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English Pages 725 [728] Year 1983
Lectins Biology, Biochemistry, Clinical Biochemistry Volume 3
Lectins
Biology, Biochemistry, Clinical Biochemistry Volume 3 Proceedings of the Fifth Lectin Meeting Bern, May 31 - June 5,1982 Editors T. C. Bog-Hansen G. A. Spengler
W DE G Walter de Gruyter • Berlin • New York 1983
Editors Thorkild Christian Bog-Hansen, cand. scient., lie. techn. The Protein Laboratory University of Copenhagen Sigurdsgade 34 DK-2200 Copenhagen N Georg Alexander Spengler, PD Dr. med. Institute for Clinical Protein Research University of Bern Tiefenauspital CH-3004 Bern
Library of Congress Cataloging in Publication Data Library of Congress Cataloging in Publication Data Lectin Meeting (5th: 1982: Bern, Switzerland) Proceedings of the Fifth Lectin Meeting, Bern, May 31 - June 5,1982. (Lectins-biology, biochemistry, clinical biochemistry; v. 3) Bibliography: p. Includes indexes. 1. Lectins-Congresses. I. Bog-Hansen, T. C. (Thorkild Christian), 1939 . II. Spengler, G. A. (Georg Alexander), 1928. III. Title. IV. Title: Proceedings of the 5th Lectin Meeting. V. Series. QP552.L42L4 1982 599'.029 83-5134 ISBN 3-11-009504-1
CIP-Kurztitelaufnahme der Deutschen Bibliothek Lectins, biology, biochemistry, clinical biochemistry: proceedings of the . . . Lectin Meeting. - Berlin; New York: de Gruyter. NE: Lectin Meeting Vol. 3 = 5 . Bern, May 31 - June 5,1982. - 1983. ISBN 3-11-009504-1
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, Berlin. - Binding: Dieter Mikolai, Berlin. - Printed in Germany.
Preface
At the end of the Fourth Lectin Meeting in Copenhagen in June 1981 we decided that future meetings should be organized at varying locations and on a collaborative basis.
Therefore, from
May 31 through June 5, 1982, the Fifth International Lectin Meeting 'INTERLEC 5' was held in Switzerland in cooperation of the Universities of Copenhagen and of Bern. Over 100 participants attended the following sessions:
Detec-
tion of Cancer Markers; Biological Function and Biological Effects of Lectins; and Lectins as Specific Tools.
Eighty five
communications (lectures and poster presentations) were given, the majority of which appears in this volume.
Although the
scope of topics in the present book is wide again - as it should be from a meeting covering the whole range of recent progress in the rapidly developing field of lectins - it is noteworthy that a great many contributions were centered on interactions of lectins with normal or malignant cells, opening new and exciting aspects for the application of these natural tools, e. g. in transplantation immunology and tumor diagnosis. In addition to the scientific sessions, the Third Meeting of the International Working Party on Standardization of Lectins for Diagnosis was held, and a test program for con A from different sources was set up. After four successive meetings in Copenhagen, it was indeed a challenge to organize 'INTERLEC 5' in Bern. It was for the large number and the scientific quality of the presentations, as well as for the high spirits that prevailed throughout the entire meeting that this event was particularly rewarding and unforgettable for the organizers. We wish to express our sincere appreciation to all participants of 'INTERLEC 5' and to thank Dr. B.Nordbring-Hertz, Lund, for her helpful assistance in planning the meeting.
VI
'INTERLEC 5' was generously supported by the following institutions and companies (in alphabetical order):
The Authorities
of the State and of the City of Bern; Behringwerke AG, Marburg, Lahn; Boehringer Mannheim GmbH, Hamburg; Koechst-Pharma AG, Zurich;
Medac GmbH, Hamburg; Miles Italiana S.p.A., Cavenago
Brianza, Milano; Riact, Copenhagen.
Their help has been greatly
appreciated. 'INTERLEC 5' will be held in 1984, and we look forward to meet you again at our next lectin meeting. Copenhagen and Bern, January, 1983 T.C.B0g-Hansen and G.A.Spengler
VII
Obituary
During preparation of this volume, we recieved notice that one of the devoted participants of the INTERLEC meetings had unexpectedly deceased.
Prof.Dr.med. Gunther Hermann, Docteur de
l'Université de Paris, mention Sciences, Chief of the Immunological Division at the Surgical University Hospital in Cologne, was born September 20, 1924, in Stuttgart and died August 20, 1982, in Avignon. We mourn for Gunther Hermann and we shall always remember him as a distinguished scientist and a devoted friend of the lectinologic community. Copenhagen and Bern, January, 1983 T.C.B0g-Hansen and G.A.Spengler
T A B L E
OF
C O N T E N T S
INTRODUCTION: DEFINITION OF LECTIN A note on the recent discussion on definition of the term "lectin" J. Kocourek, V. Horejsi
3
PART I. BIOLOGICAL EFFECTS OF LECTINS Mechanisms of induction of transplantation tolerance in mice by lectin treatment I. Hilgert, V. Horejsi, H. Kristofova, P. Angelisova
9
The effect of lentil lectin treatment on skin allograft survival in mice and rats W. Harel, D. Nelken
17
Possible involvement of lectins in bacteria-induced histamine release in intrinsic asthma P. Stahl Skov, C. Jensen, S. Norn, T. C. B0g-Hansen, H. L®wenstein, C. Koch, H. Permin, N. H«iiby
27
T cell stimulating lectins are mitogen inducers but not mitogens B. M. Stadler, J. Liechti, G. D. Bonnard
37
Membrane alterations and induction of responsiveness to interleucin 2 in lymphocytes by lima bean lectins W. G. Bessler, H. Kraut, D. Busing, W. Muller-Hermes, H. Peters
45
T lymphhocyte-mediated cytolysis. and non-mitogenic lectins mediate interactions? G. Berke
55
IV. How do mitogenic lymphocyte-target
Lectin coated beads stimulate single cells from mouse embryos to spread S. J. Kimber, M. Azim, H. Surani
63
X Lectin-mediated endocytosis of Helix pomatia lectin by Zajdela hepatoma cells K. W. Lempfrid, H.-P. Weil, G. Hermann
73
PART II. LECTINS AS SPECIFIC TOOLS Lectins diagnostic G. Coggi,in P. Dell'Orto,pathology E. Bonoldi, P. Doi, G. Viale
87
Reactions with lectins on benign and malignant lesions of the human breast. Relation with the presence of differentiation antigens of the mammary gland P. Hageman, L. Bobrow, M. A. van der Valk, W. Misdorp, J. Hilkins
105
Ultrastructural study on the presence of receptors for several lectins in human breast cancer J. Calafat, H. Janssen
119
Ultrastructural localization of peanut agglutinin receptors on cells of human mammary tumors J. Calafat, P. C. Hageman, H. Janssen
131
Endocrine therapeutical studies on carcinogen-induced rat mammary carcinomas characterized by hormone-dependent lectin-binding sites M. Vierbuchen, P. J. Klein, S. Rossel, J. Fischer, G. Uhlenbruck
145
The characterization of milk proteins by lectins and antibodies in hormone dependent breast cancer P. J. Klein, M. Vierbuchen, J. Fischer, G. Farrar, G. Uhlenbruck
157
Histochemical and biochemical characterization of glycoprotein components in normal gastric mucosa, intestinal metaplasia and gastric cancers with lectins J. Fischer, P. J. Klein, M. Bierbuchen, R. Fischer, G. Uhlenbruck
167
Affinities of Ricin 120 and misteltoe lectin 1 for membrane components of liver and nervous tissues B. K. Groeger, L. G. Williams, J. Pigott, P. Ziska, D. S. 0'Dell, D. J. Williams, H. Franz, P. L. Debbage
179
Stability and steric hindrance of lectin-labelled gold markers in transmission and scanning electron microscopy M. Horisberger, M. Tacchini-Volanthen
189
Lectin binding sites on semithin sections of epoxy-embedded tissues G. Viale, P. Dell'Orto, R. Colombi, V. De Gennaro, A. Comi, G. Coggi
199
XI
Comparison of lectin binding sites in the kidneys of different animal species H. Holthofer, A. Miettinen, I. Virtanen
205
Receptors for Helix pomatia lectin on normal human lymphocytes and lymphocytes from patients with chronic lymphocytic leukaemia G. Hermann, J. Lembke, H.-P. Weil, D. Gerecke
213
Lectin binding patterns of normal and leukaemic and myeloid cells M. Harding, D. Crowther, J. T. Gallagher
225
lymphoid
The binding and stimulation of human leukocytes by the five pokeweed lectins M. J. Waxdal, B. F. Haynes, B. J. Fowlkes, C. T. Thomas, B. J. Mathieson, A. Fauci
235
The use of Pa-4 for the identification and removal of monocytes from human peripheral blood mononuclear cells C. Murre, M. J. Waxdal
243
Analysis of subpopulations of human peripheral blood leukocytees and splenic cells isolated by peanut agglutinin B. J. Mathieson, B. F. Haynes, M. J. Waxdal, B. J. Fowlkes, C. A. Thomas, S. 0. Sharrow
251
Detection and characterization of murine thymocyte delineated by lectins and flow microfluorometry B. J. Fowlkes, B. J. Mathieson, M. J. Waxdal
263
subsets
The late appearance of a PNA "dull" subset in the mouse thymus development D. Drakeford, W. M. Leiserson, S. 0. Sharrow, B. J. Mathieson
275
Characterization of peanut agglutinin receptors as possible expression sites of sialic acid during the maturation of mouse thymocytes J. Favero, J.-C. Bonnafous, J. Dornand, R. L. O'Brien, J.-C. Mani
283
Effect of 32 purified animal and plant lectins on human T lymphocytes F. Licastro, M. Chiricolo, L. Barbieri, F. Stirpe, A. Falasca, C. A. Rossi, C. Franceschi
293
Lectins as probes of blood platelet activity K. J. Clemetson, J. L. McGregor, E. F. Luscher
303
Sialic acid as a cell surface binding site for wheat germ agglutinin J. T. Gallagher, M. Harding, R. E. Dale
311
XII
Interaction of human young and old erythrocytes with WGA. A fluorescence study D. Bladier, M.-A. Deugnier, M. Caron
319
Labeling of rat spermatogenic cells with fluorescein isothiocyanate conjugated lectins R. Malmi, K.-O. Soderstrom, K. Karjalainen
327
Affinity of ten insolubilized lectins towards various glycopeptides with the N-glycosylamine linkage and related oligosaccharides H. Debray, A. Pierce-Cretel, G. Spik, J. Montreuil
323
Herpesvirus glycoproteins from wild-type and ricinresistant BHK cells. Characterization of glycopeptides by conA-Sepharose F. Dall'Olio, F. Serafini-Cessi, M. Scannavini, G. Campadelli-Fiume
351
Con-A-reactivity of serum and leucocyte alpha-1 anti-trypin. Electrophoretic heterogeneous alpha-1 antitrypsins studied by crossed affinity Immunoelectrophoresis. M. M. Andersen, S. Noack
361
Seminal acid phosphatase. chromatography M. Iwasa, K. Sagisaka
371
Purification by lectin affinity
Isolation and characterization of Poa pratensis acid phosphatases interacting with conA I. Lorenc-Kubis
379
WGA affinity Immunoelectrophoresis of glycophorin from human erythrocyte membranes. Capacity measurements of WGA gel and binding constant determination N. H. H. Heegaard, U. Christensen, 0. J. Bjerrum
387
Dissociation constants for concanavalin A at various pH values studied by affinity electrophoresis K. Takeo, M. Fujimoto, A. Kuwahara
397
Rapid methods for the demonstration of sugar residues in tissue extracts, fluids and lectins in plant extracts J. Kohn, J. Raymond, A. Voller, P. Turp
405
Hemadsorption lectin test (HALT): A simple sensitive and fast solid phase method for studying lectins J. A. Kint
415
PART III. ANIMAL LECTINS Endogeneous lectins on human peripheral leukocytes C. Kieda, M. Monsigny, M. J. Waxdal
monomuclear 427
XIII I n v o l v e m e n t of a b e t a - g a l a c t o s e - s p e c i f i c m a c r o p h a g e in binding and phagocytosis of e r y t h r o c y t e s E. Muller, C. Schroder, M. W. Franco, A. K. Shukla, R. Schauer
lectin 435
Isolation of a m e m b r a n e lectin from the m a r m o s e t cell 70N2 J. M. Decker
line 443
Studies on Lectins LV. Subcellular location of an endogenous lectin in fish oocyte J. Nosek, A. Krajhanzl, J. Kocourek
453
Lectins from tunicates and cyclostomes. characterization G. R. Vasta, J. J. M a r c h a l o n i s
461
A biochemical
Is the selectivity of proteid yolk precusor uptake insects based on a lectin-type binding reaction? D. Stynen, A. De Loof PART IV. BACTERIAL
in 469
LECTINS
Bacterial surface lectins T. W a d s t r o m , T. J. Trust, D. E. Brooks
479
The biological functions of Pseudomonas a e r u g i n o s a N. Gilboa-Garber
lectins
N o n m a n n o s e - s p e c i f i c lectins on e n t e r o t o x i g e n i c E. coli rocognizing different g l y c o c o n j u g a t e s T. W a d s t r o m , A. Faris, M. Lindahl, B. Lonnerdahl, B. Ersson PART V. PLANT
495
503
LECTIN
D i s t r i b u t i o n and function of the lectin in the genus glycine S. G. Pueppke
120,000 dalton
soybean 513
M a n n o s e - s p e c i f i c lectins and the r e c o g n i t i o n of pea roots by Rhizobium leguminosarum J. W. Kijne, I. A. M. van der Schaal, C. L. Diaz, F. van Iren
521
Pea lectin binding by Rhizobium I. van der Schaal, J. Kijne, C. Diaz, F. van Iren
531
Possible role of lectins in binding rhizobia to host B. Solheim
roots
P u r i f i c a t i o n and c h a r a c t e r i z a t i o n of an endogenous root lectin from Pisum sativum L. M. Hosselet, E. van Driessche, M. van Poucke, L. Kanarek
538
.. 549
XIV
Lectin release from imbibed soybean seed and its possible function H. Causse and P. Rouge
559
Structural relationships and properties of legume lectins L. M. Shannon
573
Speculations about a physiological role of some plant lectins W. Peumans, H. Stinissen, A. Carlier
583
In vivo synthesis and processing of cereal H. Stinissen, W. Peumans, A. Carlier
593
lectins
The alpha and beta subunits of pea lectin are the result of a post-translational cleavage of a precursor chain M. Lauwereys, E. van Driessche, A. Strosberg, R. Dejaegere, L. Kanarek
604
Light and electron microscopic localization of lectins in plant cells and tissues J.-F. Manen, A. Pusztai
611
A s p e c t r o p h o t o m e t r y study of the carbohydrate site of peanut lectin J. Ohanessian, M. Caron
623
binding
A critical study on the purification of potato lectin (Solanum tuberosum L.) E. van Driessche, S. Beeckmans, R. Dejaegere, L. Kanarek .. 629 A galactomannan precipitating lectin in Sphenostylis stenocarpa seeds T. Animashaun
639
Further investigations on misteltoe lectin I (ML I): Effect of A-chain on cell-free protein synthesis H. Franz, A. Kindt, P. Ziska, H. Bielka, R. Renndorf, L. Venker
645
Purification and partial characterization of a Streptococcus mutans cell-agglutinating substance from Caucus carota B. Matiasson, M. Ramstorp, P. Carlsson, D. Bratthall
653
APPENDIX Red cell ghosts: A tool for purification of lectins A. Faure, J. Delrieu, M. Caron
661
The molecular basis of bacterial adherence to epithelial cells Y. Eshdat, N. Sharon
667
XV Changes in lectin receptors during lymphocyte differentiation: Application to bone marrow transplantation Y. Reisner
677
Report on the third session of the International Working Party on Standardization of Lectins for Diagnosis T.C.Btfg-Hansen
699
AUTHOR INDEX
701
SUBJECT INDEX
705
INTRODUCTION DEFINITION OF LECTIN
A NOTE ON THE REGENT DISCUSSION ON DEFINITION OS1 THE TERM "LECTIN" Jan Kocourek, Vaclav Horejsi Department of Biochemistry, Charles University, Albertov 2030, 128 40 Praha 2, Czechoslovakia
Recent years brought a rapid increase of our knowledge of lectins. In spite of their widespread occurrence in Nature, their extensive study as model ligand-binding proteins and their frequent use as specific tools in biological research, at present there exists some ambiguity as to the accurate delineation of the term "lectin". The original Boyd's definition (1) is rather broad and at present it seems necessary to re-define the term more specifically. Efforts in this direction were initiated by Goldstein et al. (2) who stressed sugar-binding and cell agglutinating properties as a basis for the definition. Their definition supplemented by several comments was also published by the Nomenclature Committee of IUB in its Newsletter 1981 (3). The comments specify in a more detail the scope of the definition; sugar-binding proteins with a single binding site are not considered as lectins, whereas sugar-specific enzymes, transport proteins and toxins may be classified as lectins, provided they have multiple sugar-binding sites. The authors of the present paper have suggested a different definition (4), in which emphasis is put on the sugar-binding properties and the lack of enzymatic activity toward carbohydrate structures, whereas the number of sugar-binding sites or agglutination/precipitation activities are not considered. The Nomenclature Committee of IUB has given preference to the Goldstein's et al. definition (5) essentially because they considered the criterion of cell agglutination
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
4
and/or glycoconjugate precipitation as operational and practical to apply; our definition was found too broad and the criterion of absence of enzymatic activity difficult to apply. However, we still believe that the definition should be based solely on the carbohydrate-binding and not on agglutination or precipitation properties and, also, that sugar-specific enzymes and transport proteins (as well as carbohydrate-specific immunoglobulins) should not be considered as lectins, mainly because: (1) Cell agglutination is a complex phenomenon depending on the properties of the protein, the cells and of the medium used. Thus the selection of agglutinable cells and optimum conditions may be difficult. Moreover, cell agglutination does not represent - at least in a vast majority of cases the true physiological activity of lectins. This renders the agglutination-criterion both impractical for general use and rather artifactitious. (2) Exclusion of monovalent carbohydrate-binding proteins is not logical as they may be structurally and functionally closely related to other multivalent proteins or they may form multivalent aggregates. (3) Carbohydrate-specific enzymes and transport proteins (regardless of the number of their binding sites) constitute distinct groups of proteins with well defined specialized functions; their classification as lectins might lead to confusion. (4) The definition should reflect the assumed (and in many cases well documented) carbohydrate-recognition functions of lectins in vivo. Thus, we suggest a modified version of our original definition (4) which is based on the above considerations: Lectins are proteins of non-immunoglobulin nature capable of specific recognition and reversible binding to carbohydrate moieties of complex carbohydrates without altering covalent structure of any of the recognized glycosyl ligands.
5
Comments s 1. A lectin molecule contains one or more sugar-binding sites; lectins may (but do not have to) agglutinate cells or precipitate glycoconjugates as a consequence of binding to their glycosyl moieties. 2. Lectins may possess various biological activities - they can be toxins, hormones etc.; they can be enzymes activity of which is not directed towards sugar molecules. 3. Lectins will usually bind sugars (i.e. low-molecular-weight carbohydrates) which specifically inhibit their interaction with soluble or cell-bound glycosylated macromolecules. 4. Lectins may occur in any type of organisms; they may be soluble or membrane-bound, may be glycoproteins or other posttranslationally modified protein derivatives. 5. Carbohydrate-specific immunoglobulins and any carbohydrate-specific enzymes are not to be classified as lectins. Also carbohydrate-binding proteins complexing only with free sugars but not with complex carbohydrates (some transport proteins, chemotaxis receptors, repressors of operons of carbohydrate metabolism etc.) are not lectins.
References 1.
Boyd, W.C. in The Proteins, Vol. 2, Part B (Neurath, H. and Bailey, K., Eds.), pp. 756-844, Academic Press, New York 1954.
2.
Goldstein, I. J., Hughes, R. C., Monsigny. LI., Osawa, T., Sharon, N. : Nature (London) 28£, 66 (1980).
3.
Newsletter 1981 of the Nomenclature Committee of IUB (NC-IUB) and IUPAC-IUB Joint Commission on Biochemical Nomenclature (JCBN): Eur. J, Biochem. 114. 1-4 (1981; Arch.Biochem. Biophys. 206, 458-462 (l9Sl5; Hoppe-Seyler's Z. Physiol. C h e m . 1 % 2 . I-IV (1981); J. Biol. Chem. 256. 12-14 (1981).
4.
Kocourek, J., Hofejsi, 7. : Nature (London) 290, 188 (1981).
Dixon, H. B. P, : Nature (London) 2%2, 192 (1981).
PART I BIOLOGICAL EFFECTS OF LECTINS
MECHANISMS OF INDUCTION OF TRANSPLANTATION TOLERANCE IN MICE BY LECTIN TREATMENT Ivan Hilgert, Väclav Horejsi, Hana Kristofovä, Pavia Angelisovä Institute of Molecular Genetics, Czechoslovak Academy of Sciences, Videnskä 1083, Praha 4, Czechoslovakia
Administration of some lectins, e.g. Con A or PHA in vivo, results in prolongation of skin or organ graft survival time in such lectin treated recipients (1, 2). Lentil lectin (LCA) was found to be especially efficient in induction of transplantation tolerance in mice (3). In our initial experiments we were able to induce permanent survival of the B10.D2 mouse strain skin grafts in B10.D2(M504) recipients (abbreviated designation M504) after a twenty-dose treatment with LCA. This remarkable effect qualifies LCA as one of the most efficient immunosuppressive (or tolerogenic) substances known so far; a recent study indicates that the efficiency of LCA in rats can be still markedly increased by combination with antithymocyte serum (Harel and Nelken, these proceedings). Therefore, it was of interest to study in more detail the mechanisms underlying these in vivo effects. We tried to answer especially the following questions: (1) What is the immunosuppressive efficiency of LCA in various genetically well defined mouse strain combinations with histocompatibility disparity of different strength? What is the most efficient schedule of lectin treatment? (2) What is the effect of LCA on various functional characteristics of the recipient's lymphocytes? (3) What is the role of active suppressor cell mechanisms in this type of immunological tolerance? (4) What is the fate of LCA in the organism? Has LCA special affinity toward some tissues?
© Walter d e Gruyter & Co. 1983, Berlin • N e w York Lectins, Vol. Ill
10 Materials and methods LCA and Con A were prepared by affinity chromatography on Sephadex G-100 (4, 5).
Two to three months old female mice of
various inbred strains were obtained from the animal house of our Institute.
Skin grafting was performed by the standard Q method (6). In adoptive transfer experiments 10° spleen cells from the tolerant animals were taken 10 days after the last LCA dose and injected into sublethally irradiated recipients which were subsequently given a skin graft. LCA doses administered i.p. or i.v. were dissolved in 0.5 ml saline, the s.c. doses in 0.1 ml saline. Cytotoxicity of LCA toward spleen cells was estimated in vitro by the 51Cr-release test (7). Stimulation of spleen cell suspensions with LCA was measured by incorporation of ^H-thymidine. Mixed lymphocyte cultures (MLC) consisted usually of 3 components: responder spleen cells, stimulator (either 20 Gy irradiated allogeneic cells or a lectin) and modulator cells. Total culture volume was 0.2 ml; cultures were harvested 48 hours after a 16 h pulse with 36 kBq of H thymidine and mean cpm of cell incorporated H were measured. Stimulation index was calculated as a ratio of cpm from experimental culture to control unstimulated (or syngeneic cell "stimulated") culture. As a rule, MLC consisted of 10® stimulator cells, 5 x 10"* - 10® responder cells and 5 5 x 1 0 modulator cells. Modulator cells were prepared by cultivation of 1.5 x 10 /ml spleen cells for 40 hours in the presence of lectins (0.5 - 25 yg/ml) or without lectins (controls). After culture the cells were washed with 0.3 M methyl-a-D-glucopyranoside and pretreated with mitomycin C (50 yg/ml, 30 min, 37 C) .
Mitomycin treatment was omitted in the case of modula-
tor cells which were subsequently used in the cultures tested for cell mediated cytotoxicity (CMC) development.
Cultures
for generation of cytotoxic lymphocytes were 51 performed essentially according to Ferguson et al. (8), Cr-labelled EL-4 tumor cells were used as target cells.
The target vs. effector
11
c e l l r a t i o was 1:20 - 1 : 2 . LCA and bovine serum albumin 131 were l a b e l l e d by I using the chloramine T method ( 9 ) . r a t e of elimination of these r a d i o l a b e l l e d proteins a f t e r j e c t i o n i n t o mice was estimated by the whole-body measurement at v a r i o u s i n t e r v a l s .
(BSA) The in-
radioactivity
D i s t r i b u t i o n o f the
labelled
p r o t e i n s w i t h i n the body was f o l l o w e d a f t e r k i l l i n g the a n i mals
(24 hours a f t e r the i n j e c t i o n o f the l a b e l l e d
protein),
d i s s e c t i o n and s e p a r a t e measurement o f r a d i o a c t i v i t y i n d i f f e r ent organs and t i s s u e s . TABLE 1 Mouse s t r a i n
combinations used (donor -
recipient)
2R - B10.A
15
A.TL - A.TH
2
B10.AKM - B10.BR
16
A.TH - A.TL
3
B10.BR - B10.AKM
17
B10.AQR - B10.AKM
4
R103 - M504
18
B10.AKM - B10.AQR
1
5
B10.D2 - M504
19
B10.AQR - 4R
6
R103 - B10.D2
20
B10 - B10.A
7
B10.D2 - R103
21
B10.HTT - B10.D2
8
B10.A - B10.BR
22
B10.D2 - B10.A
9
B10 - 5R
23
B10.HTT - B10.A
10
B10.A - 4R
24
3R - B10.A
11
4R - B10.A
25
5R - B10.A
12
4R - B10.AQR
26
4R - B10
13
B10.AQR - B10.DBA/1
27
B10.AQR - B10.A
14
B10.DBA/1 - B10.AQR
28
B10.A - B10.AQR
Results E f f i c i e n c y o f LCA i n d i f f e r e n t s t r a i n combinations. ent mouse s t r a i n combinations w i t h v a r i o u s g e n e t i c at the H-2 l o c i were t e s t e d
(Table
1).
28 d i f f e r disparities
12
The efficiency of LCA was clearly dependent on the nature of antigenic disparity between the donor and recepient. In some strain combinations (No. 1-12, Table 1) LCA treatment resulted in permanent survival of the grafts (>100 days) in 80-100% recipients if LCA was administered daily (1 mg, i.p., the doses on the days 1, 3, 5, 7, 9 and 11 were given i.v., in animals bearing the grafts for more than 40 days the lectin was administered alternatively i.p. and s.c. until the rejection of the graft). In all these cases the difference between the donor and recipient is at the H-2DL locus only (No. 1-7) or H-2DL+ some of the H-2J, E, C, and S loci (No. 8-11); only in strain combination No. 12 the donor and recipient differ at the H-2K, J, C, S, DL loci. In other strain combinations involving differences at multiple H-2 loci including H-2K and/or H-2I (No. 13-26) or H-2K only (No. 27, 28) LCA treatment resulted always in marked prolongation of graft survival times as compared to controls (2-4 fold increase of the mean survival time depending on the particular strain combination but permanent survival of skin grafts was achieved only exceptionally. Thus, LCA treatment can be used to overcome the H-2DL antigenic barrier but is less efficient in the case of H-2K or H-2A antigenic disparities.
Cellular mechanisms involved in maintenance of LCA-induced transplantation tolerance.
Involvement of active suppressor
cell-mediated mechanisms was tested by adoptive transfer experiments.
B10.D2 grafts survived permanently in 70% of M504
recipients which were sublethally irradiated and reconstituted Q
with 10 spleen cells from M504 recipients bearing B10.D2 grafts as a result of LCA treatment. Only approximately 10% of R103 strain grafts survived permanently in such reconstituted recipients indicating specificity of the state of tolerance but also some degree of nonspecific inhibitory mechanisms involved. Transplantation of third-party test allografts (R103) onto recipients bearing a B10-D2 graft for >100 days
13
resulted in a rapid rejection of these grafts without affecting the survival of the original B10.D2 grafts. Effect of LCA on spleen cells in vitro. Mitogenic stimulation of murine spleen cells with LCA was typically dose-dependent (maximum stimulation index approximately 51 at 5 yg/ml in a 5% serum containing medium). The apparent decrease of mitogenic activity at higher concentrations was at least in part due to the cytotoxicity of LCA (approximately 65% of cells were killed after a 24 hours culture in the presence of 0.5 mg/ml LCA; virtually all cells were killed by Con A under similar conditions). Mitogenic response to LCA and Con A of the spleen cells obtained from the M504 mice which were given single 1 mg i.p. dose of LCA (48 hours before testing) was decreased by 93% as compared to untreated controls. There was essentially no mitogenic response in the case of spleen cells from the animals which received a 10-dose LCA treatment (each i.p. dose 1 mg, administered daily, treatment ceased 48 hours before testing). Spleen cells from the B10.A mice which received single 1 mg i.p. dose of LCA manifested a higher proliferative response (1.7 fold as compared to untreated controls) after stimulation with allogeneic B10 cells in MLC. The effects of modulator cells (i.e. spleen cells pre-cultured in the presence of the lectin) on several in vitro characteristics of murine spleen cells were tested. There was a marked difference between the effects of B10.A modulator cells generated in vitro either by LCA or Con A. Whereas addition of Con A-generated modulator cells suppressed the mitogenic response of syngeneic responder cells to LCA stimulation (by 55%), LCA-generated modulator cells enhanced this response (7.5 fold). Similarly, Con A-induced B10.A modulator cells suppressed, whereas LCA-generated modulator cells enhanced the blastogenic response of syngeneic responder cells in MLC toward allogeneic B10 stimulator cells (Hilgert et al., to be published). Both Con A- and LCA-induced modulator cells
14
suppressed the development of CMC in MLC (by 59% and 65%, respectively, as compared to the cultures containing "modulator" cells pre-cultivated in the absence of any lectin). Similar effect (40-45% suppression of CMC) was observed also when modulator cells generated in vivo were used, i.e. the cells obtained from the spleens of animals pretreated with a single 1 mg LCA dose 2 days before testing or after a 10-dose LCA treatment (ceased 6 days before testing). Distribution of LCA in vivo and the rate of its elimination. 131 The rate of elimination of I-labelled LCA was similar to 1 31 that of I-labelled BSA (approximately 80% of a 1 mg dose administered i.v. was eliminated after 48 hours; LCA administered i.p. or s.c. was eliminated approximately 2-3 times more slowly). Both LCA and BSA were distributed relatively homogeneously throughout the body but LCA possessed increased affinity for spleen, lymph nodes and lung (relative concentration per mg of the tissue was 3.1, 1.5,and 2.9 times higher in these organs, respectively, than the mean concentration in the body), whereas the level of BSA was elevated in blood only. Discussion Our results provide at least to some extent the answers to the questions raised in Introduction.
