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German Pages 450 [452] Year 1986
Biological Properties of Peptidoglycan
Biological Properties of Peptidoglycan Proceedings Second International Workshop Munich, Federal Republic of Germany May 20-21,1985
Editors PH. Seidl • K H . Schleifer
W DE G Walter de Gruyter • Berlin • New York 1986
Editors
Peter H. Seidl, Dr. rer. nat. Karl Heinz Schleifer, Prof. Dr. rer. nat. Lehrstuhl für Mikrobiologie Technische Universität München Arcisstraße 21 D-8000 München 2 Federal Republic of Germany
Biological properties of peptidoglycan. „Second International Workshop on the Biological Properties of Peptidoglycan"--Pref. Includes bibliographies and indexes. I. Peptidoglycans-Congresses. I. Seidl, R H. (Peter H.), 1948 II. Schleifer, Karl H. III. International Workshop on the Biological Properties of Peptidoglycan (2nd : 1985 : Munich, Germany) [DNLM: 1. Peptidoglycan-congresses. QW 52 B6138 1985] QP702.P47B56 1986 616.07'9 86-19791 ISBN 0-89925-262-1 (U.S.)
CIP-Kurztitelaufnahme
der Deutschen
Bibliothek
Biological properties of peptidoglycan : proceedings, 2. internat, workshop, Munich, Fed. Republic of Germany, May 20-21,1985 / [2. Internat. Workshop on the Biolog. Properties of Peptidoglycan]. Ed. P H. Seidl ; K. H. Schleifer. Berlin ; New York : de Gruyter, 1986. ISBN 3-11-010737-6 NE: Seidl, Peter H. [Hrsg.]; International Workshop on the Biological Properties of Peptidoglycan
Copyright © 1986 by Walter de Gruyter & Co., Berlin 30. All rights reserved, including those of translation into foreign languages. No part of this book may be reproduced in any form - by photoprint, microfilm or any other means nor transmitted nor translated into a machine language without written permission from the publisher. Printing: Gerike G m b H , Berlin. - Binding: D. Mikolai, Berlin. - Printed in Germany.
PREFACE This book is based on the lectures presented at the "Second International Workshop on the Biological Properties of Peptidoglycan" in Munich from May 20 to 21, 1985. The aim of this workshop was to summarize the current state of knowledge and to demonstrate the manifold progress made since the first workshop held on this topic in 1974. Included in this book are contributions from various scientific disciplines, covering such fields as immunology, pathology, microbiology, medicine, preparative organic chemistry, ultrastructure and tumor research. Some of the data presented at the workshop will indeed result in diagnostic as well as therapeutic application. Determining antibodies to peptidoglycan may be useful in the diagnosis of bacterial infections and 'MDP drugs' could be helpful as adjuvants for veterinary and human vaccines and as anticancer, antitumor and antiparasitic agents. Besides the applied aspect, numerous papers enable us to understand the biology of peptidoglycan in more detail. Such presentations as the description of soluble peptidoglycan as the natural immunogen may lead to a better understanding of the mechanism of immunogenicity of peptidoglycan. The elegant elucidation of the induction of slow wave sleep by muramyl peptides was one of the highlights of this workshop. We would like to express our gratitude to the Deutsche Forschungsgemeinschaft for its financial support and to the Carl Friedrich von Siemens Stiftung for its hospitality. Furthermore, the success of our workshop is mainly due to the excellent presentations of the participants and we thank all authors for their contributions. To the publisher we convey our thanks for good co-operation in publishing these proceedings so rapidly. Finally we are grateful to all our colleagues, in particular to B. Heymer, for their help in organizing the workshop and/or in the realization of the proceedings. Munich, June 1986
P.H. Seidl K.H. Schleifer
SPONSORS
Bayer AG, 5090 Leverkusen, FRG Behringwerke AG, 3550 Marburg, FRG Biotest Pharma GmbH, 6000 Frankfurt, FRG Boehringer Ingelheim Diagnostica, 8046 Garching b. München, FRG Boehringer Mannheim GmbH, 6800 Mannheim, FRG Carl Friedrich von Siemens Stiftung, 8000 München, FRG Ciba-Geigy GmbH, 7867 Wehr/Baden, FRG Deutsche Forschungsgemeinschaft, 5300 Bonn, FRG Deutsche Gesellschaft für Hygiene und Mikrobiologie e.V., FRG Dr. Karl Thomae GmbH, 7 950 Biberach an der Riss, FRG Heinrich Mack Nachf., 7918 Illertissen, FRG Luitpold-Werk München, 8000 München, FRG
CONTENTS
I. STRUCTURAL ASPECTS, IMMUNOCHEMISTRY OF PEPTIDOGLYCAN AND ANTIBODIES TO PEPTIDOGLYCAN Structure and Immunochemistry of Peptidoglycan P.H. Seidl, K.H. Schleifer The Diagnostic Value of Antibodies to Peptidoglycan and other Staphylococcus aureus Antigens in Serious Staphylococcal Infections B. Christensson
21
On the Relationships between Conformational and Biological Properties of Murein H. Labischinski, L. Johannsen
37
A Three-Dimensional Model of Peptidoglycan Corresponding with the Results of X-Ray and Electron Diffraction, High Resolution Electron Microscopy and the Properties of Peptidoglycan H. Formanek
43
Structure Determination of Peptidoglycans by Fast Atom Bombardment Mass Spectrometry S.A. Martin, K. Biemann, R.S. Rosenthal
49
The Peptidoglycan and Linked Polymers of the Unicellular Cyanobacterium Synechocystis PCC 6714 U.J. Jürgens, J. Weckesser
55
Chemical and Immunochemical Studies on the in vivo and in vitro Degradation of Peptidoglycan Subunits and Cell Wall Complexes in Relation to Inflammatory Diseases A. Fox, J. Gilbart, J. Harrison, G. Pararajasegaram, A. Wells, M. Hammer, C.H. Yang, Y. Ishikawa, R. Whiton, S.L. Morgan
61
Specific Immunoglobulin E Antibodies to Peptidoglycan? J. Seidl, P.H. Seidl, K.H. Schleifer
67
Specific Immunoglobulin G Antibodies in Man against the Glycan Strand of Peptidoglycan E. Zauner, S. Reissenweber, G. Leitherer, K.H. Schleifer P.H. Seidl
75
X Release of Penicillin-Binding Proteins from ß-Lactam Treated Bacteria: Determination by Anti-ß-Lactam Antibodies R. Hakenbeck, H. Ellerbrok, T. Briese, N.F. Adkinson
83
Anti-Peptidoglycan Serology in Patient Sera and Experimental Production of Anti-Peptidoglycan Antibody by Immunisation with Rheumatoid Factor H.B. Evans, K.K. Phua, P.M. Johnson
89
Antibodies against a Synthetic Peptidoglycan-Precursor Pentapeptide Containing Lysine Cross-React with Soluble Peptidoglycan Containing Diaminopimelic Acid A.R. Zeiger
95
Antibodies to Various Bacterial Cell Wall Peptidoglycans in Patient Sera and in Rabbit Sera H.I. Wergeland, C. Endresen
99
Antibodies to the Pentapeptide Subunit of Peptidoglycan in Human Sera T. Kuchenbauer, K.-D. Tympner, P.H. Seidl, K.H. Schleifer
105
Problems with 'Teichoic Acid" Antigen Used in Staphylococcus aureus Serology Ch. Herzog, V. Just, R. Berger, M. Just
113
Lipid A Antibodies in Man W. Marget, P. Mar, H. Haslberger, M. Huber
121
Electron Microscopic Localization of Peptidoglycan in the Cell Wall of Streptococcus pyogenes by Means of Labelled Antibodies and Lysozyme M. Wagner, M. Rye, B. Wagner
129
Immunoelectron' Microscopic Studies on Peptidoglycan from Gram Positive Bacteria: Specific Reactions with the Glycan Moiety, the Pentapeptide Subunit and the Interpeptide Bridge N. Franken, J.R. Golecki, P.H. Seidl, P. Zwerenz K.H. Schleifer
135
XI
II. DEGRADATION OF PEPTIDOGLYCAN, PEPTIDOGLYCANLIKE PRODUCTS IN THE HOST Soluble Peptidoglycans: Lymphocyte-Activating Bacterial Products Found in Man A.R. Zeiger
145
How Are Cell-Wall Components of Pathogenic Microorganisms Degraded in Infectious and Inflammatory Sites?: Facts and Myths I. Ginsburg
167
State of Peptidoglycan in Spheroplasts of Proteus mirabilis grown in the Presence of Different BLactam-Antibiotics K. Huber, H.H. Martin
187
Degradability by Lysozyme of Staphylococcal Cell Walls as a Function of O-Acetyl Groups H. Labischinski, P. Giesbrecht
191
O-Acetylation of Staphylococcal Cell Walls as an Important Factor for their Degradability Within Bone Marrow-Derived Macrophages J. Wecke, E. Kwa, L. Johannsen, P. Giesbrecht, M. Lahav, I. Ginsburg
197
Metabolic Fate of Peptidoglycan Monomer from Brevibacterium divaricatum and Biological Activity of its Metabolites J. Tomasic, Z. Valinger, I. Hrsak, B. Ladesife
203
Determination of the Size Distribution of the Glycan Strands Released from Murein of E. coli by Human Serum Amidase H. Ludewitz, J.-V. Holtje
209
Endogenous Induction of Bacterial Lysis by Cloned PhiX17 4 Gene E Product U. Blasi, R.E. Harkness, A. Witte, G. Halfmann, W. Lubitz
215
Radioimmunoassays for the Selective Detection of the Glycan Moiety and the Pentapeptide Subunit in Secreted Peptidoglycans P. Zwerenz, F. Hagen, G. Leitherer, P.H. Seidl, K.H. Schleifer
221
XII
III. ACTION OF PEPTIDOGLYCAN ON CELLS Effects of Peptidoglycan on the Cellular Components of the Immune System R. Dziarski Suboptimal Concentrations of LPS are Necessary for in vitro Activation of Rat Alveolar Macrophages by Muramylpeptides J.-P. Tenu, J.-F. Petit, D. Nolibe Antiviral and Antitumor Effects of Liposome-Entrapped MTP-PE, a Lipophilic Muramylpeptide G. Schumann Effects of Staphylococcal Peptidoglycan on Phagocytic Cells and Host Mediation Systems A. Fleer, F.C.A. Jaspers, J. Verhoef Cellular Response to Streptococcal Peptidoglycan and Tetanus Toxoid in Glomerulonephritis-Patients: Correlation to Complement Genotype H.E. Feucht, G.J. O'Neill, G. Riethmüller, A. Brase, P.H. Seidl IV. DIVERSE BIOLOGICAL ACTIVITIES OF PEPTIDOGLYCAN Acute and Chronic Inflammation Induced by Peptidoglycan Structures and Polysaccharide Complexes S.A. Stimpson, J.H. Schwab, M.J. Janusz, S.K. Anderle R.R-. Brown, W.J. Cromartie Biological Activity of Peptidoglycan in Man B. Heymer, J. v. Mayenburg Pathomechanisms of Peptidoglycan in Man J. v. Mayenburg, B. Heymer Role of Peptidoglycan in Gonococcal Arthritis R.S. Rosenthal, F.R. Montoya, W. Nogami, T.J. Fleming Teichoic Acid-Free Peptidoglycan of Staphylococcus aureus RM 5 9 Does Not Activate Complement M. Loos, P.H. Seidl, K.H. Schleifer
XIII
Somnogenic Muramyl Peptides J.M. Krueger
329
Synthetic Lipopeptide Analogues of PeptidoglycanAssociated Lipoprotein Are Potent Novel B-Lymphocyte Mitogens W.O. Bessler, B. Kleine, M. Cox, A. Lex, B. Suhr, K.-H. Wiesmüller, G. Jung, C. Martinez-Alonso
335
GUEST LECTURE Lipid A, the Endotoxic Principle of Bacterial Lipopolysaccharides: Chemical Structure and Biological Activity E.Th. Rietschel, H. Brade, L. Brade, K. Kawahara, Th. Liideritz, U. Schade, A. Tacken, U. Zahringer
341
V. ADJUVANT ACTIVITY AND IMMUNOMODULATION BY PEPTIDOGLYCAN Macrophage Activation by Muramyl Peptides M. Parant, L. Chedid ~
353
Immunomodulation by Muramyldipeptide (MDP) H. Finger, C.H. Wirsing von Koenig
371
Disaccharide MDP Analogs, Preparation and Some Biological Properties M. Zaoral, J. Farkas, M. Ledvina, J. Jezek, J. Rotta, M. Rye
379
Biological Activity of Synthetic Disaccharide-Peptide Analogues of Peptidoglycan M. Rye, J. Rotta,^R. Straka, M. Zaoral, J. Farkas, M. Ledvina, J. Jezek, J. Pekarek
383
Enzymatic Obtention of Biologically Active Glycopeptides from Actinomadura R 39 M. Guinand, P. Morel, M.J. Vacheron, G. Michel, P. Dupassieu, D. Yavordios
389
Adjuvant Active Peptidoglycans Induce the Secretion of a Cytotoxic Factor by Macrophages F. Vacheron, M. Guenounou, C. Nauciel
395
Stimulation of Nonspecific Resistance Against Aerogenic Viral and Bacterial Infections by Muramyl Dipeptide Combined with Trehalose Dimycolate K.H. Masihi, W. Brehmer, W. Lange
401
XIV Increased Adjuvant Activity of MDP by Direct Coupling of MDP to the Immunogen M. Jolivet, F. Audibert, L. Chedid, E.R. Clough
407
Contributors and Participants
413
Author Index
421
Subject Index
423
STRUCTURE AND IMMUNOCHEMISTRY OF PEPTIDOGLYCAN
Peter H. Seidl, Karl Heinz Schleifer Lehrstuhl für Mikrobiologie, Technische Universität München, D-8000 München 2, FRG
I. Structure of Peptidoglycan Peptidoglycan (murein, mucopeptide), the main cell wall polymer of eubacteria, is common to both Gram-positive and Gram-negative bacteria. Only a few prokaryotic organisms such as the Mycoplasmatales and archaebacteria lack peptidoglycan. Chemically, it is a heteropolymer consisting of glycan strands cross-linked through short peptides (Fig. 1). Investigations of the chemical structure of peptidoglycans from numerous bacterial strains demonstrated the
GlcNAc -p-1,4—Mur NAc-p -1,4 Fig. 1. Scheme of the primary structure of peptidoglycan. Unusual abbreviations: MurNAc, N-acetylmuramic acid; DA, diamino acid. Substituents in brackets may be missing.
