, 1897-1898.
73.
P i r r w i t z , J . , Damerau, W.: Z. Chem. J j s 401-402
74.
F i t t k a u , S . , Damerau, W.: J . P r a k t . Chem. 322, 1032-1038
75.
Hankovszky, H.O., Hideg, K . , Lex, L . : S y n t h e s i s 1980, 914-916.
76.
K a l k , A . , de Jong, A . S . H . , B a r r a t t , M.D.: FEBS L e t t . 60, 58-61 ( 1 9 7 5 ) .
77.
K a l k , A . : Ph.D. T h e s i s , R i j k s u n i v e r s i t e i t , Groningen, Netherlands
78.
Maksimova, L . A . , G r i g o r y a n , G . L . , Rozantsev, E . G . : I z v . Akad. Nauk S S S R , S e r . Khim. 1975, 945-948.
79.
Rauckman, E . J . , Rosen, G.M., Abou-Donia, M . B . : J. Org. Chem. 564-565 ( 1 9 7 6 ) .
80.
Goldberg, J . S . , Rauckman, E . J . , Rosen, G.M.: Biochem. B i o p h y s . Res. Commun. 79, 198-202 ( 1 9 7 7 ) .
81.
Schmidt, P . G . , B e r n a t o w i c z , M . S . , R i c h , D . H . : B i o c h e m i s t r y 2^, 1830-1835 ( 1 9 8 2 ) .
82.
F i t t k a u , S . , Kämmerer, G., Damerau, W.: Ophthalmic Res. U , 381-385 ( 1 9 7 9 ) .
83.
Lundt, S . L . , B r e s l o w , E . : J. Phys. Chem. 80, 1123-1126
84.
Lord, S . T . , B r e s l o w , E . : Biochem. B i o p h y s . Res. Commun. 8 0 , 63-70
85.
Lord, S . T . , B r e s l o w , E . : I n t . J . Peptide P r o t e i n Res. U ,
(1974).
(1976). (1980).
(1975).
(1976). 71-77
(1978).
(1979).
86.
Lord, S . T . , B r e s l o w , E. : B i o c h e m i s t r y lj}, 5593-5602
87.
Bode, W., Huber, R . : FEBS L e t t . 68, 231-236
(1980).
88.
Bode, W.: J . Mol. B i o l . 127, 357-374
89.
Ogawa, S . , McConnell , H.M.: Proc. N a t l . Acad. S e i . USA 58, 19-26
90.
R e g o l i , D . , Barabe, J . : Pharmacol. Rev. 32, 1 - 4 6 ( 1 9 8 0 ) .
91.
F i l a t o v a , M . P . , Reissmann, S . , Ravdel , G . A . , I v a n o v , V . T . , G r i g o r y a n , G . L . , S h a p i r o , A . B . : i n Peptides 1972, Hanson, H . , Jakubke, H . - D . , e d s . , North Holland Publ. C o . , Amsterdam 1973, pp. 333-340.
92.
Reissmann, S . , F i l a t o v a , M . P . , Reutova, T . O . , A r o l d , H . , I v a n o v , J . P r a k t . Chem. 318, 429-440 ( 1 9 7 6 ) .
93.
F i l a t o v a , M . P . , Reissmann, S . , Reutova, T . O . , I v a n o v , V . T . , G r i g o r y a n , G . L . , S h a p i r o , A . M . , R o z a n t s e v , E . G . : B i o o r g . Khim. 3, 1181-1189 ( 1 9 7 7 ) .
(1976).
(1979). (1967).
V.T.:
408 94.
Shapiro, A.B., Baimagambetov, K., Gol'dfel'd, M.G., Rozantsev, E.G.: Zh. Org. Khim. 8, 2263-2269 (1972).
95.
Reißmann, S., Arold, H., Filatova, M.P., Reutova, T.O., Ivanov, V.T.: Z. Chem. 15, 399-400 (1975).
96.
London, R.E., Stewart, J.M., Cann, J.R., Matwiyoff, N.A.: Biochemistry 1_7, 2270-2277 (1978).
97.
Lee, T.D., Birrell, G.B., Keana, J.F.W.: J. Am. Chem. Soc. 100, 1618-1619 (1978).
98.
Lee, T.D., Keana, J.F.W.: J. Org. Chem. 43, 4226-4231 (1978).
99.