First, it seems clear
that the immunosuppressive efficiency of LCA depends on apparent strength of histocompatibility barrier between the donor and recipient.
The H-2DL antigenic disparity can be relative-
ly easily overcome by LCA treatment, whereas H-2K and H-2A antigens represent stronger histocompatibility barrier;
the
effects of non-H-2 histocompatibility antigens were not followed in this study.
Interestingly, long-term tolerance could be
induced only in the B10.D2 - M504 (mutant) strain combination by a limited number of LCA doses.
Two in vitro observed
15
effects may be directly related to the in vivo efficiency of LCA: first, cytotoxicity of LCA at higher concentrations might cause partial depletion of alloreactive cells. Second, the suppressive effect of LCA-generated modulator cells on CMC development might indicate that also in vivo development of alloreactive cytotoxic T cells may be inhibited. This conclusion is also in agreement with our experiments on adoptive transfer of LCA-induced tolerance. This suppressor cell mechanism may be sufficiently efficient for maintenance of B10.D2 graft survival on the M504 recipient after a 20-dose LCA treatment, but the necessity for continuous supply of LCA in other strain combinations tested (with apparently stronger histocompatibility barrier) seems to indicate, that suppressor cells induced in such recipients are not able to "manage" the rejection reaction and that LCA might also block directly some membrane bound or soluble complex carbohydrate molecule(s) taking part in the rejection reaction. The lectin might bind to the histocompatibility antigens of the graft and thus block their recognition. We cannot rule out this effect of LCA in some strain•combinations (it might be in agreement with our results on the rate of LCA elimination, which also indicate the necessity for continuous application of LCA to maintain its high (blocking?) level in organism) but the experiments on retransplantation of long-term tolerated B10.D2 grafts onto untreated M504 recipients, transplantation of grafts presoaked in LCA solution or transplantation of grafts from LCA pretreated donors did not reveal apparently any modification of normal immunogenicity of such "LCA-pretreated" grafts (I. Hilgert, unpublished results). Increased affinity of LCA for spleen and lymph nodes (and lung) may support rather the notion that the recipient's immune system is the prime target of LCA action.
In summary, induction of suppressor cells inhibiting graft rejection reaction and direct cytotoxicity seem to be involved in immunosuppressive activity of LCA observed in vivo.
Signi-
16
ficance of other possible effects such as direct blocking of some cell surface or soluble molecules by LCA and some kind of antigenic modulation of the graft remains to be evaluated as well as the roles of antigen-specific and non-specific suppressor mechanisms.
References 1.
Markley, K., Thornton, S., Smallman, E., Markley, P.: Transplantations 8, 258-264 (1969).
2.
Rosenau, W., Haber, J., Goldberg, M.: 624-626 (1972).
3.
Hilgert, I., Horejsl, V. , Angelisovâ, P., Kristofovâ, H.: Nature (London) 284, 273-275 (1980).
4.
Tichä, M., Entlicher, G., Kostlr, J., Kocourek, J.: Biochim. Biophys. Acta 221, 282-289 (1970).
5.
Agrawal, B.B.L., Goldstein, I.J.: 147, 262-271 (1967).
6.
Billingham, R.E., Medawar, P.B.: 392 (1951).
7.
Wigzell, H.:
8.
Ferguson, R., Anderson, S.M., Schmidtke, J.R., Simmons, R.L.: J. Immunol. 117, 2150-2157 (1976).
9.
Hunter, W.M., Greenwood, F.C.: 496 (1962).
Transplantation 13,
Biochim. Biophys. Acta J. Exp. Biol. 28, 385-
Transplantation 3, 423-431 (1965).
Nature (London) 194, 495-
THE EFFECT OF LENTIL LECTIN TREATMENT ON SKIN ALLOGRAFT SURVIVAL IN MICE AND RATS
W. Harel and D. Nelken Laboratory of Immunohematology and Department of Immunology, Hadassah Hebrew University Medical Center, Jerusalem, Israel
I t i s well known that concanavalin A (Con A) activated lymphoid cells may suppress in vitro primary and secondary plaque-forming cell responses of mouse spleen cells to heterologous red blood cells (1) and are capable of suppressing cell mediated immune responses in vitro (2).
I t was shown
that Con-A inhibited the generation of cytotoxic lymphocytes and that this inhibition was c r i t i c a l l y dependent upon the concentration and time of addition of Con A or Con A activated cells (2).
In vivo experiments
showed that intraperitoneal injections of Con A markedly prolonged skin allograft survival in mice (3) and heart allograft survival in rats (4). In a recent article Con A was shown to inhibit immunologically specific cytolytic a c t i v i t y , without any toxic effect on target or effector cells and without interfering with 51 C r release once the l y t i c lesion has been induced.
I t was suggested that the inhibition of cytolysis was caused by
immobilization in the lymphocyte membrane of various protein moieties by the lectin which directly interfered with events at the effector cell surface (5). Others have found that the inhibitory effect of Con A on cytotoxic effector cells was dependent upon treatment of the target cells with the lectin.
When the targets were preincubated with the lectin, or when the
lectin was present in the medium, effector cells were able to k i l l the targets, with a dependence upon the presence of specific histocompat i b i l i t y antigens on the target cells (6,7). observed with phytohaemagglutinin (PHA).
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
Similar effects were also
When injected intraperitoneally
18
under appropriate conditions, i t effectively inhibited the rejection of skin allografts, even across the H-2 barrier in mice (8,9).
In a recent
study, lentil lectin was shown to have a similar effect in preventing the rejection of skin allografts in mice (10).
I t was shown that the immuno-
suppressive efficiency of l e n t i l lectin depends on the strength of the histocompatibility barrier between donor and recipient in mice.
Lentil
lectin was able to overcome the H-2DL antigenic disparity much better than the H-2K and H-2A disparity (11). The present report deals with skin allografting experiments in mice and rats treated with various combinations of lentil lectin and anti thymocyte serum.
I t was found that such a treatment may induce a state of allograft
acceptance in closely related mice and rats.
In adoptive transfer
experiments, cells from the treated animals were able to prolong skin graft survival in transplanted secondary hosts.
Materials and Methods Lentil lectin was prepared as described elsewhere (12).
In short, 250g
of l e n t i l s were homogenized in a Sorvall OMNI-mixer and centrifuged.
The
supernatant was fractionated by addition of s o l i d ammonium sulfate to obtain the material which precipitated between one and two thirds saturation.
The precipitate was dialized against Tris buffer (0.05M,
pH 8.1), and passed through a column of DEAE cellulose (Whatman DE-52). The lectin appeared in the f i r s t protein peak (0D 280 nm) passing unbound through the column. erythrocytes (13).
Activity was detected by hemagglutination of rabbit The product was compared with a commercial lentil
lectin, obtained from Pharmacia Fine Chemicals, Uppsala, Sweden, and showed a similar potency in hemagglutination tests and an identical pattern in acrylamide gel electrophoresis. Anti rat thymocyte serum (ATS) was prepared in rabbits by the injection of rat thymocytes emulsified in complete Freund's adjuvant at four week intervals.
Two weeks after the third immunization the rabbits were bled,
the serum separated, pooled and frozen at -20°C in 10ml aliquots until use.
The cytotoxic titer against rat thymocytes with guinea-pig
19
complement was adjusted to 1:64 in the lymphomicrocytotoxicity test employing the eosin staining method (14). were not used. experiments.
Antisera with weaker titers
A single serum pool was used in each series of Inbred male Lewis (RT-1 1 ), Fisher (RT-1^) rats and inbred
d
BALB/c (H-2 ) and C57B1 (H-2t>) mice were used throughout this study.
Results In a recent report i t was shown that lentil lectin was able to induce skin allograft tolerance in mice (10).
In our laboratory, treatment with
8-10 daily doses of lentil lectin alone following transplantation, resulted in prolonged skin allograft survival but a state of tolerance was never achieved (15,16).
Using two mice strains with strong H-2 d i f f e r -
ences, BALB/c and C57B1, the longest mean skin graft survival time in lentil lectin treated recipients was 22.3+3.81 days (Table 1 group 3) compared to 10.6±1.78 (Table 1 group 8) in untreated control mice.
In
experiments with rats differing in minor histocompatibility antigens (Lewis to Fisher) treatment with lentil lectin increased the mean survival time to up to 25.1+5.33 days (Table 2 group 2) compared to 10.3±1.46 (Table 2 group 6) in the untreated controls.
In another series of
experiments the syngergistic effect of rabbit anti rat thymocyte serum and lentil lectin was examined.
ATS was injected at the time of the operation
followed 48 hours later by the injection of lentil lectin and 48 hours thereafter by another injection of ATS and so on. was given, 4 of which were ATS and 4 lentil lectin.
A total of 8 injections This combined
treatment consistently resulted in prolonged skin graft survival.
In mice
the skin allografts survived for about 24 days (Table 1 groups 6,7) and in rats for an observation period over 75 days (Table 2 groups 4,5).
In
passive transfer experiments we found that spleen cells from ATS and lentil lectin treated Fisher rats with an established Lewis skin graft (Table 2 group 5) were able to prolong graft survival time when transferred to untreated syngeneic rats transplanted with Lewis skin grafts.
The transplants were performed 24 hours after transfers of 5xl0 7
spleen cells (Fig. 1).
The mean survival time of these transplants was
20 Table 1 Skin a l l o g r a f t s u r v i v a l in mice (C57B1 to BALB/c) treated with anti thymocyte serum and l e n t i l l e c t i n
Group no.
ÛT
.r û
No. of mice
Mean s u r v i v a l time ± S.D.
5mg/kg, 10 i . p . i n j e c t i o n s every 24 h s t a r t i n g at transplantation time
25
14.2 ± 2.76
15mg/kg as group 1
18
16.8 ± 2.94
25mg/kg as group 1
15
22.3 ± 3.81
50mg/kg as group 1
13
15.1 ± 4.14
15
18.3 ± 3.77
0.25ml/mouse 8-10 1.p. i n j e c t i o n s every 24-48 hours
b
0.25ml x 5 i . p . i n j e c t i o n s ; on days 0, 2, 4, 6, 8 after transplantation
25mg/kg x 5 i . p . i n j e c t i o n s on days 1, 3, 5, 7, 9 after transplantation
20
24.7 ± 5.12
7
0.25ml x 5 i . p . i n j e c t i o n s as group 6
25mg/kg 5 i . v . i n j e c t i o n s as group 6
14
23.6 ± 5.74
8
Control :
0.5ml of 0 9% NaCl 10 i . p . i n j e c t i o n s every 24 h
30
10.6 ± 1.78
c
Skin g r a f t s (1 cm in diameter) prepared from the back of the donor mice were transplanted onto the backs of the tested r e c i p i e n t s . Grafts with at l e a s t 50% necrosis were considered to be rejected. p < 0.001 between groups 1,2,3,4,5,6,7 and group 8. No s t a t i s t i c a l l y s i g n i f i c a n t difference was found between group 6 and 7. S.D. = Standard Deviation ATS = Anti Thymocyte Serum LCA = Lens C u l i n a r i s A g g l u t i n i n ( l e n t i l l e c t i n ) i . p . = i n t r a peritoneal i . v . = intra venous
21
Table 2 Skin allograft survival in rats (Lewis to Fisher) treated with anti thymocyte serum and lentil lectin Group no.
ATS
LCA
No. of rats
Mean survival time ± S.D.
5mg/kg 8 i . p . injections on consecutive days
30
22.3 ± 4.72
5mg/kg 8 i . v . injections on consecutive days
16
25.1 ± 5.33
lml/rat 8 i . p . injections on consecutive days
18.6 ± 4.94
lml/rat 4 i.p. injections on days 0, 2, 6, 10 after transplantation
5mg/kg 4 i . p . injections on days 1, 4, 8, 12 after transplantation
lml/rat 4 i . p . injections as group 4
5mg/kg 4 i . v . injections as group 4
Control:
lml of 0.9% NaCl, 8 i . p . injections on consecutive days
10
9
22
23
32.1 ± 4.17 > 75 all grafts > 75
10.3 ± 1.46
Skin grafts (1 cm in diameter) prepared from the chest of the donor rats were transplanted to the chest of the recipients. Grafts with at least 50% necrosis were considered to be rejected. p < 0.0001 between groups 1,2,3,4,5 and group 6. S.D. = Standard Deviation ATS = Anti Thymocyte Serum LCA = Lens Culinaris Agglutinin (lentil lectin) i.p. = intra peritoneal i . v . = intra venous
22 22.2±2.50, compared with 15.0±0.82 in the control group in which transferred c e l l s were from untreated and untransplanted Fisher rats. In several other Fisher rats which showed a perfect take of the Lewis skin allograft (Table 2 group 5), a second Lewis skin graft was performed 8-10 weeks after the f i r s t graft.
The second graft was rejected in a l l
cases and caused the simultaneous rejection of the f i r s t allograft 10-15 days after the operation.
When rats, which showed a perfect take of the
f i r s t Lewis skin allograft were transplanted with a second skin graft from an unrelated Sabra rat, the second graft was always rejected within 7-10 days.
In these rats, however, the f i r s t skin graft was not
rejected (Fig. 2).
Fisher
2
TWO MONTHS AFTER ATS & LECTIN TREATMENT
spleen
(ESTABLISHED GRAFT)
1
24 HOURS BEFORE TRANSPLANTATION
Lewis Fig. 1:
4
Fisher
Passive transfer of 5x10^ c e l l s from treated rats with established grafts to newly transplanted rats, causes prolongation of the skin graft survival time.
23
Fisher
TAKE
l " 2
Fig. 2:
n d
GRAFT'-
ATS
GRAFT:
NO
REJECTION
& LECTIN
TREATMENT
TREATMENT
Transplantation of second set skin grafts to treated rats with an established f i r s t graft. When the second graft i s from an un unrelated donor (Sabra), i t i s rejected within 7-10 days, while the f i r s t graft survives. When the second graft i s the same as the f i r s t , both grafts are rejected within 10-15 days.
24
Discussion Our results indicate that the combination of anti thymocyte serum and lentil lectin causes a state of acceptance of skin allografts from Fisher to Lewis rats.
Cells from the treated rats are able to prolong skin graft
survival when transferred to syngeneic recipients transplanted with the same donor type grafts.
No real tolerance i s achieved, however, since a
second allograft from the strain i s rejected and seems to cause the rejection of the f i r s t otherwise surviving allograft. In a combination of two mouse strains differing in all the H-2 loci (C57B1/6 x BALB/c) we were unable to achieve permanent acceptance of the skin allografts by our lentil lectin treatment.
These results are in
agreement with the recent work of Hilgert, Horejsi et al. who have shown that only in certain genetic combinations lentil lectin treatment could overcome the histocompatibility barrier (11).
The same authors suggest
that a suppressor cell mechanism i s at least p a r t i a l l y responsible for the allograft acceptance in the lentil lectin treated mice.
We are at present
examining this point in rats and mice. In our present report we were able to reduce the lentil lectin dose and at the same time s i g n i f i c a n t l y improve the results of the skin allografts by using a combination of lentil lectin and anti thymocyte serum.
This
synergistic effect of lentil lectin and anti thymocyte serum points to the eventual clinical f e a s i b i l i t y of this treatment in an attempt to improve allograft transplantation.
References 1.
Rich, R.R., Pierce, C.W.:
2.
Peary, D.L., Pierce, C.W.:
3.
Markowitz, H., Person, D.A., Gitnick, G.L., R i t t s , R.E.: Science 163, 476 (1969).
4.
Weil, R. I l l , Nozawa, M., Chernack, W., Weber, C., Reemtsma, K., Mcintosh, R.: Transplantation 17, 600-604 (1974).
5.
Tartof, D.:
6.
J. Exp. Med. 137, 649-659 (1973). J. Exp. Med. 140, 356-369 (1974).
Cellular Immunology 50, 48-57 (1980).
Berke, G., Hu, V., McVey, E., Clark, W.R.: 776-781 (1981).
J. Immunol. 127,
7.
Berke, G., Hu, V., McVey, E., Clark, W.R.: 782-787 (1981).
8.
Stefani, S . S . , Moore, C.D.:
9.
Rosenau, W., Habler, J . , Goldberg, M.: 624-626 (1972).
J. Immunol. 127
J. Immunol. 104, 780-784 (1970). Transplantation 12,
10.
Hilgert, I . , Horejsi, V., Angelisova, P., Kristofova, H.: Nature 284, 273-275 (1980).
11.
Hilgert, I . , Horejsi, V., Kristofova, H., Angelisova, P.: Lectins, Biology, Biochemistry, Clinical Biochemistry, Vol. 3, 1982. T.C. Bog-Hansen and G.A. Spengler (Eds.), Walter de Gruyter, Berlin - New York.
12.
Howard, I . K . , Sage, H.J., Stein, M.D.: 1590-1595 (1971).
13.
Howard, I . K . , Sage, H.J.:
14.
Mittal, K.K., Mickey, M.R., Singal, D.P., Terasaki, P . I . : Transplantation 6, 913-927 (1968).
15.
Harel, W., Nelken, D.:
Transplantation 32, 69-71 (1981).
16.
Nelken, D., Harel, W.:
Transplantation 33^, 560-561 (1982).
J. Biol. Chem. 246,
Biochemistry 8, 2436-2441 (1969).
Supported by grants from the Lil and Ben Stein Transplantation Foundati from Alan Liker and the Shaklee Fund.
POSSIBLE RELEASE
INVOLVEMENT IN
INTRINSIC
OF L E C T I N S
IN B A C T E R I A - I N D U C E D
HISTAMINE
ASTHMA
B0g-Hansen,
P. Stahl S k o v , C. J e n s e n , S. N o r n , T . C . s t e i n , C h r . K o c h , H. P e r m i n , N. H a i b y
H.
Lawen-
D e p a r t m e n t of P h a r m a c o l o g y a n d P r o t e i n L a b o r a t o r y , U n i v e r s i t y of C o p e n h a g e n , D e p a r t m e n t of P a e d i a t r i c s T G , R i g s h o s p i t a l e t and Statens S e r u m i n s t i t u t , Copenhagen, Denmark
A pathogenic sic asthma a close toms
role
temporal
and acute
vious
study
several mine
of p a t i e n t s
acute
urinary
attacks
therefore
tion ria
are
by
metabolites
to the
strom
seem
n i s m of the
we
Eshdat
cell
surface and
studied
release
has
could
The
investigated - an
lectins the
might
mechanism (4,
6). reac-
of a
direct
Since
many
bacte-
(see
also
Wad-
(7)
in
non-immunological
1ectin-mediated.
© Walter d e Gruyter & Co. 1983, Berlin • N e w York Lectins, Vol. Ill
of
during
IgE-mediated
consisting
surface.
from hista-
finding
Sharon, Gi1boa-Garber
whether be
been
to e x i s t
of
release
symptoms.
mechanism
basophil
to c o n t a i n
and Trust,
proceedings),
the
histamine
asthmatic
release
mechanisms
the
pre-
that
of h i s t a m i n e
involvement
is s u p p o r t e d
(5). B a c t e r i a - i n d u c e d
with
known
The
symp-
found
of h i s t a m i n e
and a non-immunological
interaction
release
(3-4).
we
of
show
In our
disease
histamine
different
caused
(1-3).
asthma
intrin-
asthma
exacerbations
infections
intrinsic
in v i t r o
in the
intrinsic
excretion
contribute
of b a c t e r i a l Two
with
is s u s p e c t e d with
between
tract
of b a c t e r i a
in the
release
children
relationship
leukocytes
increased
since
respiratory
strains
basophil
of m i c r o o r g a n i s m s
disease,
these mecha-
28 Materi als
Lectins. Difco lens
Con
A,
Pharmacia
Laboratories, culinaris
wheat
germ
communis
AB,
Detroit,
agglutinin
agglutinin
agglutinin
Sweden, USA,
(LCA),
(WGA),
(RCA)
poke IBF,
peanut
from
phytohemagglutinin weed
lectin
E.Y.
mitogen
Clichy,
(PWM)
France,
(PNA)
and
Laboratories,
(PHA), and
and ricinus
San
Mateo,
USA. Carbohydrates. and
D-( + ) - g l u c o s e , D - ( + ) - g a l a c t o s e ,
histamine
release
of
histamine
release
were
read
histamine content
amounted
to
30 Inhibition were
studies
performed
for e x a m i n i n g
by a d d i t i o n
of
a lectin-mediated
specific
D-glucoside, ¿c-methyl-D-mannoside,
reaction
carbohydrates:
¿ + n
i Q i ». 2
E H
+
, 77-82 (1976) .
9.
Hammarström, S., Hellström, U., Perlman, P., Dillner, M.L.: J. Exp. Med. 138, 196-203 (1973).
10. Axellsson, B., Kimura, A., Hammarström, S., Wigzell, H., Nillsson, K., Mellstedt, H.: Eur. J. Immunol. _8, 757-764 (1978) . 11. Prokop, 0.', Graffi, A., Hoffmann, F., Schnitzler, St., Dt. Gesundh.-Wesen 23,
1926-1929
(1968)
12. Harding, M., Crowther, D., Gallagher, J., this volume.
LECTIN BINDING PATTERNS OF NORMAL AND LEUKAEMIC LYMPHOID AND MYELOID CELLS
M. H a r d i n g ,
D. Crowther and J . T .
Gallagher
C a n c e r R e s e a r c h Campaign Department of Medical Oncology, Manchester U n i v e r s i t y and C h r i s t i e Hospital & Holt Radium I n s t i t u t e , Wilmslow Road, Manchester M20 9BX, E n g l a n d
Leukaemia
a r i s e s p r e d o m i n a n t l y in two c e l l l i n e a g e s ,
and in
e a c h the d i s e a s e may follow an a c u t e or c h r o n i c c l i n i c a l c o u r s e . the lymphoid m a l i g n a n c i e s , in the m a j o r i t y of c a s e s ,
c h r o n i c lymphocytic l e u k a e m i a
express
leukaemia
(CLL)
s u r f a c e immunoglobulin
c o n s i d e r e d to be B lymphocyte d i s o r d e r s
(1).
Acute
and
( c h a r a c t e r i s e d by sheep red c e l l r o s e t t i n g ) poor long term s u r v i v a l
in both c h i l d r e n
phenotype,
the uncommon T
and B c e l l t y p e s have a
(9)
and a d u l t s
(16).
ALL c e l l s which l a c k s u r f a c e m a r k e r s of T or B lymphocytes defined by the common ALL a n t i g e n ,
a glycoprotein
small numbers of normal bone marrow c e l l s of common or n u l l significantly cells,
(i.e.
(15).
(9,16).
malignant,
is limited to the l a - l i k e a n t i g e n
immature lymphocytes)
and in c o n s e q u e n c e ,
f e a t u r e s of p r o g n o s t i c
value.
To f u r t h e r c h a r a c t e r i s e
alterations
s a c c h a r i d e composition of leukaemic c e l l s ,
(13)
are
P a t i e n t s with ALL types h a v e a
By comparison with
s u r f a c e phenotyping of the myeloid l i n e a g e ,
lymphoid
both normal
in the plasma
Results h a v e been compared with those of t h e i r mature
quantitatlectins.
counterparts,
namely p e r i p h e r a l blood lymphocytes for ALL and CLL and
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
surface
membrane
we h a v e studied
(AML).
and
( e x p r e s s e d a l s o by
t h e r e a r e few c e l l
i v e l y the c e l l s u r f a c e b i n d i n g of s e v e r a l f l u o r e s c e i n c o n j u g a t e d
c y t e s for a c u t e myelogenous l e u k a e m i a
Common
found a l s o on
devoid of a l l s u r f a c e m a r k e r s )
better prognosis
cells,
are
lymphoblastic
(ALL) is c l a s s i f i e d on the b a s i s of c e l l s u r f a c e
which h a s important i m p l i c a t i o n s for p r o g n o s i s :
Of
granulo-
226 Materials and Methods Cells from 11 patients with AML, seven with ALL (one of T cell phenotype) and four with CLL were studied at the time of d i a g n o s i s , before therapy was s t a r t e d .
A further patient with T cell CLL was
included in view of the r a r i t y of this malignant phenotype;
although
he had been treated for one y e a r , his d i s e a s e was uncontrolled. Cells from f i v e normal donors were used for comparison. Normal lymphocytes and leukaemic c e l l s were isolated from p e r i p h e r a l blood by density g r a d i e n t centrifugation on Ficoll 1.077: Flow L a b o r a t o r i e s ) . Boyum (8). al (5)-
(density
Monocytes were removed a s described by
Granulocytes were s e p a r a t e d by the method of Barrett et
An aliquot of each sample was treated with Clostridium
p e r f r i n g e n s neuraminidase (Sigma Chemicals) 0.05 units/10 7 cells/ml for 30 mins at 37°C in PBS/BSA (phosphate buffered s a l i n e , pH 7 . 2 , 0.1% w/v bovine serum albumin). by Trypan blue exclusion.
Cell v i a b i l i t y was >95% a s measured
Leukaemic samples r a r e l y included morph-
ologically normal lymphocytes.
Those that did were only a n a l y s e d if
there was c l e a r s e p a r a t i o n of the cell populations on the b a s i s of light s c a t t e r , such that the leukaemic c e l l s could be a n a l y s e d ately.
separ-
All cell samples were a d j u s t e d to 2 x 10^ cells/ml in PBS/BSA
and stored on ice. Lectins were obtained commercially a s a f f i n i t y p u r i f i e d , cein conjugated p r e p a r a t i o n s ,
fluores-
v a l u e s in parentheses are the molar
ratios of fluorescein ¡protein ( F : P ) .
Wheat germ a g g l u t i n i n , WGA
( 1 . 3 : 1 ) and Ricinus communis a g g l u t i n i n ,
RCA, ( 6 . 4 : 1 ) from Miles
Chemicals L t d . , Helix pomatia a g g l u t i n i n , HPA (0.56:1) from Polysciences, Glycine max (soybean a g g l u t i n i n ) ,
SBA, ( 3 . 9 : 1 ) from Vector
Laboratories and Wisteria floribunda a g g l u t i n i n , WFA, ( 4 . 5 : 1 ) from E-Y L a b o r a t o r i e s . 105 c e l l s (50 ul of 2 x 10 6 cells/ml) were added to lectin dilutions in 100 ul PBS/BSA.
After 30 mins incubation at 4°C the
cell s u r f a c e fluorescence was measured in a Biophysics Cytofluorograf 4800A (Ortho Instruments) interfaced to a Hewlett P a c k a r d 9845S computer for d a t a accumulation (7).
Mean cell fluorescence was
227 corrected for c e l l autofluorescence,
the F : P r a t i o of each lectin
the c e l l s u r f a c e a r e a c a l c u l a t e d from the measured a v e r a g e diameter.
and
cell
S p e c i f i c i t y of lectin binding was confirmed by >90%
reduction in fluorescence of c e l l s incubated with lectin in the presence of an appropriate s a c c h a r i d e
inhibitor.
Results are expressed as the r e l a t i v e number of lectin molecules bound per unit surface a r e a as c e l l diameters v a r i e d from 7u for PBL to 17u for some AML c e l l s . given in the legends to F i g s .
Lectin concentrations used are
1 and 2.
>70% s a t u r a t i o n of lectin binding
They were selected to give
sites.
Results The l e c t i n s studied comprised two groups, which bound to untreated c e l l s of a l l types,
WGA-F and RCA-F,
although a f t e r
neura-
minidase treatment RCA-F binding i n c r e a s e d ( r e s u l t s not shown) WGA-F binding was reduced ( F i g . l ) .
In c o n t r a s t ,
WFA-F bqund s i g n i f i c a n t l y only to d e s i a l y l a t e d
HPA-F, SBA-F and
cells.
RCA is thought to have an extended c a r b o h y d r a t e binding (A) and shows the highest a f f i n i t y for a s p a r a g i n e linked with terminal g a l a c t o s e r e s i d u e s .
and
site
sequences
The i n t e r a c t i o n of RCA-F with
untreated c e l l s is shown in F i g . l .
There was a c l e a r
distinction
between the high density RCA-F binding g a l a c t o s e sites on normal lymphocytes and the lower density on lymphoid leukaemic c e l l s . the myeloid s e r i e s normal granulocytes showed s i g n i f i c a n t l y
In
more
residues recognised by RCA-F per unit s u r f a c e a r e a than did AML cells.
The a v e r a g e binding site density was s l i g h t l y g r e a t e r on
lymphocytes than g r a n u l o c y t e s ,
but appeared similar between AML and
ALL c e l l s . WGA i n t e r a c t s with both s i a l i c acid residues s a c c h a r i d e s of N-acetyl glucosamine
(GlcNAc).
(6,17)
Fig.l
and oligo-
shows that WGA-F
binding to a l l c e l l types was reduced by neuraminidase
treatment.
The percentage reduction was similar for each sample of lymphoid cells.
Untreated lymphocytes had a higher density of WGA-F binding
s a c c h a r i d e s than either
ALL or CLL c e l l s .
more marked a f t e r d e s i a l y l a t i o n .