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
2 existence of almost 100 different peptidoglycan types (1,2). The glycan moiety of the various peptidoglycans is rather uniform and reveals only a few variations such as acetylation or phosphorylation of the muramyl-6-hydroxyl groups, the occasional absence of N-acetyl substitution or lacking of part of the peptide substituents. In some mycobacteria and nocardiae, the N-acetyl group of muramic acid is oxidized to give an N-glycolyl-residue. The number of chemically different amino acids occurring in a particular peptidoglycan is restricted to three to six. Peptidoglycan does not contain branched amino acids, aromatic amino acids, cysteine, methionine, arginine, histidine and proline. The stem peptide or peptide subunit linked to the carboxyl group of muramic acid always consists of alternating L- and D-amino acids. Depending on the mode of crosslinking, two main groups of peptidoglycan named A and B, have been distinguished (1). The crosslinkage of Group A peptidoglycans extends from the distal amino group of the diamino acid in position 3 of one stem peptide to the carboxyl group of D-alanine in position 4' of an adjacent stem peptide either directly or via an interpeptide bridge (Fig. 1). Peptidoglycans of Group B are characterized by a crosslinkage between the «.-carboxyl group of D-glutamic acid in position 2 in one stem peptide and the C-terminal D-alanine in position 4' of an adjacent stem peptide. There is always a diamino acid necessary in the interpeptide bridge since two carboxyl groups must be crosslinked. Group B peptidoglycans are rather rare and are only found in some coryneform bacteria and in a few anaerobic organisms (2). The peptidoglycan of Gram-negative bacteria is rather uniform. It usually forms a monomolecular layer and is directly crosslinked. In most cases meso-diaminopimelic acid is present as the diamino acid in position 3 of the stem peptide, but a few exceptions are known. The peptidoglycan of spirochaetes often contains ornithine instead of diaminopimelic acid (3,4) among some fusobacteria, mesodiaminopimelic acid is replaced by its sulphur analogue meso-lanthionine (5). Gram-positive bacteria contain a multilayered peptidoglycan and reveal a great variation in the composition and primary structure of the constituent peptide moiety. Various peptidoglycan types can be distinguished, depending on the different amino acid sequence of the stem peptide and/or the interpeptide bridge (for review, see 1,2).
3 The amino acid sequence of the stem peptide shows some variation among the different peptidoglycans (Fig. 2). The amino acids in parantheses may replace the corresponding amino acids or substituents. The greatest variation is found in position 3. To date, 11 different amino acids have been detected in this position, mesodiaminopimelic acid and lysine are the most common ones (for review, see 1,2). Position 4 is occupied by D-alanine. The carboxyl group of this D-alanine is often blocked by crosslinkage to an adjacent stem peptide. In non-crosslinked stem peptides the D-alanine in position 4 may be split off or substituted by another D-alanine; the latter D-alanine represents a remnant of the peptidoglycan precursor. Regarding the biological properties of peptidoglycan, one should keep in mind that the structure of peptidoglycan is not as regularly as depicted in the scheme of Fig. 1. Several enzymes of the bacterial cell may split bonds in the peptidoglycan (6). Glucosaminidases and muraminidases split glycosidic linkages in the glycan strand; amidases may split the linkage between muramic acid and L-alanine in position 1 of the peptide subunit, thus leading to muramic acid residues with a free carboxyl group; endopeptidases may split linkages in the stem peptide or in the interpeptide
IJUR 1 2 3
L-ALA (3-HYG)
(GLY,L-SER)
D - G L U — * N H M-A2PM |
A
D-ALA
5
D-ALA
2
(GLY,GLYNH2,D-ALANH2,
(L-LYS,L-0RN,LL-A2PM,
CADAVERINE)
M-HYA2PM
L-DAB,L-HYL,L-HSR,L-ALA,L-GLU,L-LAN)
Fig. 2. Variations of the stem peptide (peptide subunit). Amino acids in parentheses may replace the corresponding amino acids or substituents. Unusual abbreviations: A2pm, 2,6-diaminopimelic acid; Dab, diaminobutyric acid; HyA2pm, 2,6-diamino-3-hydroxypimelic acid; Hyg, threo-B-hydroxyglutamic acid; L-Hyl, L-hydroxylysine; Hsr, homoserine; Lan, lanthionine.
4 bridge, causing additional free amino groups and carboxyl groups; D,D-carboxypeptidases may split off the D-alanine in position 5 of the peptide subunit and L,D-carboxypeptidases may split off the D-alanine in position 4. Strains lacking carboxypeptidases, such as many staphylococci and streptococci, reveal up to 20 per cent of the stem peptides as non-crosslinked pentapeptide subunits with a C-terminal D-alanyl-D-alanine.
II. Immunochemistry of Peptidoglycan Cell wall peptidoglycan is immunogenic. Up to date, at least five main antigenic epitopes (Fig. 3) of peptidoglycan have been discovered (7) that is a) the glycan strand, b) and c) N-terminal and
Fig. 3. Schematic representation of the five antigenic epitopes of peptidoglycan: a) the glycan strand; b) N-terminal and c) Cterminal sequences of the interpeptide bridge; d) the noncrosslinked peptide subunit tetrapeptide; e) the non-crosslinked peptide subunit pentapeptide.JT: endopeptidases splitting glycyl-glycine bindings.
5
C-terminal sequences of the interpeptide bridge, d) the non-crosslinked tetrapeptide subunit, and e) the non-crosslinked pentapeptide subunit. In man, specific antibodies to the glycan moiety, to the tetrapeptide subunit and to the pentapeptide subunit have been hitherto detected. 1. Antigenic properties of the glycan moiety The findings on the immunological properties of the glycan strand are summarized in Table 1. Early studies by Karakawa and Krause (8) on the antigenic properties of peptidoglycan indicated that the hexosamine polymer of peptidoglycan was a main antigenic epitope. Rolicka and Park (9) demonstrated that antibodies against the glycan strand recognized acetylglucosamine and not acetylmuramic acid, whereas Wikler (10), investigating antisera to Micrococcus luteus, claimed that acetylmuramic acid and not acetylglucosamine was the immunodominant sugar. Schleifer and Seidl (11) were finally able to resolve this controversy. A glycan strand specific antibody population directed to acetylglucosamine and a po-
ANTIGENIC PROPERTIES OF THE GLYCAN STRAND
GLCNAC
IMMUNODOMINANT;
CROSS-REACTIVITY
BE-
KARAKAWA ET AL.
1967
SPECIFIC ANTIBODIES TO MDP:
TWEEN A-POLYSACCHARIDE AND
REICHERT ET AL.
1980
A) MDP CONJUGATED TO
PEPTIDOGLYCAN
CARRIERS VIA GLUTAMIC GLCNAC AND NOT MURNAC
ROLICKA AND PARK.
IMMUNODOMINANT
1969
MURNAC AND NOT GLCNAC
WIKLER
IMMUNODOMINANT
1975
ANTIBODY
POPULATIONS
TO GLCNAC AND MURNAC
ACID B) MDP CONJUGATED TO CARRIERS VIA ANOMERIC C-L CARBON ATOM OF MURNAC
SCHLEIFER AND SEIDL,
1977
AS DETERMINANT SUGARS
SPECIFIC ANTIBODIES TO
SEIDL ET AL.,
THE GLYCAN MOIETY IN
ZAUNER ET AL.
MDP DOES NOT BIND TO
AUDIBERT ET AL.
HUMAN SERA; ANTIBODY
ANTIBODIES AGAINST
1978
COMBINING SITE AT LEAST
PEPTIDOGLYCAN
(GLCNAC-MURNAC), 2
Table 1. Antigenic properties of the glycan strand
.1985
6 pulation directed to acetylmuramic acid were found in the same antiserum . The occurrence of antibodies to the glycan strand led to the question whether the synthetic immunoadjuvant MDP would bind to such antibodies or not. An answer to this question might indicate whether reactivity of MDP with natural occurring peptidoglycan antibodies could induce clinical hazards, preventing the application of MDP or its derivatives in man. No binding of radiolabelled MDP to naturally occurring or experimentally induced antibodies was detected (12). This lack of reactivity was surprising since MDP represents part of the monomeric subunit of the peptidoglycan backbone. Although MDP in isolated form was found not to elicit an immune response, it became immunogenic when it war coupled to an appropriate carrier. Conjugates, carrying MDP substituents via the T-carboxyl group of glutamic acid of MDP, or via the anomeric C-1 carbon atom of the N-acetylmuramyl portion of MDP, were prepared (13). Both conjugates were immunogenic and the antibodies reacted with free synthetic MDP. Recently, we developed a Farr-type radioactive hapten binding assay for detecting glycan moiety specific antibodies. As an antigen, we employed low-molecular weight glycopeptides from Bacillus subtilis peptidoglycan. The structural features of the glycopeptides are presented in detail by Zauner et al., this book. It is important that the glycopeptides isolated did not reveal any pentapeptide subunits with C-terminal D-alanyl-D-alanine, and did not contain non-crosslinked tetrapeptide subunits. Thus, it was excluded that antibodies to the tetra- or pentapeptide subunit were detected employing the glycopeptide as an antigen. The glycopeptides were radiolabelled with iodine and binding of the radioactive glycopeptide hapten to animal hyperimmune sera, to human normal sera and to sera from patients was measured. High binding (70-80%) of radioactively labelled glycopeptides was obtained with rabbit reference hyperimmune sera (11) containing high levels of antibodies to the glycan moiety. No binding was achieved, however, to specific antibodies against the peptide moiety of peptidoglycan (14-18), and to antisera against the A-carbohydrate of streptococci, known to be specifically directed against N-acetylglucosamine (19). Specificity of the test system was further examined in appropriate hapten binding inhibition studies (Fig. 4). Besides the
7
homologous glycopeptide, soluble peptidoglycans from various bacterial strains revealing variations in the glycan moiety as O-acetylation (staphylococci) , partial lack of N-acetvlation (bacilli) or peptide substitution (Micrococcus luteus), gave a strong inhibitory effect. The size of the antibody combining site was at least
Fig. 4. Binding inhibition reaction of radio-iodinated glycoDeptides to peptidoglycan antiserum (A-variant streptococcal antiserum. (•) Bacillus subtilis W23 glycopeptide; (o) acetvlchitotetraose; (e) glycan oligosaccharide (GlcNAc-MurNAc)2. Soluble peptidoglycans (MW >10 000) from (•) Bacillus subtilis, (Q} Bacillus licheniformis, Micrococcus luteus, Staphylococcus epidermidis. The following compounds gave no significant inhibition (umin with peptidoglvcans from (•) Micrococcus roseus ATCC 418, (o) M. varians C C M 8 8 3 , and (x) S. aureus H or S. epidermidis ATCC 14990.
10
ration of staphylococci from micrococci (21). Carboxyl terminal oligoglycine sequences of the interpeptide bridges from staphylococci further reveal an independent antigenic epitope of peptidoglycan as was proved using appropriate synthetic protein-peptide conjugates (Fig. 5d). Oligoglycine peptides revealing free carboxyl groups are the product of endopeptidases splitting glycylglycine linkages (22). 3. Antigenic properties of the pentapeptide subunit a) Characterization of animal hyperimmune sera The stem peptide was presumed to be an antigenic epitope of peptidoglycan already in 1968 by Karakawa and Krause (23). Employing a series of synthetic peptides as inhibitors in the quantitative peptidoglycan precipitin reaction, Schleifer and Krause (1971) demonstrated an antibody population with specificity for the pentapeptide subunit in A-variant streptococcal antisera (24). The conclusions drawn from their results are summarized in Table 2. The pentapeptide subunit being an antigenic epitope was consequently corroborated by several approaches using synthetic antigens. Zeiger and Maurer (1973) coupled synthetic pentapeptide subunits to a random alanine/glutamic acid copolymer (25). Schleifer and Seidl 1.
THE
PENTAPEPTIDE
TETRAPEPTIDE TIDE 2.
THE A N T I B O D I E S
THE NANT THE
AND NOT T H E
PREDOMINANTLY
THE A N T I G E N I C
DETERMINANT
OCCURRING OF T H E
PEP-
SUBUNIT
PORTION 3.
IS
OF T H E
C-TERMINAL SITE
ARE
GLUTAMIC
SITE
IS
ACID)
AGAINST
D-ALANYL-D-ALANINE
OF T H E
THE
C-TERMINAL
IS
THE
IMMUNODOMI-
ANTIGEN
CONTRIBUTION
TIGENIC
DIRECTED
PEPTIDE
OF T H E OF
OR
OTHER
LESSER IS
AMINO A C I D S
IMPORTANCE
INSIGNIFICANT
TO T H E
(LYSINE
AN-
AND
(L-ALANINE)
Table 2. Characterization of the pentapeptide subunit as an antigenic epitope of peptidoglycan (24)
11
(1974) synthesized the protein peptide conjugate albumin-(CH2COGly-L-Ala 2 -D-Ala 2 -OH) 39 , carrying peptide substituents with C-terminal D-alanyl-D-alanine; the amino acids L-alanine, D-glutamic acid and L-lysine from the stem peptide were replaced (14). Employing the conjugates synthesized by Zeiger and Maurer (1973) and by Schleifer and Seidl (1974) as an immunogen specific antibodies directed against the peptide substituents were obtained. Monospecific antibodies to the C-terminal D-alanyl-D-alanine moiety of the pentapeptide subunit (14) allowed demonstrating the distribution of pentapeptide subunits in the cell walls of several Gram-positive bacteria (26,27, Franken et al., this book). b) Characterization of human sera Antibodies directed to the pentapeptide subunit of peptidoglycan are frequent in sera from normal blood donors or from patients (28,29). Recently, Franken et al. (1984, 1985) linked tri-D-alanine covalently to albumin via the amino group (18,30) and employed this protein peptide conjugate as an antigen in an ELISA. Specific IgG (18) and IgA class antibodies (30) against the immunodominant D-alanyl-D-alanine moiety of the pentapeptide subunit were detected in human sera. It was furthermore clear from appropriate inhibition studies in the ELISA (Figure 7) or from inhibition of radiolabeled H-L-Ala-D-Glu(L-Lys-D-Ala2-OH)-OH hapten binding (18, 31, Figures 8,9) that human sera also may contain antibodies with exclusive or predominant specificity for the carboxyl-terminal Dalanyl-D-alanine sequence of the pentapeptide subunit, similar as shown for streptococcal hyperimmune sera (24, compare Table 2). The results from the radioactive hapten binding inhibition studies with specific antibodies in human serum 004, depicted in Fig. 9, are of interest for several reasons: 1. In contrast to the strong inhibitory effect of Ac2-L-Lys-D-AlaD-Ala-OH or of tri-D-alanine, oligoglycine peptides or D-AlaGly-OH did not inhibit, thus excluding cross-reactivity between the C-terminal sequences of the interpeptide bridge (16) and the pentapeptide subunit. 2. Ac2~L-Lys-D-Ala-D-Ala-OH and Ac-j-L-Lys-D-Ala-D-lactic acid are both substrates for the penicillin-sensitive D-alanine carboxypeptidases of Bacillus subtilis, Escherichia coli and Staphylo-
12 Gly2-L-Ala-0-Ala2 L-Ala-O-duL-Lys-O-Alaj)
üSerum058
m L-Ala-O-GlulL-Lys-D-Ala) Gly2-L-Ala-D-Ala2 L-Ala-D-öu(U.ys^O-Ala2)
L-Alo-D-GlulL-Lys-D-Alo) ay2-L-Ala-D-Ala2 L-Ala-O-GML-Lys-D-Ala^
L-Ala-O-Glu(L-Lys-O-Ala) 1 10 100 1Ö00 Inhibitor Concentration (umoles/l)
J
o;33 3.3 33 Inhibitor Concentration (umoles/l)
Fig. 7. Inhibition of binding of specific IgG in human sera nos. 004, 058 and 262 to albumin-(D-Ala-D-Ala-D-Ala-OH)g in the ELISA technique, using as inhibitors several peptides: (o) HD-Ala-D-Ala-D-Ala-OH, (x) H-L-Ala-L-Ala-L-Ala-OH, (+) H-L-AlaL-Ala-D-Ala-OH (18). Fig. 8. Inhibition of radiolabelled H-L-Ala-D-Glu(L-Lys-D-Ala-DAla-OH)-OH hapten binding (human sera nos. 004, 058 and 262) by various synthetic inhibitors: (•) H-Gly-Gly-L-Ala-D-Ala-DAla-OH), O H-L-Ala-D-Glu(L-Lvs-D-Ala-D-Ala-OH)-OH, M H-LAla-D-Glu(L-Lys-D-Ala-OH)-OH (18,31) .