Lee, T.D., Birrell, G.B., Bjorkman, P.J., Keana, J.F.W.: Biochim. Biophys. Acta 550, 369-383 (1979).
100.
Weinkam, R.J., Jorgensen, E.C.: J. Am. Chem. Soc. 93, 7028-7033 (1971).
101.
Rassat, A., Rey, P.: Bull. Soc. Chim. Fr. 1967, 815-817.
102.
Lex, L., Hideg, K., Hankovszky, H.O.: Can. J. Chem. 60, 1448-1451
(1982).
103.
Bucherer, H.T., Lieb, V.A.: J. Prakt. Chem. 141, 5-43 (1934).
104.
v. Goldammer, E., Kreysch, W., Wenzel, H.: J. Solution Chem. 2 , 197-204 (1978).
105.
Jahr, D., Rebhan, K.H., Schwarzhans, K.E., Wiedemann, J.: Z. Naturforsch. 28b, 55-62 (1973).
106.
Terzian, G., Cormons, A., Asso, M., Benl'ian, D.: J. Chim. Phys. 73, 146-148 (1976).
107.
Nakaie, C.R., Goissis, G., Schreier, S., Paiva, A.C.M.: Brazilian J. Med. Biol. Res. 14, 173-180 (1981).
108.
Oldenziel, O.H., van Leusen, D., van Leusen, A.M.: J. Org. Chem. 42, 3114-3118 (1977).
109.
Rauckman, E.J., Rosen, G.M.: Synth. Commun. 6, 325-329 (1976).
110.
Corey, E.J., Schmidt, G.: Tetrahedron Lett. 1979, 399-402.
111.
Schlude, H.: Tetrahedron ^9, 4007-4011 (1973).
112.
Morrisett, J.D.: in Spin Labeling Theory and Applications, Berliner, L.J., ed., Academic Press, New York 1976, pp. 273-338.
113.
Rosen, G.M., Rauckman, E.J.: Org. Prep. Proc. Int. 10, 17-20 (1978).
114.
Szykula, J., Zabza, A.: Experientia 36, 149-150 (1980).
115.
Weinkam, R.J., Jorgensen, E.C.: J. Am. Chem. Soc. 93, 7033-7038 (1971).
116.
Gross, E., Meienhofer, J., eds.: The Peptides, Analysis, Synthesis, Biology, Vol. 1, Major Methods of Peptide Bond Formation, Academic Press, New York 1979.
117.
Gross, E., Meienhofer, J., eds.: The Peptides, Analysis, Synthesis, Biology, Vol. 2, Special Methods in Peptide Synthesis, Part A, Academic Press, New York 1980.
118.
Offord, R.E.: Semisynthetic Proteins, John Wiley & Sons Ltd., Chichester 1980.
THE ULTRASTRUCTURE OF MACROMOLECULAR COMPLEXES STUDIED WITH ANTIBODIES
Georg Stöffler and Marina Stoffler-Meilicke Max-Planck-Institut für Molekulare Genetik, Abt. Wittmann, Berlin-Dahlem, Germany
I. Introduction The translation of mRNA into protein occurs on ribosomes with the participation of macromolecules such as tRNAs and protein synthesis factors. The factors play important roles during the three main steps of the cycle of protein synthesis, namely initiation, elongation and termination. Ribosomes are nucleoprotein particles which consist of two subunits of unequal size. The most extensively studied species of ribosomes is that of Escherichia coli. One of the main topics on which research into bacterial ribosome structure has recently concentrated was directed towards the description of the shape of ribosomal particles and on studies as to the spatial arrangement of the various ribosomal components, i.e. ribosomal topography (1-6). Another main objective from the very beginning was to relate the three-dimensional distribution of ribosomal proteins and rRNAs to ribosomal function. The small subunit recognizes the initiation site on mRNA with the participation of three initiation factors and initiator tRNA. It is responsible for the binding of aminoacyl tRNAs and for the translational fidelity of messenger reading. The large subunit binds the acceptor stem of aminoacyl tRNAs, catalyses peptide bond formation and participates in translocation and chain termination.