This distinction
In c o n t r a s t ,
became
untreated normal and
leukaemic c e l l s of the myeloid l i n e a g e showed similar densities of
228 WGA-F b i n d i n g
sites.
was a s i g n i f i c a n t on AML c e l l s : slightly
However,
reduction
a f t e r neuraminidase
in WGA-F b i n d i n g
b y comparison WGA-F b i n d i n g
reduced b y the enzyme treatment
RCA-F 2 m9
WGA-F 2 Mg
treatment,
per unit s u r f a c e to g r a n u l o c y t e s
(Fig.l).
there area
was
The d e n s i t y
only
of
WGA-F 2 Mg Neuraminidase
0.5 t
•
I =
0 PBL ALL CLL
PBL ALL CLL
PBL ALL CLL
1.0-
T> 0 O Ru ti 1 us ru t i lu Vici a cr acca ;
Dr. J. Kocourek
Wistaria
Dr. T.
floribunda;
Kurokawa
Vicia v i l l o s a ;
Dr. H. W i g z e l l
Abrus precatorius (agglutinin), Abrus precatorius (Abrin C), Adenia digitata (modeccin 4B), Adenia digitata (modeccin 6B), Hura crepitans (latex), Hura crepitans (seeds), Momordica c h a r a n t i a , Ricinus communis (R60), Ricinus communis (R120), Vicia sativa;
Our
Bandeiraea
Commercial
gare
s i m p l i c i f o l i a , Triticum
vul-
laboratories
tions
prepara-
295 Human lymphocytes. 3 0-4 0 ml of heparinized venous blood were collected from a total of 10 blood donors. The peripheral blood lymphocytes were separated by density gradient centrifugation through Ficoll-Hypaque (2) . Enriched T lymphocytes were obtained by incubating lymphocytes with 2-aminoethylisothiouronium bromide hydrobromide (AET)^treated sheep red blood cells (SRBC), according to Pellegrino et al. (1975) (3) with minor modifications as described elsewhere (4). Briefly 2.5 x 10 /ml lymphocytes were incubated with AET-SRBC (0,5%) for 15 min at 37°C in RPMI 1640 plus 10% of foetal calf serum. After incubation in an ice bath for 10 min, the rosetted cells (T lymphocytes) were separated from non-rosetted cells (B lymphocytes) by a Ficoll-Hypaque gradient. Preparation of T lymphocytes were 90% pure as judged by re-rosetting. 5 Effect of lectins. 0.1 ml of cell suspension ( 1 x 1 0 T lymphocytes) in complete medium (RPMI 1640, containing 2mM glutamine, 100 U/ml penicillin, 100 ^ug/ml streptomicin and 10% inactivated pooled human AB serum) was distributed in triplicate in microplate wells (Falcon Plastics, Los Angeles) and 0.1 ml of complete medium containing 2 ^ug/ml of PHA (PHA-P, Difco De troit) or 0.01,0.1,1,10 and 100 ^ug/ml of the 32 lectins tested was added. T lymphocyte cultures were incubated in a humidified3 atmosphere of 3 5% C0 9 and 95% air for 72 hours. Methyl- H-thymidine ( H-TdR, the Radiochemical Center, Amersham, spec. act. 5 Ci/mmol) was added for the last 6 hours (0.5 ^uCi/well). The inhibitory experiments with Dolichos biflorus, Perca fluviatilis and Momordica charantia lectins were performed by ad ding each lectin to 1 x 10^ T lymphocytes stimulated with PHA or ConA (10 yug/ml, ConA 3x crist.,Miles, Lausanne) as described above. Inhibitory lectins were added at the initiation of the culture period in appropriate amounts to reach final concentrations of 0.0 1 ,0.1 ,1 ,1 0 and 100 ^ug/ml. At the end of the incubation period the T lymphocytes were harvested and washed
296
on glass fiber filters with the aid of a multiple cell culture o harvester (Skatron, Norway) and H-TdR incorporation (expressed as cpm) was measured by liquid scintillation counting as previ^ ously described (5). Data evaluation. The results obtained in cell cultures were expressed as Stimulation Index (S.I.). S.I. was calculated as the ratio between cpm of stimulated and unstimulated cultures: g j
=
cpm of cultures stimulated with lectin cpm of cultures without lectin
Results To test the mitogenic and/or the toxic activity of the lectins included in the present study more than ten experiments were performed. In each experiment a negative (T lymphocytes without mitogen) and a positive control (T lymphocytes plus PHA) were always included. In the different experiments the "^H-TdR incor poration ranged from 200 to 4 ,000 cpm in negative controls (mean 1,120 cpm) and from 44,880 to 232,015 cmp (mean 99,840 cpm) in positive PHA-stimulated control cultures. 3 TABLE 2. Lectins which do not affect the H-TdR incorporation of human purified T lymphocytes. Lectin concentrations (/ug/ml) 0. 01
0 .1 (a) 1 _ 1 .13 11
Arachis hypogaea Coregonus lavaretus M.
0. 68
Helix pomatia
0. 47
Pisum sativum
0. 66
Sarothamnus scoparius Triticum vulgare Ulex europaeus
0. 81 1.01 0. 74
Vicia villosa
0. 53
1 0..73 0.. 97
10 0 .58
1 00 0. 84
0 . 68
0. 22
0 .46
0. 33
0. 51 0. 57
0..57 0..43 0..79
0 .52
0. 49
0. 68 0. 50 0. 20
1 .. 01 0..29 0,.34
0 .82 1 . 00 0 .34
1 .27 0. 88 0. 65
0 .30
0. 38
1 .1 2 0. 85
(a) Results are expressed as stimulation index(see Mat.and Met)
297
Table 2 shows the results obtained with a group of lectins which do not affect the ^H-TdR incorporation of the T lymphocytes. Although using a wide range of lectin concentrations (0.01-100
,ug/ml) the S.I. values are close to 1. 3 Twelve lectins were found which caused a H-TdR incorporation significantly higher than that observed in control unstimulated cultures. The results of these experiments are shown in Table 3. TABLE 3. Lectins which have mitogenic effect on human purified T lymphocytes.
Lectin concentrations ( yug/ml) 0..01 Crotalaria júncea Glycine max Hura crepitans (latex) Hura crepitans (seeds)
0.. 1
1
0..55 (a) 54.. 91 189..87 0..85 0.. 78 0..69 2,.84 45..10 132..59 2,.74
51 .00 .
Phaseolus lunatus Vicia sativa
0.,56 0..69
103..73 0..76 1 .. 25 0.. 68 1 .67 .
Datura stramonium Erythrina indica
0..77 0..78
1 .. 02 4 .. 98
1 .. 92 22,.59
Ononis spinosa
1 .26 .
1 .66 .
6..24
Phaseolus coccineus Robinia pseudoacacia
. 1 .58 2.. 97 1 .59 .
Rutilus rutilus
10
1 00
32,.77 0..81
7 .. 63 4.,15 15,. 67
.57 1 57. 98.. 24 16,.86 1 1.47 . 2..41 9..69 52,.36
. 1 .70 2.. 97 64..15 0..11 0..10 0.. 55
74.. 08 278 .37 132..1 25 0..80 . 48 .74 . 1 05. , 78 17.. 1 3 0.. 34 4 .. 28 1 4.,04 2..75 0.. 04
(a) Results are expressed as stimulation index (see Materials and Methods); A = lectins which are mitogenic even at the highest concentrations tested; B = lectins which bring about a decreased H-TdR incorporation at higher concentrations, after a peak of optimal activity.
298 The mitogenic power of many lectins (Crotalaria juncea, Hura crepitans from latex, Hura crepitans from seeds, Vicia sativa, Ononis spinosa, Phaseolus coccineus and Robinia pseudoacacia) is quite strong. The mitogenic activity of other lectins such as Glycine max and Datura stramonium is weak, while other lectins such as Erythrina indica, Phaseolus lunatus and Rutilus rutilus have, in these experimental condition, an intermediate mitogenic power. These mitogenic lectins have been further divided into two sub groups. In the first lectins are mitogenic even at the highest concentrations tested, while in the second lectins bring about 3 a decreased incorporation of H-TdR at higher concentrations, after a peak of optimal activity. 3
Many lectins caused a decreased H-TdR incorporation below the level observed in control unstimulated cultures. They are listed in Table 4. TABLE 4. Lectins with toxic effecton human purified T lymphocytes. Lectin concentrations ( ^ug/ml) 0. 1 (a)_ 2. 1 3 — 0. 02 0. 02 0. 02 0. 02 0. 02 0. 02
_1 0. 62
10 0.50
1 00
0. 01 0. 02 0. 04
0.02 0.02 0. 01
0.03 0. 01 0.01
0. 38 0. 93
0. 36 0. 39
0. 36 0. 24
0.18 0.22
0.13
0. 55
0. 49
0. 28 0. 02 0. 02 0. 1 1 0. 06 0. 50 0. 39
0.08 0.01
0.07 0.02 0. 06
0. 01
Abrus precatorius (agglutinin) Abrus precatorius (Abrin C) Adenia digitata (modeccin 4B) Adenia digitata(modeccin 6B) Dolichos biflorus Momordica charantia Perca fluviatilis Ricinus communis (ricin 60) Ricinus communis (ricin 120) Vicia cracca Wistaria floribunda
0. 02 0. 04 0. 54 —
• -
1. 04
0. 65
0.03 0.09 0.49
0.27
0.10 0.13
(a) Results are expressed as stimulation index (see Materials and methods).
299 Some of these lectins such as ricin, abrin and modeccin are well known inhibitors of protein synthesis (6—8)• The toxic activity of three of these lectins has been confirmed by their addition to T lymphocytes previously stimulated by PHA and ConA (Fig. 1). In this case the inhibition of 3H-TdR incorporation is dose-dependent and Momordica charantia lectin appears to be the strongest inhibitor. The results obtained with Bandeiraea simplicifolia (data not shown) were not clear enough to allow an assignment to one of three aforementioned group of lectins.
Discussion The main results of the present study may be summarized as fol lows.
ration of PHA and ConA stimulated lymphocytes. Results are given as per cent of control values.
300
First, as far as we know, the mitogenic activity for human T lymphocytes of Datura stramonium, Erythrina indica, Hura crepitans (from latex), Ononis spinosa and Rutilus rutilus lectins is described for the first time. The mitogenic activity of other lectins has been previously described (9,10). It is interesting to note that two of the most potent mitogenic lectins derive from the same plant, i.e. Hura crepitans. Preliminary data suggest that the two lectins which can be purified from the seeds and from the latex respectively are different although very similar molecules. (Barbieri et al., unpublished results). Particularly interesting seems also to be the lectin from Rutilus rutilus which is of animal origin and has also toxic properties in a cell-free system (as will be later discussed). Further studies are needed to ascertain whe ther the mitogenic activity of some of these lectins is restricted to the T lymphocytes. Many mechanisms have been proposed to account for the bell-sha ped responses observed with mitogenic lectins (11). Taking into account the dose-response curves the mitogenic lectins have been divided in two subgroups, a first one in which the 3 H-TdR incorporation is always higher than that observed in unstimulated control cultures, even at the highest concentration used, and a second subgroup in which high lectin concen3 trations cause a H-TdR incorporation lower than that of control cultures. This subdivision is proposed here as a working hypothesis to ascertain whether it can help in finding differences among the lectins of the two subgroups in terms of cell binding and toxicity, preferential stimulation of lymphocyte subpopulations with suppressor activity etc. Second, we observed that the lectins with the highest inhibito ry power on in vitro protein synthesis, such as abrin, ricin and modeccin, are also highly toxic for intact T lymphocytes. However apparent contradictions between the toxic activity in a cell-free system and on intact lymphocytes were also obser_ ved. In fact the lectins from Crotalaria juncea, Hura crepitans (latex), Hura crepitans (seeds) and Rutilus rutilus are
301
all mitogenic (and in the case of the first three lectins among the strongest mitogens) for T lymphocytes and still they exert a strong inhibitory effect on protein synthesis in a cell-free system (1, and unpublished results). This strongly suggests that these lectins bind to cell receptors but either any or very few molecules are able to enter within the cells or that, even if they are able of entering, they are rapidly inactivated. The mechanisms and the structural requirements which determine and control the penetration of a lectin into a cell and the subsequent fate within the cell (enzimatic clea vage, breakdown of disulphide bridges etc.) seem to be critical as far as the overall biological effect (stimulation, killing etc.) on the cell is concerned. Third, a group of lectins which did not affect the "^H-TdR incorporation in intact lymphocytes was identified. It is interesting to note that, apart from Coregonus lavaretus maraena lectin, .which has a weak inhibitory activity, all other lectins of this group are also inactive as protein synthesis inhibitors in a cell-free system (1). However, there are also lectins, such as those from Dolichos biflorus and Perca fluviatilis, which exert a toxic effect on the spontaneous blastogenesis of T cells and totally inhibit the "^H-TdR incorporation of PHA or ConA stimulated T lymphocytes at concentrations (100 ^ug/ml) that do not affect at all protein synthesis (1). Thus, the mechanism by which these two lectins exert a toxic effect on intact lymphocytes is different from that of the majority of the other toxic lectins, i.e. ribosome inactivation and consequently inhibition of protein synthesis (6). In conclusion our study suggest that different and apparently opposite properties such as the capacity to stimulate cell mitosis and to inhibit protein synthesis may belong to the same molecule and stress the importance of the experimental system used to assess the lectin activity. Moreover we hope that our approach i.e. the study of the effects exerted by lectins on a homogeneous population of intact purified human T cells, to-
302
gether with the study of the effects exerted by the same lectins on protein synthesis in a cell-free system, may help in the understanding of the structural requirements and the type of cell interactions that control binding, penetration, activation or inactivation, and consequently the final biological effect exerted by each lectin.
This work was supported by grants n. 81.01371.96 and number 81.01469.96 from Consiglio Nazionale delle Ricerche to prof. C. Franceschi and F. Stirpe, respectively, within the "Progetto Finalizzato sul controllo della Crescita Neoplastica", and by grant n. 81.00340.04 to Prof. C. A. Rossi. References 1. 2.
Barbieri, L., Lorenzoni, E., Stirpe, F.: Biochem. J. 182, 633-635 (1979). Böyum, A.: Scand. J. Clin. Lab. Invest. 21, Suppl. 97, 77-89 (1968).
3.
Pellegrino, M.A., Ferrone, S., Dierich, M.I., Reisfeld, R.A.: Clin. Immunol. Immunopathol. 324-333 (1975).
4.
Licastro, F., Franceschi, C., Chiricolo, M., Battelli, M.G., Tabacchi, P., Cenci, M., Barboni, F., Pallenzona, D.: Carcinogenesis 3, 45-48 (1982).
5.
Franceschi, C., Licastro, F., Paolucci, P., Masi, M., Cavicchi, S. and Zannotti, M.: J. Ment. Defic. Res. 22, 179-1 91 (1 978).
6.
Olsnes, S., Pihl, A.: In Cuatrecasas, P. (Ed.), the Specificity and Action of Animal, Bacterial and Plant Toxins 129-173, London: Chapman and Hall (1977).
7.
Olsnes, S., Haylett, T., Refsnes, K.: J. Biol. Chem. 253, 5069-5073 (1978).
8.
Gasperi-Campani, A., Barbieri, L., Lorenzoni, E., Montanaro, L., Sperti, S., Bonetti, E., Stirpe, F.: Biochem. J. 174, 491-496 (1978).
9.
Falasca, A., Franceschi, C., Rossi, C.A., Stirpe, F.: Biochim. Biophys. Acta 5J7J7, 71-81 (1 979).
10.
Falasca, A., Franceschi, C., Rossi, C.A., Stirpe, F.: Biochim. Biophys. Acta 632, 95-105 (1980).
11.
Hume, D.A., Weidemann, M.J.: Mitogenic Lymphocyte Transformation, Elsevier, North Holland Biomedical Press, Amsterdam. New York. Oxford 1980.
LECTINS AS PROBES OF BLOOD PLATELET ACTIVITY Kenneth J. Clemetson*, John L. McGregor*, and Ernst F. Lüscher* •Theodor Kocher Institute, University of Berne, P.O. Box 99, CH-3000 Berne 9, Switzerland. **INSERM Unité 63, 22 ave du Doyen Lépine, F-69500 Bron and Faculté de Médicine, Alexis Carrel, rue Guillaume Paradin, F-6900 Lyon, France.
Blood
platelets
form
an
ideal
test-system
for
studying
the
effect of lectins in inducing cellular activity and in inhibiting its induction by physiological stimulators. they
show
where
three
the
major
resting
activation
discoidal
stages:
platelet
is
In vitro,
a) Shape
change,
transformed
to
a
spherical form, which rapidly develops long pseudopods; b) the platelets storage
become
"sticky" and aggregate; c) the contents of
organelles,
released.
many of which are also stimulators,
are
This latter stage may produce an enhanced aggrega-
tion, the so-called second wave.
In addition, in vivo, plate-
lets can adhere to exposed subendothelium, a process in part dependent on a plasma glycoprotein, the von Willebrand factor. These
processes
various on
the
lectins effects
can and of
be
either
several
stimulated
studies
have
lectins on platelet
or been
activity
inhibited made,
by
either
(1-3) or to
find out which lectins bind to which platelet membrane glycoproteins
(4-7). However, little work has been done on corre-
lating the binding of a lectin to a particular with the biological effect produced.
© Walter d e Gruyter & Co. 1983, Berlin • N e w York Lectins, Vol. Ill
glycoprotein
304 Considerable
details
are
known
major platelet glycoproteins These
come
from
glycoproteins 1
mann s with
studies
thrombasthenia, The
role
of
some
of
syndrome, and
acid
GPIb,
Ilia)
against
sialic
the
in the functions detailed above.
GPIIb
directed
major
the
on platelets with genetically
(Bernard-Soulier
antibodies
15).
of
(8-11)
specific
containing
absent
and
Glanz-
and
studies
glycoproteins glycoprotein
(12— (GPIb)
is known to be the von Willebrand factor receptor and to contain
a
thrombin
binding
site,
while
GPIIb
and
Ilia
complexes
and
probably
constitute
receptors,
possibly
via
form
2+ Ca
-
dependent
telet
aggregation
ding.
the
pla-
fibrinogen
bin-
Glycoprotein V is the only thrombin-cleavable
protein
and
is
indispensable
for
thrombin-induced
glyco-
activation
(16) .
Methods and Materials Platelets for of
the the
(17). by
were Central
Swiss
from
Laboratory
Red
Cross
citrate-treated
of
and
the
Blood
washed
sonication
and
(6).
glycoproteins
differential In
by
order
to
endogenous
blood
Transfusion
Ca
Service described
from washed platelets
centrifugation avoid 2+
collected
as • previously
Platelet membranes were prepared
described
peptin
isolated
as
degradation
-activated
previously of
membrane
proteases,
leu-
(100 ng/ml, Sigma) was added before sonication.
Lectin-affinity membranes
chromatography
solubilized
bound to Sepharose (4,6) or purchased
in
1%
was
carried
sodium
out
with
deoxycholate
on
4B either prepared as previously from
Pharmacia
platelet lectins
described
(Uppsala, Sweden) or Medac
(Hamburg, F.R.G.). Two-dimensional by
the method
gel
electrophoresis
of Wang and Richards
or by the method of O'Farrell
(19).
was (18)
carried
out
(unreduced,
either reduced)
Lectin binding components
305
were identified by treating the fixed, washed gels 125 I-labelled lectins as previously described (20). Aggregation platelet
studies.
The
effects
agglutination/activation
activation
induced
by
of
or
lectins
in
physiological
with
in
inducing
inhibiting
platelet
agents
were
studied
by
adding different concentrations of lectin to 200 pi of plateg
lets (5x10 /ml).
When inhibition of other agents was tested,
the agent was added lectins
5 sec after the lectin.
The effects of
on platelets which had been desialated by
treatment
with neuraminidase (Behringwerke) (6) were also checked. Results and Discussion The effects of various lectins on platelets have been studied by
several
these
groups
lectins
little attempt
(1 - 3 ) but
bind
have
not
and
been
glycoprotein
to
which
so well characterized
and
has been made to correlate binding of lectins
with the effects produced. attempted
the
the
major
In Table I such a correlation is
glycoproteins
bound
and
effects
on
platelets are shown for those lectins which have been studied in
the most detail.
drawn
from
In part, the effects on platelets
previously
work
(1-3)
complemented
by
our
are own
studies,reported here,while the results for the glycoproteins bound come principally chromatography platelet though on
the
into
various it
conclusions two
separated
gel electrophoresis
platelets
broad
studies with lectin-affinity 125 (4,6) and binding of I-labelled lectins to
glycoproteins
acrylamide
from our
classes.
lectins
is
produce
nevertheless
and
to
see
These
are
by
two-dimensional
poly-
(results reported here).
that
a wide range of possible the
firstly,
to
Al-
effects
draw
certain
lectins fall
roughly
those
lectins
which
induce aggregation but only at relatively high concentrations and which are not strong inducers of the platelet release re-
306 TABLE I Lectin
Major GP bound
Direct effect
Lens culinaris
lb, lib, Ilia (4) Aggregation
Inhibition of
(2)
Second wave^
Concanavalin A Ilia, 111b
Shape change, release (2)
Aggregation"^
Wheat germ agglutinin
Strong aggregation and release (3)
vWf induced aggregation
la, lb, Illb (4)
Ricinus communis lectin I*
la, lb, Illb (V)
Aggregation and release (1,2)
Soy bean agglutinin*
None,glycolipid?
No shape change but Aggregation (1)
Peanut agglu-- Ib (5,6) tinin*
Strong aggregation and release (1)
vWf induced aggregation
Maclura aurantiaca
lb, high mol.wt. component (5)
Strong aggregation and release
vWf induced aggregation
Phaseolus vulgaris
Ib, Ila, Illb
Aggregation + release (1)
Aggregation^
*
With platelets treated with neuraminidase
'
Induced by ADP, epinephrine or arachidonic acid
action and secondly, lectins which induce strong aggregation and release first agents
at low concentrations.
group
tends
but
not by
to
inhibit
In inhibition studies the
aggregation
ristocetin/von
by a wide
Willebrand
factor
range while
second group inhibits ristocetin/von Willebrand factor aggregation other
strongly
agents.
but has
little
The main members
effect
of the
induced
on aggregation
first group
of the
are
by
Lens
culinaris lectin, concanavalin A and Phaseolus vulgaris lectin while wheat germ agglutinin agglutinin platelets)
and are
Ricinus the
(with normal platelets) and peanut
communis
principal
lectin
lectins
of
(with the
desialated
second
group.
307 Fig. 1 shows the results obtained with Lens culinaris
lectin
as representative of the first group while Fig. 2 shows those obtained
with
peanut
lectin as representative
of the
second.
It is of course not yet possible to exclude that lectins bind also to glycolipids and thus affect platelet function.
Soybean
agglutinin may be a lectin which falls in this category. addition,
because
glycoprotein they of
the
the lectins bind to more than one
is
some
overlapping
in
the
effects
induced first
release
group
culinaris
of
storage
inhibit
granules
aggregation.
though
This
can
the
lectins including wheat germ agglutinin and
lectin
be
lectins
despite
bind
to
glycoprotein
V
(the
cleavable glycoprotein) albeit relatively weakly. obtained
which
None of the lectins tested had any effect on
fact that several Lens
of
there
produce.
thrombin
most
In
interpreted
as
follows;
those
thrombin-
The results lectins
which
bind strongly to GPIb such as wheat germ agglutinin or, after neuraminidase both
aggregation
gation
if
culinaris though
they
which
Lectins
weak
treatment, and can
lectin
be
used
to
or
agglutinin, strongly
and at
GPIIb are
inhibit
a high and/or
concanavalin
amounts
A
required,
vWf-induced
enough
induce
adrenalin proteins
terms
or
as
Lens
generally
induced by agents such as ADP,
thrombin.
bound
results some of
compared brand
such
aggregation,
are
and
The
the
obtained
relationship
effect using
produced
monospecific
between
alonly
differences
in
the
sites
to
binding
antibodies.
factor-induced
effect
which
collagen,
the
is in good
glyco-
agreement
or monoclonal
bodies directed against specific glycoproteins are
aggre-
concentration.
GPIIIa but
induce
inducers of release. They inhibit aggregation or second-
wave of aggregation
with
release
bind
larger
peanut
can
(12-15). be
antiThere
explained
on
the
glycoprotein
Thus,
the
inhibition of von Wille-
platelet
for
in
lectins
aggregation by lectins binding
GPIb supports earlier suggestions
(21) that
it is the outer,
308
100 n Fig.1
T 1
0
Fig. 2
A
2
1
1 3
A
T 1
1 4
T
r 2
4
Fig. 1: Effect of Lens culinar^s lectin on ADP/fibrinogeninduced platelet aggregation (xlO platelets/ml, 4)iM fibrinogen). A: Aggregation curve with ADP added at arrow 2. B: Aggregation curve with Lens culinaris lectin (final concentration (200jig/ml added at arrow 1, followed by 5)iM ADP at arrow 2. Fig. 2: Effect of peanut lectin on ristocetin-induced aggregation of neuraminidase treated platelets resuspended in plasma. A: Aggregation curve with ristocetin (final concentration, 1.5 mg/ml) added at arrow 2. B: Aggregation curve with peanut agglutinin (20|ig/ml, final concentration) added at arrow 1 followed by ristocetin as in A at arrow 2. carbohydrate-rich
part
of
Willebrand
factor
lectin
concanavalin
by
and
a
gives
variety further
mediated ducing The
the
A
to
platelets blocking
inhibiting idea
sites
that
the
involved of
Lens
platelet
von
between
this
aggregation.
fibrinogen
von
aggregation factor)
agglutination
GPIIb
may
in
culinaris
Willebrand and
on the platelet
molecules
causing
is
effects
(excluding the
fibrinogen
by
in
formation
binding
which
The
agents
weight
dimeric either
binding.
complex
fibrinogen
between act
by
of
GPIb
surface
then
form
The
binding
Ilia,
(22).
bridges
lectins
sites
is
pro-
may
directly
309 or
by
preventing
complex
It
is
not
why
second
clear
wave
served with
is
two
different
the
aggregation
the
platelets, can
clear
with
affected
antibodies
Lens
but
produced
are by
between
culinar is
similar
directed
mechanisms be
formation
In
have
whereby
Ilia.
only
the
been
ob-
GPIIb/IIIa.
fibrinogen
inhibited.
and
lectin
results
against
involved
GPIIb
Possibly
only
one
i.e.
and ADP released
from
conclusion,
it
is
now
that many of the effects of lectins on platelets can be
explained
in
terms
of
the
glycoproteins
to
which
they
bind
but that not all of the problems have yet been solved.
Acknowledgements This
work
was
supported
by
grants
from
the
Swiss
National
Science Foundation and INSERM CRL 817016. References 1.
Patscheke, H., Brossmer, R., and Wörner, P. Biophys. Res. Commun. , 7_5, 200-206, (1977).
2.
Patscheke, H. and Wörner, P. 402, (1977).
3.
Greenberg, J.H. and Jamieson, G.A. Acta, 345, 231-242, (1974).
4.
Clemetson, K.J., Pfueller, S.L., Lüscher, E.F. and Jenkins, C.S.P. Biochim. Biophys. Acta, 464, 493-508, (1977) .
5.
Judson, P.A. and Anstee. D. In: Proc. of the 27th Meeting, Protides of the Biological Fluids, H. Peeters (Ed.) Pergamon, Oxford, New York 1980 pp. 871-874.
6.
Clemetson, K.J., Nairn, H.Y. and Lüscher, E.F. Natl. Acad. Sei. USA, 78, 2712-2716, (1981).
7.
Hagen, I. and Gogstad, G. In: Lectins, Biology, Bio chemistry, Clinical Biochemistry, T.C. B?ig-Hansen (Ed) Vol 1, de Gruyter, Berlin, New York 1981 pp 347-357.
8.
Jenkins, C.S.P., Phillips, D.R., Clemetson, K.J., Meyer D., Larrieu, M.-J. and Lüscher, E.F. J. Clin. Invest. 57, 112-125, (1976).
9.
Hagen, I., Nurden, A., Bjerrum, O.J., Solum, N.O. and
Thromb. Res.
Biochem. 11, 391-
Biochem. Biophys.
Proc.
310
Caen, J.P.
J. Clin. Invest.
£5, 722-731, (1980).
10.
Nurden, A.T. and Caen, J.P. 250, (1979).
Semin. Haematol.
16^, 234-
11.
Phillips, D.R. and Poh Agin, P. 535-545, (1977).
12.
Ali-Briggs, E.F., Clemetson, K.J. and Jenkins, C.S.P. Br. J. Haematol. 48, 305-318, (1981).
13.
Jenkins, C.S.P., Ali-Briggs, E.F. and Clemetson, K.J. Br. J. Haematol. 49, 439-447, (1981).
14.
Ruan, C., Tobelem, G., McMichael, A.H., Drouet, L., Legrand, Y., Degos, L., Kieffer, N., Lee, H. and Caen, J.P. Br. J. Haematol. 49, 511-519, (1981).
15.
Kornecki, E., Lee, H., Tuszynski, G.P. and Niewiarowski, S. Fed. Proc. 41, 528 (1982) abstr.
16.
Berndt, M.C. and Phillips, D.R. 59-65, (1981).
17.
Massini, P. and Liischer, E.F. 372, 109-121, (1974).
18.
Wang, K. and Richards, F.M. 8018, (1974).
19.
O 1 Farrell, P.H.
20.
McGregor, J.L., Clemetson, K.J., James, E., Capitanio, A., Greenland, T., Liischer, E.F. and Dechavanne, M. Eur. J. Biochem. 116, 379-388, (1981).
21.
Jamieson, G.A., Okumura, T. and Hasitz, M. Haemostas. 42, 1673-1678, (1979).
22.
Nachman, R.L. and Leung, L.L.K. 263-269, (1982).
J. Clin. Invest.
J. Biol. Chem.
60,
256,
Biochim. Biophys. Acta J. Biol. Chem.