Ac2-Lys-D-Ala2 •°D-Ala3 •Penicillin G •Ampicillin
0,33
i-Glv- MDP 3.3 33 Inhibitor Concentration lumoles/l)
Fig. 9. Inhibition of radiolabelled H-L-Ala-D-Glu(LLys-D-Ala-D-Ala-OH)-OH hapten binding (human serum no. 004) by various inhibitors.
13
coccus aureus (32). The ester substrate was hydrolysed faster than the peptide analogue, diacetyl-L-Lys-D-Ala-D-Ala-OH, by the B. subtilis (15-fold) and E. coli (4-fold) carboxypeptidases, no rate acceleration was observed for the S. aureus carboxypeptidase (32). However, in contrast to the strong inhibition found with Ac2-L-Lys-D-Ala-D-Ala-OH, Ac2~L-Lys-D-Ala-Dlactic acid did not react as hapten in the radioimmuno-assay. 3. Due to proposed structural analogy between acyl-D-alanyl-D-alanine and penicillin (32) , we investigated a possible crossreactivity between E-lactam antibiotics and R-D-alanyl-D-alanine and came to the following conclusions: - All 22 penicillins and cephalosporins investigated (Penicillin G and Ampicillin depicted in Fig. 9) bound to antibodies with specificity against D-alanyl-D-alanine. - In general, cephalosporins bound less than penicillins. - An intact B-lactam ring was absolutely necessary for the interaction of the antibiotic with the antibody. A failing or very weak inhibitory effect of penicillin or tri-Dalanine on the binding of radioactive H-L-Ala-D-Glu (L-Lys-D-Ala,,OH)-OH to several human sera led us to studying in detail specificity of human antibodies to the pentapeptide subunit and investigating binding of several iodine labelled synthetic peptides to human sera. Fig. 10 gives some typical examples. As depicted in Fig. 10a, all radioactively labelled peptides employed bound quite similarly to human serum 004. As was already shown from the previous studies (compare Figs. 7-9), this human serum revealed specific antibodies exclusively directed against D-alanyl-D-alanine, similar as described for A-variant streptococcal antisera by Schleifer and Krause, 1971 (24). In contrast, it is evident from Fig. 10b that serum 426 strongly bound the pentapeptide subunit HL-Ala-D-Glu(L-Lys-D-Ala2-OH)-OH and the peptide H-Gly-Gly-L-Lvs-DAla 2 -OH; the peptide H-L-Ala-D-Glu(L-Ala-D-Ala2~OH)-OH revealing L-alanine instead of lysine, or tri-D-alanine inhibited less, thus obviously indicating a dominant role of lysine. On the other hand, serum 019 bound radioactively labelled H-L-AlaD-Glu(L-Lys-D-Ala2-OH)-OH or the peptide L-Ala-Glu(L-Ala-D-Ala2OH)-OH to the same extent, peptides lacking D-glutamic acid inhibited less. The results regarding specificity of antibodies direc-
14
•Ala-D-Glutys-D-Ala +Ala-D-Glu(Ala-D-Ala
O) o c o
1:5-
u)
R120
1:400
dSerum 004 20
40
60
b) Serum 426
c)Senjm019
0 20 40 60 0 20 Hapten Binding Capacity (%)
40
60
Fig. 10. Binding of radioactively labelled synthetic peptides with structural similarity to the pentapeptide subunit to human sera nos. 004, 426 and 019.
ted against the pentapeptide subunit in human sera are summarized in Table 3.
1. FOR SOME HUMAN SERA, ANTIBODIES DIRECTED AGAINST THE PENTAPEPTIDE SUBUNIT REVEAL PREDOMINANT SPECIFICITY FOR D ALANINE AS THE IMMUNODOMINANT GROUP, L-LYSINE AND/OR D GLUTAMIC ACID PLAYING A MINOR ROLE, SIMILAR AS DEMONSTRATED FOR ANIMAL HYPERIMMUNE SERA BY SCHLEIFER AND KRAUSE, 1971 (24). 2. FOR SOME HUMAN SERA, L-LYSINE AND/OR D-GLUTAMIC ACID SIGNIFICANTLY CONTRIBUTE TO THE ANTIGENIC SITE, THE SEQUENCE D-ALANYL-D-ALANINE PLAYING A MINOR ROLE.
Table 3. Specificity of human antibodies directed against the pentapeptide subunit.
15
4. Antigenic properties of the tetrapeptide subunit The tetrapeptide subunit further represents an independent antigenic epitope of peptidoglycan. This was clear from serial radioactive hapten binding studies employing as haptens the radioactivelv labelled tetrapeptide subunit or the pentapeptide subunit. It is obvious from Fig. 11 that serum 033 strongly bound the radiolab e l e d pentapeptide subunit and lacked specific antibodies to the tetrapeptide subunit. Serum 327, on the contrary, strongly bound the radioactively labelled tetrapeptide subunit whereas the pentapeptide subunit was bound less. The final proof for the occurrence of specific antibodies to the tetrapeptide subunit in serum 327 was furnished by appropriate inhibition studies (Fig. 12). The tetrapeptide subunit and C-terminal sequences of the tetrapeptide inhibited strongly, whereas the sequences H-L—Lys-L-Ala or C-terminal sequences of the pentapeptide subunit did not inhibit or only insignificantly. The tetrapeptide from the pseudomurein, H-L-Ala-L-Lys-L-Glu-L-Ala-OH did also not inhibit. Fig. 11
Fig. 12
L-Ala-D-GlulL-Lys-D-Ala) o D-Glu(Lys-D-Ala) a Ac 2 -L-Lys-D-Ala
L-Ala-D-Glu(L-Lys-D-Ala2) ACt-L-Lvs-D-AI»,
0.33
3i3
33
Inhibitor Concentration l(jmoles/l)
0 20 ¿0 60 0 20 40 60 Hapten Binding Capacityfii)
Fig. 11. Binding of radioactively labelled synthetic tetrapeptide subunit (•) or pentapeptide subunit (•) to human sera nos. 033 and 32 7. Fig. 12. Inhibition of radiolabelled tetrapeptide subunit H-L-AlaD-Glu(L-Lys-D-Ala-OH)-OH hapten binding (human serum no. 327) with several synthetic inhibitors.
16
In conclusion, the stem peptide of peptidoglycan reveals at least two main antigenic epitopes, i.e. the pentapeptide subunit and the tetrapeptide subunit. With few exceptions, no cross-reactivity was observed between the tetrapeptide and the pentapeptide of the stem peptide. 5. Immunoglobulin classes involved in the immune response to peptidoglycan Specific antibodies to peptidoglycan have been reported of the IgG
20
30
Elution Volume (ml) Fig. 13. Separation of IgG, IgM and IgA antibodies by the Pharmacia FPLC-system. Two 1-ml samples of serum no. 449, revealing specific immunoglobulins to peptidoglycan sequence R-D-Ala-DAla-OH of the IgG, IgA and IgM classes, respectively, were separated on a Mono Q anion-exchange column (for detail, see (30)). Specific antibodies of the particular immunoglobulin classes were detected by ELISA (18,30).
17
class (18,29,33,37), of the IgA class (29,30,33,36), of the IgM class (29,35-37) and of the IgE class (38). However, only Zeiger et al. (29) and Franken et al. (18,30) employed chemically welldefined antigens thus clearly proving that the immunoglobulin class identified was directed to a sequence of peptidoglycan. Recently, separating the particular immunoglobulin classes by the Pharmacia FPLC chromatography system we could demonstrate in human sera the occurrence of specific IgG, IgM and IgA class antibodies to the same epitope of peptidoglycan (Fig. 13, (30)). Regarding specific immunoglobulin M antibodies reported (35-37) , one should be aware of the fact that unless carefully excluded, all indirect immunoassays may be severely disturbed by the presence of rheumatoid factor. This holds particularly true for sera exhibiting both specific IgG and IgM antibodies to the same antigen. Similarly, reported IgE antibodies with specificity for peptidoglycan may not yet be accepted (Seidl et al., this book). Conclusion The immunochemistry of peptidoglycan in man is rather complex. At least 3 main classes of immunoglobulins may be directed to at least five main antigenic epitopes, with a broad spectrum in particular antigenic specificity. Studying the immunochemistry of peptidoglycan may, however, be useful for understanding the immune response to peptidoglycan in man.
References 1. Schleifer, K.H. and 0. Kandier. 1972. Peptidoglycan types of bacterial cell walls and their taxonomic implications. Bacteriol. Rev. 36, 407-477. 2. Schleifer, K.H. and P.H. Seidl. 1985. In: Chemical Methods in Bacterial Systematics (M. Goodfellow and D.E. Minnikin, eds). Academic Press, London, pp. 201-219. 3. Schleifer, K.H. and R. Joseph. 1973. A directly cross-linked L-ornithine containing peptidoglycan in cell walls of Spirochaeta stenostrepta. FEBS Letters 36, 83-86.
18
4. Yanagihara, Y., K. Kamisango, S. Yasuda, S. Kobayashi, I. Mifuchi, I. Azuma, Y. Yamamura and R.C. Johnson. 1984. Chemical compositions of cell walls and polysaccharide fractions of spirochetes. Microbiol. Immunol. 2_8, 535-544. 5. Vasstrand, E.N., T. Hofstad, C. Endresen and H.B. Jensen. 1979. Demonstration of lanthionine as a natural constituent of the peptidoglycan of Fusobacterium nucleatum Fevl. Infection and Immunity 2J5, 775-780. 6. Rogers, H.J., H.R. Perkins and J.B. Ward. 1980. Microbial cell walls and membranes. Chapman and Hall, London, U.K. 7. Heymer, B., P.H. Seidl and K.H. Schleifer. 1985. Immunochemistry and biological activity of peptidoglycan. In: Immunology of the bacterial cell envelope (Stewart-Tull DES, ed). John Wiley, Chichester, U.K. 8. Karakawa, W.W., H. Lackland and R.M. Krause. 1967. Antigenic properties of the hexosamine polymer of streptococcal mucooeptides. J. Immunol. 99_, 1179-1182. 9. Rolicka, M. and J.D. Park. 1969. Antimucopeptide antibodies and their specificity. J. Immunol. 103, 196-203. 10. Wikler, M. 1975. Isolation and characterization of homogenous rabbit antibodies to Micrococcus lysodeikticus with specificity to the peptidoglycan and to the glucose-N-acetylaminomannuronic polymer. Z. Immun.-Forsch. 148, 193-200. 11. Schleifer, K.H. and P.H. Seidl. 1977. Structure and immunological aspects of peptidoglycans. In: Microbiology (D. Schlesinger, ed). American Society for Microbiology, Washington, 12. Audibert, F., B. Heymer, C. Gross, K.H. Schleifer, P.H. Seidl and L. Chedid. 1978. Absence of binding of MDP, a svnthetic immunoadjuvant, to antipeptidoglycan antibodies. J. Immunol. 121, 1219-1222. 13. Reichert, C.M., C. Carelli, M. Jolivet, F. Audibert, P. Lefrancier and L. Chedid. 1980. Synthesis of conjugates containing N-acetylmuramyl-L-alanyl-D-isoglutaminyl (MDP). Their use as hapten-carrier systems. Mol. Immunol. V7, 357-363. 14. Schleifer, K.H. and P.H. Seidl. 1974. The immunochemistry of peptidoglycan. Antibodies against a synthetic immunogen crossreacting with peptidoglycan. Eur. J. Biochem. 43, 509-519. 15. Seidl, P.H. and K.H. Schleifer. 1975. Immunochemical studies with synthetic immunogens chemically related to peptidoglycan. Z. Immun.-Forsch. 149, 157-164. 16. Seidl, P.H. and K.H. Schleifer. 1977. The immunochemistry of peptidoglycan. Antibodies against a synthetic immunogen crossreacting with an interpeptide bridge of peptidoglycan. Eur. J. Biochem. 74, 353-363.