Modern Methods in Protein Chemistry - Review Articles © 1983 by Walter de Gruyter & Co. - Berlin • New York
410
The localization of functional domains can be approached by relating the three-dimensional distribution of ribosomal proteins and of rRNA to known biochemical information on the functional contribution of individual ribosomal components. Such attempts to localize functional domains have been published (1,7) . The unraveling of the structure and insight into the details of the function of E^ coli is derived from a variety of technologies: the isolation, purification and chemical and physical characterization of the proteins of E^ coli ribosomes (8), the structure determination of the ribosomal RNAs (9), the reconstitution of active ribosomal subunits from their molecular components, i.e., from RNA and protein (4,5). The topography of ribosomal components has been studied by immuno electron microscopy, by crosslinking experiments, neutron scattering studies and by enery transfer (1-7, 9). Since 1968 a concentrated effort has been undertaken to use antibodies in the analysis and function of ribosomes. It occurred to us fifteen years ago that the immunochemical methods that had been used to explore the structure of enzymes might well be applied to more complex assemblies and perhaps even to organelles. For this reason we began to raise antibodies against Escherichia coli ribosomes, ribosomal subunits and then, as they became available, against each of the 53 individual ribosomal proteins. The purpose of this article is to show the contribution which immunochemical experiments have made to the knowledge of the structure and function of ribosomes (reviewed in 1, 2, 7, 10-14). Most of the experiments have been performed with antisera to Escherichia coli ribosomes, some antisera were raised against
411
ribosomes from other bacterial species (e.g.. Bacillus stearothermophilus, Bacillus subtilis), from plants (cytoplasmic and chloroplast), from chicken and from mammals (preferentially rat). Bacterial and plant ribosomes and their subunits are strongly immunogenic in mice, rabbits and sheep, more immunogenic than mixtures of extracted ribosomal proteins. Immunisation with ribosome particle leads to the formation of precipitating antibodies directed primarly against the protein; formation of precipitating antibodies to RNA is an exceptional occurrence (1,10). Ribosomal proteins from chicken liver and rat liver are less immunogenic than bacterial ribosomal proteins (11-13); reasonable antisera can be obtained by immunizing sheep, rabbit or swine (11-14). Only few attempts have so far been made to use monoclonal antibodies (15, 16); they may however become very useful for several applications in the near future. Most of the immunological techniques applied for the elucidation of ribosome structure and function may be applied in other research fields for the study of other complex structures, such as multienzyme complexes or for the study of a variety of enzymes and proteins in cell membranes and organelles.
II. Molecular Composition and Shape of the E. coli Ribosome Before discussing immunochemical methods it is necessary to describe the components which build up the ribosome as well as the shape of ribosomes and of ribosomal subunits. Molecular composition Bacterial ribosomes sediment with a sedimentation co-
412
32 Proteins
21 Proteins
[ Z M.W. 460.000]
IXM.W350.000]
Figure 1: Molecular composition of E^ coli ribosomes (modified from reference 17) efficient of 70S. By lowering the magnesium ion concentration, 70S ribosomes dissociate into two subunits of unequal size, the small 30S subunit and the large 50S subunit. The 30S subunit consits of one 16S RNA molecule (1542 nucleotides) and 21 proteins which are numbered in E^ coli S1-S21. The 50S subunit contains two RNA molecules, the small 5S RNA (120 nucleotides) and the large 23S RNA (2904 nucleotides) and 32 proteins, designated L1-L34 (Fig. 1). The rRNA molecules represent two-thirds of the mass of a ribosome. Sequence studies have provided us with the complete primary structures of the RNA and protein moieties of E^ coli ribosomes (for review see 8, 9).
413
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Figure 6: Antibody-ribosome complex formation after centrifugation of 50S subunits with increasing antibody concentrations (anti-L11) in sucrose gradients: (a,e) 50S subunits; (b-d) 50S subunits + a 30 to 170fold excess of IgG; (f-h) 50S subunits + a 3 to 9fold molar excess of specific IgG which had been purified by affinity chromatography (36). Peak 1 = 50S-IgG-50S complexes; Peak 2 = 50S subunits; Peak 3 = IgG. Methods which employ sedimentation select for the binding of those antibodies which have an affinity sufficiently high to survive centrifugation. Antibodies to proteins S9 and S12 did not form such Complexes, although these antibodies reacted with 30S subunits under the equilibrium conditions that prevail in double antibody precipitation assays. On the other hand, antibodies to protein S1 removed the antigen from the 30S particle (unpublished observation).