J. Biol. Chem.
252, 8005-
2j>0, 4007-4021, (1975).
Thromb.
J. Clin. Invest. 69,
SIALIC ACID AS A CELL SURFACE BINDING SITE FOR WHEAT GERM AGGLUTININ John T. G a l l a g h e r * ,
Margaret Harding* and Robert E.
Dale#
* C a n c e r Research Campaign Department of Medical Oncology, #Paterson
Laboratories,
Christie Hospital & Holt Radium I n s t i t u t e , and Manchester Wilmslow Road, Manchester M20 9BX, E n g l a n d .
University,
The combining site of wheat germ a g g l u t i n i n (WGA)consists of three i d e n t i c a l s u b - s i t e s each complementary to N-acetylglucosamine
-GlcNAc-:
the free s u g a r is a poor i n h i b i t o r of lectin binding to g l y c o c o n j u g a t e s but the d i - and t r i s a c c h a r i d e forms (chitobiose and chitotriose) potent i n h i b i t o r s
suggesting that high a f f i n i t y binding is
are
associated
with l i g a n d s that i n t e r a c t simultaneously with two or more of the available subsites ( 1 , 2 ) .
In glycoproteins terminal GlcNAc residues
in a s p a r a g i n e - l i n k e d g l y c a n s are not r e a c t i v e with WGA although lectin will
precipitate
with
the isolated t r i s a c c h a r i d e
GlcNAc which forms the l i n k a g e sequence to a s p a r a g i n e
the
man-GlcNAc(3,7).
In
native glycoproteins the proximity of this sequence to the core protein may impair recognition by WGA.
The interaction of WGA with cell
s u r f a c e s is i n h i b i t e d by treatment of c e l l s with
neuraminidase
suggesting that s i a l i c acid may be an important s u g a r in the binding process.
(5,6,9)
When used as a s a c c h a r i d e inhibitor of WGA,
acid has very low a c t i v i t y .
(3)
sialic
However, multiple i n t e r a c t i o n s with
s i a l y l residues may be favoured at c e l l s u r f a c e s because of the location of t h i s s u g a r at the terminal non-reducing end of c a r b o h y d rate c h a i n s .
In an attempt to elucidate the roles of s i a l i c acid and
GlcNAc we have c a r r i e d out k i n e t i c and inhibition studies on the influence of neuraminidase on WGA binding to the surfaces of K562 cells. Materials and Methods Cells used were an erythroleukaemic cell l i n e ,
K562, derived from
a patient with chronic myeloid leukaemia in b l a s t c r i s i s . binding of F-WGA (Miles Chemical C o . ,
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
molar r a t i o ,
(8)
fluorescein
The :
312 protein
1.3:1)
was determined
as described
p r e v i o u s l y (4).
v a r y i n g c o n c e n t r a t i o n s of F-WGA were a d d e d to K562 c e l l s 150 u l ) a n d i n c u b a t e d
a t 4°C f o r 30 m i n u t e s .
l e c t i n w a s t h e n m e a s u r e d b y flow c y t o m e t r y . (GlcNAc a n d c h i t o b i o s e ) cells.
Cell Sugar
Briefly, (1C)5 c e l l s in
surface-associated inhibitors
were mixed with t h e l e c t i n b e f o r e a d d i t i o n of
In k i n e t i c a n a l y s e s
l e c t i n b i n d i n g to c e l l s w a s e f f e c t i v e l y
s t o p p e d b y d i l u t i n g t h e i n c u b a t i o n t e n f o l d w i t h cold p h o s p h a t e saline
(PBS)
(pH 7 . 2 ) .
buffered
C o m p e t i t i v e i n t e r a c t i o n b e t w e e n F-WGA a n d
n a t i v e form of t h e l e c t i n w a s c a r r i e d out b y f i r s t i n c u b a t i n g
the
the cells
for v a r y i n g times with the f l u o r e s c e i n - d e r i v a t i v e and then a d d i n g two to t e n f o l d e x c e s s of t h e u n c o n j u g a t e d f o r m . be f o u n d in t h e f i g u r e l e g e n d s .
Neuraminidase
Further details
a may
( T y p e IV - from
Sigma C h e m i c a l Co. ) t r e a t m e n t w a s c a r r i e d out b y i n c u b a t i n g
10? c e l l s
w i t h 0 . 0 5 u n i t s of enzyme in a t o t a l volume of 1 ml of PBS.
Maximum
d e c r e a s e in F-WGA b i n d i n g c a p a c i t y
was achieved under these con-
ditions . Results S p e c i f i c i t y of i n t e r a c t i o n of WGA w i t h t h e K562 c e l l s u r f a c e w a s established
by t h e complete i n h i b i t i o n of l e c t i n b i n d i n g
in t h e
of c h i t o b i o s e a n d t h e s i g n i f i c a n t b u t l e s s complete i n h i b i t i o n GlcNAc.
presence by
(Fig.1)
D i s t i n c t i v e b i n d i n g c u r v e s were o b t a i n e d when c o m p a r i n g and neuraminidase-treated a plateau
between
(Fig.2).
in t h e f o r m e r b i n d i n g
1 u g a n d 5 u g of l e c t i n ,
treated cells binding range
cells:
w h e r e a s in
increased quite s h a r p l y over this
control
approached the concentration
The d e g r e e of i n h i b i t i o n of b i n d i n g to t r e a t e d
was dependent upon the lectin c o n c e n t r a t i o n ,
64% i n h i b i t i o n
cells
at 0.1
ug
d e c l i n i n g to 39% a t 5 u g . Kinetic a n a l y s i s considerably cells
(Fig.3).
i n d i c a t e d t h a t t h e r a t e of WGA b i n d i n g
more r a p i d to u n t r e a t e d t h a n to
neuraminidase-treated
In t h e t r e a t e d c e l l s f a s t a n d slow p h a s e s of
b i n d i n g process were observed with each p h a s e r e p r e s e n t i n g of t h e b i n d i n g c u r v e .
In t h e c o n t r o l c e l l s ,
w a s c o m p l e t e a t 1 min ( f a s t p h a s e ) tatively less significant
(Fig.3).
was
however,
70% of
a n d t h e slow p h a s e w a s Further complexity was
the a b o u t 50% binding quanti-
evidenced
313 when b i n d i n g (Fig.4).
was e x a m i n e d o v e r
In the c o n t r o l
achieved
within
enzyme-treated that
different
iments ation
(Figs. as t h i s
selective
5 sees w h e r e a s cells
led
lectin
analysis
of
were
significant
saturation
sites o c c u p i e d
tration
lectin
concentration
agglutination.
so some p o t e n t i a l
fast phase
of b i n d i n g lectin
was not a remain
in
exper-
control
popul-
preventing
concentration.
cells
we c o u l d employ
sites w o u l d
sites
was
emphasise
used in the k i n e t i c
at low
The l a t t e r
We would
f o r the u n t r e a t e d
5 ug was used f o r the n e u r a m i n i d a s e - t r e a t e d the h i g h e s t
site occupancy
25% o c c u p a n c y .
1 ug w a s chosen virtual
short time increments of 5 sees
60% b i n d i n g
the c o r r e s p o n d i n g
to o n l y
concentrations
3-5). gave
very
population,
because
without
this
was
causing
'saturating'
concen-
unoccupied.
100
•s 50
\
50
100
2.5
5
GlcNAc Chitobiose
C o n c e n t r a t i o n of Inhibitor(mM)
Fig.l.
Saccharide
inhibition
of
F-WGA b i n d i n g
to K562 c e l l s
GlcNAc ( ) and D i , N - a c e t y l c h i t o b i o s e ( ) were mixed with the l e c t i n ( l u g / 1 5 0 u l ) b e f o r e a d d i t i o n of K562 c e l l s . For each s a c c h a r i d e c o n c e n t r a t i o n i n c u b a t i o n s with c e l l s were f o r 30 mins at A°C. C e l l f l u o r e s c e n c e was measured b y f l o w c y t o m e t r y .
314
Fig.2.
I n f l u e n c e of n e u r a m i n i d a s e on F-WGA b i n d i n g
Neuraminidase-treated( ) and untreated cells ( ) were i n c u b a t e d with the s t a t e d r a n g e of F-WGA c o n c e n t r a t i o n s for 30 mins at 4 ° C . 10^ c e l l s were mixed with the a p p r o p r i a t e l e c t i n c o n c e n t r a t i o n in a t o t a l volume of 150 ul of PBS.
2
-3
2-5
ng F-WGA When the f l u o r e s c e i n - c o n j u g a t e d
WGA (1 u g ) w a s i n c u b a t e d
with
K562 c e l l s for 30 mins a n d then a t e n f o l d e x c e s s of n a t i v e WGA a d d e d , no d e c r e a s e in cell f l u o r e s c e n c e ,
a n d hence no e o u i l i o r i u m
bound a n d f r e e forms of the lectin w a s o b s e r v e d
( r e s u l t not
between shown).
However, in view of the complex b i n d i n g k i n e t i c s of WGA we d e c i d e d to e x p l o r e the p o s s i b i l i t y dependent,
i.e.
that i r r e v e r s i b i l i t y
of b i n d i n g may be time
t h a t a c e r t a i n r e s i d e n c e time of the lectin at the
cell s u r f a c e is n e c e s s a r y for i r r e v e r s i b l e b i n d i n g .
Cell
suspensions
were t h e r e f o r e i n c u b a t e d with F-WGA for v a r i o u s times a n d the
bind-
ing p r o c e s s i n t e r r u p t e d by a d d i t i o n of an e x c e s s of n a t i v e WGA. n a t i v e l e c t i n s h o u l d both compete with F-WGA for unoccupied s i t e s a n d e s t a b l i s h an e q u i l i b r i u m with bound F-WGA if l e c t i n
The
binding binding
315
Fig.3.
Rate of b i n d i n g
of
F-WGA
F-WGA w a s a d d e d to u n t r e a t e d { ) and n e u r a m i n i d a s e treated ( ) c e l l s at a l e c t i n c o n c e n t r a t i o n of 1 ug/150 ul and 5 ug/150 ul r e s p e c t i v e l y . At the times i n d i c a t e d F-WGA b i n d i n g w a s stopped b y a d d i t i o n of 10 volumes of PBS. 100 a>
0
1
2
3
4
5
Incubation time (mins.)
Fig.4.
Rate of
Conditions
b i n d i n g of
F-WGA
as in F i g . 3 e x c e p t
much s h o r t e r
tirr:e increments
v/ere
used.
316 is r e v e r s i b l e . Fig.L,
The r e s u l t s showed that in c o n t r a s t to the d a t a
the b i n d i n g c u r v e s for u n t r e a t e d a n d
c e l l s were almost i d e n t i c a l
(Fig.5).
At the 5 s e c .
time p o i n t ,
c o n c e n t r a t i o n of bound F-WGA on the u n t r e a t e d c e l l s (Fig.4).
In c o n t r a s t ,
effectively
the b i n d i n g c u r v e s
n e u r a m i n i d a s e - t r e a t e d c e l l s were almost i d e n t i c a l ,
the
( F i g . 5 ) w a s only
a b o u t 25% of the v a l u e o b s e r v e d when F-WGA b i n d i n g was s t o p p e d by d i l u t i o n
in
neuraminidase-treated
for
i r r e s p e c t i v e of
whether the l e c t i n b i n d i n g p r o c e s s w a s i n t e r r u p t e d by d i l u t i o n or e x c e s s n a t i v e lectin
(Fig.4)
(Fig.5).
Discussion N e u r a m i n i d a s e treatment c l e a r l y d e c r e a s e s cells
(Fig.2)
indicating
an important role for s i a l i c a c i d in the cell
s u r f a c e r e a c t i v i t y of t h i s l e c t i n . f i n d i n g s of other workers of p a r t i c u l a r
F-WGA b i n d i n g to K562
These r e s u l t s a r e in a c c o r d
(see Introduction).
S i a l y l r e s i d u e s may be
s i g n i f i c a n c e at low lectin c o n c e n t r a t i o n s
s i n c e the
neuraminidase-inhibition
e f f e c t w a s more pronounced at 0 . 1 ug
5 ug of lectin
However,
(Fig.2).
d a t a i s complex.
1
2
than
i n t e r p r e t a t i o n of F-WGA b i n d i n g
The lectin r e c o g n i s e s both s i a l i c
a c i d a n d GlcNAc
r e s i d u e s a n d it i s c o n c e i v a b l e that removal of s i a l y l g r o u p s
0
with
3
may
4
Incubation time (mins.)
Fig.5.
Competitive i n h i b i t i o n of F-WGA b i n d i n g
F-WGA w a s a d d e d to u n t r e a t e d ( ) and neuraminidasetreated ( ) c e l l s u s i n g lectin c o n c e n t r a t i o n s of 1 u g / 1 5 0 ul a n d 5 u g / 1 5 0 ul r e s p e c t i v e l y . At the s p e c i f i e d times, ( i d e n t i c a l to those in F i g . 4 ) 10 ug of n a t i v e lectin w a s a d d e d to the i n c u b a t i o n m i x t u r e a n d c e l l f l u o r e s c e n c e determined i m m e d i a t e l y .
317 e x p o s e GlcNAc in
sites
F-WGA b i n d i n g
balance
between
cryptic and
sites.
it c o u l d
loss of Sialic
lectin
by
sialyl acid
concentrations.
may be i n f l u e n c e d
suggest
that
acid.
involves
proximal
to the membrane
of e x c e s s treated
native
and
binding
lectin
primary
quantitatively represents and
F-WGA i n t e r a c t i o n
lectin
yielded cells
of
3 & A) •
the b i n d i n g
with
sialic
is r e v e r s i b l e
acid
so that
fluorescence declines and
f r e e forms.
' lectin-binding
i r r e v e r s i b i l i t y and 30 min. contrast,
similar
(Fig.5)
were determined (Figs.
stage
acts m a i n l y
with
to
of
neuramlectin
the
binding
to GlcNAc.
We
most n o t a b l e the l e c t i n
in
and
more important
WGA r e c o g n i t i o n
of
sialic
in
the
sites
consisting
principally
with c e l l
surfaces by
after
dilution
process
more
of
with
that
of
not
native
lectin
influence cell
interrupting
curves
are
the b i n d i n g
results
point
cells
native
when
addition in
F-WGA
lectin
the
is
these added,
between
contact acquired
a pre-incubation
fluorescence cells
almost
inter-
of
a progressive,
after
is,
values. in the
identical
process
of In
main,
irrespective
(cf.Figs.4
to c o n s i d e r a b l e
of
the
is e s t a b l i s h e d of
to
the
occupancy
prolongation undergo
to n e u r a m i n i d a s e - t r e a t e d
our
than
an e x c e s s of
binding
with
rather
Initially,
addition
populations
indicate
to u n t r e a t e d
complexes
lectin
contrasted
two c e l l
results
residues.
However,
addition
In c o n c l u s i o n ,
r a t e s of
and this
in these
These
when
so that b i n d i n g
the method of
net
as a new e q u i l i b r i u m
site'
F-WGA d i d
binding
irreversible, of
Additionally,
between
at
interaction
resistant
of WGA b i n d i n g ,
differences observed
rates
native
of
untreated
conspicuous
bound
matrix.
surface
the
readily
f a c t o r s and the r a t e of
an i n t e r a c t i o n
cells,
r a t e of and
of
chains
residues. Interruption
sites
and
of
interact
impede WGA b i n d i n g
the f a s t component
cells,
at the p e r i p h e r y may
a
expression
s u g a r on s a c c h a r i d e
GlcNAc
steric
may
The s l o w e r component,
GlcNAc
time,
by
Changes
may thus comprise
sites
to be m a i n l y
residues
neuraminidase-treated
cell
These
the p e r i c e l l u l a r
WGA to s i a l y l
to the l e c t i n .
accompanying
Accessibility
inidase,
diffusion through
and
localised
glycocalyx.
sites, presumed
untreated
sites
is a t e r m i n a l
internal
of
available
neuraminidase
be p r e f e r e n t i a l l y
surface-associated low
not n o r m a l l y
induced
and
5).
heterogeneity
318 in F-WGA b i n d i n g s i t e s at the K562 c e l l s u r f a c e . b i n d i n g p r o c e s s by k i n e t i c a n a l y s i s , neuraminidase-induced
Dissection of the
competitive inhibition
and
inhibition indicates that s i a l y l residues
the p e r i p h e r y of the g l y c o c a l y x
a r e the most
at
rapidly-recognised,
q u a n t i t a t i v e l y p r e d o m i n a n t s i t e s a n d t h a t following d e s i a l a t i o n g r o u p of r e l a t i v e l y i n a c c e s s i b l e ,
which a p p e a r l e s s r e a d i l y s a t u r a b l e than the s i a l y l c a r e f u l choice of the e x p e r i m e n t a l c o n d i t i o n s low lectin c o n c e n t r a t i o n )
a
s l o w - r e a c t i n g GlcNAc s i t e s a r e sites.
exposed
By
(short incubation
time,
it seems p o s s i b l e t h a t WGA may be u s e d
a s e l e c t i v e probe of cell s u r f a c e s i a l i c
as
acid.
References 1. A d a i r ,
W.L. & K o r n f e l d , S .
J.Biol.Chem.
249,
2. Allen, A . K . , Biochem.J.
3. B h a v a n a n d a n , J.Biol.Chem.
V.P. & Katlic,
E.B.,
J.Biol.Chem. Biochemistry, 7. G o l d s t e i n , Biochim.
Li,
(1973)
(1979)
J.T.,
Swindell,
R. & Crowther,
222-226 (1977)
1107-1116 (1973) 1312-1323
12,
Hammastrom, S. & S u n d b l a d ,
Biophys.
Blood, 45,
A.W.
E. & K o r n f e l d , S.
P.
I.J.,
8. Lozzio, C . B . 9. S t a n l e y ,
IV,
252,
6. C u a t r a c a s a s ,
N.
4000-40C8
G., Gallagher,
Flow Cytometry Briles,
A. & S h a r o n ,
155-162
254,
4. B l a c k l e d g e , 5.
4696-4704
Neuberger,
K51,
(1974)
Acta 405,
& Lozzio,
53-61
B.B.
(1975)
321-334
P. & C a r v e r ,
Proc.Natl.Acad.Sci.
J.P.
U.S.,
(1977)
74,
5056-5059
G.
(1975)
D.(1980)
INTERACTION OF HUMAN YOUNG AND OLD ERYTHROCYTES WITH WGA. A FLUORESCENCE STUDY.
Dominique Bladier0,Marie-Ange Deugnier®°and Michel Caron° "Laboratoire de Biochimié et Immunochimie (Pr P.Cornillot) 9
"Laboratoire de Microscopie Quantitative (Pr J.-C.Bisconte) U.E.R. Biomedicale,74,rue Marcel Cachin-93012 BOBIGNY,France
Introduction During its lifespan in the circulation,the macromolecular components of the red blodd cell (RBC) are submitted to progressive modifications leading to the alteration of its physicochemical and functionnal properties and ultimately resulting in its removal by the macrophages.Erythrocyte aging,among other events,gives rise to the homogeneous loss of membrane fragments (1) and to modifications of some membrane dynamic properties (2).Changes at the membrane level have an even higher importance since it is the membrane which interacts with the extracellular environment.The role attributed to the surface glycoconjugates in such interactions led us to examine these structures and their properties in relation with the age of the cells. The aim of the study,reported here,was thus to investigate the interaction of human RBC with rhodamine labelled WGA,looking for possible differences between young and old cells.
Material and methods Cell labelling.Young and old human 0 erythrocytes,obtained from healthy donors of the blood bank (Centre Departemental de transfusion Sanguine,Bobigny,France)were separated accor-
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
320
ding to Murphy (3).Rinsed RBC were incubated with the rhodamine wheat germ agglutinin conjugate (WGA-T,IBF) for 30 min at 20°C.A subagglutinating concentration,i.e. 9;6ug of WGA-T per 1C>8 cells,was used for all experiments.Cells were washed twice with 0.9% NaCl solution before being resuspended in lmL of phosphate buffered saline solution (PBS).Fluorescein diacetar te (FDA) was used as a freely diffusing intracellular probe, at 6 yg per 10®RBC (4).The labelling was performed for 10 min at 37°C and followed by 3 whashings with PBS.The labelled samples were kept at 4°C until the analysis. Fluorescence measurements.Suspensions of erythrocytes were mounted on a glass slide covered with a coverslip and examif ned under a microscope equipped with a laser illumination.The basic instrument has been previously described (5) and detail of the computer control is given in (6).Briefly,the laser beam (Spectra Physics,Aemission=514.5 nm) is focused through the microscope objective (xl25) to a 3.5 ym diameter spot, which allows cell by cell measurements.Light pulses of preselected duration (500 msec) and intensity (30viW) are delivered using an accousto-optical modulator (S0R0) monitored by a PDP 11-34 (DEC) computer.The fluorescence emission is detected by a photomultiplier (Leitz,MPV2) also connected to the computer.The fluorescence intensity values,stored for further processing,are proportionnal to the number of fluorescent sites per illuminated cell location. Data analysis.Two types of analysis have been made: i)determination of the mean (-sd) fluorescence intensity of a given cell population.In this case,one measurement per cell was performed and about 100 cells were examined.A histogram can be plotted with these 100 values. ii)determination of the reproducibility of the measurement on a single cell.In this case,5 successive measurements were performed per cell and about 20 cells per sample were assayed
321
It should be pointed out,that before each of the 5 measurements the chosen cell was repositionned at the center of the microscopic field,where the laser beam is focused,thus resulting in the eventuality that the 5 locations,successively examined,are not exactly superimposable.The results are expressed as follows: for each cell,the differences between the 5 measured values of fluorescence intensity were determined 2 by 2.Ten numbers are thus obtained.The set of numbers,calculated for the 20 assayed cells,are then distributed,into classes of 1 arbitrary unit wide,on a histogram.
Results 1)Mean fluorescence intensity.of the RBC populations.lt was measured:i)on young and old WGA-T-labelled RBC.The results obtained from 5 samples are listed in table l.It appears that the mean values found for the old RBC populations are significantly higher than that found for the young ones.A typical his togram of fluorescence distribution is shown in figure 1 B. ii)on old FDA-labelled RBC,figure 1 A.Very similar fluorescence distributions were obtained for both WGA-T and FDA labelled populations,figure 1 A and B. 2)Reproducibility of the measurements on a single cell.It was tested on both FDA and WGA-T labelled RBC.Typical histograms are presented in figure 1 A' and B' respectively.These histograms are very different,suggesting that the reproducibility of the measurements on a single cell is better on FDA labelled RBC than on WGA-T labelled RBC.
Discussion The results obtained in this study of WGA interaction with
322 TABLE 1 Mean value of fluorescence intensity old and young RBC. Sample N°
m
Old Cells sd
(arbitrary units) of WGA-T labelled
n
m
Young Cells sd
n
1
51
13.5
lOO
41
9
102
2
59
10
104
52
10
99
8.5
100
3
61
12
100
50
4
65
14
lOO
58
10
100
5
61
14
101
47
10
101
n=number of measurements per sample. The mean value of autofluorescence was less than 11 a.u.In all cases, the difference between fluorescence intensity of young and old RBC are significant (p 0.001)
young and old human RBC reveal a double heterogeneity of WGA binding:on a single cell,and within a same cell population. i)Heterogeneity on a single cell:it was established by comparing the measurements obtained on FDA(a freely diffusing intracellular probe)and WGA-T labelled RBC.It can be seen that the reproducibility of the measurements on the FDA labelled RBC is rather good,fig.1 A'.This means that whatever each of the 5 cell locations successively illuminated,the corresponding measurements are very close together.This is true for each of the 20 analysed cells.The distribution of the FDA probe can thus be considered to be homogeneous within the cell.On the contrary,the wide histogram exhibited by WGA-T labelled RBC,fig.1 B' reveals that the measurements,obtained for esch of the 5 cell locations successively illuminated,are different.The distribution of the lectin,at such subagglutinating concentration,can thus be considered to be heterogeneous at the surface of the cell,due to the presence of clusters.Whether these clusters are induced by the lectin interaction,or preexist,is currently under study.It cannot be excluded that differences in some
323
w J J w u Dk o « H m
20
20 !
10"
10 "
a D
nJ
2
20
60
Bin '
100
0
F L U O R E S C E N C E
60
w a
Ik
Id 65 I'OO I N T E N S I T Y (a.U.)
60 .
A'
40.
40 .
20-
20
H p4 o OS
w «
s D
z
X
-10
0
10
- t h
0
-Ur-
-20
0
' l"l. f I 20
VARIATION OF FLUORESCENCE INTENSITY (a.u.)
Fig. 1
Fluorescence of FDA and WGA-T labelled RBC:
Above: Histograms of fluorescence distribution, one measurement per cell (100 cells per sample), classes of 4 a.u. wide. A = FDA labelled RBC; B = WGA-T labelled RBC. Below: Reproducibility of the measurements: the difference of fluorescence intensity between the 5 successive measurements per cell (20 cells per sample are distributed into classes of 1 a.u. wide). A* = FDA labelled RBC; B' = WGA-T labelled RBC.
324
dynamic properties of the cell membrane with aging(2)could also participate in the mechanism of cluster formation. ii)heterogeneity within a same cell population:old RBC populations are characterized by both higher mean values of fluorescence intensity and wider fluore scence distribution.As WGA bin ding to cells is known to be biphasic,due to the presence of high and low affinity binding sites(7)this difference may Be due either to a higher density of WGA binding sites on old RBC or to modifications in the balance of the number of high and low affinity binding sites,or to variations of the affinities. In the interaction between the cell surface and W-a-Mjn-(|-»«)/
9
i - G « l - ( l - » 4 ) 0-GIcNAe-(l->2)-o-.Man-I.I-3) x 0-Gk-N A c - ( 1 -4)-0-MaJl-< 1 -4)-ClcNAe i-Ga1-(l-4)-0-C!cNAc-(!-»2)-o-Mar.-(l-6)/
10 0-G.il-< 1 —II-1• ClcNAf-( 1 - 2 ) - a - » l a n - ( 0-Cal-(l-4)-,J-GlcNAc--n-(l-4)-,l-GlcNAc- 3 ) > )|J-Man-(1~4)- G!cNAc
Fig. 1.- Interaction of insolubili zed lectins N-glycosylamine linkage.
UEA,
LTA
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR"
FNR
FNR
FNR
FNR
FE
FR"
FR*
FNR
FNR
FNR
FNR
FE
FE
FR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FR
FR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR"
FNR
FNR
FNR
FNR
FE
FE
FE
FR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
LCA
VFA
PSA
FNR
FNR
FNR
FR"
FR +
FNR
FNR
FNR
FNR
FNR
FR"
NO
ND
ND
ND
FNR
ND
ND
ND
ND
FE lOmM
FE
FE
FE
Con A FE iomM "MG FE iomM «MG
RCA, RCA || G S A „ WGA
*(MG FE iomM VMG FE 10 mM FNR MG FE 10m M «MG FNR
+
FE 10mM of MG FE lOmM «iMG
with glycans
from g l y c o p r o t e i n s w i t h
the
340
GLYCAN STRUCTURE 12
tt-NeuAc-(2-+6)-0-Ojl-(l-*4)-í3-GlcNAc-(W2)-a-Man-(l-*3K \-Man-(l-4)-ClcN-Ac O-Min-(l~6K
13
c-N:uAc-C-J)-((-C3l-(l-4)-;-GlcNAc-(l-:)-e-Man-(l-3)-(!-Mjn-(l->-o-Man-(l~3) i-Man-(l-4)-CkNAt
15
(-GJI-(I-4)
16
Ca,
-„'J
-JI-GlcNAc--(l~2)-a-Man-(1-3>. J-Clc\'Ac-(l-:)-o-Xbn-(l-0)/
M:.n-(l"-l)-P-C;icNAc-U-'4)- > i ClcSAc-(l".l)-Asn
_-*H>-ClrNAe--«-S1ai!-
17
J-Gal-d-MlCj
. -i-C.lcNAc-(1-2)-«-M»n-{l-3). }0-Man-(!--GlcNAc-(l->41-J-GlcNAc-(l-4)-AJll -Í-C.ICNAC-(I-:)-O-MJH-(I-6/
18
| 1.6
•-Fuc
-|>dcNAc-(l-2)-n-M:m-(l-3)^ ^ . . G I I N A V - 0 "4)-j)-M3n-(l-4)-()-CkNAc-(l-4)_/)-GIcNAc- ()-4)-A»n "~^--0-GlcNAc-(l~2)-a-M»n-2)-a-Maa-< 1-3). V-M>n--Man--0-
(1—2)-a-Man-(l—6)'
Cal-(l-4)-0-G!cNAc-(l-M).^
o-NcuAc-C-6)-()-Gal-(l—ll-fl-ClcNAc-ll-D-a-M.ni-0-3). p-Mun-(l—4)—0—GlcNAc-(l—4)-0-GlcNAc-(l—3)-Asn a - N t u A c - ( 2 — 3 ) - P - G a t - ( l — 4 ) - 0 - GlcN A c - ( 1 — ? ) - « - M a n - ( l —
31
t -Gal-( 1 - 4 ) - 0- GlcNAc-(l Man—(I—4)-iJ-GlcNAc-(l—4)-|3-GlcNAc-( I—4)-A»n i-Gal(l-4)-S-GlcNAc-(l-:)--Man-(I-6K
.