19
17. Seidl, P.H. and K.H. Schleifer. 1978a. Specific antibodies to the N-termini of the interpeptide bridges of peptidoglycan. Arch. Microbiol. 118, 185-192. 18. Franken, N., P.H. Seidl, E. Zauner, H.J. Kolb, K.H. Schleifer, L. Weiss. 1985. Quantitative determination of human IgG antibodies to the peptide subunit determinant of peptidoglycan by an enzyme-linked immunosorbent assay. Mol. Immunol. 22, 573579. 19. Eichmann, K., D. G. Braun, T. Feizi and R.M. Krause. 1970. The emergence of antibodies with either identical or unrelated individual antigenic specificity during repeated immunizations with streptococcal vaccines. J. Exp. Med. 131, 1169-1189. 20. Seidl, P.H. and K.H. Schleifer. 1979. The immunochemistry of peptidoglycan. Serological detection of a difference in a single N-terminal amino acid. Mol. Immunol. 1_6, 385-388. 21. Seidl, P.H. and K.H. Schleifer. 1978b. Rapid test for the serological separation of staphylococci from micrococci. Appl. Environ. Microbiol. 35_, 479-482. 22. Wadström, T. 1973. Bacteriolytic enzymes from Staphylococcus aureus. Contrib. Microbiol. Immunol. 397-405. 23. Karakawa, W.W., D.G. Braun, H. Lackland and R.M. Krause. 1968. Immunochemical studies on the cross-reactivity between streptococcal and staphylococcal mucopeptide. J. Exp. Med. 128, 325340. 24. Schleifer, K.H. and R.M. Krause. 1971. The immunochemistry of peptidoglycan. The immunodominant site of the peptide subunit and the contribution of each of the amino acids to the binding properties of the peptides. J. Biol. Chem. 246, 986-993. 25. Zeiger, A.R. and P.H. Maurer. 1973. Immunochemistry of a synthetic peptidoglycan-precursor pentapeptide. Biochemistry 12, 3387.-3394 . 26. Seidl, P.H., J.R. Golecki, N. Franken and K.H. Schleifer. 1985. Immunoelectron microscopic studies on the localization of peptidoglycan peptide subunit pentapeptides in bacterial cell walls. Arch. Microbiol. 142, 121-127. 27. Seidl, P.H., P. Zwerenz, J.R. Golecki and K.H. Schleifer. 1985. Streptococcus pyogenes grown under sublethal concentrations of penicillin G accumulates close to the septum pentapeptide subunits of peptidoglycan. FEMS Microbiol. Lett. 30^, 325-329. 28. Heymer, B., K..H. Schleifer, S. Read, J.D. Zabriskie and R.M. Krause. 1976. Detection of antibodies to bacterial cell wall peptidoglycan in human sera. J. Immunol. 117, 23-26. 29. Zeiger, A.R., C.U. Tuazon and J.N. Sheagren. 1981. Antibody levels to bacterial peptidoglycan in human sera during the time course of endocarditis and bacteremic infections caused by Staphylococcus aureus. Infect. Immun. 33^, 795-800.
20 30. Franken, N., P.H. Seidl, T. Kuchenbauer, H.J. Kolb, K.H. Schleifer, L. Weiss and K.-D. Tympner. 1984. Specific immunoglobulin A antibodies to a peptide subunit sequence of bacterial cell wall peptidoglycan. Infect. Immun. £4, 182-187. 31. Heymer, B., D. Bernstein, K.H. Schleifer and R.M. Krause. 1975. A radioactive hapten-binding assay for measuring antibodies to the pentapeptide determinant of peptidoglvcan. J. Immunol. 1J_4, 1191-1196. 32. Rasmussen, J.R. and J.L. Strominger. 1978. Utilization of a depsipeptide substrate for trapping acyl-enzyme intermediates of penicillin-sensitive D-alanine carboxypeptidases. Proc. Natl. Acad. Sei. USA 7j>, 84-88. 33. Helgeland, S.M. and A. Grov. 1971. Immunochemical characterization of staphylococcal and micrococcal mucopeptides. Acta Pathol. Microbiol. Scand. Sect. B, 79, 819-826. 34. Heymer, B., W. Schachenmayr, B. Bültmann, R. Spanel, 0. Haferkamp and W.C. Schmidt. 1973. A latex agglutination test for measuring antibodies to streptococcal mucopeptides. J. Immunol. m , 478-484. 35. Verbrugh, H.H., R. Peters, M. Rozenberg-Arska, P.K. Peterson and J. Verhoef. 1981. Antibodies to cell wall peptidoglycan of Staphylococcus aureus in patients with serious staphylococcal infections. J. Infect. Dis. 144, 1-9. 36. Wilhelm, J.A., L. Matter and K. Schopfer. 1982. IgG, IgA and IgM antibodies to S. aureus purified cell walls (PCW) in normal and infected individuals. Experientia ^8, 1375-1376. 37. Wheat, L.J., B.J. Wilkinson, R.B. Kohler and A.C. White. 1983. Antibody response to peptidoglycan during staphylococcal infections. J. Infect. Dis. 147, 16-22. 38. Schopfer, K., S.D. Douglas and B. Wilkinson. 1980. Immunoglobulin E antibodies against Staphylococcus aureus cell walls in the sera of patients with hyperimmunoglobulinemia E and recurrent staphylococcal infection. Infect. Immun. 27_, 563-568.
THE
DIAGNOSTIC
VALUE
STAPHYLOCOCCUS
OF A N T I B O D I E S
AUREUS
ANTIGENS
TO
PEPTIDOGLYCAN
IN S E R I O U S
AND
OTHER
STAPHYLOCOCCAL
INFEC-
TIONS
B.
Christensson
D e p a r t m e n t of Lund, Sweden
Infectious
Diseases,
University
Hospital,
S-221
85
Introduction Staphylococcus in m o d e r n
aureus
medicine.
ill p a t i e n t s , infections. well
are
The
use
there S.aureus
primary
foci,
to e s t a b l i s h
The
the
When
blood
of S . a u r e u s can be
cultures
antibiotic
treatment,
tic
as w e l l
value,
bacteriological gested,
that
in a n t i b o d y
this
has been
These
and
used for
in
problem
seriously
staphylococcal
joint
prostheses
predisposing
factors
infections
number
patients
of t h e s e
isolation
a valuable
are
negative,
of
infections
as for
(1-4).
community-ac-
often
lack
may
isolation,
are
response
levels by
to
against others
of d i f f e r e n t
have
obvious
be
difficult
complicated
by
still
of t h e b a c t e r i a ,
which
in
can
many
be
serology
seated
due
treatment S.aureus
but
be
to
previous diagnos-
also
been
reflected
teichoic
S.au-
unavailable
It h a s
could
mainly
instances.
can be of
infections,
suspected.
acid
to
sugby
(5),
a but
(6-8). focused
serological
an u n c o m p l i c a t e d
is c e r t a i n l y
complement
staphylococcal
investigations
between
septicemia
deep
opposed
a combination a septicemia
often
staphylococcal
as w h e n
the
fall
present
other
an i n c r e a s i n g
origin
upon bacteriological serology
guish
been
increasing
of e n t r y
vascular
are
bacteremic
septicemia.
and
reus
The
abuse
an
(2).
diagnosis
based
drug
has
quired
devices,
portals
of v a l v u l a r ,
serious
However,
constitute
Intravenous well-known
as i n t r a v e n o u s
achieving
infections
course
upon assays
the
question
can help
of S . a u r e u s
endocarditis
distin-
septicemia
or m e t a s t a t i c
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin • New Y o r k - Printed in Germany
to
whether and
abscesses.
22 This
distinction
cations
require
treatment
and
replacement
Materials Patients
and
important,
often
and
and
is
a more
also
drainage
since
aggressive surgical of d e e p
and
patients
with
these
long-standing
intervention
like
compli-
antibiotic heart
valve
abscesses.
Methods controls
S.aureus endocarditis. Twenty-two to 25 p a t i e n t s w i t h S.aureus The diagendocarditis w e r e i n v e s t i g a t e d in t h e v a r i o u s a s s a y s . nostic c r i t e r i a w e r e e l e v a t e d b o d y t e m p e r a t u r e ( > 3 8 . 5 C) for at l e a s t two d a y s t o g e t h e r w i t h t w o or m o r e p o s i t i v e b l o o d c u l t u r e s . Additionally, the p a t i e n t s d e v e l o p e d c h a n g e s in heart murmurs (n = 1 3 ) , t y p i c a l u l t r a s o u n d e c h o c a r d i o g r a p h i c s i g n s (n = 1 3 ) , s e c o n d a r y m a n i f e s t a t i o n s ( n = 1 6 ) or d i a g n o s i s w a s m a d e at s u r g e r y ( n = 2 ) tricuspid valve or autopsy (n=6). Six of 10 d r u g a d d i c t s h a d i n v o l v e m e n t ; no p a t i e n t s h a d i n f e c t e d p r o s t h e t i c v a l v e s . S.aureus complicated septicemia. The c r i t e r i a of e l e v a t e d body temperature and p o s i t i v e blood cultures among the 10-23 p a t i e n t s i n v e s t i g a t e d w e r e t h e s a m e as for t h e e n d o c a r d i t i s p a t i e n t s , but there w e r e o t h e r w i s e no s i g n s of endocarditis. These patients generally developed s e c o n d a r y i n f e c t i o u s f o c i in the skeleton ( n = 7 ) b u t a l s o d e e p s e a t e d a b s c e s s e s in i n t e r n a l o r g a n s ( n = 5 ) a n d meningitis (n=4). Patients with persistently infected joint p r o s t h e s e s ( n = 7 ) t h a t for s o m e r e a s o n w e r e n o t r e m o v e d or d r a i n e d within a few d a y s w e r e c o n s i d e r e d c o m p l i c a t e d e v e n if m e t a s t a t i c infections did not d e v e l o p . 5.aureus uncomplicated septicemia. This group comprised 14-23 p a t i e n t s and c r i t e r i a of body t e m p e r a t u r e and b l o o d c u l t u r e s w e r e as m e n t i o n e d a b o v e . No i n f e c t i o u s c o m p l i c a t i o n s d e v e l o p e d . When primary foci were p r e s e n t (n=19) they were easily eradicated w i t h i n a few d a y s . T h e s e f o c i w e r e s k i n i n f e c t i o n s ( n = 1 0 ) , i n t r a v e n o u s d e v i c e s (n = 6) a n d o s t e o s y n t h e t i c m a t e r i a l ( n = 3 ) . N o n - S . a u r e u s e n d o c a r d i t i s and s e p t i c e m i a . The d i a g n o s t i c c r i t e r i a of these i n f e c t i o n s w e r e t h e s a m e as for S . a u r e u s endocarditis and septicemia. M o s t of t h e 27 e n d o c a r d i t i s a n d 39 septicemia patients investigated were infected with gram-positive bacteria, mainly s t r e p t o c o c c i and S . e p i d e r m i d i s . In t h e a n t i - a l p h a toxin a s s a y ( s e e b e l o w ) o n l y f o u r a n d 18 p a t i e n t s , respectively, were tested. Febrile controls. When these 63 p a t i e n t s w e r e a d m i t t e d to the hospital, s e p t i c e m i a of u n k n o w n o r i g i n w a s i n i t i a l l y suspected. They w e r e e v e n t u a l l y c o n s i d e r e d as n o n - s e p t i c e m i c w h e n at least two b l o o d c u l t u r e s w e r e n e g a t i v e . Their s u b s e q u e n t d i a g n o s e s w e r e pneumonia (n=23), viral infection (n=18), urinary tract infection (n=8), f e v e r of u n k n o w n o r i g i n ( n = 5 ) , s k i n a b s c e s s ( n = 3 ) a n d o n e p a t i e n t e a c h p r o v e d to h a v e t o x o p l a s m o s i s , m a s t i t i s , c h o l a n g i t i s , pleural empyema, brain abscess and gas g a n g r e n e .
23 H e a l t h y c o n t r o l s I. T h i s g r o u p c o n s i s t e d of 1 6 0 i n d i v i d u a l s w h i c h were divided into d i f f e r e n t age groups. T h e y w e r e a l l h e a l t h y at t h e t i m e of s e r u m s a m p l i n g a n d h a d no p r e v i o u s h i s t o r y of s t a p h y lococcal infection. Healthy monthly
c o n t r o l s II. These 11 individuals s e r u m s a m p l i n g for six m o n t h s .
were
followed
with
Antigens Alpha toxin. S.aureus a l p h a t o x i n f r o m s t r a i n W o o d 46 w a s p u r i f i e d by i o n e x c h a n g e c h r o m a t o g r a p h y , i s o e l e c t r i c f o c u s i n g a n d g e l c h r o m a t o g r a p h y a c c o r d i n g to T h e l e s t a m et al (9) a n d W a d s t r o m and Mollby (10). T h e p u r i t y of t h e p r e p a r a t i o n w a s v e r i f i e d by m e a n s of p o l y a c r y l a m i d e gel e l e c t r o p h o r e s i s and I m m u n o e l e c t r o p h o r e s i s . Peptidoglycan. Peptidoglycan (PG) from two d i f f e r e n t strains, E2371, r i c h in p r o t e i n A ( 1 1 ) , and E1369, protein A deficient (12), was p r e p a r e d by a m o d i f i c a t i o n of t h e m e t h o d of P a r k and Hancock (13) u s i n g t r i c h l o r a c e t i c a c i d and t r y p s i n t r e a t m e n t of whole S.aureus cells. This insoluble preparation was solubilized in three different ways; by u l t r a s o n i c a t i o n (SO-PG), lysozyme t r e a t m e n t ( L Z - P G ) or l y s o s t a p h i n t r e a t m e n t ( L S - P G ) . A l l PG p r e p a rations were investigated in crossed Immunoelectrophoresis against polyspecific rabbit hyperimmune serum against S.aureus c e l l w a l l s . M o r e o v e r , t h e d i f f e r e n t PG p r e p a r a t i o n s w e r e c o m p a r e d by c r o s s e d - l i n e i m m u n o e l e c t r o p h o r e s i s . Crude staphylococcal antigen. Ultrasonication of t h e p r o t e i n A negative s t r a i n W o o d 46 w a s u s e d to p r e p a r e t h e c r u d e staphylococcal a n t i g e n (SA) (14). This preparation was investigated in crossed immunoelectrophoresis against both rabbit hyperimmune serum and h u m a n s e r u m a n d m o r e t h a n 50 different precipitates were obtained. A similar preparation has also been proposed to c o n t a i n t e i c h o i c a c i d , l i p o t e i c h o i c a c i d as w e l l as p e p t i d o g l y c a n (15). Lipase. Purified lipase from S . a u r e u s s t r a i n TEN 5 (16) was p r e p a r e d a c c o r d i n g to t h e m e t h o d s d e s c r i b e d by J u r g e n s et al (17) and J u r g e n s and H u s e r (18) u s i n g a m m o n i u m s u l p h a t e p r e c i p i t a t i o n of t h e c u l t u r e s u p e r n a t a n t , u l t r a f i l t r a t i o n , a d s o r p t i o n on O c t y l Sepharose CL-4B and finally elution with a linear Triton X-100 gradient. T h e p r e p a r a t i o n c o n t a i n e d b o t h t h e 44 kD a n d t h e 4 3 kD lipase, where the l a t t e r p r o b a b l y r e p r e s e n t s the n i c k e d 44 kD e n z y m e . T h e p u r i t y o f t h e l i p a s e p r e p a r a t i o n w a s v e r i f i e d by S D S p o l y a c r y l a m i d e gel e l e c t r o p h o r e s i s , d e t e r m i n a t i o n of e n z y m e a c t i vity and lack of h e m o l y t i c a c t i v i t y , inhibition of catalytic a c t i v i t y by c o r r e s p o n d i n g a n t i s e r u m a n d i m m u n o d i f f u s i o n ( 1 7 - 1 9 ) .