421
IV. Protein Topography in Ribosomal Subunits The principle of immuno electron microscopy is to bind a purified IgG-antibody, specific to a single ribosomal protein, to the appropriate ribosomal subunit; the bivalent antibody dimerizes two subunits which can then be examined under the electron microscope. The location of the bound antibody on the subunit surface can be determined and the position of an antigenic determinant of a particular protein can thus be directly made visible. The dimeric immunocomplexes obtained by density gradient centrifugation (Fig. 6, peak 1) are directly used for specimen preparation. The 30S subunit Figure 7 shows examples of electron micrographs of small subunits reacted with protein-specific antibodies. Images of subunits connected by an IgG molecule are easily recognized, and the location of the antibody attachment site can readily be described in two dimensions. For example, antibodies against proteins S10 and S13 bind at the head of the small subunit (Fig. 7a,b), anti-S11 and anti-S18 bind at the large lobe (Fig. 7e,f) and anti-S17 binds near the lower pole (Fig. 7h). In order to determine the three-dimensional location of a given protein it is necessary to locate the antibody attachment site to subunits seen in different orientations. This proceedure is exemplified in Figure 3 for the location of protein S15. Determination of the antibody binding site on all four projections (Fig. 8) led to the three-dimensional location as shown in Figure 11. Thus 15 of the 21 ribosomal proteins have been localized in three dimensions on the surface of the 30S subunit of E^ coli at distinct sites (Fig. 11).
422
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w m Figure 8: General field and selected electron micrographs of 30S subunits, reacted with anti-S15. The interpretative diagrams relate to the micrograph to their left and illustrate antibody binding to the different 30S projections.
Figure 7: Electron micrographs of 30S subunits, reacted with anti-S13 (a), anti-S10 (b), anti-S5 (c), anti-S4 (d), anti-S11 (e) , anti-S18 (f), anti-S6 (g) and anti-S17 (h) . »-30S-IgG-30S complexes, 30S-IgG-30S complexes, in which two antibodies are simultaneously bound.
424
425
Protein S8 has been mapped in previous studies by Tischendorf et al. (31) and by Lake (32). The specificity of the antibody was not sufficiently proven by either group (see below). It is, however, very likely from other studies (protein-protein crosslinking and neutron scattering) that protein S8 is located at the one-third/two-thirds partition. The 30S proteins are localized in distinctive domains (Fig. 11). There are two domains on the head of the subunit, one of them comprises proteins S3, S10 and S14. The second domain comprises proteins S7, S13 and S19. There is evidence that protein S9 is also located at the head of the 30S subunit. Four proteins are located on the larger lobe, whereas three proteins, viz. S4, S5 and S16 are located at or below the small lobe (Fig. 11). Proteins S12 and S20 are, according to preliminary data, also in this region. The antigenic sites of two proteins, namely S15 and S17, have been mapped at the body of the 30S subunit. The distribution of the proteins in domains agrees well with other studies on protein topography, e.g. protein-protein crosslinking (34) and neutron scattering (35). The 50S subunit Altogether, 14 of the 32 ribosomal proteins of the 50S subunit have been mapped in comprehensive studies. Figure 9 shows general fields of electron micrographs obtained from 50S subunits which had been incubated with protein-specific antibodies. Since 50S subunits are predominantly observed in the crown-view, a two-dimensional localization of the antibody binding site on this projection is easily achieved: Figure 9: Electron micrographs of 50S subunits, reacted with anti-L1 (a), anti-L18 (b), anti-L11 (c), anti-L7/L12 (d), anti-L19 (e), anti-L17 (f), anti-L9 (g) and anti-L23 (h). Arrows indicate characteristic 50S-IgG-50S complexes.
426
For example, anti-L1 binds to the broad lateral protuberance (Fig. 9a), anti-L18 to the central protuberance (Fig. 9b), and anti-L7/L12 to the rod-like appendage (Fig. 9d). For an unambiguous three-dimensional localization it is necessary to determine the antibody binding site also on the kidney projection. This necessity is illustrated by the example in Fig. 10: The binding sites for antibodies against L17 and L19 are indistinguishable from each other when only the crown-view is considered (first row), but they are clearly seen to be different in the kidney-view (second row) Complexes, in which a crown form is connected with a kidney projection prove that (because of the identity of the two Fab-arms of one IgG molecule) the two sites observed on the two-dimensional electron micrographs correspond to a single
a-L17
a-L19
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Figure 10: Selected electron micrographs and interpretative diagrams of 50S subunits, reacted with anti-L17 (left) and anti-L19 (right).