P - G a l ^ l ^ - i - C l c N A c - d - t ) ^
32
i
GlcNAc-(l-4K^
K-ClcNAo (1-3)
aMjil-(l-J)^
(1- C : i c N A c - ( l - 4 t
a -M.m ( 1 - 4 ) - 0 - G l c W U - ( l - 4 > - 0
CltNAf-d-tt-Avl
(1 G t c N A c - t l - . ' > - n - M j n - ( l — < ! > /
F i g . 3 . - I n t e r a c t i o n of i n s o l u b i l i z e d N-glycosylamine linkage.
lectins
Con A
LCA
VFA
PSA
UEA,
LTA
FR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FI^R
FNR
FNR
FNR
FNR
FR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
ND
FR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
ND
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR
FNR
FNR
FNR
RCA, RCA || GSA|| WGA
-
with glycans from glycoproteins with the
346
GLYCAN STRUCTURE 33 J-GkNAc-(I-2)-«-Man-(l-3). \3). 0-Man-(l"4)-GlcNAc P 'GlcMAc-(l-2)-ii~Man-(!-«/ 39 i-GlcNAc- ( l - > : ) - a - M a n - ( l - 3 ) ^ i - G L N A c - i 1-41-11-Man-( l - 4 ) - f f - C l c N A c - ( l - 4 ) - U - G ! c N A c - ( ! - 4 1 - A s n o-Man-(l-O) -a-Man-(l-G)/ a-MznAWr
F i g . 4 . - I n t e r a c t i o n of i n s o l u b i l i zed l e c t i n s N-glycosylamine l i n k a g e .
RCA, RCA,, G S A „ W G A
UEA,
LTA
FNR
FNR
FNR
FR"
FNR
FNR
FNR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FE
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FE
FNR
FNR
Con A
LCA
VFA
PSA
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FNR
FR
FNR
FNR
FNR
FNR
FR
FNR
FNR
FNR
-
FR +
FE 0.3M «< MG
FNR
FE lOmM VMG
with glycans
from g l y c o p r o t e i n s w i t h
the
348
glycopeptides such as those found in hen ovalbumin
(Structure
39). Structure 16 which possesses also a g-N-acetylglucosamine residue linked to C-4 of the g-linked mannose residue but belongs to the N-acetyllactosaminic type family, presents a weaker affinity for WGA, and structure 18 which just differs from structure 16 by the presence of an a-L-fucose residue in C-6 position on the N-acetylglucosamine residue involved in the N-glycosylamine bond is no more recognized by insolubilized WGA. The lectin does not present any affinity for oligomannosidic-type glycopeptides
(Structure 37). As found also by
Yamamoto it at. (13), the N-N'-diacetylchitobiose moiety has to be intact, for, oligosaccharide 21 which possesses the 8 - Nacetylglucosamine residue in C-4 position on the B-mannose residue, but where the g-GlcNAc-(l -*• )-Asn sequence is lacking is not retained on WGA-Sepharose. It can also be noted that sialylated glycopeptides oligosaccharides
(Structures 1, 29, 30) or sialylated
(Structure 2) are not recognized by insolubi-
lized WGA. These interactions involve a charge effect and depend on a mechanism called by Monsigny it at. (14) "avidity effect"
: only glycopeptides with a high density of terminal
non-reducing N-acetylglucosamine or N-acetylneuraminic acid residues interact with WGA.
GA^^on^a
iLmptLc-iloila.
agglutinin.-
This
insolubilized
lectin represents a very useful tool for the fractionation of glycopeptides or oligosaccharides with unmasked N-acetylglucosamine residues in a terminal non-reducing position and the affinity of the lectin increases with the number of such residues : glycopeptide 19 is more retarded on the column than glycopeptide 33. But, at least two of such N-acetylglucosamine residues are necessary for the interaction to take place, for glycopeptides 15, 16, 17, 18 or 39 with only one unmasked Nacetylglucosamine residue are not retained on the column. In the case of structures with two terminal non-reducing N-acetylglucosamine, GSAjj presents a greater affinity for the glycopeptide than for the related oligosaccharide
(Glycopeptide 19
349
compared to o l i g o s a c c h a r i d e 20 or 2 1 ) . This can a l s o be e x p l a i ned by the f a c t t h a t the g l y c a n - a m i n o a c i d l i n k a g e l e a d s t o s t r u c t u r e s more r i g i d than those of the o l i g o s a c c h a r i d e s . Le.ct£m
w^th
a ipzailtcity
{¡oh. L-^uco,se.-
Lotui
te.£fiagonolobu.i
a g g l u t i n i n or U£ex euAopzui a g g l u t i n i n I have no a f f i n i t y f o r g l y c o p e p t i d e s or o l i g o s a c c h a r i d e s of the N - a c e t y l l a c t o s a m i n i c t y p e , even i f t h e s e s t r u c t u r e s p o s s e s s one or two f u c o s e r e s i dues c t - ( l •*• 3) or a - ( l 6 ) - l i n k e d to N - a c e t y l g l u c o s a m i n e r e s i dues as i n g l y c o p e p t i d e 5 o r 6. As p r e v i o u s l y d e s c r i b e d by P e r e i r a t£ a.1. (15) , the s p e c i f i c i t y of t h e s e two l e c t i n s seems to be d i r e c t l y towards the a - ( l -*• 2 ) - l i n k e d fucose r e s i d u e s found i n blood-group H a c t i v e substances.
Conclusions This work completes and e x t e n d s our p r e v i o u s r e s u l t s o b t a i n e d by i n h i b i t i o n of the a g g l u t i n a t i o n of human-red blood c e l l s induced by l e c t i n s ( 7 ) . These r e s u l t s c o n f i r m t h a t l e c t i n s , c o n s i d e r e d " i d e n t i c a l " i n terms of monosaccharide s p e c i f i c i t y , p o s s e s s the a b i l i t y to r e c o g n i z e f i n e d i f f e r e n c e s i n more comp l e x s t r u c t u r e s and t h i s can be used to f r a c t i o n a t e m i x t u r e s of N - g l y c o p e p t i d e s of v a r i o u s o r i g i n s .
Acknowledgements This work was supported i n p a r t by the Centre N a t i o n a l de l a Recherche S c i e n t i f i q u e ( L a b o r a t o i r e Associé n° 217) and by the D é l é g a t i o n Générale à l a Recherche S c i e n t i f i q u e e t Technique (Grant 7 9 - 7 - 0 6 6 9 ) . We thank Drs G. S t r e c k e r , B. Fournet and A. Kobata f o r t h e i r generous g i f t s of o l i g o s a c c h a r i d e s and glycopeptides.
350 References
1.
Lotan, R., Nicolson, 329-376 ( 1979) .
2.
F i n n e , J . , K r u s i u s , T . , J ä r n e f e l t , J . : 27th I n t e r n a t i o n a l C o n g r e s s o f P u r e and A p p l i e d C h e m i s t r y ( e d . A . V a r m a v u o r i ) Pergamon P r e s s , O x f o r d - N e w Y o r k , p p . 1 4 7 - 1 5 9 , 1980.
3.
D a l l ' O l i o , F . , S e r a f i n i - C e s s i , F., Scannavini, C a m p a d e l l i - F i u m e , G. : T h e s e p r o c e e d i n g s .
4.
O g a t a , S . , Muramatsu, 687-696 ( 1 9 7 5 ) .
5.
Krusius, T . , Finne, 117-120 ( 1 9 7 6 ) .
6.
Debray, H . , M o n t r e u i l , J. : 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 , C l i n i c a l B i o c h e m i s t r y , V o l . 1, p p . 2 2 1 - 2 3 0 , W a l t e r de G r u y t e r , B e r l i n - N e w York ( 1 9 8 1 ) .
7.
Debray, H., Decout, D., S t r e c k e r , G., Spik, J . : E u r . J . B i o c h e m . 117, 41-55 ( 1 9 8 1 ) .
8.
Montreuil, J. (1980) .
9.
March, S . C . , P a r i k h , 60_, 149-152 ( 1974) .
10.
Strecker, ( 1979) .
11.
Koide, N., (1974) .
12.
K o r n f e l d , K . , Reitman, M . L . , 256 , 6633-6640 ( 1981) .
13.
Yamamoto, K . , T s u j i , T . , M a t s u m o t o , B i o c h e m i s t r y 2Q_, 5894-5899 ( 1 9 8 1 ) .
14.
Monsigny, Delmotte,
15.
P e r e i r a , M.E.A., K i s a i l u s , E . C . , Gruezo, F . , Kabat, A r c h . B i o c h e m . B i o p h y s . 185 , 108-115 (1978 ) .
G.,
: Adv.
G.L.
T.,
J.,
: Biochim.
Kobata,
Rauvala,
Carbohyd. I.,
Montreuil,
Muramatsu,
T.
Biophys.
A. H.
: J.
M., 78,
: FEBS-Letters
71,
G.,
Montreuil,
Chem. B i o c h e m . _37» P.
: Biochimie
: J.
Biol.
: Anal. 6J_,
Chem.
Kornfeld,
M., Roche, A . C . , Sene, C . , F . : E u r . J . B i o c h e m . 104,
559,
Biochem.
Cuatrecasas, J.
Acta
I.,
R.
157-223 Biochem.
1199-1246
249,
4897-4904
: J.
Biol.
Osawa,
T.
Chem.
:
Maget-Dana, R . , 147-153 ( 1 9 8 0 ) . E.A.
:
HERPESVIRUS GLYCOPROTEINS FROM WILD-TYPE AND
RICIN-RESISTANT
BHK CELLS. CHARACTERIZATION OF GLYCOPEPTIDES BY CON A-SEPHAROSE
F. Dall'Olio, F. Serafini-Cessi Istituto di Patologia Generale, Università di Bologna, Italy
M. Scannavini and G. Campade11i-Fiurne Istituto di Microbiologia e Virologia, Bologna, Italy
Herpes simplex virus-1
(HSV-1) specifies the synthesis of seve-
ral antigenically distinct classes of glycoproteins
(1, 2),
which mainly contain N-linked glycans. In the infected cells both the mature forms gB, gC, gD and gE, and their partially glycosylated precursors (gA-pgB, pgC, pgD and pgE) accumulate. Sialylated complex-type glycans are present in the mature forms whereas mannose-rich glycans predominate in the precursors
(3)
In a preceding paper (4) we reported that the synthesis of HSV-1 glycoproteins is altered in a mutant cell line (Ric 14) defective in the N-acetylglucosaminyltransferase
(5), which is
required for the processing of mannose-rich to complex-type glycans. Mature forms of HSV-1 glycoproteins were absent in Ric 14 cells whereas underglycosylated proteins accumulated. In the present study the detailed structure of glycans synthesized in HSV-l-infected Ric 14 and parent BHK cells were examined using a combined technique of ion-exchange and Con A-Sepharose binding.
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Voi. Ili
chromatography
352 Materials and Methods
Radiolabeling of infected cells. R 2 Ric 14 (5) and BHK cells in 25 cm Falcon flasks were
infected
with HSV-l(MP) at an imput multiplicity of 10 PFU/cell. The cells were labeled between 5 and 18 h after infection with minimum essential medium containing one-half the usual concentration of glucose, 1% foetal calf serum and 4 jiC/ml of 14
C-glucosamine.
Polyacrylamide gel electrophoresis of HSV glycoproteins. Cells in Tris/HCl, pH 7, were solubilised with
2% SDS and 5%
[} -mercaptoethanol , and heat denatured for 2 min.
Samples were
run in a slab gel containing 8.5% acrylamide and analyzed autoradiography of the dried slab
by
(3).
Digestion of glycoproteins with endo-|3-N-acetylglucosaminidase H. Portions of sonicated cells were dialyzed against 0.1 M citrate buffer, pH 5.5. 300 Ail aliquots of the suspensions
(protein
concentration 1.5 mg/ml) were incubated at 37° C with 0.025 U of endo-j3-N-acetylglucosaminidase H (Seikagaku Kogio Co., Tokio). At the indicated times 50 Ail aliquots were withdrawn and proteins precipitated with 50 Ail of 12.5% TCA. The release of acid-soluble labeled glycans was measured on 50 Ail of the supernatant. Separation and analysis of glycopeptides. Infected labeled cells were harvested in 0.1 M phosphate buffer, pH 7.9, and digested with pronase (3). Pronase-digests were
chromatographed on 1 x 7 5 cm column of Bio-Gel P-10. The
fractions corresponding to elution position of acidic and neutral glycopeptide
markers (from 4800 to 1500 daltons) were
pooled. A portion Sephacel
column
(2 m l ) of this pool was loaded on a DEAE-
(1x15
c m ) equilibrated w i t h 0.05 M
acid. A f t e r a w a s h i n g w i t h H^O
acetic
(10 ml), a salt g r a d i e n t
(50 ml
0.05 M acetic a c i d — • 50 ml 0.05 M acetic acid and 0.5 M N a C l ) w a s applied to the column. Fractions of 1 ml w e r e and the r a d i o a c t i v i t y
of 0.1 ml w a s m e a s u r e d . The central
tions of each peak w e r e pooled. One p o r t i o n for n e u r a m i n i d a s e another portion -Sepharose.
treatment as previously
(1 m l ) w a s
described
(2 m l ) for affinity c h r o m a t o g r a p h y
The column
( 0 . 5 x 1 0 cm) was .washed w i t h
pH 7.4, c o n t a i n i n g 0.1 M NaCl and 0.02% MnCl^;
collected
it w a s subsequently
and then w i t h 200 mM
eluted with
a-methyl-mannoside
NaN 5 mM
frac-
used
(3) and on Con ATris/HCl,
, CaCl2, MgCl2
and
a-methyl-mannoside
in the same
buffer.
Results Glycoprotein Fig.
analysis.
1 shows the p a t t e r n of e l e c t r o p h o r e t i c a l l y
coproteins synthesized
in H S V - 1 ( M P ) - i n f e c t e d
Fig. 1. S D S - P A G E of g l y c o p r o teins from H S V - 1 ( M P ) - i n f e c t e d R Ric l ^ a n d BHK cells labeled with C-glucosamine
Ric
separated R
14 and
gly-
BHK
Fig. 2. A c i d - s o l u b l e glycans released by endo-|9-N-acetylg l u c o s a m i n i d a s e H from infected-Ric 14 (O), and BHK (•)
354 cells. Tn the mutant cells only the partially glycosylated precursors (pgD, pgB and gA) accumulated, whereas the fully glycosylated forms (gB and gD) were absent. Since previous observations (3) indicate that precursors of HSV-glycoproteins, namely gA and pgD contain glycans of the mannosyl-rich type, they should be sensitive to endo-^-N-acetylglucosaminidase H. This enzyme cleaves between the two N-acetylglucosamine
residues
in high-mannose glycans (four to nine residues) (6). Fig. 2 shows the results of a typical digestion experiment of 14 R C-glucosamine-labeled HSV glycoproteins from BHK and Ric 14 cells. The amount of acid-soluble glycans released by the enzyme from glycoproteins of mutant cells was significantly
high-
er than that from wild-type cells. This result confirms that mannosyl-rich glycans predominate in precursors glycoproteins of mutant cells and suggests that glycan processing is arrested before the action of N-acetylglucosaminyltransferase Glycopeptide
characterization.
Both neutral
(N) and acidic
(A) pronase-glycopeptides
by preparative Bio-Gel filtration
T.
obtained
(free from undigested mate-
rial and low molecular weight molecules) were analyzed on DEAESephacel
(Fig. 3). Five peaks N, ATa, Alb, ATT and AITI were
separated. N was not absorbed by the column and emerged with the neutral mannosyl-rich glycopeptide marker. The most acidic glycopeptide AIII was eluted together with a triantennary marker (fetuin glycopeptide) and ATI with a diantennary
glycopeptide
(prepared from human transferrin). In the elution position of slightly acidic glycopeptides two distinct peaks were obtained, ATa and Alb. Tn the BHK sample all peaks were present and AITI was the most represented. In the Ric 14 sample N represented the major peak; among the acidic glycopeptides only Ala and
355
t ract i o n n u m b e r
Fig. DEAE-Sephacel chromatography of pronase-glycopeptides from C-glucosamine-labeled HSV-infected BHK (•) and Ric 14 (o) cells. The arrows represent, from left to right, the elution positions of ovalbumin-, human transferrin- and fetuinglycopeptide. The horizontal bars indicate the fractions of each peak which were pooled and chromatographed on Con A-Sepharose. All! were present but the latter was small in amount. After neuraminidase treatment the acidic glycopeptides were all split in two peaks when rechromatographed on DEAE-Sephacel: one emerged as desialylated
glycopeptide
(unretained) and the other
one emerged as free sialic acid. This shows that the negative charge responsible for absorption to the DEAE column was due to sialic acid. The amount of radioactivity cleaved by neuraminidase as sialic acid from ATTI, ATI, Alb and Ala was 40%, 25%, 13% and 10%, respectively. These results reinforce the indication that the structures of AIIT, ATT and A1
(a and b) are, re-
spectively, those of triantennary, biantennary and monoantennary glycans. Since the processing of mannosyl-rich
to complex-
type glycans changes the affinity of glycopeptides to ConA
(7),
356 Table. Comparison of glycopeptides from HSV-1(MP)-infected BHK and Ric 14 cells separated with DEAE-Sephacel chromatography.
Glycopeptide
%
14
C-glucosamine incorporated
BHK
NANAase suscept ibi1i ty
Ric 14
Elut i on from Con ASepharose by Me-Man (mM)
16
51
-
200
Ala
5
20
+
200
Alb
18
All
20
AITT
40
N
Proposed structure
O JD-e-e
« - • - • - a
unbound
•N-Acetylglucosamine, A s ialic ac id.
OMannose,
• Galactose,
the five glycopeptides were further characterized by Con Aaffinity chromatography using two different concentrations of a-methyl-D-mannoside
(Me-Man) as specific eluent. N, Ala, Alb
and AIT were all retained by Con A-Sepharose; N, and Ala were eluted by 200 mM Me-Man, whereas ATb and ATI were eluted at the lower concentration
(5 mM Me-Man); AITI from both kinds of
cells was not retained by the column. The table summarizes the experimental data and shows the relative distribution of the glycopeptides
in each cell type. On the basis of the results
a putative structure of the glycopeptides is proposed.
357 Discussion
The combined technique of ion-exchange separation and Con A-affinity chromatography was a good approach for the structural analysis of pronase-glycopeptides from HSV-infected cells. Neu raminidase treatment and DEAE-Sephacel chromatography
provided
informations on the number of sialic acid residues which accounts for the antennary structure of complex-type glycans, while the binding to Con A-Sepharose correlated with processing of the oligomannosyl core. It was shown that in N-linked glycans the presence of the oligomannosyl moiety at the nonreducing terminal position results in a strong binding to Con A and that any addition of sugars to the mannosyl core causes a progressive decrease in the association constants of the binding between glycopeptide and lectin The results reported here indicated that
(7). (i) AITI was not bound
by Con A-gel as expected for triantennary glycans (8, 9);
(ii)
diantennary All was retained by Con A-Sepharose and was eluted with a low concentration of a-methyl-mannoside;
(iii) Alb was
eluted by Con A-Sepharose like a diantennary glycans; after neuraminidase treatment the amount of label emerging by DEAESephacel in the elution position of sialic acid was half of that released with the same treatment from All. All together these results suggest that Alb has a diantennary structure in which only one branch carries the terminal sialic acid;
(iv)
Ala was strongly retained by Con A column like neutral mannosyl rich glycans (N), suggesting that it still retains the mannosyl cluster which is usually trimmed during the assembly of complex-type oligosaccharides. On the other hand its behaviour on DEAE-Sephacel indicated the presence of terminal sialic
358 acid,
in that b e f o r e n e u r a m i n i d a s e d i g e s t i o n
acidic s t r u c t u r e
it b e h a v e d
(bound to the DEAE c o l u m n ) but a f t e r
the single radiolabeled peak w a s split m a j o r one w a s neutral
digestion
in two f r a c t i o n s ,
(unbound to the D E A E ) w h e r e a s
the
one coeluted with u n l a b e l e d sialic acid. W h e n Ala was to high resolution gel filtration p o s i t i o n of the g l y c o p e p t i d e s m a n n o s y l - r i c h glycans results).
it emerged
remarkably
in the
the other
subjected
elution
larger than
(five m a n n o s e r e s i d u e s )
For these reasons we suggest
oligo-
(unpublished
that Ala has a h y b r i d -
- t y p e structure similar to that present glycoproteins.
as
in Rous sarcoma
Hunt and W r i g h t ( l O ) showed
in this virus
virus the
presence of a h y b r i d - t y p e glycan w i t h an o l i g o m a n n o s y l
core
(Man GlcNAc - A S N ) c h a r a t e r i s t i c 5 2
plus
"branch" sugars acidic
of neutral
structures,
(NeuNAc-Gal-GlcNAc) c h a r a t e r i s t i c
of
complex
structures. R
The reduction of c o m p l e x - t y p e g l y c a n s sistent with
the g l y c o s y l t r a n s f e r a s e
in Ric 14 cells deficiencies
of
these
mutant cells and shows the relevance of p o l y b r a n c h e d to the b i n d i n g of ricin by the cell This
is con-
glycans
surface.
investigation was supported by g r a n t s from C o n s i g l i o
zionale delle Ricerche and M i n i s t e r o della Pubblica
Na-
Istruzione.
References
1. Spear, P. G.: J. Virol.
17_, 991-1008
(1976);
2. Baucke, R. B., Spear, P. G.: J. Virol.
32,
779-789
( 1979);
3. S e r a f i n i - C e s s i , F., C a m p a d e l l i - F i u m e , G.: Arch. Virol. 331-343 (1981); 4. C a m p a d e l 1 i - F iume, G., Poletti, L., D a l l ' O l i o , F., - C e s s i , F.: J. V i r o l . 43, (1982) (in press);
70,
Serafini
359 5. V i s c h e r ,
P.,
Hughes,
R.
C.:
Eur.
J.
Biochem.
117,
275-284
(1981) ; 6.
Tarentino, (1974) ;
A.
L.,
Maley,
F.:
J.
Biol.
Chem.
249,
811-816
7.
Baezinger, ( 1979 ) ;
J.
U.,
Fiete,
D.:
J.
Biol.
Chem.
254,
2400-2407
8.
Krusius, T., Finne, 120 (1976) ;
9.
Debray,
10.
Hunt,
L.
H., A.,
J.,
Montreuil, Wright,
S.
Rauvala,
J.: E.:
H.:
Biochimie, J.
Virol.
FEBS
Lett.
7_1_,
117-
60_, 6 9 7 - 7 0 4
( 1978);
39,
(1981).
646-650
C O N - A - R E A C T I V ITY ELECTROPHORETIC CROSSED
Mette
OF
LEUCOCYTE
aj-ANT ITRYPSIN.
a^-ANTITRYPSINS
STUDIED
BY
IMMUNOELECTROPHORESIS.
Andersen,
The Finsen Denmark.
AND
HETEROGENEOUS
AFFINITY
M.
SERUM
Susanne
Laboratory,
The
Noack Finsen
Institute,
Copenhagen,
Introduction
In a p r e v i o u s contain tor). cell
study
(1)
a^-antitrypsin
We
also
line,
6 0 ctjAT's
showed
HL-60 have
we
(2)
similar
sis
of
by
sis
(B0g-Hansen
about dy
the
more
closely
to
compare
was
undertaken.
in o r d e r
to
Materials
from
We
compare
Concanavalin
was
the
A
does
affinity give
involved
molecular
variants defined
also
more
studied
this
with
a^AT
and
HL-
in c r o s s e d
Im-
(2).
precise (2).
present
serum
leukemic
Analy-
Immunoelectrophore-
ctjAT's from
normal
inhibi-
Leucocyte
heterogeneous
not
leucocytes
promyelocyte
morphologies
very
with
(conA)
Sigma,
Difco
(6))
human
a^-protease
information
In o r d e r in t h e s e
the
to
stu-
a^AT's
present
study
ajAT-deficient
sera
a,AT.
Methods
Chemicals, from
human
traditional
al.
them
and
being
subpopu 1 ations
various
and
Fine
et
the
that
called
a j - a n t i t r y p s in.
precipitate
both
oijAT's
(also
that
synthesizes
munoelectrophoresis these
demonstrated
(aj A T )
Lab.,
(Batch
no
Sweden;
Porcine
U.S.A.,
and
Detroit,
GL
23289)
pancreatic
Trypsin
U.S.A.
© Walter d e Gruyter & Co. 1983, Berlin • N e w York Lectins, Vol. Ill
1:250,
Five
was
from
elastase "Difco"
normal
human
Pharmacia (type
III)
certified sera
were
362 obtained viduals
from with
a normal
volunteers genotype
serum
trophoresis
adjusted
(both
1 mg/ml)
thereafter.
DAKOPATTS, Cells: HL-60 of
Human
by
1):
gel
without
to
The
der
minimize
and
were
on
the
width
of
placed
Prealbumin,
at
used the
as
out
in
and
the
conA
gel.
by
normal
containing
Both
in
centration out.
All
dation 5
elec-
Sepharose.
trypsin °C,
or
and
This
elastase
run
immediate-
were
1640
as
described
with
10%
respectively
al.
This (6)
was
or
as
(1)
and
from
a first
in
of out
for
of
the
the
internal
edge
the
dimension
second
the
was
antigen
con-
and
in
The
gel
added
cast.
into
a
well
gel
was
electrophoresis
sec-
plate
was
containing
or-
gel
secondary
electrophoresis
dimension
gel
5 mm
antigen.
of
elec-
Immunoelectrophowas
conA-containing
standard,
between
used
applied
cathodic
space
affinity
mostly
cut
as
a
dimension
sections
plates
(2).
procedure
were
sections
pg/ml
either
a two-step
electrophorized
(i.e.
and
50
described
performed
as
were
FCS
respective
gel
as
(R
and
was
conA-reactivity
included
prepare
slice
performed
into
anti-
gel.
the
Technical
Biue
antigen(s)
First
coefficient
% was
gels.
to
indi-
agarose
The
traditional in
used
by
separated
the
border
body
the
et
width
remaining
from
anti-prea1 bumin
obtained
RPMI
antigen(s)
gel
the
cut
followed
were in
secondary
resis.
on
with
sera
Denmark.
conA).
of
were
i h 37
and
electrophoresis
fractions
transferred
tions
ratios
streptomycin
the
sera
purified
mixed
anti-a^AT
leucocytes
Firstly
trophoresis
to
was
volume
B0g-Hansen
agarose
taining
1:1
and
was
immunoe1ectrophoresis.
described (Fig.
in
Rabbit
normal
ajAT
chromatography
1 mg/ml,
propagated
penicillin
free
by
8 otj A T - d e f i c i e n t
The
to
Copenhagen,
cells,
Affinity
ZZ. Serum
followed
ctjAT,
ly
pool.
and
the
two-step
standardized fractions
= Lo/Lr-1)
specific
details
at
were
(7).
as
140
the ?
ug/cm
defined
by
conA
in
in
all
(6).
con-
throughtheir
retar-
a-methy1-D-mannoside
displacer
otherwise
technique
second
(MM)
dimension
363
—
1. dimension
-j-
—
F i g . 1: Two-step crossed a f f i n i t y Immunoelectrophoresis (schematic drawing), a the controlplate, i l l u s t r a t i n g the p o s i t i o n of the heterogeneous molecul a r variants of a protein after electrophoretic separation (A, B, C and D) and the p r e c i p i t a t e pattern of these molecular variants after second dimension e l e c t r o p h o r e s i s . b> the f i r s t step of t h i s technique with electrophor e t i c separation of multiple protein samples in p a r a l l e l (controls are run next to t e s t samples). £ the second step, in which a molecular variant (A) has been transferred to a secondary plate where f i r s t and second dimension electrophoresis has been performed. Results i-
g^AT f r o m normal
mal
serum was a p p l i e d
ly
or d i l u t e d
trophoresis, tions, these
fig.
(R(Sj) 3 pi, tion
30 pi
2 a.
= 0.62
low a m o u n t s ,
(1:100)
either
however directly
same i n
R ( S 2 ) = 1 .48 + / - 0 . 0 4 ,
or d i l u t e d
30 pi
fraction
(R + / R(S3)
higher
(1:10),
frac-
S-)
normal
of
sera
= 2.39
amounts,
a fourth
was p r e c i p i t a t e d
e.g.
frac-
in the
first
if
specific
displacer
fraction
was not
defined
d e p e n d e d on t h e
length
the
it
relative
size
eluted
Immunoelec-
of t h i s
precipitate,
was n o t
in
direct-
The r e t a r d a t i o n
since
it
affinity
nor-
conA-reactive
individual
applied
If
u1,either
coefficients all
serum was
The f o u r t h since
in three
serum.
was not p r e s e n t . affinity
gel
eg 0 , 3
in t r a d i t i o n a l
The r e t a r d a t i o n were t h e
+/- 0.02,
If
appeared.
dimension
in
t h e otjAT was d i v i d e d
fractions
+/- 0.07).
serum and a ^ A T - d e f i c i e n t
which d i f f e r e d
and t h e
retardation
in of
of the g e n e r a l individual this
conA-
sera.
fraction
wellBoth
depended
364 on t h e t e c h n i c a l
details
The c o n A - r e a c t i v i t y lar
to t h a t
less
than
nient
in
of
relative
normal
values
these
producing
coefficients
sizes
experiments.
serum otjAT. S i n c e
3 ul-amounts
retardation
the
of oijAT f r o m a j A T - d e f i c i e n t
normal
10 % of
of
were t h e
the
sera
sera
was
simi-
concentration
was
were r u n most
4 fractions
(fig.