Serological
methods
Radioimmunoassay (RIA). Purified alpha toxin was iodinelabe11ed. d i l u t e d s e r u m a n d l a b e l l e d a n t i g e n in plastic After incubating t u b e s t h e a n t i g e n - a n t i b o d y c o m p l e x e s w e r e p r e c i p i t a t e d by adding an e x c e s s of a S . a u r e u s C o w a n I s u s p e n s i o n , thus utilizing the non-specific ability of p r o t e i n A to b i n d to t h e F c p o r t i o n of
24 IgG. After centrifugation, the r a d i o a c t i v i t y of the bacterial pellet was calculated as c o r r e s p o n d i n g to t h e amount of IgG antibodies against alpha toxin (20). Solid-phase radioimmunoasay (SPRIA). The SA- and the v a r i o u s P G p r e p a r a t i o n s w e r e c o a t e d on p l a s t i c t u b e s , and remaining b i n d i n g sites were b l o c k e d by b o v i n e s e r u m albumin. After incubating d i l u t e d s e r u m , b o u n d s e r u m IgG a n t i b o d i e s w e r e d e t e c t e d by a d d i n g iodinated protein A (14,21,22). Enzyme-linked immunosorbent assay (ELISA). The same p r e p a r a t i o n s as in S P R I A t o g e t h e r w i t h t h e l i p a s e p r e p a r a t i o n w e r e p l a c e d i n t o t h e w e l l s of m i c r o t i t e r p l a t e s . The following s t e p s w e r e according to a m o d i f i c a t i o n of t h e E L I S A of E n g v a l l a n d P e r l m a n n ( 2 3 ) with the a d d i t i o n of b o v i n e s e r u m a l b u m i n , d i l u t e d p a t i e n t s e r u m , a l k a l i n e - p h o s p h a t a s e c o n j u g a t e d a n t i - h u m a n IgG a n d p - n i t r o p h e n y 1 phosphate substrate. T h e a m o u n t of s p e c i f i c s e r u m IgG antibody b o u n d c o r r e s p o n d e d to t h e o p t i c a l d e n s i t y v a l u e m e a s u r e d s p e c t r o p h o t o m e t r i c a l l y after the e n z y m e - s u b s t r a t e reaction (22,24,25). Statistical
analysis
The reproducibility error of t h e m e t h o d single determination Upper limit
o f a n a s s a y w a s e x p r e s s e d as t h e analytical c a l c u l a t e d as t h e s t a n d a r d d e v i a t i o n o f the (22).
normal antibody l e v e l s w e r e s e t at t h e 99 % of t h e v a l u e s in t h e f e b r i l e c o n t r o l g r o u p .
confidence
A s i g n i f i c a n t c h a n g e in a n t i b o d y l e v e l w a s b a s e d u p o n t w o standard deviations of b o t h t h e a n a l y t i c a l e r r o r of t h e m e t h o d and the mean v a r i a t i o n of a n t i b o d y l e v e l s in the healthy control g r o u p II ( 2 4 , 2 5 ) . Predictive values test results were vall (27).
for p o s i t i v e (PV p o s ) a n d n e g a t i v e c a l c u l a t e d a c c o r d i n g to V e c c h i o (26)
(PV and
neg) Kron-
Results There
w a s no
patients
with
single
serological
S.aureus
capable
of
diagnosing
endocarditis/septicemia
or
excluding
patients
with
antibody
levels
during
one
determined
(Table
1).
were
an u n c o m p l i c a t e d to
assay course
four
of
weeks
infection, after
onset
when of
all those peak
infection
25 Table 1. Number a n d P e r c e n t a g e of P a t i e n t s a n d Controls with Positive P e a k A n t i b o d y L e v e l s in S t a p h y l o c o c c u s a u r e u s S e r o l o g y
NONS.
AUREUS COMPL
Alphatoxin
RIA
PG-ELISA SA-ELISA
ENDO
SEPT
S.
AUREUS
UNC0MPL
FEBRILE
HEALTHY
SEPT
ENDO
SEPT
NON-SEPT
CONTROLS
N.D.
4/160 N.D.
14/22
4/10
1/14
0/4
0/18
64 %
40
7 %
0%
0 %
20/25
7/23
6/23
10/27
1/39
0/63
80 %
30 %
26 %
37 %
3 %
0 %
21/25
17/23
6/23
3/27
3/39
1/63
11 %
Q O
1 .6 %
84
74 %
26 %
Lipase-
19/24
14/23
3/23
0/27
ELISA
79
61
13 %
•
Alpha
toxin
The
alpha
were
seen
mia
(Table
%
%
%
2.5
0/ /O
%
N.D.
0/39
0/63
0/157
0 %
0 %
0 %
antibody toxin
RIA
was
in p a t i e n t s
endocarditis cated
%
%
1).
highly
with
However,
was
only
the
64 % ,
and u n c o m p l i c a t e d
specific,
non-S.aureus
and
sensitivity
and only
septicemia
no
cross-reactions
endocarditis
or
septice-
in d i a g n o s i n g
40 % a n d
groups,
S.aureus
7 % in t h e
compli-
respectively.
PG-antibody When
the
solubilized
PG-preparations
investigated
in c r o s s e d
precipitates
but with
(22).
No t r a c e s
preparations crossed-line influenzed optimal lysozyme ring
cross-reacted
while
SO-PG.
variations acid
were
serological two
the
hours
seen.
with
sonication
all
showed
of
the
lysostaphin
continued
Moreover,
when
The time
activity
they
and LS-PG
in e l e c t r o p h o r e t i c
serologically
Immunoelectrophoresis.
time was
LZ-PG
Immunoelectrophoresis
some
of t e i c h o i c
the
SO-PG,
for
enzyme
all
and
four
PGin
treatment
preparations. hours
30 m i n u t e s
two
mobility
investigated
for
were
in
The with
prepa-
26 No
differences
were
seen whether
negative
S.aureus
striking
differences
preparations
when
The
sensitivity
was
impossible
slightly
higher
tory
assays better
could
used
with
patient
shown
sonicated sera
in T a b l e
1.
and
and
56 %,
respectively,
also
test
the
complicated
considered
(Table
positive,
and the some
2).
%)
non-S.aureus
The
However, were
The
with
a
labora-
were
dilutions vs.
1/40).
determined remained
in un-
SPRIA.
was
chosen
of p e a k could
for
antibody be
peak
levels
are
specificity
not
uncommon
endocar-
to 94 as a
density
the
and
all
%
antibody
was considered in o p t i c a l
testing
S.aureus
raised
a positive
endocarditis
it
reproducibility serum
antibodies
in d i a g n o s i n g
only
SPRIA
sera.
(1/3000
IgG s u b c l a s s e s
in t i t e r
using
ELISA.
routine
and higher
subclass
A 50 % r i s e
antibodies
as
LS-PG
or
negative
specificity
results
not
and
A
most
LZ- and
satisfactory
advantages.
18.1
The
in S P R I A
PG-SPRIA
as a n t i g e n
rise
significant.
cross-reacting
SO-PG.
septicemia
when
a significant
result
the
The s e n s i t i v i t y
ditis but
using
A in t h e
PG
from
or p r o t e i n
PG.
SO-,
low,
were
IgG3
protein
too
SO-PG
of a l l
possible
using
much
improved
antibodies
when
The ELISA the
with
the
as a n t i g e n s
positive
+/-
A rich
preparing
and
had
12.0 % vs.
whereas
detected
was
PG-ELISA
the P G - E L I S A
Furthermore, ELISA,
the
(+/-
be
used
LZ-PG
sensitivity
comparing
protein
for
seen between
were LS-PG
with
the
used
to d i s t i n g u i s h
obtained
was
were
were
they
of t h e
results
When
strain
was
in,
and level
positive
values
low,
was
because
mainly
gram-
septicemia.
SA-antibody The of
results the
SPRIA
of
PG-assays. regarding
laboratory.
The
using
peak
ELISA
but
often
positive
Similar
the
to
SA-assays Again,
the
sensitivity
antibody
levels
in
the
was
in d i a g n o s i n g was
SA-ELISA
ways
similar
superior
and c o n v e n i e n c e
S.aureus
PG-ELISA,
in m a n y
SA-ELISA
reproducibility
complicated the
were
for
S.aureus
comparable
to t h a t
septicemia
patients
than
serial
to
those
to t h e the
SA-
routine
endocarditis of
the were
PGmore
in t h e
PG-ELISA
(Table
1).
serum
sampling
raised
the
27 sensitivity,
because
(> 50 % r i s e a positive high,
but
patients
Lipase
significant
in o p t i c a l level
some
was
density
not
reached
cross-reactions
(Table
changes
values)
in
could
(Table
2).
antibody
be
levels
detected
The
even
specificity
were
seen
in n o n - S . a u r e u s
were
only
investigated
if was
infected
1,2).
antibody
Antibodies
to
S.aureus
This
was
ditis
and c o m p l i c a t e d
with
repeated
advantage reaching
the most
sensitive
100 %
assay
septicemia
serum
with
lipase
sampling
this
assay
(Table
1,2).
diagnosing
in 100 % a n d
(Table
was
the
2).
by
S.aureus 89 % ,
endocar-
respectively
Moreover,
extremely
ELISA.
high
the
major
specificity
Table 2. Number and P e r c e n t a g e of P a t i e n t s a n d C o n t r o l s with Positive Peak Antibody L e v e l s or Significant Titer Rises in Staphylococcus aureus Serology N0NS.
AUREUS C0MPL
ENDO PG-ELISA S A - E L ISA Lipase-ELISA Lipase- + P G - or
SA-ELISA
Combined The with
either
AUREUS
UNC0MPL
FEBRILE
SEPT
SEPT
ENDO
SEPT
NON-SEPT
15/16
10/18
7/18
3/11
4/20
3/63
94
56 %
39 %
27 %
20 %
5 %
14/16
15/18
8/18
0/11
2/20
2/63
88
0 %
1055
3 %
0/11
1/25
0/63
%
83 %
44
16/16
%
16/18
3/18
%
100
89 %
17
0 %
4 %
0 %
16/16
14/18
0/18
0/11
0/25
0/63
100
78 %
0 %
0 %
0 %
0 %
% %
%
serology
problem the
S.
PG-
w i t h c r o s s -• r e a c t i n g and
SA-ELISAs.
antibodiesi could not
Instead,
the
three
very
be o v e r c o m e sensitive
28 assays
(PG,
specific, well
SA a n d
were
be u s e d the
positive
peak
well
highly
as in e i t h e r
clinical should
tive
(PV
PG-
all
pos) PV
neg
of
2).
rise
for
could
correlation
positivity
in t h e
This
highly
assays
of a b s o l u t e
lipase
proved
combination
to
(Table
septicemia
course
were ELISA be
2)
patients
an u n c o m p l i c a t e d
upper
as p e r
infection.
the three
only
may
a
where could
or
non-
of e a c h
of 99.5 assays which
be
estimated, University
different as w e l l
variables
group to be
will
test
febrile
%.
The
true
then
be
influenzed a s by
upon
least be
but
was
will
as n e g a t i v e
10 % a m o n g
all
1982.
These
result
in PV
higher
test
results
(Table
%
but 99 %
corresof
99.5
rather
in
88
the
endocarditis/complicated
Hospital
= 2),
controls
at
the
S.aureus
30/34
specificity
must
is
indivi-
(Table
based
the
in r e a l i t y
pos
the
be
posi-
individuals be
in
will 100 %
was
PV
as w e l l
from would
of S . a u r e u s
PV
combinafor
positive
sensitivity
seem
results
at L u n d
positive
The
three
can
all
of t h e t e s t
septicemia
100 %,
mia
results.
The
levels
The p r e v a l e n c e
test among
(26,27).
specificity
of t h e
ly.
neg)
individuals
to a s p e c i f i c i t y
septicemia
(PV
patients
test
values
non-diseased
normal
as
or
negative
and
of the
test
of p r e d i c t i v e
cent
specificity
limit
as m u c h
of a l a b o r a t o r y
positive
the
The
combination
for
also
three
serology
and negative cent
negative
confidence
hardly
with
in t e r m s
endocarditis/complicated
ponding
titer
and c o m p l i c a t e d
significance
as p e r
prevalence
the
lack
o_r S A - E L I S A .
of c o m b i n e d
the s e n s i t i v i t y
(Table
the
The c r i t e r i a
specific
those
be e v a l u a t e d
and
among
from
values
The
by
to
(lipase)
These
infection.
tion
duals
the
endocarditis
Predictive
defined
due
assays.
and highly
differentiated
S.aureus
of t h e m
value £ £ significant
sensitive
S.aureus be
individual
one
in c o m b i n a t i o n .
in p a r a l l e l
between as
lipase),
evaluated
the %
but
unlikeseptice-
diagnosed values than
3).
for 95
%
29 T a b l e 3. P r e d i c t i v e V a l u e s for P o s i t i v e (PV p o s ) a n d N e g a t i v e (PV neg) Results of t h e C o m b i n e d U s e of the PG-, SA- and Lipase E L I S A s in D i a g n o s i n g S . a u r e u s E n d o c a r d i t i s / C o m p l i c a t e d S e p t i c e m i a Sensitivity
88 Si
Specificity
99.5 %
PV
Prevalence
10 %
PV
P°s
95
"1
S
98
'7
*
Discussion When
estimating
proposed which to
to b e u s e d
need
often
to b e
obtained
be
Clinical
assays
a patient between
of i n f e c t i o n .
with
endocarditis
long
persistence
require
a more
from
often
have
a
serology,
probably
serological
there
investigated.
are many
The
often
due
aspects
various
between
what
to
assay results
is
supposed
variations
in
characteristics.
the
with those
a
The higher
of the
antibody
treatment focus
difficult,
diagnostic
that
diagnosis which
criteria
is
seen
These
it
in
can
of
be
of e . g . between
to
to
early the
the also
separate
infection and
S.aureus
underlines
patients
due
patients
is n a t u r a l
course
important
uncomplicated
are probably
foci. and
it and
levels
abscesses
infectious
clinical
often
bacteremia
a complicated
an u n c o m p l i c a t e d
primary
same
S.aureus with
or m e t a s t a t i c
with
The
however,
using
of
laboratories
are
aggressive
those
eradicated. is,
routine
value
characteristics
defining
them
in
thoroughly
and patient
to d i s t i n g u i s h course
diagnostic
in d i f f e r e n t
similar
methodology
When
the
which easily
endocarditis importance
different
of
investiga-
tors. Positive the
relate symptoms day
IgG
onset
for
antibody
levels
of b a c t e r e m i c
the
time
(like the
for
fever,
first
can be e x p e c t e d
infections. serum chills,
positive
sampling general
blood
7-14
days
after
T h e r e f o r e , .it is i m p o r t a n t to
the
day
disability)
culture
or
for and
admission
onset not to
to
the to of the
hospital
30 Adequate All
control
patients
tectable when
as
extremely upper
similar
well
antibody
Therefore, the
groups
the
normal
antibody
patient
present
investigations
tially
was
well
ting this
the change
must not
are
Septicemia evaluated. positive,
patients
the
be
possible
due
to
other
The
cell
bacteria
bacteria
walls
share
of
antibodies
cross-reacting
streptococcal and
need
S. a u r e u s choic
acid
for show
for (15).
has
the ini-
serology evalua-
antibody
level,
group.