427
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%
19
Figure 11: Three-dimensional models of the 30S (a) and the 50S subunit (b) of E^ coli with the locations of the centers of the antibody binding sites for individual proteins. site in the three-dimensional structure (Fig. 11). Thus the binding site on both crown- and kidney-views has been determined for antibodies specific for 14 proteins of the 50S subunit, the resulting three-dimensional locations of these proteins are given in Figure 11. As in the 30S subunit, the proteins are clustered in domains. The central protuberance contains antigenic determinants of proteins L18 and L25, both of which bind independently to 5S RNA. This data is in agreement with the location of the 3'-end of 5S RNA (see Chapter V). Protein L27 is, according to Lake (36) , also located on this protuberance. Another domain is found on the broad lateral protuberance and comprises proteins L1 and L9. The stalk contains antigenic determinants of L7/L12, whereas the protuberance from which the stalk originates contains proteins L6, L10 and L11. A
428
determinant of protein L19 was found slightly separated from the latter domain (Fig. 11). Another domain is on the concave surface of the 50S subunit, below proteins L1 and L9 and comprises determinants of proteins L23 and L29. Protein L17 has been mapped on a unique position. The domain structure as found by immuno electron microscopy also agrees in principle with other topographical studies as described above (4-6) . Determination of antibody specificity It is a general working principle in immunochemistry that it should always be assumed that an antigen which is pure by biochemical criteria, is not pure immunologically. The consequences of this assumption have been drawn by most investigators working with antisera against pure ribosomal proteins. Double
immunodiffusion, quantitative immunopreci-
pitation, Immunoelectrophoresis etc. have been used for assessing the purity of the various antisera. The purity, as established by these criteria, was sufficient for most applications. Impure antisera have also been purified by immunoaffinity chromatography (37). When studying the reaction of antibodies with ribosomal particles it is essential to prove the specificity of that particular interaction, since a small population of contaminating antibodies which escaped detection with the above mentioned techniques may be very reactive with determinants on the intact particle. Therefore, even for "pure" antisera, it cannot a priori be assumed that the antibodies react only with the antigen protein and no other protein in situ. Several methods have so far been applied for testing antibody specificity, none of which was sufficient to prove the specificity of the antibodies used for immuno electron microscopy (1, 7, 22, 30, 31, 36, 37).
429 We have recently developed a series of control experiments which clearly eliminate effects of contaminating and crossreacting antibody (38). Dimeric immunocomplexes must be completely abolishable by preincubation of the antibody with stoichiometric amounts of the antigen protein. An example of such an adsorption experiment is shown in Figure 12a. This experiment clearly shows that the determinant to which antiLi 1 binds, is contained in protein L11. The experiment does, however, not exclude that the reactive determinant on the ribosome is present on another protein which has the same determinant. It is possible that some antibody to protein L11 may bind to protein L16, since both proteins contain a common hexapeptide (Thr-Phe-Val-Thr-Lys-Thr). Such cases of crossreactivity may frequently occur, since common tetrapeptides have been found with a high frequency (reviewed in 8) and a tetrapeptide is the minimal size for an antigenic determinant. A second control is thus necessary. The formation of dimeric immuno-complexes should also be inhibitable with a mixture of all ribosomal proteins (Fig. 12b), but not with total proteins lacking the protein to be mapped (Fig. 12c). Such mixtures can be obtained in various ways. (1) The most easiest way is the use of mutants which lack a single protein; a mutant lacking protein L11 exists (39). (2) A mixture of single ribosomal proteins, omitting the protein in question, can be prepared. (3) Total ribosomal protein can be passed over an immunoaffinity column to which an antibody against the particular protein has been bound (to be published). It is clear that this second type of control experiments is also necessary when monoclonal antibodies are being used. The mapping data for the proteins shown in Figure 11 have all been performed with the complete set of these control experiments.
430
50 S • anti - L 11 • ljig SP L11
• 2¿ig SP L11
•5/ig SP L11
• 25 Jig TP 70 WT
.50/ig TP 70 WT
•100¿ig TP 70 WT
• 25(¿g TP 70 AM 68
.50/ig TP 70 AM 66
•100 /ig TP 70 AM 66