2 b).
of t h e
3 genuine
fractions
same as
i n normal
serum.
conveThe
and
their
F i g . 2: Crossed a f f i n i t y immunoelectrophoresis of 0,3 gl normal seKum (a) and 3 ul a,AT-deficient serum (b). Both plates contained 0,36 gl/cm a n t i a,AT plus in (a) 0,06 Ml/cm , and in (b) 0,14 pl/cm anti-prealbumin. A total of three f r a c t i o n s (S, to S O was seen in normal serum and four f r a c t i o n s (Sj to S 4 ) in a^AT-deficient serum (see t e x t ) . V!hen normal divided the
serum a^AT was r u n
into
three
serial
relative
sizes
of
varied front
within
gelslice
precipitate
leg)
leg)
where
intermediate tive
almost
gelslice
distribution
gelslices
(not
of
shown
o f 5 mm g e l
conA-fractions
it
relatively
gelslice
contained
ajAT
a^AT,
to
the The rela-
to the that
3). the
and
to
but t h e
demonstrated
S^)
(fig.
more a j A T ( S j )
intermediate
that
and
and S3 d o m i n a t e d .
more t o t a l This
being
seen
S2
(a^AT c o r r e s p o n d i n g
and S^ was
in f i g u r e ) .
was
(Sj,
a j AT c o r r e s p o n d i n g
no S^ was p r e s e n t
Sj,
technique
the e l e c t r o p h o r i z e d
(containing
contained
t h a n t h e most c a t h o d i c hind
sections
the three
systematically
The most a n o d i c
in the t w o - s t e p
S,
other has
365
the h i g h e s t the t h r e e Similar
and S3 the l o w e s t e l e c t r o p h o r e t i c
mobility
among
fractions.
results
were o b t a i n e d w i t h ctjAT from
cijAT-deficient
sera.
b
a
s W&
^
„
PA
2
3
mm
||B|
S
¿'sfiH'
|
fpffsif
2
$
PA
S 3 S i
3
3
. •
Fig. 3: Crossed a f f i n i t y Immunoelectrophoresis (the two-step technique) of serum a,AT. (a) and (b) i l l u s t r a t e the distribution of conA-reactive fractions (5,, Sp and S 3 ) in the anodic and cathodic fractions, respectively. In the f i r s t step 3 pi normal serum was applied. The second step was performed with 3 gelsections of 5 mm each. Antibody: 0,14 ul/cm anti-a,AT and 0,06 gl/cm anti-prealbumin. 2.
g^AT-elastase
and o ^ A T - t r y p s i n
acted w i t h e l a s t a s e
reaction
p r o d u c t s . a^AT
produced two p r e c i p i t a t e
Immunoelectrophoresis,
peaks
one w i t h s i m i l a r m o b i l i t y
bility
and one w i t h
Serial
sections
The oijAT h a v i n g m o b i l i t y
were as
follows:
to serum cx^AT had the
as serum oijAT.
to the c t j A T - e l a s t a s e or the two a j A T -
of s l o w e r m o b i l i t y
fined conA-reactivity.
had d i f f e r e n t
Only one ( o r two b a d l y The r e t a r d a t i o n
and l e s s
separated)
c o u l d be seen w i t h t h e s e otjAT's and t h e i r
were o f t e n d o u b l e c o n t o u r e d . 2,20.
(^-mo-
l e n g t h of the a j A T -
The r e s u l t s
corresponding
same t h r e e c o n A - r e a c t i v e f r a c t i o n s The oijAT c o r r e s p o n d i n g
from 1,19 to
produced
as serum a j A T , one w i t h
p r o t e a s e p a t t e r n s were p e r f o r m e d .
tion^)
a^M
^-mobility.
of 5 mm t h r o u g h the e n t i r e
trypsin fractions
crossed
as serum
and one w i t h (J-moti 1 i t y . a^AT r e a c t e d w i t h t r y p s i n t h r e e p e a k s , one w i t h m o b i l i t y
in
re-
de-
frac-
precipitates
coefficient
varied
366
a-, AT
/
PA B PA
B
1-6
Le LS
L
D
6 LS L
4
L4
—- L'-j
'0
E
1-2-1
l3 L7 (J" íy H
367
_3-
HL-60
grown In
cells.
in f e t a l
all
calf
samples
thesized
by t h e s e
wide
nity
with
strong
H L - 6 0 a ^ A T was
if
specific
affinity
precipitate
In t h e most
coefficient
a fraction
were p r e s e n t
with could
anodic
syn-
a^AT
one o r after
was p r e s e n t ,
a lower
conA-reactivity. due t o
conA. conA-affidespite dimen-
having
as w e l l
Whether
was
two
in the f i r s t
to
be d e t e r m i n e d
this
a fraction
similar not
Sj
lab.
be
was o m i t t e d
was f o r m e d
gelslices
to
towards
smaller
displacer
was
in our
it
of
reactivity
of
line
one y e a r proving
containing
area
dation of
sections
electrophoresis gel.
cell
The c o n A - r e a c t i v i t y
5 mm g e l
precipitates
no v i s i b l e sion
more t h a n
a^AT was p r e s e n t ,
cells.
all
The p r e c i p i t a t e
human p r o m y e l o c y t e
serum f o r
taken
heterogeneous, very
This
as
S2
the wide
retartraces
and
S3
precipita-
tes . 4.
Leucocytes.
could within
be d i s t i n g u i s h e d a single
fractions
reacting
(fig.
fractions
found
(R(Lj)
0,05),
to
with
= 0 +/-
fig.
conA-reactive
4).
Up t o
5 fractions
section
(fig.
4C).
= Sp
anodic
4 F-H).
three +/-
(L4
retardation
7 different
(fig.
cathodic
similarly
undefined pitate
in the
The m o s t
of
5 mm g e l
were f o u n d
were p r e s e n t A-C).
A total
part
part
that
L5
of
of
= S2
of
0,00,
Lg
very
= S3)
pattern
R(L2)
the
and
(fig.
with
0,01,
4 a^AT
rather
contoured
leucocyte
+/-
they
contained
preci-
a^AT
low c o n A - r e a c t i v i t y = 0,21
present
serum-a^AT
1eucocyte-ajAT
and a d o u b l e of
were
3
the a j A T - p r o t e a s e s ,
In the middle or
the
t h e a^AT
coefficient zero
and
All
fractions
pattern
were
R(L 3 )
=
0,45
4B-F.
F i g . 4: Crossed a f f i n i t y Immunoelectrophoresis (the two-step technique) of leucocyte otiAT. The upper p i c t u r e i l l u s t r a t e s the control plate (the 5 mm gel s e c t i o n s t r a n s f e r r e d from the corresponding experimental plate are marked A-H). Plates A-H i l l u s t r a t e the various conA-reactive f r a c t i o n s within each gel s l i c e . Antigen: 3x10 leucocytes. Antibody: control plate 0,43 Ml/cm and A-H 0,14 pl/cm a n t i - a , A T . A l l plates 0,06 pi anti-prealbumin. The prealbumin p r e c i p i t a t e (PA) i l l u s t r a t e d on plate A but has been cut o f f from plates B-H.
368 Discussion
Serum lar
ajAT
was
variants
recently reover
been
fraction
S2
content
of
decreased The high
of
of
the
both
Bayard
et
that
uniformity fraction
acid
Sj
this
had
glycans
S3
could of
fraction most
since the
(S^)
probably
it
varied
general
serum
appearing
when
represent
in
a^AT
individual
within
each
with
chains.
due
to
since
higher sialic
mobility
and
conA-affinity seen
was
according
precipitate.
with
the
applied
in
unspecificica11y
sera
probably
because
the
major
glycoproteins
affinity
precipitate
(e.g.
o^-macrog1obu1in)
to
A fourth
two-step
fracti-
technique,
producing are
en-
the
the
conA-
excluded
by
procedure. presence
rously
of
tion
such
conclusions
otj A T - d e f i c i e n t (fig.
al.(10)
2a,
found
centration explained
sera
the
they
non-reactive
moreover
conA-reactivity the
to
the
as
the
found to
The
unchanged
the
their
same of
was
due
if
In
basis
ever,
same
in
whether
latter
ours,
a
conA.
pattern
small This of
elastase
of
free
a,AT
are of
the of
run
in
could
a^AT
after
trypsin
compared despite
to
their
fraction (1
(0,93
% of
concentra-
conA can
et
conbe
pi). the
Howtotal
reproduce.
reaction was
erwith
Hinnerfeldt
applied
not
to
serum
higher
aj AT
fourth
fraction
lead
normal
Since
serum
we
or
could
of
serum
fractions.
amount
conA-reactivity
surplus
entrapment
comparison
study
4 conA-reactive
was on
unspecific
eg.
b).
otjAT)
had
mo-
electrophoretic be
serum
never
be
workers
biantennary
a^AT,
was
The
very
triantennary,
electrophoretic
a^AT
this
molecu-
have
carbohydrate higher
This
fraction
increased
These
having
fraction
fractions. on
of Sj
distinct results
(5).
residue
fraction
provide
al.
for
and
three
Similar
found
biantennary
other
into
methods.
con A - r e a c t i v i t y .
amounts
size on
by
They
showed
sialic
fourth
trapped,
divided
N-acetylglucosamine
than
would
be
evidence
having
results
mobility
to
present
obtained
variant.
intercalated
acid
the
provided
molecular
Our
found
by
used.
serum
with
protease
Some
otjAT
a^AT.
theoretical
This
higher
could molar
369 ratios vity
of e n z y m e s .
compared
acted
with
to
the
this
Baumstark
mine
and
with
elastase.
peptide
of
dues
cleares
aj AT c o u l d sidues,
and
probably
from a^AT.
way
have
to t h e s e
This
could
thetic
products
strong to
reactivity
lack
of
Leucocyte Three was
a^AT
fractions
similar
ning
three
could
be
break
down
Thirdly (2)
sialic
of m o s t
products
from
similar with with
and o t h e r s steps
(11,
that and
4000 from
aj AT
(37
resi-
of e i t h e r
effect
enzyme
with
on c a r b o h y d r a t e
do
or c o n t i n u o u s
on t h e
re-
that to
serum a^AT or
with
very
to
devoid
HL-60
conA
syn-
synthesis could
and o n e
protease.
low
of
The be
due
fraction The
components
of c a r b o h y d r a t e a^AT,
studied. remai-
conA-reactivity
leucocyte
synthesize
of
in s e r u m a ^ A T .
of t h e o t h e r a j A T ' s
reacted
zero
steps
conA-
glycans.
12), t h i s aj AT c o u l d
compared
heterogeneous
multiple
present
specific
of a ^ A T
leucocytes
a
a jAT
of t h i s aj AT w i t h
to t h a t of a ^ A T
if
than
residues
differed
fractions
different
cleave
(3) f o u n d
exhibited
present
types
were
at
may from
be d u e to e i t h e r
acid
in c o m p l e x
synthetic
indirect
reacts
et a l .
interaction
cells
being
glycan
about
interaction
peptides.
reactivity. a^AT
MW
The
with
peptide
a 4000-5000
of
(7)).
inter-
N-acetylglucosa-
enzymes
Banda
conA-reactienzymes
In a g r e e m e n t
after
both
by H L - 6 0
with more
of 8
(8))
otjAT s y n t h e s i z e d
a^AT
loss
most
Gann
both
of a j A T .
elastase
a peptide
in t h i s
linked
net
changed
that
per m o l e o^AT
removed
et a l .
had
and
size
elastase
(Carell
residues
(4) f o u n d
(Feste
a^AT
indicating
residues
similar
macrophage trypsin
et a l .
trypsin
of a j A T
remaining
carbohydrate
10 h e x o s e
Although sites
The
serum a^AT
as be
be
residues.
suggested stored
or
at
by
us
different
o^AT.
C o n e 1us ion. aj AT f r o m a ^ A T - d e f i c i e n t reactive
fractions
as
normal
sera
contained
s e r u m ot,AT
(S,,
the S~
same and
three S,).
conA-
370 2.
Seven
individual
stinguished
in h u m a n
vity.
of t h e
a^AT One
Three
in s e r u m variant
3_. with
or v e r y The a j A T conA.
no d e f i n i t e
similar
of a j A T
basis
of t h e i r
similar
by t h e i r
molecular
could
to t h e
variants
di-
conA-reacti-
variants
retardation with
be
of
coefficients.
trypsin
or
elasta-
in l e u c o c y t e s
had
conA-reactivity.
synthesized
One
on
were
to otjAT r e a c t e d
remaining low
variants
leucocytes
variants
as d e t e r m i n e d
was
se. T h e t h r e e zero
molecular
variant
by
was
retardation
HL-60 similar
reacted
cells to
coefficients
heterogeneously
Sj , b u t f o r could
be
the
remaining
given.
Acknowledgements This cil
study
was
supported
(grant
no.
12-1054).
by t h e
Danish
Medical
Research
Coun-
References 1.
Andersen,
M.M.
Scand.
2.
Andersen,
M.M.
(submitted
3.
Banda, M.J., Clark, 1563-1570 (1980).
4.
B a u m s t a r k , J.S., Babin, D.R., Lee, C.T., Allen, B i o c h i m . B i o p h y s . A c t a 62J3, 2 9 3 - 3 o 2 ( 1 9 8 0 ) .
R.C.
5.
B a y a r d , B., K e r c k a e r t , J . - P . , L a i n e , J. B i o c h e m . J_24, 371 - 3 7 6 ( 1 982 ).
A.
6.
B0g-Hansen, T.C., nol . 4, suppl . 2,
7.
B 0 g - H a n s e n , T . C . , P r a h l , P., L 0 w e n s t e i n , M e t h o d s 22!, 2 9 3 - 3 0 7 ( 1 978 ) .
8.
C a r r e 11 , R . W . , B o s w e l l , D . R . , G r e n n a n , S . O . , O w e n , B i o c h e m . B i o p h y s . R e s . C o m m . _93, 4 0 2 - 3 9 9 ( 1 9 8 0 ) .
9.
F e s t e , A., (1981).
10.
Hi n n e r f e l d t , F., A l b r e c s e n , J . M . , B 0 g - H a n s e n , T . C . Elect r o p h o r e s i s '82, e d . S t a t a c h o s , W. de G r u y t e r , B e r l i n , (in p r e s s ) .
11.
I k u t a , T., O k u b o , Biochem. Biophys.
12.
Wilson, G.B., Walker, Proc. Soc. Exp. Biol.
Gann,
J.
E.J.,
I m m u n o l . _1_5, 3 9 9 - 4 0 7 to
Scand.
Werb,
Z.
J. c l i n . J.
A.,
Bjerrum, 0., Ramlau, 141 - 1 4 7 ( 1 975 ) .
J.C.
J.
Biol.
Chem.
Exp.
( 1 982 ). lab.
Med.
Hayem,
J.
Invest.). 152,
Scand. H.
256,
J.
Eur. J.
Immu-
Immunol. M.C.
6374-6380
H., K u d o , J . , I s h i b a s h i , H., I n o u e , R e s . C o m m . _1_04, 1 5 0 9 - 1 5 1 6 ( 1 982 ). J.H., Watkins, J.H., Wolbroch, M e d . 164, 1 0 5 - 1 1 4 ( 1 9 8 0 ) .
T. D.
SEMINAL ACID PHOSPHATASE. Purification by lectin affinity chromatography.
Mineo Iwasa and Kaoru Sagisaka Department of Legal Medicine Gifu University School of Medicine, Gifu, 500 Japan
Acid phosphatase (AcP,E.C.3.1.3.2.)from human prostate gland has been known to be a phosphaoric monoester hydrolase (5) which is used for identification of seminal stains in forensic practice (3). AcP is widely distributed in animals,plants and microorganisms (7,10). As for human body, AcPs from prostate and seminal plasma have the same specificity of substrate but a few differences in the pattern of polyacrylamide electrophoresis were pointed out (6). On the reactivity with lectins, human urinary AcP was demonstrated to have different activity to Con A from serum AcP (4). On the other hand, some plant AcPs identified as glycoproteins were inhibited or activated by Con A ( 8,9). From these results lectins have been used to isolate glycoproteins in affinity chromatography. In this paper, we report the reaction of AcP from seminal plasma with 5 different lectins and purification of AcP by affinity chromatography with CanavaJLLa. gladcata
DC lectin.
Materials and Methods Preparation of lectins. Ground seeds of PhainoluA coc.dine.Lii, L. , I/¿gna Ccutiang
Endl. varis Sinensis , Cytliai
icopcvU.uA Link. , WiAta/uA
bsia.chbo£>iyA Sieb et Zucc.and CanavaLLa. gladiaXa
© Walter de Gruyter & Co. 1983, Berlin • N e w York Lectins, Vol. Ill
DC
(Can G) were ex-
372 tracted with 10 volumes of saline at room temperature for 60 min. The suspensions were centrifuged and the supernatants were defatted with an equal volume of ethyl ether. Purification of Can G was performed by affinity chromatography (1). The defatted extract was precipitated with 60 % saturated (NH.JzSO., and precipitate was applied onto a Sephadex G-200 column (Fig.l). Elution was carried out stepwise with 1.0 M NaCl and 1.0 M NaCl containing 0.1 M a-methvl-D-mannoside as specific displacer. AcP activity of Can G was eluted as a single peak with maximum activity in tube number 55. Inhibition tests revealed that only the specifically displaced fraction had lectin activity and reacted with AcP of seminal plasma. The affinity purified lectin was coupled to agarose by the cyanogen bromide method (2). -0.7
Fig.l. Affinity chromatography of (NBU)2SO„ fraction of Can G lectin on Sephadex G-200. The dotted line is the activity of Can G AcP. The arrow indicates addition of a-methyl-D-mannoside. The fraction indicated with the black bar contained Can G lectin with agglutinin activity (the second peak).
¿0.6
c 3 0.5 o
I OA
e §0.3 «VI g 0.2 fl
A
o 0.1 in
n
Sieb et Zucc., 15 %). Of the five lectin extracts tested, only Can G
374 lectin reduced the activity of AcP. When the lectins of less than 5 mg/ml were added, AcP activity of seminal plasma changed scarcely. However, adding of the lectins of concentration of 10 mg/ml or more resulted in increasing or reducing of the AcP activity. Fig.2. Inhibition of AcP activity with various lectins. O O ,Phcu,zoZiH cocclne.uA L.; O-Q ,1/igna. Ccutiang Endl. varis Sinensis; •—W,Cytl&u6 ¿copa/UuS Link.; a—ft, Ultita/uA bnachbottyi Sieb et Zucc.;#—•,CcLna.vaLia. gladCata DC. 0 I 0
, 5
. 10
, , 15
20
Lectin ( m g / m l )
Fig.3. Crossed immunoelectrophoretic patterns of seminal plasma (a) and the supernatant of seminal plasma precipitated with Can G lectin (b). The gel plates were stained for AcP.
a \ b Crossed Immunoelectrophoresis was performed of the supernatants and the height of the AcP peak was remarkably reduced with Can G lectin(Fig.3). When gel plates were stained with Coomassie brilliant blue, about 15 precipitation peaks were observed and the peaks other than AcP were not affected by the lectins. Fractionation of seminal plasma. Three protein peaks were observed by gel filtration of seminal plasma on Sephadex G-200. The AcP assay revealed that some activity was eluted with the first peak and most of the activity with second peak. By addition of pure lectin to the active fractions, we found that the activity of both fractions was some what reduced (Fig.4). The rate of reduction was 3.6 % at 1.5 mg/ml of lectin added and
375
13.7 % at 2.0 mg/ml or more. 85
Fig.4. Inhibition of the two fractions possessing AcP activity separated by Sephadex G-200 gel filtration with purified Can G lectin. O—O »Fraction 1; Fraction 2.
0
0i5
1.0
1.5
20
25
Lectin (mg/ml) Isolation of AcP by affinity chromatography. By elution with a linear 0-0.1 M a-m.ethyl-D-mannoside gradient, the AcP fraction was recovered with the eluent at low concentration (Fig.5). The specific activity of AcP was elevated (54 fold) by this method. Rabbits immunized with AcP-coupled gels produced potent antibody to AcP. A week activity to one of the seminal proteins was absorbed with serum.
0.1
1.0
3 (A
O c c m E
ot I
0.05 « £ E 20 ^
05
S n
1 -p
•H
O
•H
MH •H
0 a) eu
W
-p to x: c tn •H •H -p (I) ü S a) rH M (0 Q) rH > 0 •H U •P A) (d H tí 0 1 S
-p c ai -p
tí
0
0
Ifl -p
-H C
0 XI 0 10 1
a) -p id SH TI >1 si 0 XI M Id u
a 0 •rl -P
W
X CU
tí
\
TI
•r| id
01
3-
id
.tí
•rl
a ai —. W rH I o CM Id W 2
•H
E
TN
id
-P
tí
>I •P
•H
0 A
O
CO •
•
10 R^ CN -p œ a: di o- a e •H -p -p TI td id : 387-398 (1979). 33. Sun, S.M., Mutschler, M.A., Bliss, F.A., Hall, T.C.: Plant Physiol. 61: 918-923 (1978). 34. Talbot, C.F., Etzler, M.E.: Biochemistry 17: 1474-1479 (1978). 35. Tully, R.E., Beevers, H.: Plant Physiol. 58: 710-716 (1976). 36. Van Dreissche, E., Smets, G., Dejaegere, R., Kanarek, L.: Planta 15J3: 287-296 (1981) . 37. Youle, R.J., Huang, A.H.C.: Plant Physiol. 5J3: 703-709 (1976).
A SPECTROPHOTOMETRY STUDY OF THE CARBOHYDRATE BINDING SITE OF PEANUT LECTIN
Jacqueline Ohanessian, Michel Caron Laboratories of Biomolecular Structural Chemistry and Immunochemistry UER Biomédicale, 74, rue Marcel Cachin, 93012 Bobigny Cedex, France.
Introduction There i s a need for rapid and s e n s i t i v e assays of the interactions of l e c t i n s with carbohydrates (1,2). The difference spectrophotometric method i s one of the useful tools for the study of s p e c i f i c binding of sugars to a l e c t i n . As pointed out e a r l i e r (3-6) changes in the spectrum of the l e c t i n from Arachis hypogaea (peanut) may be used to calculate a s s o c i a t i o n constants. Difference spectra i n t e n s i t i e s dependent on the amount of sugars bond are obtained with s p e c i f i c sugars, but not with non s p e c i f i c sugars. The binding of lactose to the l e c t i n i s accompanied by pronounced changes dependent on the temperature, the a f f i n i t y decreasing with increasing temperature (5). The interactions between the l e c t i n and d i f f e r e n t mono- and o l i g o saccharides are related to the structure of the sugars (6). The present study i s undertaken to ascertain whether these sugars interacts with the binding s i t e of the l e c t i n .
Materials and Methods Peanut l e c t i n i s p u r i f i e d by a f f i n i t y chromatography on desialylated red cell ghosts as previously described (7) and dialyzed extensively to remove the eluting sugar. Sugars are commercial products of analytical grade except f o r methyl-7-deoxy-L and D-glycero-e-D-galacto-heptopyranosides synthetized as described by Lemieux and a l . (8). Measurements are performed with a concentration of l e c t i n in the range 0 . 5 - 1 mg/ml, concentrations of sugars of 1-10.10
M, in NaCl 0.15 M at 10°C.
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
624
625
626 Absorbance and difference spectra are recorded between 260 and 300 nm using a temperature-controlled Cary 219 spectrophotometer. The intensities of difference spectra are determined between the typical positive and negative peaks (3,5). By plotting the change in difference spectrum aA versus the sugar concentration, a typical saturation curve is obtained. Linearisation according to Matsumoto (3) results in a straight line. The slope and the intersections obtained with this representation, calculated by the least-squares method, permit the determination of the binding constant (6).
Results and Discussion By plotting [sugar]/AA as a function of [sugar] we investigated the association constants for sixteen mono- and oligosaccharides at a constant temperature of 10°C. The resulting data are summarized in Table 1. With D-galactopyranose (conformation
4
C,) K = 1200 M 1 -i
constant measured for L-galactopyranose is 170 M
-1
while the
. The other saccha-
rides studied possess structural configuration differences and are substituted on C(6), C(4), C(2) and C(l) (see Table 1). The following conclusions were drawn with respect to the importance of the configuration of these atoms for
the interaction with the carbohydrate
binding site of peanut lectin. Atom C(6) An extracyclic chain is necessary for the carbohydrate lectin interaction and the orientation of the hydroxyl group on C(6) is essential. A substitution of the hydroxymethyl group decreases the strength of the association. Atom C(4) A free axial hydroxyl on C(4) is needed for binding. Atom C(2) A C(2) equatorial hydroxyl group is not essential for the interaction but the axial position of this group decreases the binding. Atom C(l) 0(1) methylated : Methylation favorises association. Among methyl-D-
627 galactosides differing only in the configuration about the anomeric C(l), there seems to be a slight preference for the a anomer. 0(1) involved in glycosidic bond : for the oligosaccharides studied the second residue appears to be involved in the association. The linear chain of the gluconic acid prevents the binding. Furthermore, the 3(1-4) linkage seems to give better binding than the a(l-6) linkage. These results suggest that the configuration on C(l) is important. Comparing their effectiveness to interact with the carbohydrate binding site of peanut lectin, the only sugars to have a more marked affinity than D-galactose appeared to be galactosides substituted on C(l).
Conclusion Our results show the following details : the sequence C(4)-0(4), C(5), C(6)-0(6) of the galactopyranosyl ring is involved in the interactions in the carbohydrate binding site of peanut lectin as postulated by Lotan et al.(9). Furthermore, for di- and oligosaccharides, it appears that the configuration on C(l), the nature of the osidic bond and of the second residue may influence the strength of the association.
References 1. Takeo, K., Fujimoto, M. and Kuwahara, A. (1982). These proceedings. 2. Wu, A.M. (1982) These proceedings. 3. Matsumoto, I., Jimbo, A., Kitagaki, H., Golovtechenko-Matsumoto, M. and Seno, N. (1980) J. Biochem. 88, 1093-1095. 4. Neurohr, K.J., Young, N.M. and Mantsche, H.M. (1980) J. Biol. Chem. 255, 9205-9209. 5. Caron, M., Ohanessian, J. and Becquart, J. (1981) 1st European symposium on Carbohydrates and Glycoconjugates (Vienna) Abstract G.S. 3. 6. Caron, M., Ohanessian, J., Becquart, J. and Gillier-Pandraud, H. Biochim. Biophys. Acta (In press). 7. Caron, M., Ohanessian, J., Faure, A. and Felon, M. (1981) C.R. Acad. Sci. Paris 292, 183-186.
628 8. Lemieux, R.U., Boullanger, P.H., Bundle, D.R., Baker, D.A., Nagpurkar, A. and Venot, A. (1978) Nouv. J. Chim. 2, 321-329. 9. Lotan, R., Skutelsky, E., Danon, D. and Sharon, N. (1975) J. Biol. Chem. 250, 8518-8523.
A CRITICAL STUDY ON THE PURIFICATION OF POTATO LECTIN (SOLANUM TUBEROSUM L.) Edilbert Van Driessche'®'^ , Sonia Beeckmans1®" , Robert Dejaegere^ and Louis Kanarek'®' t Laboratorium voor Chemie der Proteinen, and ^Laboratorium voor Plantenfysiologie; Vrije Universiteit Brüssel, Instituut Moleculaire Biologie, Paardenstraat 65, B-1640 Sint-Genesius-Rode, Belgium
Introduction The purification of the lectin from potato tubers has been described by different groups (1-5). Most of these methods are based on affinity chromatography, taking advantage of the sugar specificity of the lectin (NAG^; x 2-5). During the isolation of proteins from phenol-rich tissues such as potatoes, special attention has to be paid to the inhibition of phenol oxidases. Indeed, during the extraction, endogeneous phenols are quickly enzymatically oxidized to quinones which can irreversibly modify proteins by covalent binding to reactive groups such as sulfhydryl-, amino- and imino groups. These modifications result in most instances in reduced solubility and stability of the proteins or in complete loss of activity due to precipitation and/or inhibition of the proteins (6-8). The problems mentioned above can best be avoided either by eliminating the phenols or by inhibiting the phenolase activity with reagents such as sodium metabisulphite (Na 2 S 2 0 5 ), diethyldithiocarbamate (DIECA) or thiourea (6, 7) . Until now, exclusively Na2S20,- was used as antioxidant (1, 2, 4, 5). Previously we noticed (2) that when Na2S 2 0^ (2 mM) had been added during the extraction of the tubers, the purified lectin displayed some unexpected spectral properties,
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
630 i.e. the UV-absorption spectrum had a maximum at 271 nm, and more curiously the ratio of the absorbances at 280 to 250 nm was 1.1 - 1.3. Later we found that all the hemagglutinating activity was lost when ^ 2 8 2 0 ^ (2 mM) was added during the dialysis of the ammonium sulphate precipitate of the extract. In this paper, we describe a new preparation method for potato lectin and we compare the effect of the use of different phenolase inhibitors on the activity and the spectral properties of the lectin, model peptides, enzymes and amino acids.
Materials and Methods 1. Purification of potato lectin : potatoes were washed, peeled, cut in fine pieces and homogenized in 0.1 M sodiumacetate buffer containing 9 g/1 NaCl and 0.2 g/1 NaN^. The pH of the buffer was adjusted to 3.8 or 5.4 and either 2 mM Na2S20j-, or 1 mM DIECA, or 5 mM thiourea were added. Extractions were allowed to proceed at 4°C for 6 hours, the slurry was passed through cheesecloth and centrifuged for 30 minutes at 7000 r.p.m. Solid ammonium sulphate (243 g/1) was added to the clear supernatant in order to get 40% saturation at 4°C. The ammonium sulphate pellet was collected by centrifugation and dialyzed against the respective extraction buffers at room temperature. Precipitated proteins were removed by centrifugation and the clear supernatant was slowly applied to a chitin column which was equilibrated with the same buffer. The column was then washed with buffer until the absorbance of the effluent had dropped to zero. The column was then washed with 1 M C a C ^ in buffer and finally with saline. The lectin was eluted with 0.1 M acetic acid. 2. SDS-electrophoresis was performed on 10% polyacrylamide slab gels according to Laemmli (9), or on linear 12.5%-25% polyacrylamide gradient gels. Molecular weights were determined from the migration relative to standard proteins with known molecular weight.
631
3. Hemagglutinating activity was tested using rabbit red blood cells. 4. Chitin was prepared as follows : commercial (Sigma Chem. Comp.) chitin was exhaustively washed with 0.1 N HC1, water, 0.1 N NaOH, water, and was deproteinized with pepsin and trypsin.
Results 1. The effect of Na 2 S 2 0 5 > DIECA and thiourea on N-acetyltryptophanairide, N-acetyl-tyrosinamide, model peptides and proteins : The deleterious effect of ^2820,. on the UV-absorption spectrum of N-acetyl-tryptophanamide is shown in Fig. 1. Similar
Fig. 1.