This
from
is
healthy
concentrations assay
are
used
important
found
measuring
preparation
been
not
and
gram-
the
pep-
surprising, and
against
lipase
alpha
toxin
assay
assay
exo-
are
not
and
li-
and
technique
preparations
used
regarding
preparation,
purified
when
and
emphasized
of a n t i g e n using
data
mainly
in e . g .
be
in S . e p i d e r m i d i s
toxin
of a n t i g e n
in t h e
other,
also
specificity.
previously when
should
cross-reactions alpha
assays
antigen
The m e t h o d
antigens
the
These
of
be
like
standardization
gen
different
and
in
when
It is t h e r e f o r e
can
the h i g h e s t
aspects
serology
contaminating
S.aureus
and
determinants
However,
consequently
antibodies
Methodological The
sex
used
samples
S.aureus
S.aureus
complex.
infections.
unique
than
antigenic
that
expected,
serum
as
used.
acid
pase
in
be
septicemia
in t h e c o n t r o l
if s i n g l e
should
Moreover,
of a c h a n g e
used.
defining
staphylococcal
clinician.
evaluated
tidoglycan/teichoic
proteins
routine
where
are
age,
controls
de-
antigens
when
group
regarding
represent by
and ELISA
The control febrile
have
S.aureus
important
The
significance
also
is
as p o s s i b l e
and where
used
clinical
certainly controls
been
generally
as S P R I A
group
levels.
symptoms.
suspected,
have
methods
group
clinical
controls
the d i f f e r e n t
of c o n t r o l
initial
may
against
sensitive choice
to t h e
as h e a l t h y
levels
the
lack
preparations,the the
comparing
results
of
anti-
reproducibility the
in tei-
of from
laboratories.
aspects
are
illustrated
in t h e c o m p a r i s o n s
between
the
31 different reacted
PG-preparations.
in c r o s s e d
Although
all
recommended
as a n t i g e n
in S P R I A
antibodies
due
its
poor
sensitivity.
with
both
lysostaphin
enzyme
in r e a c h i n g of
to
treatment
an o p t i m a l
different
batches
solubilization standardize,
the
or E L I S A
sensitivity. may
of P G by and
PG-preparations
immunoelectrophoresis,
also
and
serum
not
be
anti-PG
the
lysozyme
time
for
was
crucial
in e n z y m e
activity
a disturbing
chosen
cross-
could
Moreover,
Variations
have
was
LS-PG
measuring
u1tra-sonication
SO-PG
the
influenze.
is p r o b a b l y
as a n t i g e n
more
The
easy
in t h e
to
present
PG-ELISA. Although lacked
the
a great
problem
tivity.
One
unexpected ticemia alpha
use
of
Single
point
titrations
antibody amount
of
dilution
infection as
to
may
wide. be
reached.
sensitivity
peak
found
serum
reached
generally
had
study
a low
been
sensi-
findings
of
an
S.aureus
sep-
maintained,
that
95 % of
of S . a u r e u s
dilutions
generally the
show
all
S.aureus
Christensson septicemia
is
in T a b l e
a good only
antibody
of a n t i b o d y
and
strains
compared
levels
against
also
by
2 as c o m p a r e d
titer
the
the
serum
antigens
level cut rises
higher
to T a b l e
the
laboratories.
S.aureus
in a n t i b o d y
end-
antibody
influence
the p o s i t i v e
illustrated
with
laborato
absolute
different
of e v a l u a t i n g
the
correlation the
Therefore,
a change
for
affinity
between
although
advantage
serology convenient
not
(32-34).
Therefore,
in
more
However,
standardized
values
RIA
recent
and
has
(30).
significant The
purified
previously
toxin producing
in a r e c e n t
is m u c h
also
the
in a b o u t
(51/88)
antibody be
variation
very
positive
58 %
(31,32). but
bound
needs
normal
is o f t e n
is
highly
toxin
be
is p r e v i o u s l y
dilutions
level
could
of a l p h a
titrations
tory.
toxin,
anti-alpha
producers
single
serum
which
However,
only
toxin
were
delta
the
production
found
to b e a l p h a
is n o t
It
preparations
reason
low p r e v a l e n c e
(28,29).
serial
with
(9,10),
strains.
Hedstrom
The
toxin
possible
toxin
strains
The
alpha
contaminations
1.
during
off
level
as
well
values
for
32 Predictive When
values
a new
the
serological
clinical
significant if
these
sions
value
differences assay.
calculated. level
levels
very far
standing pected,
in the
front
assay
will
large
1 and
reach
use
city
100 % in t h e
cated
septicemia
quite
satisfactory
will
where
were
patient 99.5
made
is m u c h
with
used
no
will
Both
PV
than
95 %
serologi-
a
a n d PV
(Table
the
specifi-
material
pos
In of
However,
give
endocarditis
serological
sus-
higher.
single
and control
!£.
is
a prevalence
100 % .
ELISAs
S.aureus
be h i g h e r
routine
specificity
is to b e
septicemia
of t h e d i s e a s e
present
then
for
if
when
patient
to
least
test
is
important
rates
close
in d i a g n o s i n g
high
situation,
lipase
of at
a
specificity
prevalence
SA- and
specificity
reaching
be
with
a specificity
combination
should
in t h e c l i n i c a l
that
this
on
(PV)
Therefore,
if t h e
seen,
true
concluroutine
high
2 it c a n b e
of P G - ,
no
is e s p e c i a l l y
(27).
Even
a
as
values
populations
However,
calculations
combined of
low
groups.
(pr serum no. F.H. (specific IgE to wheat) as determined by RASTw(Pharmacia, Uppsala, Sweden). It was, however, most surprising that in contrast specific IgE to S. aureus cells or cell walls in serum F.H. reported by Schopfer et al. (1,2), was not affected at all. Removal of IgE antibodies from serum F.H. by affinity chromatography at solid-phase bound anti-human IgE further demonstrated that reported binding of radioactivity in the SPRIA (2) was not due to IgE antibodies. It is obvious from Table 4 that the concentration of total IgE antibodies in serum F.H. was reduced to zero level after affinity chromatography of this serum to matrix-bound anti-IgE. The same was true for allergen (wheat)-specific IgE in this serum (internal control). However, "specific IgE to S. aureus cell walls" was not affected thus demonstrating that the binding reported (2) was not due to IgE antibodies. Fractionation of serum no. F.H. according to molecular weight by HPLC (TSK 4000 column, Pharmacia, Uppsala, Sweden) revealed, that the elution patterns of total IgE and of "specific IgE to S. aureus cell walls" were not identical with respect to molecular weight, thus again supporting the finding that binding obtained (2) was not due to IgE antibodies (Fig. 2). It was of interest that heat inactivation of IgE antibodies in the serum fraction revealing maximal binding in the SPRIA (2) again did not affect binding.
B E F O R E TOTAL
IGE
(IU/ML)
SPECIFIC
IGE
TO WHEAT
(CPM)
"SPECIFIC
IGE
TO S .
A F T E R
AUREUS
CELL WALLS"
7350
40
4470
80
9701
9630
(CPM)
Table 4. Affinity chromatography of serum F.H. to matrix-bound antihuman IgE.
72
Fig. 2. Fractionation of serum F.H. by HPLC on a TSK 4000 column. For details, see materials and methods section.
Fig. 3. Binding of serum F.H. in the SPRIA described by Schopfer et al. (1).
20 o
x
TD C D O JD
i
15
10
o a o TJ a cr
0
1:10
1:100
Dilution of serum
In the present report we demonstrated that reported "specific IgE to S. aureus cells or cell walls" was antibodies. The nature of the binding caused in the unknown, but binding is dependent on serum dilution is noteworthy that "specific IgE to S. aureus cells
binding of not due to IgE SPRIA is yet (Fig. 3). It or cell walls
73 was hitherto only described for patients with hyperimmunoglobulinemia E (1,2). Recently, nonspecific adsorption of IgM from certain pathological sera with raised IgM was reported (9) and parallelity may be discussed. Further detailed studies are, however, necessary to elucidate the nature of the reported binding (1,2).
Acknowledgement This work was supported by DFG grant Se 427/1-1.
References 1. Schopfer, K., K. Baerlocher, P. Price, U. Krech, P.G. Quie and S.D. Douglas. 1979. Staphylococcal IgE antibodies, hyperimmunglobulinemia E and Staphylococcus aureus infections. N. Engl. J. Med. 300, 835-838. 2. Schopfer, K., S.D. Douglas and B.J. Wilkinson. 1980. Immunoglobulin E antibodies against Staphylococcus aureus cell walls in the sera with hyperimmunoglobulinemia E and recurrent staphylococcal infection. Infect. Immun. 2^7, 563-568. 3. Schleifer, K.H. and 0. Kandier. 1972. Peptidoglycan types of bacterial cell walls and their taxonomic implications. Bact. Rev. 36., 407-477. 4. Seidl. P.H., P. Zwerenz, J.R. Golecki, N. Franken and K.H. Schleifer. 1986. Isolation of specific antibodies to the glycan moiety of peptidoglycan and their application in the indirect immunoferritin technique. FEMS Microbiol. Letters, in press. 5. Hartree, E.F. 1972. Determination of protein: a modification of the Lowry method that gives a linear photometric response. Analyt.Biochem. 48, 422-427. 6. Bennich, H. and K. Darrington. 1972. Structure and Conformation of the Immunglobulin E System. In: The Biological Role of the Immunglobulin E System (K. Ishizaka and D.H. Dayton, eds.). National Institute of Child Health and Human Development, Bethesda, MD. p. 19. 7. Johansson, S.G.O., T. Berg and T. Foucard. 1972. Circulating IgE antibodies measured by RAST and their significance in allergic diseases. In: The Biological Role of the Immunglobulin E System (K. Ishizaka and D.H. Dayton, eds.). National Institute of Child Health and Human Development, Bethesda, MD. pp. 211219.
74 8. Killingworth, L.M. and Savory J. 1972. Manual nephelometric methods for immunochemical determination of immunoglobulins IgG, IgA and IgM in human serum. Clin. Chem. J_8, 335-342. 9. Palusuo, T. and K. Aho. 1983. Technical falsely positive rheumatoid factor by ELISA in sera with elevated IgM levels. Med. Biol. 61, 203-207.
SPECIFIC IMMUNOGLOBULIN G ANTIBODIES IN MAN AGAINST THE GLYCAN STRAND OF PEPTIDOGLYCAN
E. Zauner, S. Reissenweber, G. Leitherer, K.H. Schleifer, and P.H. Seidl Lehrstuhl für Mikrobiologie, Technische Universität München, Arcisstr. 21, D-8000 München 2, FRG
Introduction The peptidoglycan molecule reveals at least five antigenic epitopes (for review see Seidl and Schleifer, this book). In man, specific antibodies to the non-crosslinked pentapeptide subunit with C-terminal R-D-Ala-D-Ala-OH and to the glycan strand have been hitherto detected, and several studies reported on a diagnostic role of antibodies against the pentapeptide subunit (1,2) . The applicability of these assay systems is restricted, however, since many eubacteria including almost all gram-negative organisms lack such pentapeptides. On the other hand, the glycan strand of peptidoglycan is a rather uniform chemical component of all eubacteria. Therefore, an enzyme-linked immunosorbent assay for routine quantification of glycan specific antibodies should be useful.
Materials and Methods Antigen albumin-(glycopeptide)n. Glycopeptides were isolated from peptidoglycan of Bacillus subtilis NCIB 8060 by treatment with hen egg-white lysozyme (3), dialysis and fractionation of the dialysable material on a Sephadex G-25 column (compare Ref. 4, Fig. 2 and Results section). Glycopeptides were covalently coupled to albumin as a carrier (Sigma A-1887) by reacting 7.17 mg protein and 21 mg glycopeptides in 1.5 ml 0.1 M sodium carbonate buffer pH 9.6 with 100 ul 25% glutardialdehyde for 18 hours at 4°C. After addition of 0.2 moles lysine, the reaction mixture was dialysed and lyophilized. ELISA• The ELISA was performed according to published procedure (5) with the following modifications: Polystyrene microtiter wells were coated with 50 p.1 of the antigen (2 ug/ml) ; 0.02 M phosphatebuffered saline pH 7.2 containing 0.2% Tween 20 was employed for
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin New York - Printed in Germany
76
dilution of sera and washings. Inhibition of ELISA. Glycan strands, unsubstituted by peptides, were obtained by action of thiophenol (6) on peptidoglycan of S." aureus 52A5 (glycan I). Aliquots were N-acetylated (glycan II) and, in addition, the carboxyl groups of muramic acid were reduced (glycan III) (6). Glycans I, II, III, diacetyl-chitobiose, triacetyl-chitotriose, MDP (Sigma), diacetyl-L-Lys-D-Ala2~OH (Serva) and diacetyl-L-Lys-D-Ala-OH (UCB-Bioproducts, Brussels, Belgium) were employed as inhibitors according to published procedures (7), the methodology for preadsorption of sera to peptidoglycans was recently reported (8).
Results and Discussion Peptidoglycan from Bacillus subtilis NCIB 8060 was used for isolation of glycopeptides because of its particular primary structure (Fig. 1). Special emphasis was put on complete removal of protein impurities and of teichoic acids from the peptidoglycan employed for isolation of glycopeptides. After extensive incubation of cell walls with trypsin, subtilisin, proteinase K and protease Type V
PEPTIDOGLYCAN OF BACILLUS S U B T I L I S NCIB
8060:
-
LACKS AN INTERPEPTIDE
BRIDGE
-
LACKS NON-CROSSLINKED PENTAPEPTIDE SUBUNITS WITH C-TERMINAL R - D - A L A - D - A L A - O H
PEPTIDOGLYCAN
GLYCOPEPTIDES
MURAMIC ACID
1.06
0.97
GLUCOSAMINE
1.08
1.0
L-ALANINE
1.0
1.0
N-TERMINAL L-ALANINE
0
N.D.
-
LACKS NON-CROSSLINKED TETRAPEPTIDE
1.0
1.0
-
REVEALS 62% OF PEPTIDE SUBUNITS AS TRIPEPTIDES WITH C-TERMINAL DIAMINOPIMELIC ACID
MESO-DIAMINOPIMELIC ACID
1.05
0,98 N.D.
THE HIGH PERCENTAGE (55%) OF MESODIAMINOPIMELIC ACID RESIDUES WITH FREE «•-AMINO GROUPS IS IMPORTANT FOR COVALENT LINKAGE TO THE CARRIER
C-TERMINAL MESODIAMINOPIMELIC ACID
0.62
-
N-TERMINAL MESODIAMONOPIMELIC ACID
0.55
N.D.
-
SUBUNITS
AMINO A C I D / AMINO SUGAR
REVEALS CARBOXYL GROUPS OF MURAMIC ACID COMPLETELY SUBSTITUTED BY PEPTIDE SUBUNITS REVEALS A MINOR CONTENT OF DE-N-ACETYLATED GLUCOSAMINE RESIDUES
D-GLUTAMIC
ACID
D-ALANINE C-TERMINAL
ALANINE
UNSUBSTITUTED AMINO GROUP OF GLUCOSAMINE
0.38
0.22
0
N.D.
0.09
N.D.
Fig. 1. Structural features of peptidoglycan from Bacillus subtilis NCIB 8060.
77
from Streptomyces griseus, the protein content was reduced to 0.7%. Teichoic acids were quantitatively removed by 7 0% hydrogen fluoride (9), as was demonstrated by the phosphate content of 0.05% and not detectable polyols by GLC (compare Fig. 2). Detection of Glycan Specific IgG Antibodies Employing albumin-(glycopeptide) as an antigen in the ELISA described above, specific IgG antibodies to the glycan moiety could be detected in human sera. Fig. 3a shows the binding curves of Fig. 2
Fig. 3
©
PEPTIDOGLYCAN FROM BACILLUS S U B T I L I S
PROTEIN
NC IB 8060
: 0 . 7 % •, PHOSPHATE
GLYCEROL,
RIBITOL
E 1.2c C N 1.0CD
: 0.05 X
: NOT D E T E C T A B L E
BY
GLC
-3 0.8'
\
Í 0,6-
o. •>
\
508 3063
D I G E S T I O N WITH LYSOZYME
SOLUBLE
FRACTION
DIALYSABLE
Optical „o => ro
& 0,4+.
1:40
i Dilution of Serum
FRACTION,
BW< 6000-8000 F R A C T I O N A T I O N ON SEPHADEX G 25
GLYCOPEPTIDE
FRACTION
COVALENT
LINKAGE
TO ALBUMIN
ALBUMIN-(GLYCOPEPTIDE)N ANTIGEN
1:40
1:80
1:160
1:320
1.640
Dilution of Serum
Fig. 2. Scheme of the preparation of albumin-(glycopeptide) as an antigen in the ELISA.
used
Fig. 3. Binding of specific IgG antibodies in an ELISA a) to the glycan strand of peptidoglycan. Albumin-(glycopeptide)n was adsorbed to polystyrene microtiter plates, and specific IgG antibodies to the glycan were detected with goat anti-human IgG conjugated to peroxidase; b) to the peptidoglycan sequence R-D-Ala-D-Ala-OH (7).
78 three human sera to albumin-(glycopeptide) (Fig. 3b), to albumin-(D-Ala 3 ) g
, and in comparison
(7). Serum 508 revealed specific
antibodies to the glycan strand and lacked antibodies to the pentapeptide subunit. In contrast, serum 195 contained only specific antibodies against C—terminal R—D—Ala—D—Ala—OH, whereas serum 3063 revealed antibodies to both, the glycan moiety and the pentapeptide subunit. Thus, it was evident that the glycan moiety and the pentapeptide subunit represent independent antigenic epitopes of peptidoglycan in man. Antigenic Specificity of the ELISA Various glycan strands no
more substituted by peptide subunits
were prepared by treatment of peptidoglycan with thiophenol
(6),
compare Fig. 4; Glycan I, completely de-N-acetylated; Glycan II, completely N-acetylated; and completely N-acetylated Glycan III with free carboxyl groups of N-acetyl muramic acid reduced to -CI^OH groups. It was important that binding of glycan strand specific human antibodies to the albumin-(glycopeptide)
antigen was
completely inhibited by oligosaccharides composed of alternating 81,4-linked N-acetylglucosamine and N-acetyl muramic acid residues (Glycan II). The specificity of the ELISA for detecting antibodies directed against the glycan moiety of peptidoglycan was thus clearly proved. It was obvious from comparing the nearly identical inhibition curves obtained with Glycan II and Glycan III
(carboxyl
groups of N-acetyl muramic acid reduced to the -CH^OH group) that
100-
Serum 197
*
Glycan II, N-acetylated
Concentration of InNbitor l u g / m l )
Fig. 4 . Binding inhibition in the ELISA for measuring glycan strand specific antibodies, employing as inhibitors several glycan strand preparations no more substituted by peptides. For details, see text.
79
free carboxyl groups of N-acetyl muramic acid did not contribute to the antibody combining site. Complete removal of N-acetyl groups (Glycan I) affects binding of glycan strand specific antibodies, whereas in contrast, partial de-N-acetylation has no effect (Seidl and Schleifer, this book). Synthetic peptides with structural similarity to the C-terminal sequences of the stem peptide (Ac2-L-Lys-D-Ala-OH, Ac2-L-Lys-D-Ala2-OH) or MDP did not inhibit, thus excluding binding specificity for these structures. Further proof for the specificity of the ELISA was furnished by appropriate inhibition studies, employing as inhibitors culture filtrates from bacterial cells. It is well established that growing bacteria secrete peptidoglycan fragments into the medium (1013; Rosenthal and Fleming, this book; Zwerenz et al., this book). According to this, the ELISA for detecting glycan specific antibodies was specifically inhibited by bacterial culture filtrates taken from the logarithmic phase of growth (e.g. from Staphylococcus aureus, Streptococcus pyogenes, Bacillus subtilis, Escherichia coli, Pseudomonas aeruginosa, Salmonella typhimurium, Edwardsiella spec., Enterobacter aerogenes, Shigella spec. , Proteus mirabilis; data not depicted). Culture filtrates from yeasts as well as uninoculated nutrient broth did not inhibit.
®
®
Serum 059 Seaim 059. adsorbed to peptidoglycan from Bacillus subtilis E coli Staphylococcus
1.0
c0,8 aureus
•50.6-
0
• Serum 004 Serum 004. adsorbed to peptidoglycan from
\ \ °
\
\
° Bacillus subtilis * E.coti • Staphylococcus aureus
\ 1:20 1:40 1:80 1:160 1:320 Dilution of Serum
1:1601:320 1.6401:12801:2560 Dilution of Serum
Fig. 5. Preadsorption of several peptidoglycans a) to serum 059 revealing specific antibodies to the glycan moiety of peptidoglycan and b) to serum 004 revealing specific antibodies to the pentapeptide subunit of peptidoglycan, prior to subsequent performance of the ELISA a) for detecting glycan specific antibodies b) for detecting specific antibodies against the pentapeptide subunit (7).
80 Finally, the specificity of the ELISA for detecting antibodies against the glvcan strand of peptidoglycan was again corroborated by preadsorption studies (Fig. 5). Human serum 05 9 revealing glycan moiety specific antibodies was preadsorbed to bacterial peptidoglycan, prior to performance of the ELISA for measuring glycan specific antibodies (Fig. 5a). All peptidoglycans examined (several species of staphylococci and streptococci, E. coli, Enterobacter aerogenes, Bordetella pertussis, Klebsiella pneumoniae) markedly reduced subsequent binding in the ELISA for detecting glycan moiety specific antibodies. Cell walls from yeasts (e.g. Candida albicans, Saccharomyces spec.) or pseudomurein did not affect binding. In comparison, specific antibodies to the pentapeptide subunit (serum 004) detected by an appropriate ELISA (7) were only adsorbed by peptidoglycans revealing such peptides (e.g. Staphylococcus aureus). Peptidoglycans from Bacillus subtilis or E. coli lacking pentapeptide subunits, or cell walls from yeasts did not affect binding (compare Fig. 5b). In conclusion, due to its relative structural uniformity (14) and regarding the immunological data reported here, the glycan moiety of peptidoglycan may be considered an antigenic epitope shared by all eubacteria.
Acknowledgement This research was supported by grant 01 ZR 112 from the Bundesminister für Forschung und Technologie (BMFT).
References 1. Heymer, B., K.H. Schleifer, S. Read, J.B. Zabriskie, R.M. Krause. 1976. J. Immunol. 117, 23 2. Zeiger, A.R., C.U. Tuazon, J.N. Sheagren. 1981. Infect. Immun. 33, 795. 3. Schleifer, K.H., L. Huss, O. Kandier. 1969. Arch. Microbiol. 68, 387.
81
4. Seidl, P.H., J.R. Golecki, N. Franken, P. Zwerenz, K.H. Schleifer. FEMS Microbiol. Lett, (in press). 5. Engvall, E., P. Perlmann. 1971. Immunochemistry 8, 871. 6. Kawagishi, S., Y. Araki, E. Ito. 1980. Eur. J. Biochem. 112, 273. 7. Franken, N., P.H. Seidl, E. Zauner, H.J. Kolb, K.H. Schleifer, L. Weiss. 1985. Mol. Immunol. 22, 573. 8. Franken, N., P.H. Seidl, T. Kuchenbauer, H.J. Kolb, K.H. Schleifer, L. Weiss.K.-D. Tympner. 1984. Infect. Immun. 44, 182. 9. Fiedler, F., M.J. Schäffler, E. Stackebrandt. 1981. Arch. Microbiol. 129, 85. 10. Glaser, L., B. Lindsay. 1977. J. Bacteriol. 130, 610. 11. Sinha, R.K., R.S. Rosenthal. 1980. Infect. Immun. 29.•
914
-
12. Mychajlonka, M., T.D. McDowell, G.D. Shockman. 1980. Infect. Immun. 2J3, 65. 13. Doyle, R.J., M.A. Motley, P.H.B. Carstens. 1982. Carbohydrate Res. 104, 147-152. 14. Schleifer, K.H., P.H. Seidl. 1985. Chemical Methods in Bacterial Systematics (M. Goodfellow, D.E. Minnikin, eds). Academic Press, London, p. 201.
RELEASE OF PENICILLIN-BINDING PROTEINS FRCM ß-LACTAM TREATED BACTERIA: DETERMINATION BY ANTI-ß-LACTAM ANTIBODIES
R. Hakenbeck, H. Ellerbrok, Th. Briese Max-Planck Institut für molekulare Genetik, Ihnestr. 63-73, D 1000 Berlin 33 N.F.Adkinson The Good Samaritan Hospital, 5601 Loch Raven Bld., Baltimore, MD 21239
Introduction Antibiotics that interfer with murein biosynthesis belong to the class of lytic antibiotics, i.e. they cause cellular lysis when added to a growing bacterial culture. However, in lysis-defective mutants or in bacteria with a suppressed autolytic systan, it is possible to study biochanical events that are induced in the cells upon treatment with these drugs, since they respond only by grcwth inhibition without acccmpanied lysis. Tcmasz and coworkers have documented in several gram-positive bacteria, that treatment with these antibiotics (under non-lytic conditions) leads to secretion of several cell wall ccmoonents (murein and teichoif acid precursors, as well as lipids and lipoteichoic acid) (1-4) . Recently, we have analyzed also proteins that are released during bacitracin or penicillin treatment of autolysin-defective pneumococci. The proteins were mainly membrane proteins, and they were associated with membrane vesicles which could easily be recovered frcm the culture medium of the drug treated bacteria by high speed centrifugation. Among the membrane proteins, penicillin binding proteins (PBP) could be identified (5). These minor membrane canponents occur in all penicillin-sensitive bacteria. By definition, they are able to bind 13lactams covalently, and it is this feature by which they can be visualized after incubation with radioactive penicillin, SDS-nolyacryl-amide-gel-electrophoresis (PAGE) and fluorography (for review, see 6,7). At the same time, it is this very property which makes it difficult to quantitate than after the cells have been treated with B-lactams. They do bind the (nonradioactive) antibiotics already in vivo by forming a PBP-penicilloyl-(BP0-)connlex (Fig.1), are then partly released associated to the manbrane vesicles. Postincubation of either cells or vesicles with radioactive penicillin, followed by PAGE and fluorography as described above, will then reveal only those PBP that had not reacted
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin New York - Printed in Germany
84
COOH
+ E-Ser-OH Ser-E
Penicillin
+
PBP --•> — > (fast)
penicilloyl-PBP
>• pen-derivative (slow)+ p B p
Fig.1: Interaction of PBP with B-lactam antibiotics with the nonradioactive 6-lactam in vivo, or have lost it during the isolation or postincubation period. Thus, PBP could be studied only when cell wall inhibitors others than B-lactams were used for induction of menbrane secretion. Recently we discovered that B-lactam/PBP-ccmplexes can also be dsnonstrated after SDS-PAGE, blotting onto nitrocellulose membrane and immunostaining with anti-6-lactam antibodies (submitted for publication; details of materials and methods are described in that manuscript). The method allows direct determination of penicilloyl-PBP without the need of radioactive penicillin. In the present canmunication, the release of PBP during penicillin- and aztreonam (AZ)treatment of Streptococcus pneumoniae will be documented using the corresponding anti-B-lactam antisera.