The effect of 20 mM metabisulphite on the UV-absorption spectrum of N-acetyl-tryptophanamide in 0.1 M sodium-acetate buffer, pH 5.4. Incubation times : At = 0 h (initial spectrum) (—); 1 h 30 (-•-); 3 h ( ); 4 h 30 ( ); 10 h ( ); 25 h ( ) and 46 h (final spectrum) ( — ) .
632 changes were observed in a broad pH-range with tryptophane containing model proteins such as melittin (1 tryptophane, no tyrosine) (10), lysozyme, pig heart fumarase and purified potato lectin. No spectral changes were observed with N-acetyl-tyrosinamide or bovine pancreas ribonuclease A (6 tyrosines, no tryptophane) (11). Concomitant with the induction of changes in the UV-absorption spectrum, loss of activity of lysozyme, fumarase and potato lectin was observed. On the other hand, neither DIECA, nor thiourea had any effect on the spectral properties of the above mentioned probes. The action of the three phenolase inhibitors was also tested on a model S-S-bridge (5,51-dithio-bis(2-nitrobenzoate)) and on a cysteine containing peptide (glutathion). The extent of modification of cysteinyl groups (-SH) was estimated (according to Ellman (12)) from the measurement of the residual -SH groups of glutathion after incubation with phenolase inhibitor (Scheme 1 and Table 1). The extent of modification of the Scheme 1. "00C
COO"
COO" + Glu-Cys-Gly — • SH
1
5,5 -dithio-bis (2-nitrobenzoate)
COO"
Cys-S-S-^-N02 + Gly
glutathion
2-nitro-5-thio benzoate anion
model S-S-bridge with phenolase inhibitor (R) was estimated directly from the generation (Scheme 2) of 2-nitro-5-thiobenzoate anion (see Table 2). Scheme 2. "00C
COO"
02N-^^-S-S-^yN02
COO" +
R
»
COO"
R-S-^^-N02 +
5,5'-dithio-bis (2-nitrobenzoate)
"S^^-f^
2-nitro-5-thio benzoate anion
From these results it is clear that only thiourea does not interfere with S-S bridges or sulfhydryl groups.
These
results are further confirmed by the fact that thiourea is
633 the only phenolase inhibitor tested which does not inactivate lysozyme, an S-S containing enzyme (13), or fumarase, an enzyme with essential SH-groups (14). Table 1.
The effect of phenolase inhibitors on cysteine. [2-nitro-5-thiobenzoate anion] (mM) pH
no addition
thiourea
DIECA
Na
2S2°5
3.8
6.56
6.51
3.68
6.25
5.4
6.56
6.49
3.53
6.38
7.0
6.47
6.28
4.41
6.35
8.0
6.16
6.02
5.44
6.09
Glutathion (6.5 mM) in buffer (0.1 M sodium-acetate pH 3.8 and 5.4, or 0.1 M Tris-acetate pH 7.0 and 8.0) was incubated with 5 mM of respectively thiourea, DIECA or metabisulphite during 3 hours. The concentration of the remaining free -SH groups was determined spectrophotometrically at 412 nm according to Ellman (12) by adding 30 fil of the glutathion solutions to 3 ml of 5 mM DTNB in 0.1 M potassium phosphate buffer pH 7.0; a solution containing 5 mM DTNB in 0.1 M potassium phosphate buffer pH 7.0 and 50 ¡iM of the corresponding phenolase inhibitor was used as bianco. The concentration of 2-nitro-5thiobenzoate anion was estimated from its specific absorbance : e = 13600 M ^ m " 1 (12) . 412 nm Table 2.
The effect of 50 pM phenolase inhibitors on 5 mM DTNB (5,5'-dithio-bis(2-nitrobenzoate)) in 0.1 M potassium phosphate buffer pH 7.0. [2-nitro-5-thiobenzoate anion]
(fM) Thiourea
0
Diethyldithiocarbamate
30
Sodium metabisulphite
90
The concentration of 2-nitro-5-thiobenzoate anion was estimated from its specific absorbance : e =* 13600 M 1 cm 1 (12).
4 1 2
n m
634 2. Comparison of the effect of ^26205» DIECA and thiourea on the activity of potato lectin in extracts : In order to compare the effect of adding ^2820^, DIECA or thiourea during the extraction on the activity of potato lectin, tubers were homogenized in saline and extracted for 30 minutes. The coloured extract was passed through cheesecloth and centrifuged at 15000 r.p.m. for 20 minutes. The supernatant was devided into different fractions which were adjusted to pH 3, 4, 6 (0.1 M sodium-acetate, final concentration), 8 and 9 (0.1 M Tris-acetate, final concentration) and incubated with 5 mM Na n £„O c , 5 mM DIECA or 5 mM thiourea. ¿ZD After respectively 2 1/2 and 24 hours of incubation, the phenolase inhibitors were removed by dialysis against the corresponding buffer and finally against saline containing 0.02% NaN 3 . From the results in Table 3 it is clear that ^2820,. should be avoided as anti-oxidant for the preparation of potato lectin and should be replaced by DIECA or by thiourea.
Table 3.
The effect of different phenolase inhibitors on the agglutinating activity of potato lectin in extracts. Titer Thiourea
Diethyldithiocarbamate
Metabisulphite
pH
2.5 h and 24 h incubation
2.5 h and 24 h incubation
2.5 h 24 h incubation
3 .0
128
128
16
1
128
128
8 - 16
0
128
128
0
0
.0
128
128
0
0
9 .0
128
128
0
0
6 .0 00
4,.0
635 3.
Purification of potato lectin :
The lectin was prepared as described in Materials and Methods. The progress in the purification is shown in Fig. 2.
1 2
3
4
KD •m 92 -60
KD 92 —
ft»
% » »
» « *
I
48 5
.
-40 — 35
60 —
-.23 3
48.5 — 4035 — 23 3 -
1 2 3 4 5 6 7 8 9 10 11 1213 A
Fig. 2.
B
The progress in the purification of potato lectin as demonstrated by SDS-PAGE on
(A) 10% Polyacryl-
amide and (B) a linear 12.5%-25% gradient slab gel. Lane_in_gel A B 1 2 3 4 5 6 7 8 9 10 11 12 13
2 3 4 1
Sample Preparation with DIECA (pH 5.4) elution from chitin (0.1 M acetic acid) fraction I from Fig. 3A (pure lectin) fraction II from Fig. 3A Preparation with thiourea (pH 5.4) elution 1 from chitin (0.1 M acetic acid) elution 2 from chitin (0.1 M acetic acid) fraction I from Fig. 3B (pure lectin) fraction II from Fig. 3B 1 M CaCl2 wash Preparation with thiourea (pH 3.8) elution 1 from chitin (0.1 M acetic acid) elution 2 from chitin (0.1 M acetic acid) fraction I from Fig. 3C (pure lectin) fraction II from Fig. 3C Preparation with metabisulphite (pH 3.8) purified lectin
636 The lectin is strongly bound to the chitin matrix and is eluted as two fractions. A first lectin containing peak is eluted immediately with 0.1 M acetic acid (elution 1), while a second peak can only be released after an overnight incubation period in 0.1 M acetic acid (elution 2). When the eluted fractions are further chromatographed on Sephadex G-150 (Fig. 3), highly pure potato lectin is obtained as can be seen in Fig. 2A, lanes 2, 6, 11. The UV-absorption spectrum of potato lectin which has been prepared with DIECA, thiourea or Na2S20,- during the extraction is shown in Fig. 4. Lectin which has been isolated with DIECA or thiourea displays a normal protein absorption spectrum with a maximum at 280 nm and a 280/250 nm absorption ratio of 2.
Fig. 3.
Gel filtration of affinity purified potato lectin on Sephadex G-150 in 0.1 M sodium acetate containing 9 g/1 NaCl and 0.2 g/1 azide, pH 5.4 (A: 1 mM DIECA and B: 5 mM thiourea used in the extract at pH 5.4) or pH 3.8 (C: 5 mM thiourea used in the extract at pH 3.8).
637
Fig. 4.
The UV-absorption spectrum of potato lectin in phosphate buffered saline. Ultra-pure lectin prepared with DIECA or thiourea (—); lectin prepared with iretabisulphite ( ); pure lectin prepared with DIECA and completely inactivated with metabisulphite ( ) .
Discussion In this paper we clearly demonstrate that Na2S20j_ should be avoided as anti-oxidant for the preparation of proteins from phenol-rich tissues and should be replaced by thiourea which was shown to have no effect on either tryptophane, tyrosine, S-S bridges or cysteine. Although DIECA can react with both cystine and cysteine, it can be successfully used for the preparation of potato lectin which is free of SH-groups, but rich in S-S bridges (1). Since DIECA does not affect the activity of purified potato lectin, it may be assumed that the cystines are well buried in the interior of the molecule. Although potato lectin can be isolated to purity according to available literature procedures (using Na2S20j_), the specific activity of such preparations is only about 25% when compared to lectin prepared as described above. The reduced specific activity could be ascribed to the modification of an essential
638
tryptophane residue whose presence has been demonstrated by Ashford et al. (15) in the carbohydrate binding site. Although two active peaks are consecutively eluted from the chitin column with 0.1 M acetic acid, electrophoretic analysis demonstrated that these two fractions are indistinguishable, suggesting that the difference in elution has to be attributed to heterogeneity of the chitin matrix rather than to the presence of isolectins which differ in their affinity for carbohydrate .
References 1. 2. 3.
Allen, £.K. and Neuberger, Biochem. J. 135, 307-314 (1973) Van Driessche, E. and Kanarek, L. : Arch. Intern. Physiol. Bioch. 82, 414-415 (1975) Delmotte, F., Kieda, C. and Monsigny, M.: FEBS Lett. ^3, 324-330 (1975)
4.
Desai, N.N. and Allen, A.K.: Anal. Bioch. 93, 88-90 (1979)
5.
Owens, R.J. and Northcote, D.H.: Phytochem. 1_9, 1861-1862 (1980) Anderson, J.W.: Phytochem. 7, 1973-1988 (1968) Mayer, A.M. and Harel, E.: Phytochem. 1_8, 193-215 (1979)
6. 7. 8.
Patil, S.S. and Zucker, M.: J. Biol. Chem. 240, 3938-3943 (1965) 9. Laemmli, U.K.: Nature (Lond.) 227, 680-685 (1970) 10. Habermann, E. and Jentsch, J.: Hoppe-Seyler1s Z. Physiol. Chem. 348, 37-50 (1967) 11. Richards, F.M. and Vfyckoff, H.W. : The Enzymes 4 (3rd. ed.) (P.D. Boyer, ed.) pp. 647-806 (1971) 12. Ellir.an, G.L.: Arch. Biochem. Biophys. 82, 70-77 (1959) 13. Imoto, T., Johnson, L.N., North, A.C.T., Philips, D.C. and Rupley, J.A.: The Enzymes 2 (3rd. ed.) (P.D. Boyer, ed.) pp. 665-868 (1972) 14. Hill, R.L. and Teipel, J.V7. : The Enzymes 5 (3rd. ed.) (P.D. Boyer, ed.) pp. 539-571 (1971) 15. Ashford, D., Menon, R., Allen, A.K. and Neuberger, A.: Biochem. J. 199, 399-406 (1981)
A G A L A C T O M A N N A N P R E C I P I T A T I N G L E C T I N IN STENOCARPA
Theresa
SPHENOSTYLIS
SEEDS
Animashaun
B i o c h e m i s t r y D e p a r t m e n t , U n i v e r s i t y of Ife, Ile-Ife, Nigeria
Introduction H a e m a g g l u t i n a t i o n a c t i v i t y was r e p o r t e d in e x t r a c t s of S p h e n o stylis s t e n o c a r p a seeds by S c h e r t z e_t a_l ( 1 ) . In the paper the a g g l u t i n a t i o n of red blood cells by saline from S p h e n o s t y l i s s t e n o c a r p a lionaceae)
present extracts
(Hochst. ex A. Rich) Harms
seeds was e x a m i n e d f u r t h e r . The
(Papi-
haemagglutination
a c t i v i t y of this e x t r a c t was shown to be i n h i b i t e d by D - g a l a c tose and its d e r i v a t i v e s . Some D - g a l a c t o s e b i n d i n g lectins, from R i c i n u s c o m m u n i s
(2) and B a n d e i r a e a B i m p l i c i f o l i a
e.
(3),
p r e c i p i t a t e v a r i o u s g a l a c t o m a n n a n s . 3. s t s n n r a r p a e x t r a c t was found to p r e c i p i t a t e a g a l a c t o m a n n a n from A f z e l i a a f r i c a n a (Caesalpiniaceae)
s e e d s . The p o t e n t i a l use of this
Sm
polysaccha-
ride in p u r i f y i n g the lectin from S. s t e n o c a r p a seeds is d i s cussed .
M a t e r i a l s and M e t h o d s P r e p a r a t i o n of S. s t e n o c a r p a e x t r a c t . S. s t e n o c a r p a seeds w e r e p i c k e d l o c a l l y and i d e n t i f i e d by M r . I.B. F a r e m i . The
seeds
w e r e g r o u n d , d e f a t t e d w i t h p e t r o l e u m ether and s t i r r e d for h o u r s at 4°C w i t h 5 v o l u m e s
(wt/vol) of 0 . 8 5 % s a l i n e . The
n a t a n t , o b t a i n e d a f t e r s p i n n i n g the s u s p e n s i o n at 20 m i n , is r e f e r r e d to as the P r e p a r a t i o n of
10,000g
18 supe for
extract.
a f r i c a n a g a l a c t o m a n n a n . A. a f r i c a n a
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
seeds
640 were kindly donated by the Seed Section, Forestry Research Institute of Nigeria, Ibadan. After removal of the aril and husk, A. africana seeds were ground and defatted. Two grams of the meal were stirred in 100 ml water with heating. The polysaccharide was precipitated
from the hot-water extract by 40% ethanol
and resuspended in water. The carbohydrate concentration was determined by the anthrone procedure
(4).
Haemagglutination studies. Haemagglutination studies were performed in V-shaped micro-titre plates with 1.5% formalinised red blood cells
(5). The titre value was determined with doub-
ling dilutions of S. stenocarpa extract. The concentration of sugar which reduced the titre value by one was said to have inhibited haemagglutination by 50%
(6).
Agar-gel double diffusion studies. Agar-gel plates contained 1.5% agar
(Oxoid Ltd.) and 0.01% sodium azide
(Difco Laborator-
ies) in PBS (0.1 M sodium chloride, 0.025 M phosphate, pH 7.4). The plates were incubated in a humid atmosphere at room temperature for 48 hours. Examination of affinity chromatography media. Sepharose 6B was purchased from Pharmacia while immobilised-lactose was from Pierce Chemical Co. Acid-treated Sepharose was prepared ing to Ersson e_t a_l(7). 0.5 ml of the affinity
accord-
chromatography
media being tested was incubated with 0.5 ml of S. stenocarpa extract for 1 hour. The titre value of the supernatant was determined and compared with a control containing the same dilution of extract.
Table I:- Titre Values of S .stenocarpa Extract Blood Type
Titre Value
A1
A2
B
0
Bat
25
25
25
26
0
641 Table II:- Concentration of Sugar Producing 50% Inhibition of Agglutination of 0 Red Blood Cells by S. stenocarpa
extract
mM D-galactose
3.0
N-acetyl-D-galactosamine
0.2
Lactose
0.8
Raffinose
3.0
Results Saline extracts of S. stenocarpa seeds agglutinated 0 red blood cells with a titre value of 2^ (Table I). The extracts agglutinated A^ , Ag and B cells to the same or to a lesser extent, but did not affect the sedimentation pattern of chicken and fruit-bat
(Eidolon helvum) erythrocytes. There was no clear-
cut difference between the agglutination of A^and A^ red blood cells by the extract. The agglutination of 0 erythrocytes by a
2
2
dilution of S. stenocarpa extract was totally abolished by
50 mM N-acetyl-D-galactosamine, D-galactose, lactose or raffinose. 50 % inhibition of 0 red blood cells was achieved in the presence of 0.2 mM N-acetyl-D-galactosamine, 0.8 mM lactose, 3 mM raffinose or 3 mM D-galactose
(Table II).
The polysaccharide isolated from A. africana seeds has been shown to be a galactomannan
(8). S. stenocarpa extract formed
precipitin bands in agar gel double diffusion plates with 13 to 0.4 mg/ml A. africana galactomannan
(Figure I). The galacto-
mannan did not precipitate dilutions of the S. stenocarpa extract. Various reagents were examined for their potential to purify the lectin from S. stenocarpa extract by affinity
chromatogra-
phy. The lectin did not bind to Seharose or acid-treated
Seph-
arose. The amount of lectin bound to immobilised-lactose was very low (approximately 20y^g protein per ml of gel).
642
@
®© o Figure I:- Diffusion of S. stenocarpa extract and A. africana galactomannan in agar gel. Centre well - S. stenocarpa
extract,
outside wells
(1 - 6) - doubling dilutions of A. africana
galactomannan
(13 - 0.4 rag/ml).
Discussion It has been confirmed that S. stenocarpa extracts human erythrocytes
agglutinate
(Table I). This haemagglutination is rela-
tively non-specific and unlike the findings of Schertz et a_l (1) the extract did not preferentially agglutinate h^ rather A^ cells. Haemagglutination was inhibited not only by N-acetylD-galactosamine and D-galactose but also by the fl- and the vLD-galactoside containing disaccharide lactose and
trisacchar-
ide raffinose. Some galactose-binding lectins have been purified by affinity chromatography on Sepharose e.g. ricin abrin
(10) and lectin from Pseudomonas aeruginosa
(9)>
(11). Tomita
et al (12) found that only three of the four galactose-binding
643 lectins tested bound to Sepharose. Acid-treated Sepharose has been used to purify lectin from Erythrina corallodenron
(13).
However,¡the lectin from S. stenocarpa did not bind to Sepharose or acid-treated Sepharose and the yield from
immo&ilised-
lactose was poor. Lectins from R. communis
(2) and B. simplicifolia
(3) precipi-
tate galactomannans from several sources such as guar gum, locust bean and Cassia alata. Moreover, cross-linked guaran has been used to purify both these lectins and that from Echinocystis labata
(14). Guaran immobilised in polyacrylamide gel was
used to prepare a high-capacity adsorbent for B. simplicifolia lectin
(15). Since S. stenocarpa extracts interact with A. af-
ricana galactomannan
(Figure I), the possibility of isolating
S. stenocarpa lectin employing cross-linked or immobilised A. africana galactomannan will be explored.
Acknowledgements I am grateful to Messrs A. Abimbola, 0.0.0. Binutuand O.M. Udeagu for technical assistance and to Mr. B.M. Salami for the photography
References 1.
Schertz, K.F., Boyd, W.C., Jurgelsky, W., Cabanillas, E.: Econom. Botany J_4, 232-239
(1960)
2.
Van Wauwe, J.P., Loontiens, F.G., De Byuyne, C.K.: Biochim. Biophys. Acta 3J_3, 99-105 (1973)
3.
Hayes, C.E., Goldstein, I.J.: J. Biol. Chem. 24_9,. 19041914 (1974)
4.
Viles, F.J.Jr., Silverman, L.: Anal. Chem. 21, 950-953 (1949)
5.
Butler, W.T.: J. Immunol. 90, 663-671
6.
Schimizu, S., Ito,M., Niwa, M.: Biochim. Biophys. Acta 500, 71-79 (1971)
(1963)
644 7.
E r r s o n , B., A s p b e r g , K., P o r a t h , J.: B i o c h i m . Acta 3_1_0, 446-452 (1973)
Biophys.
8.
Ikhile, P., A n i m a s h a u n , T.: S u b m i t t e d to X l t h ional C a r b o h y d r a t e S y m p o s i u m (1982)
Internat-
9.
O l s n e s , S., Pihl, A.: B i o c h e m i s t r y _1_2, 3121-3126
10.
O l s n e s , S., Pihl, A.: Eur. J. B i o c h e m . 35,
11.
G i l b o a - G a r b e r , N., M i z r a h i , L., G a r b e r , N.: FEBS 28, 93-95 (1972)
12.
T o m i t a , M., K u r o k a w a , T., O n a z a k i , K., Ichiki, N., Osawa, T., Ukita, T.: E x p e r i e n t i a 28, 24-26 (1972)
13.
G i l b o a - G a r b e r , N., M i z r a h i , L.: Can. J. B i o c h e m . 59., 315-319
(1973)
179-185
(1973?
Letts.
(1981)
14.
L o n n g r e n , J., G o l d s t e i n , I.J.: FEBS L e t t s . 68, ( 1976)
31-34
15.
H o r i s b e r g e r , M.: C a r b o h y d r a t e
(1977)
Res. ¿ 3 , 231-237
.FURTHER INVESTIGATIONS ON MISTLETOE LECTIN I (ML I): OF A-CHAIN ON CELL-FREE PROTEIN SYNTHESIS
1
2
EFFECT
H. Franz, Annemarie Kindt and P. Ziska H. Bielka, R. Renndorf and Liselotte Venker
Staatliches Institut fur Immunpraparate und Nahrmedien, 1120 Berlin-Weißensee, DDR 2 Zentralinstitut fur Molekularbiologie, Abteilung Zellphysiologie, Akademie der Wissenschaften der DDR, 1115 Berlin-Buch, DDR On the 4 th lectin meeting we presented a method for simultaneous reduction of mistletoe lectin I (ML I) and affinity chromatography of its A- and B-chains (1). In analogy to ricin and abrin we expected toxophoric properties of the A-chain of ML I. It is the aim of this paper to describe the inhibition of protein synthesis in cell-free system by the A-chain of ML I. Material and methods 1. Preparation of the A- and B-chains of ML I ML I was prepared as described earlier (2) the procedure for the isolation of both chains was slightly modified in comparison to our first communication. The lectin was dissolved in phosphate buffered saline (PBS), pH 7.2, (1 mg ML I/ml) and applied to a column of partially hydrolized Sepharose 4B. Non-bound proteins were washed out with PBS. About 10 mg of ML I were bound to 50 ml of partially hydrolized Sepharose 4B. Then ß-mercaptoethanol (5%) was applied to the column. After appearence of the ß-mercaptoethanol in, the effluent the flow was stopped and the reduction of ML I in the column was allowed to proceed overnight at room temperature. Thereafter the
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
646 column was washed with PBS and the effluent was applied to a second column of partially hydrolized Sepharose 4B in order to eliminate residual amounts of the B-chain. The A-chain passed the columns together with 3-mercaptoethanol. The B-chain remained bound and was eluted with 0.1 M D-galactose. The fractions were dialysed against PBS or 0.05 M potassium acetate to remove 3-mercaptoethanol and D-galactose. The chains were identified by SDS-PAGE according to the method of WEBER and OSBORN (3). If the B-chain fractions contain small amounts of A-chain the whole procedure has to be repeated. The protein content of the preparations was measured by the method of LOWRY et al. with bovine serum albumin as standard (4). Cell-free protein synthesis systems. Two different translation systems have been used in this study: a. A polysomal system from rat liver as described in (5) (but 100 |il samples only) containing 10 jig of polysomes (prepared with some modifications according to (6)), 20 (il of rat liver cytosolic fraction (corresponding to 20 |j.g protein; 105 000 x g supernatant in 50 mM Tris/HCl, pH 7.6, 1 mM EDTA, 6 mM 3-mercaptoethanol by Sephadex G-10 filtration) and, besides the other ingredients as described in (8), 1 |iC (^H) leucin (68 Ci/mmol). The samples were incubated at 37°C for 30 min without (controls) or in the presence of varying amounts of the A-chain samples (see Table 1) and then furthermore treated and counted for radioactivity as described in (5). b.
A rabbit reticulocyte lysate system.
The lysate was prepared with some modifications following the procedure of CRYSAL et al. (7) (the buffer for lysis of the reticulocytes contained additionally 5 mM Hepes/KOH, pH 7.0). Immediately before use the lysate was filtered through Sephadex G-25, equilibrated and eluted with a buffer containing 25 mM KC1, 10 mM NaCl, 3 mM Mg(0Ac)2, 1 mM ATP, 1 mM GTP, 0.25 mM
647 dithioerythritol, 1 mM glycose and 20 mM Hepes/KOH, pH 7.2, following JAGUS and SAFER (8). To 1.0 ml of the filtered lysate were added 25 )il of a hemin stock solution and 20 |il of a creatine phosphokinase stock solution as described by SAFER et al. (9) to give final concentrations of 25 jiM and 0.2 mg/ml, respectively. 2.5 of 2 M KC1 plus 10 mM Mg (0Ac)2, 1 of 400 mM creatine phosphate, 1 |il of 0.5 M putrescine acetate, pH 7.0, 1 |il of 0.2 mM spermine plus 2 mM spermidine, 2 p.1 of a mixture containing all amino acids (1 mM each) , and 3 )il of U ( 1 4 C) leucine (0.6 |i.C; 213 mCi/mmol) were added to 40 p.1 of the gel filtered lysate. A-chain preparations were added as specified in Table 2. The volume was completed to 57.5 |il by addition of aqua bidest. Incubation was at 37°C for 30 min; thereafter, two 20 samples were removed and pipetted into filter paper discs. The discs were processed for determination of hot TCA-insoluble radioactive material by liquid-scintillation counting.
Results and discussion 1.
Reduction of ML 1 under mild conditions:
Attempts to split ML I using &-mercaptoethanol only in absence of denaturating reagents were not successfull. Therefore, we tried to separate A- and B-chains by reducing Sepharose-bound ML I. This procedure is based in the hypothesis that only the B-chain is responsible for lectin activity. The result was the liberation of a single protein, which passed the column and another one, which was eluted by D-galactose solution. This leads to the following conclusions: ML I consists of two different chains. The A-chain does not bind D-galactose. The B-cha in is fixed to the carrier and therefore represents the virtual lectin component in ML I. Binding to a D-galactose bearing carrier effects alterations in the conformation of ML I which permit to reduce the S-S-bound. Denaturating reagents like 6 M urea can be avoided. This method
648 O) (1) M m i rH H a) u
H 0 4-1 M 0 -P c 0\O 0 o
H H H
1
m
(N!
LD
1
ai
1 id en U) id
o CN ro •H
m
o
\
o LD LO (Ti (M
rH
o o n ^D LD
o in CN
o
O IO rH
tn C
Oì
rH
O in 00 m
O f IT) O ro
o
o o m
m 0
ft
a) rH -P U) •H e
•H
—
M a)
>
-p •H u H Q) 4H -P 4-1 Iti W (-1
m
o
id
Cn C
H 0 4-1 S-L 0 4-1 C 0\° 0 a
H c 0 •H -P (0 SH •4J U -H ai io o o tu co UI • o o CO U C ai e u o co O "0 en >•Gì U k4 Q.4J 4-1 a < "O w -H C T3 X) o c ^ t !c O C rH O Ü C0 -H -C U •— C0O) 2 Q.4J W —^ kl • Q)ai m ai^ rH O ai C Ä X — >M TI "H ai *tH N a* >.jî 4-1 -O E rH C O • 3 ai CO J3 \ C o kj ^c u c cp ai o E e 1000 rad) t o t a l body i r r a d i a t i o n may well be needed to ensure engraftment of HLA-disparate c e l l s in m u l t i t r a n s f u s e d immunocompetent leukemic h o s t s . I t i s hoped that continued p r o g r e s s of t h i s l i n e of work should permit us in the near f u t u r e to apply marrow t r a n s p l a n t s to a l l i n d i v i d u a l s and not j u s t to the 40% of i n d i v i d u a l s p o s s e s s i n g matched s i b l i n g d o n o r s . Use of such t r a n s p l a n t s w i l l a l s o enable us to e x p l o r e the a l l o g e n e i c advantage f o r promoting leukemia r e s i s t a n c e in d i s e a s e d human h o s t s . Furthermore, a b r o g a t i o n or a m e l i o r a t i o n of GVH d i s e a s e a s a c o m p l i c a t i o n of marrow t r a n s p l a n t a t i o n , should reduce the a c u t e m o r b i d i t y and m o r t a l i t y a s s o c i a t e d with t h i s procedure to between 5 and 10% and, t h e r e f o r e , may u l t i m a t e l y permit us to c o n s i d e r t r a n s p l a n t s f o r a number of other blood d i s e a s e s and c o n g e n i t a l enzymopathies which a r e not a c u t e l y l e t h a l but r a t h e r l e t h a l over the c o u r s e of y e a r s (25) .
696 References 1.
Camitta B.W., Blood 4 5 , 355
Rappeport (1975).
2.
Thomas E . D . , B u c k n e r C . D . , C l i f t R . A . , F e f e r A . , J o h n s o n F . L . , Neuman P . E . , S a l e G . E . , S a n d e r s J . E . , S i n g e r J . W . , Shulman H . , S t o r b R . , Weiden P . L . : New E n g . J . Med. 3 0 1 , 597 ( 1 9 7 9 ) .
3.
Gale R . P . , G., Fahey (1976) .
4.
Neiman P . E . , Thomas E . D . , R e e v e s W . C . , Ray C . G . , S a l e G . , L e r n e r K . G . , B u c k n e r C . D . , C l i f t R . A . , S t o r b R . , Weiden P . L . , Fefer A.: T r a n s p l a n t . P r o c . 8 , 663 ( 1 9 7 6 ) .
5.
Thomas E . D . , Storb R., Clift R.A., Fefer F . L . , Neiman P . A . , L e r n e r K . G . , G l u c k s b e r g C.D.: New E n g . J . Med. 2 9 2 , 8 3 2 ( 1 9 7 5 ) .
6.
Lowenberg B . , D i c k e K . A . , v a n Bekkum T r a n s p l a n t . P r o c . 8 , 527 ( 1 9 7 6 ) .
7.
Y u n i s E . J . , Good R . A . , S m i t h J . , A c a d . S e i . USA 7 1 , 2 5 4 4 ( 1 9 7 4 ) .
8.
Von Boehmer H . , 322 ( 1 9 7 5 ) .
9.
Zinkernagel R.M.Jr.: J.
Feig J.,
S . , Opelz G . , Cline K.J.:
Sprent J . ,
Dicke K.A., (1971).
11.
Rich R.R., Kirkpatrick, 5 , 190 ( 1 9 7 2 ) .
R.,
Nathan
van
Eekkum
D.W.,
Stutman
Spooner
D.W.: C.H.,
12.
Dexter
Reisner Y. , Itzicovitch L. , P r o c . N a t l . A c a d . S e i . USA 7 5 ,
14.
L i s H. , S h a r o n N. : of Plants Vol. 6 p. 371.
15.
Reisner (1980).
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R e i s n e r Y. , L i n k e r - I s r a e l i 2 5 , 129 ( 1 9 7 6 ) .
17.
Reisner Y., Commun. 7 2 ,
18.
R e i s n e r Y . , Kapoor ( 2 ) , 1320 (1980) .
Sharon
E.:
M.:
0.: J.
N.,
O'Reilly
Natl.
Med. G.,
141, Welsh
3,
666
Immunol.
(1978).
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(ed.): The B i o c h e m i s t r y Academic Press, 1981),
Trends M.,
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Cell.
Meshorer A., 2933 ( 1 9 7 8 ) .
i n l^arcus A. (New Y o r k ,
Ravid A . , S h a r o n 1585 ( 1 9 7 6 ) .
135
Johnson Buckner
Dooren
Proc.
Smith T . K . : 275,
A., H. ,
Exp.
Transplant.
Nature
N.:
D.G. :
T e r r i t o M . , Young L. , S a r n a Transplant. Proc. 8, 611
Nabholz
13.
Y.,
Parkman
R.M., Althage A., Callahan, Immunol. 1 2 4 , 2 3 5 6 ( 1 9 8 0 ) .
10.
T.M.,
J.M.,
Biochem. R.J.,
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5,
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Good R . A . :
29
Res. Lancet
697
1920. 21. 22. 23. 24. 25.
R e i s n e r Y. , Kapoor N . , K i r k p a t r i c k D. , P o l l a c k fc.S., Dupont B . , Good R . A . , O ' R e i l l y R . J . : Lancet ( 2 ) , 327 (1981) . R e i s n e r Y. , Kapoor N . , Hodes M.Z., O ' R e i l l y R . J . , Good R . A . : Blood 5 9 , 360 ( 1 9 8 2 ) . R e i s n e r Y . , Pahwa S . , Chiao J . W . , Sharon N . , Evans R . L . , Good R . A . : P r o c . N a t l . Acad. S c i . USA 77, 6778 ( 1 9 8 0 ) . F r i e d r i c h W., O ' R e i l l y R . J . , Koryiner B . , Gebhard D . F . , Good R . A . , Evans R . L . : Blood 5 9 , 696 ( 1 9 8 2 ) . Korngold R. , S p r e n t J . : J . Exp. fied. 148, 1687 ( 1 9 7 8 ) . Woodruff J . f t . , E l t r i n g h a m J . R . , Casey H.W.: Lab. I n v e s t . 2 0 , 499 ( 1 9 6 9 ) . Good R . A . : New E n g l . J . Med. 306, 421 ( 1 9 8 2 ) .
REPORT ON THE THIRD SESSION OF THE INTERNATIONAL WORKING PART? ON STANDARDIZATION OF LECTINS FOR DIAGNOSIS.
T.C. B0g-Hansen (secretary) The Protein Laboratory, University of Copenhagen, Denmark
The International Working Party on Standardization of Lectins for Diagnosis at the Fourth Lectin Meeting in Copenhagen, June 1981, was outlined in the first report (1). The ultimate goal would be to draw up guidelines for lectin production, the first phase of the program being a well-controlled test scheme for a few widely used lectins. It was voted to test various commercial and non-commercial con A preparations in as many chemical and biological assays as possible, and most major lectin producers responded to my request to provide con A. The preliminary test program is listed in (1). The Third Session was held during Interlec 5 and coded con A samples were distributed for testing.
There was a motion for
a more thorough test program and the following additional groups volunteered to take part in the test program to make it very comprehensive: M.J.Waxdal and B.J.Mathieson (Bethesda), J.Y.Lin (Taiwan), J.A.Kint (Gent), A.M.Wu (College Station), I.Lorenc-Kubis (Wroclaw), B.Ersson (Uppsala), J.Kohn (London) and M.Caron (Bobigny), and G. A. Spengler (Bern). A number of participants wished to provide non-commercial con A for inclusion into the test program.
This was wellcomed,
especially since this would mean a controlled comparison of a lectin provided as a solution and as a freeze dried powder. It is anticipated that all con A samples should be distributed during September 1982.
© Walter de Gruyter & Co. 1983, Berlin • New York Lectins, Vol. Ill
700
It was decided that commercial companies could take part in the program on the same terms as other partners, i.e. promarily that the highest scientific standards should be applied and that all test results of the coded samples should be made available for the Working Party. After the Third Session of the Working Party a letter was received from R.E. Ritts, chairman of International Union of Immunological Societies Standardization Committee Communicating Minutes of the IUIS/WHO Standards Executive Committee, WHO, Geneva, 27-28 May, 1982. The Minutes contain the following paragraph under the heading New Subcommittees: "Several comments or requests have been received concerning standardization of lectins. Correspondence has also been transmitted by WHO from the International Working Party in Standardization of Lectins. After reading Secretary B0g-Hansen's report of this group, the committee members voted to ask Profs. J. Breborowicz and B0g-Hansen if they would be willing to have their group act as an official subcommittee of the WHO/IUIS Standardization Program with the assurance that we would assist them with review of protocols to assure biostatistical acceptibility for eventual WHO submission for the candidate preparations, annual budget support of $2,000 ~ 3,000 if available and assistance in raising funds for this effort.'' On behalf of the International Working Party for Standardization of Lectins for Diagnosis, I have accepted to serve as an IUIS/WHO subcommittee.
1. T.C.B0g-Hansen, J.Breborowicz, H.Franz: A report from the International Working Party on Standardization of Lectins for Diagnosis. On the necessity of standardized products. Lectins - Biology, Biochemistry, Clinical Biochemistry, Vol. 2, pp. 789-791.
A U T H O R
Andersen, M. M. 361 Àngelisova, P. 9 Animashaun, T. 639 Azim, M. 63 Barbieri, L. 293 Beeckmans, S. 629 Berke, G. 55 Bessler, W. G. 45 Bielka, H. 645 Bierbuchen, M. 167 Bjerrum, 0. J. 387 Bladier, D. 319 Bobrow, L. 105 B0g-Hansen, T. C. 27, 699 Bonoldi, E. 87 Bonnafous, J. C. 283 Bonnard, G. D. 37 Bratthall, D. 653 Brooks, D. E. 479 Busing, D. 45
I N D E X
Decker, J. M. 443 Debray, H. 323 De Gennaro, V. 199 Dejaegere, R. 604, 629 Dell'Orto, P. 87, 199 Delrieu, J. 661 Deugnier, M. A. 319 Diaz, C. 521, 531 Doi, P. 87 Dornand, J. 283 Drakeford, D. 275 Driessche, E. van 549, 604, 629 Ersson, B. 503, 667 Eshdat, Y. 667 Falasca, A. 293 Faris, A. 503 Farrar, G. 157 Fauci, A. 235 Faure, A. 661 Favero, J. 283 Fischer, J. 145, 157, 167 Fischer, R. 167 Fowlkes, B. J. 235, 251, Franceschi, C. 293 Franco, M. V. 435 Franz, H. 179, 645 Fujimoto, M. 397
Calafat, J. 119, 131 Campadelli-Fiume, G. 351 Carlier, A. R. 583, 593 Carlsson, P. 653 Caron, M. 319, 623, 661 Causse, H. 559 Chiricolo, M. 293 Christensen, U. 387 Clemetson, K. J. 303 Coggi, G. 87, 199 Colombi, R. 199 Comi, A. 199 Crouther, D. 225
Gallagher, J. T. 225, 311 Gerecke, D. 213 Gilboa-Garber, N. 495 Groeger, B. 179
Dale, R. E. 311 Dall'Olio, F. 351 Debbage, P. L. 179
Hageman, P. C. 105, 131 Harding, M. J. 225, 311 Haynes, B. F. 235, 251
702 Heegaard, N. H. H. 387 Hermann, G. 73, 213 Hilgert, I. 9 Hilkins, J. 105 Htfiby, N. 27 Holthofer, H. 205 Hörejsi, V. 3, 9 Horisberger, M. 189 Hosselet, M. 549 Iren, F. van 521, 531 Iwasa, M. 371 Janssen, H. 119, 131 Jensen, C. 27 Kanarek, L. 549, 604, 629 Karjalainen, K. 327 Kieda, C. 427 Kijne, J. W. 521, 531 Kimber, S. J. 63 Kindt, A. 415, 645 Klein, P. J. 145, 157, 167 Koch, C. 27 Kocourek, J 3, 453 Kohn, J. 405 Krajhanzl, A. 453 Kraut, H. 45 Kristofova, H. 9 Kuwahara, A. 397 Lauwreys, M. 604 Leireson, W. 275 Lembke, J. 213 Lempfried, K. W 73 Liechti, J. 37 Licastro, F. 293 Lindahl, M. 503 Lonnerdahl, B. 503 Loof, A. De 469 Lorenc-Kubis, I. 379 Ltfwenstein, H. 27 Luscher, E. F. 303 Malmi, R. 327 Manen, J. F. 611 Mani, J. C. 283 Marchalonis, J. J. 461 Mathieson, B. J. 235, 251, 263, 275 Mattiasson, B. 653 McGregor, J. L. 303 Miettinen, A. 205 Misdorp, W. 105
Monsigny, M. 427 Montreuil, J. 323 Muller, E. 435 Muller-Hermes, W. J. P. 45 Murre, C. 243 Nelken, D. 17 Noach, S. 361 Norn, S. 27 Nosek, J. 453 O'Brien, R. L. 283 0'Dell, D. S. 179 Ohanessian, J. 623 Permin, H. 27 Peters, J. H. 45 Peumans, W. J. 583, 593 Pierce-Cretel, A. 323 Pigott, J. 179 Poucke, M. van 549 Pueppke, S. G. 513 Pusztai, A. 611 Ramstorp, M. 653 Raymond, J. 405 Reisner, Y. 677 Renndorf, R. 645 Rossel, S. 145 Rossi, C. A. 293 Rouge, P. 559 Sagisaka, K. 371 Scannavini, M. 351 Schaal, I. van der 521, 531 Schauer, R. 435 Schröder, C. 435 Serafini-Cessi, F. 351 Shannon, L. M. 573 Sharon, N. 667 Sharrow, S. 0. 251, 275 Shukla, A. K. 435 Skov, P. S. 27 Soderstrom, K. 0. 327 Solheim, B. 538 Spik, G. 323 Stadler, B. M. 37 Stinissen, H. M. 583, 593 Stirpe, F. 293 Strosberg, A. 604 Stynen, D. 469 Surani, M. A. H. 63 Tacchini, M.
189
Takeo, K. 397 Thomas, C. A. 251 Thomas, C. T. 235 Trust, T. J. 479 Turp, P. 405 Uhlenbrock, G. 145, 157, Valk, M. A. van der 105 Vasta, G. R. 461 Venker, L. 645 Viale, G. 87, 199 Vierbuchen, M. 145, 157 Virtanen, I. 205 Voller, A. 405 Wadstrom, T. 479, 503 Waxdal, M. J. 235, 243, 263, 427 Weil, H. P. 73, 213 Williams, D. 3, 179 Williams, L. G. 179 Ziska, P. 179, 645
S U B J E C T
Abrin 263, 405, 479 Abrus precatorius agglutinin 263, 293 N-Acetyl D-glucosamine 479 Acid phosphatases 371, 379 Acrosome 327 Acute leukaemia 225 Adenia digitata 293 Adenocarcinoma 131 Adherence 479, 495, 667 Adhesins 479 Affinity chromatography 45 167, 243, 303, 335, 371, 379, 387, 443, 503, 513, 539, 559, 573, 593, 623, 629, 639 Affinity electrophoresis 361, 379, 387, 397, 405 Affinity fixation 405 Affinity Immunoelectrophoresis 361, 379, 387 Afzelia africana 639 Ageing 319 Agglutination 3, 263, 283, 303, 427, 531 Agropyrum repens 583 Amino acid composition 461 Antibodies 371, 521, 539, 573, 611 Antioxidant 629 Antiserum 549, 583 ^ - a n t i t r y p s i n defiency 361 Arachis hypogaea lectin 293, 405, 573 Asthma, histamine release 27 Autoaggregate 479 Avidin-biotin-peroxidase complex 87
I N D E X
Bacterial lectins 27, 479, 495, 503, 667 Bandeiraea Simplicifolia lectin 573 Barley lectin 583 Bauhinia purpurea alba lectin 573 Bauhinin 573 Beetle lectin 469 Berberis variegata lectin 405 Binding constants 387, 623 Binding curve 311 Binding sites, lectin 3, 145 Binding sites, multiple 479 Binding specificity 623 Biotinylated lectins 87, 199 Blotting 179 Brachypodium 583 Breast cancer 105, 119, 131, 145, 157 Canavalia ensiformis lectin, see con-A Canavalia gladiata DC lectin 371 Carcinomas 105, 131 Calcium independent interaction 63 Cell culture 179 Cell cycle 37 Cell membranes, cerebellar 179 Cell membranes, liver 179, Cell suspensions 179 Cell sorting 225, 235, 243, 251, 263, 275 Cell-spreading 63 Cells, affinity chromatography 243
706 Cellular location 611 Cereal lectins 583, 593 Cerebellum (chick) 179 Chick embryo cerebella 179 Chitin 629 Chitobiose 311 Cholera lectin 479 Chromatofocusing 521 Colloidal particles 189 Colorado potato beetles 469 Compactin 63 Con-A 17, 27, 63, 73, 87, 131, 167, 189, 293, 303, 327, 335, 361, 379, 397, 405, 415, 573 Coregonus lavaretus M. 293 Cotoneaster horizontalis lectin 405 Cotyledons 559 Countercurrent electrophoresis 405 C-reactive proteins 461 Crotalaria juncea lectin 293, 503 Crossed affinoimmunoelectrophoresis 361, 379, 387 CTL-cytotoxic T lymphocytes 55 Cupressus lectin 405 Cyclostome lectin 461 Cydonia oblonga lectin 405 Cytisus scoparius link lectin 371 Cytofluorimetry 427 Cytolytic activity 17 Cytotoxic T lymphocytes 55 Cytotoxicity lectin-dependent 55 Datura stramonium 293 DBA 87, 105, 327, 573 Definition 3 Diarrhoea 503 Differentiation 145 Differentiation antigens of the breast 105 Difference spectrophometry 623 Differentiation markers 105 Dissociation constant of Concanavalin A 397 DNA 235 DNA synthesis 427 Didemnum candidum 461
Dolichos biflorus 293 Dolichos biflorus lectin, see DBA Double diffusion 521, 611, 639 E. coli 503 ECA 435 Elastase 361 Electron microscopy 131, 189, 199 Embryo 559 Embryonic cells 63 Endocrine therapy 145 Endocrine treatment 157 Endogeneous lectins 427 E-PHA 611 Erythrina crystagalli agglutinin 435 Erythrina indica 293 Erythrocytes 435 Erythrocytes, binding to macrophages 435 Erythrocytes, phagocytosis by macrophages 435 Erythrocytes, sialidase treatment 435 Estrogen 145 Estrogen receptor 131, 145 Evolution 461, 573 Evolutionary relationship 461 Favin 603 Ferritin 87 Fetuin 443 Fetuin-binding material 443 Fimbriae 479, 503, 521 Fish oocyte lectin 453 FITC-lectins 145, 157, 167, 179, 235, 263, 311, 327, 513, 539 Flagellae 521 Flow cytometry 235, 245, 251, 263, 275, 311, 427 Flow microfluormetry 235, 243, 275 Fluorescein labelled lectins see FITC-lectins Fluorescence 205, 225 Fluorescence activated cell sorter 263 Fluorescence technique 319 Fluorescent labelled antibodies 611
707 Fluorochromes 87 Frozen sections 179 Galactomannan 639 Galactose-specific lectins 573 ^-Gal-specific lectin 435 of-Galactosidases 573 Galactosides 623 Gastric cancers 167 Gastric mucosa, normal 167 Gastrointestinal glycoproteins 167 Germinal cells, labeling of 327 Germination 583 Glomerulus 205 Glycine max 293, 513, 573 Glycine soya 513 Glycine soya lectin 513 Glycocalyx 311 Glycoconjugates 205 Glycophorin 387, 479 Goblet cells 167 Gold label 611 Gold markers 189 Gold staining 189 Grass family lectins 583 Grass seeds 379 Grass seed acid phosphatase 379 GSA 335 Host specificity 531 H-2 17 HA 479 Haemadsorption 415 Haemadsorption solid phase technique 415 Haemagglutinating 559 Haemagglutination 469, 495, 503, 513, 521, 549, 573, 639 Haemagglutinin 573 Halocynthia Pyriformis 461 Hemadsorption lectin test 415 HDA 415 Helix pomatia 293 Helix pomatia lectin 73, 213 Helper T cells 427 Herpes virus glycoproteins 351 Histamine release 27
Histochemistry 87, 105, 119, 131, 145, 157, 167, 179, 189, 199, 205 Histocompatibility antigens 55 HL-60 cells 361 Hormone dependence 145, 157 Hormone receptor 145 Hp 167, 213 HPA 131 Hp-peroxidase conjugate 73 Human erythrocyte 319 Hura crepitans 293 Hyperplastic gastric mucosa 167 IL see Interleukin Iodine-125-labelled lectins 303 Immunochemistry 573 Immunocytochemistry 189, 611 Immunodiffusion 549 Immuno double diffusion 573 Immunoelectrophoresis 371, 559 Immunofluorescence label 611 Immunological cross reactions 513, 573 Immune lysis 55 Immunoglobulin 573 Immunoglobulins 27 Immunoglobulin secreting cells 235 Immunoprecipitation 283 Induced tumor 443 Infection threads 513 Infectivity 479, 495, 513, 521, 539 Inhibitors of protein synthesis 293 In vivo synthesis 593 Insect lectin 469 Interleukin 2 (IL 2) 37, 45 Internalisation 179 Intestinal metaplasia 167 Intrinsic asthma 27 Isolectins 45, 539, 583, 593, 611 Iuglans regia lectin 405 Kidneys 205 Kinetic constants 387 Lactose, immobilized 513
708 Labeling lectins 87 L a m p r e y lectin 461 LCA 17, 55, 63, 303, 355, 573, 603 Leaf lectins 583 L e c t i n assay 415 L e c t i n - b l o t t i n g 179 Lectin-carbohydrate i n t e r a c t i o n 623 L e c t i n - d e p e n d e n t lympholysis 55 L e c t i n h i s t o c h e m i s t r y 167 L e c t i n - i m m u n o c h e m i s t r y 167 L e c t i n l e s s soybean lines 513 L e c t i n - r e c e p t o r - c o m p l e x e s 583 Legume lectins 573 Lens c u l i n a r i s lectin 63, 303, 573 Lentil lectin, see LCA L e u c o c y t e s 361 L e u k a e m i a 213 Liver (rat) 179 Limulus polyphemus lectin 63 Lima bean lectin 45 Linear contact assay 63 L i p o p o l y s a c c h a r i d e (LPS) 539 L o c a l i z a t i o n 611 Lotus lectin 573 Lotus tetragonolobus a g g l u t i n i n 335, 573 L - P H A 611 LTA see Lotus T e t r a g o n o l o b u s agglutinin L e u k a e m i a 225 L y m p h o c y t e a c t i v a t i o n 235 L y m p h o c y t e d i s o r d e r s 225 L y m p h o c y t e lectin 443 L y m p o c y t e - m e d i a t e d cytotoxic lysis 55 L y m p h o c y t e - t a r g e t cell c o n j u g a t i o n 55 L y m p h o c y t e s 45, 55, 231, 235, 443 L y m p h o k i n e s 37 Lysis 55 L y s o s o m o t r o p i c 73 M o d e c c i n 293 M a d u r a a u r a n t i a c a 303 M a c r o p h a g e assay 435 M a c r o p h a g e lectin 435 M a c r o p h a g e s 427, 435 Major h i s t o c o m p a t i b i l i t y complex (MHC) 55
M a m m a r y c a r c i n o m a s 145 M a m m a r y gland 105 M a m m a r y tumors 105, 119, 131, 157 Mannose r e s i s t a n t h a e m a g g l u tination 479 Mannose sensitive h a e m a g g l u tination 479 M a r m o s e t l y m p h o c y t e s 443 Membrane g l y c o p r o t e i n s 303, 387 Membrane lectins 427, 435, 443 M i c r o c l u s t e r i n g 55 M i c r o g l i a l 179 M i c r o h e t e r o g e n e i t y 361, 387 M i c r o p i n o c y t o s i s 469 Milk fat g l o b u l e s 105, 157 M i s t e l t o e lectin 179, 645 M i t o g e n m e c h a n i s m 37 M i t o g e n i c lectins 55, 293 M o m o r d i c a c h a r a n t i n 293 Monkey lymphocyte lectin 443 M o n o c l o n a l antibody 243, 275 M o n o c y t e s , human 243 M o n o c y t e s , m a r k e r 235 M o n o s a c c h a r i d e s 63 Motility 179 Mouse embryo 63 MPL 263 MRHA, see m a n n o s e resistant haemagglutination MSHA, see m a n n o s e sensitive haemagglutination M u c i n - l i k e 479 M u c u s 479 N e p h e l o m e t r y 405 N e p h r o n 205 Nervous tissue 179 N e u r a m i n i c acid specific lectin 443 N e u r a m i n i d a s e , see sialidase N i t r o g e n - f i x i n g 513 Nodulating 513 N o n - m i t o g e n i c lectins 55 N o n - s p e c i f i c esterase stain 243 O n o n i s spinosa 293 Oocyte lectin 453
709 P r o c e s s i n g , l e c t i n 539, 603 Postsynthetic modification 603 PA-1 235 PA-2 235, 263, 427 P A - 3 235, 263 PA-4 235, 243 PA-5 235 P e a l e c t i n 521, 531, 603 P e a root l e c t i n 549 P e a seed l e c t i n 549 P e a n u t a g g l u t i n i n , see PNA P e r c a f l u v i a t i l i s 293 P e r c a f l u v i a t i l i s l e c t i n 453 Peroxidase labelled rabbit a n t i b o d i e s 145 Peroxidase labelled lectins 87, 119, 131, 157, 179, 213, 405 P e r s e a g r a t i s s i m a l e c t i n 405 P e t r o m y z o n m a r i n u s 461 PHA 17, 27, 55, 293, 405, 573 P h a g o c y t o s i s 435 P h a s e o l u s 611 P h a s e o l u s c o c c i n e u s 293, 371 P h a s e o l u s l u n a t u s 293 P h a s e o l u s l u n a t u s l e c t i n 573 P h a s e o l u s v u l g a r i s 303, 559 Phaseolus vulgaris agglutinin see PHA P h a s e o l u s v a l p a n i s e e d s 611 P h e n o l o x i d a s e s 629 P h o s p h o l i p i d m e t a b o l i s m 45 P h y s i o l o g i c a l f u n c t i o n 583 P h y t o h a e m a g g l u t i n i n 405 Phytolacca americana polys a c c h a r i d e 243, 427 Phytolacca americana lectins 235, 243, 263, 427 Pili 479, 521 P i n o c y t o s i s 73 P i s u m - r o o t s 521 P i s u m s a t i v u m 293 P i s u m s a t i v u m lectin 573 P l a s m a m e m b r a n e liver cell 179 Plasmid mediated a g g l u t i n a t i o n 479 P l a t e l e t g l y c o p r o t e i n s 303 P l a t e l e t s 303 PNA 55, 63, 87, 105, 119, 131, 145, 157, 167, 205, 243, 263, 275, 283, 303, 327, 415, 623
Pokeweed lectin 235, 243, 263, 427 Pokeweed mitogen 235, 415, 427 P o l y s a c c h a r i d e 427, 639 Post-translational cleavage 603 P o t a t o l e c t i n 5 8 3 , 629 P r e c u r s o r 461, 593, 603 P r e c i p i t i n r e a c t i o n 639 P r o g e s t e r o n e r e c e p t o r 131 P r o s t a t e 371 P r o t e a s e s 361 P r o t e i n b o d i e s 559, 593, 611 P r o t e i n A 27, 189, 283 PSA 335 Pseudomonas aeruginosa l e c t i n s 495 PWM, see p o k e w e e d m i t o g e n Q u a n t i t a t i o n of cell s p r e a d i n g 63 R a d i a l i m m u n o d i f f u s i o n 559 Rat 327 Rat m a m m a r y c a r c i n o m a s 145 RCA-1 63, 131, 167, 335, 405, 415 Receptor characterisation 55, 179 R e c e p t o r - c o m p l e x 583 R e c e p t o r - m e d i a t e d 73 R e c e p t o r m e g a t h e r a p y 479 R e c o g n i t i o n 3, 521, 583 R e c o g n i t i o n m o l e c u l e s 461 Red b l o o d c e l l s 189 Red cell g h o s t s 623 R e j e c t i o n 17 Reversible binding 3 Rh. l e g u m i n o s a r u m , m a n n o s e s p e c i f i c a g g l u t i n i n 521 R h i z o b i a l a g g l u t i n i n 521 R h i z o b i u m 513, 539 R h i z o b i u m l e g u m i n o s a r u m 531, 521 R h i z o b i u m p h a s e o l i 531 R h i z o b i u m r e c o g n i t i o n 513 R h o d a m i n e l a b e l l e d 519, 213 R i c i n 17, 120, 179, 189, 263, 293, 405, 479 R i c i n u s c o m m u n i s 593, 611 Ricinus communis agglutinin 189 R i c i n u s c o m m u n i s l e c t i n 573, 303
710
Robinia pseudoacacia 293 Rutilus rutilus 293 Rye lectin S Q parameter 461 Sarothamnus scoparius 293 SBA 55, 63, 87, 105, 205, 263, 327, 405, 415, 559 Scanning electron microscopy 539 Scatchard analysis 73, 213 Screening for lectins 513 Sea lamprey 461 Seed coat 559 Seminal plasma 371 Serum factor 435 Sialic acid 479, 435, 311 Sialic acid specific lectin 443 Sialidase 73, 145, 157, 167, 179, 189, 205, 213, 225, 283, 303, 311, 435 SJ-11 263 Skin allografts 17 Solanaceous lectins 583 Solid phase lectin sandwich enzymossay 405 Sophora japónica lectin 573 Sophora lectin 573 Soybean agglutinin, see SBA Specificity 623 Spectral properties 629 Spermatid differentiation 327 Spermatogenesis 327 Sphenostylis stenocarpa 639 STA 583 Standardization of electrophoresis 397 Stimulation index 293 Stingray 461 Storage proteins 593 Structural homology 461 Subpopulations 263 Subset 275 Subunits 611 Subunits, leguminous lectins 603 Succinyl concanavalin A 397 Sugar-binding 3 Sugar-specific enzymes 3 Surface-associated lectin 311 Surface glycoprotein 225 Surface receptors 55 Surfaces cell 311
Symbiosis 513, 521, 539 Synthesis, lectin 539, 593, 603 Synthesis 235 Tamoxifen 145 Target cells 55 T cell growth factor 37 TCGF 37 Thomsen-Friedenrich antigen 105 Thymocytes 263 Thymocytes subsets 263 Thymus development 275 Tissue extracts 405 T lymphocyte differentiation 283 T lymphocytes 37, 55, 293 Tolerance 17 Toxic activity 293 Toxicity 293 Transplantation 17 Transport 593 Trifoliin A 521 Trifolium repens 539 Triticeae 583 Triticum vulgare 293 Trypsin 361 Tunicate lectin 461 Tunicates Tumor induction 145 Tumors 105 Two-chain lectins 603 UEA 87, 131, 167, 205, 335, 415 UEA-1 63 Ulex europaeus 293, 573 Ulex lectin 573 Urinary tract infection 503 Vaccines 479 Vascular endothelia 131 Vectorial translation 593 VFA 335 Vicia cracca 293 Vicia hirsuta seed 539 Vicia sativa 293 Vicia villose 293 Vigna catiang endl. varis sinensis 371 Vigna lectin 573 Vigna radiate lectin 573
Viscum album 179 Vitellogenesis 469 von Willebrand factor 303 WGA 55, 63, 73, 87, 131, 167, 189, 205, 263, 303, 311, 319, 327, 335, 387, 405, 415, 479, 539, 583, 593 Wheat germ agglutinin, see WGA Wistaria floribunda 293 Wistaria floribunda agglutinin 73, 573 Wistaris brachbotrys sied, et zucc. 371 Yolk formation 469 Zajdela hepatoma 73
G
Walter de Gruyter Berlin-New York
Bog-Hansen
Lectins
w DE
(Editor)
Biology, Biochemistry, Clinical Biochemistry Volume 1 Proceedings of the Third Lectin Meeting, Copenhagen, June 1980 1981.17 cm x 24 cm. XII, 418 pages with figures and tables. Hardcover. DM 120,-; approx. US $60.00 ISBN 311 008483 X
Bog-Hansen (Editor)
Lectins Biology, Biochemistry, Clinical Biochemistry Volume 2 Proceedings of the Fourth Lectin Meeting, Copenhagen, June 8-12,1981 1982.17 cm x 24 cm. XVI, 801 pages. Numerous figures and tables. Hardcover. DM 248,-; approx. US $124.00 ISBN 3110086808
Scott Brewer (Edltors)
Concise Encyclopedia Q f Biochemistry 1983.14,0 cm x 21,5 cm. VI, 519 pages. Approx. 650 illustrations. Hardcover DM 59,-; US $29.90 ISBN 3110078600 Prices are s u b j e c t t o c h a n g e w i t h o u t n o t i c e