Results and discussion 1. Bacterial growth under non-lytic conditions. S. pneumoniae, either an autolysin defective mutant (cwl) or the wildtype (R6) grown under lysis-nonDermissive conditions, were used. It has been described, that the autolysin of oneumococci (an N-acetyl-L-alanine-amidase) (8) which is the only autolysin described in this species can be inhibited by growth in medium suoplanented with 2% choline (9,10). This way, the amidase is obviously no longer capable of interaction with its proper substrate (11,12) and the cells do not lyse. Growth in 2% choline also interfers with cell separation (although proper cell division still occurs), and chain formation is the consequence. It has been argued, that this demonstrates a participation of the amidase in cell separation. Hcwever, the autolytic defective mutant cwl does not grow in chains under normal grcwth conditions, but it did so in 2% choline (Fig. 2B). This could mean, that either the mutant still contains residual amidase activity which is sufficient for cell separation, or that growth in 2% choline interfers also with other, still
85
A
N 100-
50-
¿t o
10 0
r1
"T
2
o
3
h
Fig.2: Growth of pneumoniae under non-lytic conditions. A. At time=0, benzylpenicillin (0.1 ,ug/ml) was added to exponentially growing cultures of cwl , . The control cwl grown with 2% choline (•), and R6 grown with 2% choline culture ranained without antibiotic (9) • Growth was monitored by nephelcmetry (N) B. Strain cwl grown with 2% choline for several generation. undetected enzymes which participate in cell separation. In any case, wild type R6 as well as the mutant grown in 2% choline do not lyse upon treatment with 13-lactam antibiotics (Fig. 2A) . 2. Determination of penicilloyl-PBP during penicillin treatment. S. pneumoniae contains six PBP ranging frcm a molecular weight of 94 kDa to 43 kDa (PBP 1a, 1b, 2x, 2a, 2b and 3). Strains cwl and R6 were grown in the presence of 2% choline, and cwl also without further choline-addition to the medium .Cells were treated with 0.1. ^ug/ml benzylpenicillin corresponding to approximately 10 x MIC, which is sufficient to saturate all PBP with the antibiotic in 5 min at 37°C. After 80 min, the cells were centrifuged and the supernatant (medium) recovered. PBP in the medium were measured either after acetone precipitation (which denatures) the BP0- PBP complex inmediately) , or alternatively, matibrane vesicles were collected frail the medium after high speed centrifugation. Although this step is carried out at 4°C, binding and release of penicillin could occur during this period. This method might therefore not be as accurate as the precipitation procedure, although larger quantities of the vesicles can be collected this way. Fig. 3A shows the outcome of this experiment. One can see, that under all conditions equivalent amounts of PBP are released fran the various bacterial cultures. Judging frcm the staining intensities, approximately 25% of the total cellular PBP ends up outside the cell after penicillin treatment, which corresponds fairly well with values obtained by determination of penicillin-binding
5
6
3 2
3
Fig. 3A. PBP in supernatants of penicillin- treated S. pneumoniae detected on inmunoblots with anti-BPO-antibodies. Cultures of the mutant cwl (1,4), cwl grcwn with 2% choline (2,5), and wild type R6 grown with 2% choline (3,6) received 0.1 ,ug/ml benzylpenicillin for 80 min. Cells were then centrifuged. Either 0.5ml of the supernatant were mixed with 2ml acetone in order to precipitate proteins (1-3), or manbrane vesicles fran 4nl supernatant were recovered by centrifugation for 14h, 48,000 ran, 50 Ti rotor (4-6). An R6 control culture received no drug during growth; after lysis of 1ml culture, PBP were labeled in vitro with penicillin (0). Proteins were separated on SDS-PAGE, blotted onto nitrocellulose and stained after incubation with anti-BPO-antibodies using phosphataseconjugated anti-IgG. PEP are indicated. B. PBP in cells and supernatant of penicillin treated R6. Strain R6 was.grown in the presence of 2% choline, and 0.1 ,ug/ml penicillin was added for 90 min. PBP were separated and visualized as described above. 1: PBP in 5ml medium after 90 min Pen-treatment of the cells; 2: PBP in cells (1ml culture equivalent) after Pen-treatment for 10 min; 3: PBP in control cells (1ml culture equivalent) after labeling with Pen of cell-lysate. activity (manuscript in preparation). Fig. 3B shows another aspect of the protein release, that is a quantitative difference of the PBP in the vesicles canpared to those found in whole cell lysates. PBP 2a is present in larger amounts in the medium than PBP 2x and 2b, whereas the opposite is true in the lysed cell. Anti-BPO-antibodies do not react with PBP 3-ccmplex for still unknown reasons, therefore the amount of PBP 3 can not be accurately determined with this method. Hcwever, it can be determined using anti-aztreonam-antibodies (13) as the AZPBP ccmplex shown below. 3. Determination of aztreonam-PBP during aztreonam treatment. Fig. 4a shows PBP in the medium of AZ-treated cultures of cwl. The MIC for AZ is 50 ^ug/ml. PBP are saturated under these conditions with the exception of PBP 2b, which binds AZ only at 0.5 mg/ml and higher. Nevertheless, one can see that the higher the concentration of AZ the more PBP appear in the medium.
87
'f 1
2
3
4
5
1
2
3
1'
2'
3'
4
5
6
Fig. 4. PEP in cells and medium of aztreonam-treated pneumococci. A. To aliquots of an exponentially growing culture of cwl, different amounts of AZ were added. After 25 min, cells frcm 1ml culture were ranoved by centrifugation and proteins of 0.5ml supernatant acetone precipitated. PBP in the samples were revealed after SDS-PAGE and imnunoblotting using anti-AZ-antibodies. Concentrations of AZ used (mg/ml): 1-0.05; 2-0.2; 3-0.8; 4-2.0; 5-0. B. Strain R6 was grown in the presence of 2% choline and various concentrations of AZ for 5h. Cells were recovered by centrifugation and lysed with detergent. One part was incubated with radioactive penicillin and radioactive BPO-PBP detected after fluorography (1'-3'). The other part was directly prepared for SDSPAGE (0.2ml culture equivalents. AZ-PBP complexes in the cells (1-3) and in 0.5 ml medium (4-6) were visualized after blotting with anti-AT-antiserum. Concentrations of AZ used ( ,ug/ml) : 1,1',4:10; 2,2',5:1; 3,3',6:0.1. Fig. 4B shows PBP in cells and supernatants of R6 grcwn with 2% choline after treatment for several hours with subinhibitory concentrations of f-Z. Binding of AZ to the cell-associated PBP was determined either directly with anti-AZ-antiserum (Fig.4B, 1-3) , or indirectly by postlabeling PBP in cell-lysates with radioactive Pen (1'-3'). After SDS-PAGE and autoradiography, only those PEP show up that have not reacted with AZ during growth. Even at these low concentrations PBP appear to be labeled with AZ, and secretion of PBP occurs although at a much slower rate when canpared to growth in the presence of high concentrations of AZ. Therefore, the samples were taken after several hours of AZ-treatment. Samples 4-6 show AZ-PBP secreted into the medium. It is again striking as has been pointed out already in Fig. 3B, that PBP 2x and 2b are preferentially associated with the cells, whereas almost all of PBP 2a appears in the medium. That finding confirms former results, in which the total protein composition of the secreted material was compared to manbrane and mesoscmal proteins (the term mesosames refers to a manbrane fraction which can be recovered frcm the medium after spheroplasting of the cells). In summary it appears that only a subtraction
88 of the manbrane proteins, which might correspond to a subfraction of the manbrane itself, participate in the secretion process which is induced by antibiotics that interfere with muréin biosynthesis (5). Another aspect concerns the situation in a patient whose infection is treated with ß-lactam antibiotics. Our results show, that massive amounts of proteins (BPO-PBP) that contain the antigenic site for anti-ß-lactam antibodies are released from the pathogenic bacteria, not only during cellular lysis but also frcm tolerant, non-lytic bacteria. Production of anti-ß-lactam antibodies is associated with the antibody-dependent penicillin-allergic reaction against ßlactams (see 14 for review). In which way the BPO-PBP as penicilloyl-antigens influence this reaction ranains to be clarified.
Acknowledgement
The technical assistance of Spassena Tomette is greatfully acknowledged.
References 1. 2. 3. 4.
Home, D., A. Tanasz. 1977. Antimicrob. Agents Chemother. Y\_, 888. Hörne, D., R. Hakenbeck, A. Tcmasz. 1977. J. Bacterid. 132, 704. Waks, S. A. Tcmasz. 1978. Antimicrob. Agents Chanother. 39, 293. Hakenbeck, R., S. Waks, A. Tanasz. 1978. Antimicrob. Agents Chanother. 13, 302. 5. Hakenbeck, R., C. Martin, G. Morelli. 1983. J. Bacteriol. 155, 1372. 6. 7. 8. 9.
Waxman, D.J., J.L. Straninger. 1983. Ann. Rev. Biochan. 52, 825. Frère, J.-M., B. Joris. 1985. CRC Crit. Rev. in Microbiol. 1_1_, 299. Mosser, J.L., A. Tcmasz. 1970. J. Biol. Chan. 245, 287. Briese, Th., R. Hakenbeck. 1983. In: The target of penicillin (R. Hakenbeck, J.-V. Höltje, H. Labischinski, eds.). DeGruyter, Berlin, p.173. 10. Giudicelli, S., A. Tcmasz. 1984. J. Bacteriol. J58, 1188. 11. Höltje, J.-V., A. Tanasz. 1975. J. Biol. Chan. 250, 6072. 12. Briese, Th., R. Hakenbeck. 1985. Eur. J. Biochan. ¿46, 417. 13. Adkinson, N.F., E.A.Swabb, A.A. Sugerman. 1984. Antimicrob. Agents Chanother. 25, 93. 14. Dewdney, J.M. 1977. In: The antigens (M. Sela, ed.). Acadanic Press New York, p. 82.
ANTI-PEPTIDOGLYCAN
SEROLOGY
IN PATIENT SERA AND EXPERIMENTAL PRODUCTION
OF
ANTI-PEPTIDOGLYCAN ANTIBODY BY IMMUNISATION WITH RHEUMATOID FACTOR
H.B. Evans, K.K. Phua, P.M. Johnson Department of Immunology, University of Liverpool, P.O. Box 147, Liverpool, L69 3BX, U.K.
Introduc tion
There
is some association between bacterial immunity and the genesis of
rheumatoid factor (RF) autoantibody in man (1), ditis; a
e.g.
in bacterial
endocar-
RF being characterised in the laboratory by its weak interaction with
determinant in the Fc region of IgG immunoglobulin (2).
reactive
with
Gram-positive
peptidoglycan-polysaccharide
bacterial (PG-PS),
cell
wall
Serum antibodies
structures,
including
are elevated in rheumatoid
arthritis
(RA) and there is no direct cross-reaction of RF as anti-PG-PS,
i.e. RF does
not itself act as an anti-PG-PS antibody (3).
investigated
the of
We have further
anti-PG-PS response in man with respect to the predominant IgG anti-PG-PS
subclass
antibody and the nature of the PG-PS antigen with which
such
antibodies interact. Experimental
animals
substantial
amounts
possibility
of
some
of
immunised with streptococcal cell serum RF-like
idiotypic
anti-IgG(Fc)
complementarity
walls
antibodies
between
RF
produce
(4).
and
The
antibody
reactive with streptococcal PG-PS has therefore been investigated.
Should RF
represent an auto-anti-idiotypic response to a common idiotype of
anti-PG-PS
antibodies, responses, reverse,
as then
i.e.
themselves antibodies.
bear
part it some
of ought
the to
antibodies
idiotypic
normal
immunoregulation
of
be possible experimentally raised against a common RF
activity related to
those
of
This concept is represented in Fig. 1.
Biological Properties of P e p t i d o g l y c a n © 1986 Walter d e Gruyter & Co., Berlin • New York - Printed in G e r m a n y
such to
antibody
produce
idiotype some
the could
anti-PG-PS
90
RF
a-PG-PS
a-idiotype idiotype Fig. 1
» « »
idiotype a-idiotype
Possible idiotypic interrelationship between RF and anti-PG-PS
Materials and Methods
Cell
wall
PG-PS
Streptococcus pyogenes preparation sulphate
was
(SDS)
polymer as
further at
100°C
preparations
were
described previously purified for
(3).
by extraction
15 minutes.
derived
with
PG-PS
at 2 g/ml.
Group
aliquot 1%
This antigen
modification of the anti-PG-PS ELISA technique (3). SDS-treated
An
from
of
sodium was
this
dodecyl
used
in
Wells were coated
The IgG subclass distribution of
A
a
with
anti-PG-PS
antibodies was assessed using monoclonal anti-human IgG1, IgG2, IgG3 and IgG4 reagents
(Unipath)
at 1/1000 dilution,
followed
by
rabbit anti- mouse Ig (Dakopatts) at 1/1000 dilution.
peroxidase-conjugated Results were expressed
as binding indices (5). Details
of
repeated immunisation of Balb/c mice with purified
non-RF immunoglobulin preparations are given elsewhere (6). experiment, components
a on
G-200
(Pharmacia) using
0.1M
and
In an additional
purified RF preparation was separated into IgG-RF and Sephadex
RF
citric
IgM-RF
acid/sodium
citrate buffer,
pH 3.6.
intraperitoneal
immunisations
preparations
Groups of Balb/c mice were given repeated with
either IgM-RF,
in Freund's incomplete adjuvant.
IgG-RF
or
sterile
non-RF
IgG
Anti-PG-PS antibody activity
in sera from these mice was measured by ELISA.
Results
Our juvenile
previous
studies
have shown anti-PG-PS levels
to
be
raised
in
chronic arthritis and both seronegative and seropositive rheumatoid
arthritis (3).
We have now shown that,
activity,
36%
subclass.
In addition, of 10 tuberculosis patients, all with raised anti-PG-
PS,
of
these
of such sera with raised anti-PG-PS
exhibit an IgG isotype
restriction
to
the
IgG2
2 showed restriction to IgG2 antibody (Evans et al., in preparation). In
contrast,
in a study of serial samples from rheumatic fever patients
(n=10),
all of whom had high anti-PG-PS levels, 20% of patients exhibited restriction of antibody to the IgG3 subclass.
However, preliminary experiments comparing
PG-PS
the presence of
preparations
antibody
levels
preparation and,
isolated
consistently
in
appear
with this antigen,
SDS
higher using
have
the
revealed
SDS-treated
that PG-PS
anti-PG-PS antibodies of the IgGI, IgG2
and IgG3 subclasses could be detected in rheumatic fever patient sera. Detailed isolated given
results of anti PG-PS antibody levels in mice
polyclonal
elsewhere
(6).
RF,
immunised
non-RF IgG and non-RF IgM preparations Anti-PG-PS levels for mice immunised with
IgM-RF and IgG-RF preparations are shown in Table 1 . of >3.0 are considered positive.
have
with been
separated
Binding indices (B.I.)
92 TABLE I
Anti-PG-PS Levels in Mice Immunised With IgM-RF, IgG-RF or Non-RF Ig B I.
Immunogen
Mouse No.
3 02 1 87 3 74 4 70 2 45 1 39 1 0 80 0 74
IgM-RF IgM-RF IgG-RF IgG-RF non-RF IgG non-RF IgG PG-PS
1 2 3 4 5 6 7 Pre-immune mouse sera (n=6)
-
Discussion Anti-PG-PS
levels
rheumatoid arthritis,
have
been shown to be raised
in
rheumatic
juvenile chronic arthritis and tuberculosis,
fever, although
it is not certain exactly with which antigenic components of PG-PS that these antibodies react.
In our hands,
SDS-treated
PG-PS,
density
relevant antigenic epitopes than an eguivalent
of
treated with SDS. responses
to
suggesting
higher antibody levels were detected using that this preparation may contain
a
higher
preparation
not
IgG2 antibodies are known freguently to be associated with
carbohydrate antigens (7),
and this may well be the case
for
those human anti-PG-PS antibodies showing IgG-isotype restriction to the IgG2 subclass. an
The
antibody
possibility of
an idiotypic
reactive with streptococcal PG-PS has also
Repeated
immunisation
produces
an anti-PG-PS antibody response (6).
can
complementarity between RF and
of mice
with human RF,
be absorbed by either PG-PS or RF,
been
investigated.
of either IgG
or IgM class,
As this anti-PG-PS
but not non-RF Ig,
activity
a cross-reactive
antibody which reacts with both PG-PS and with a RF idiotype appears to been
produced.
This interpretation is consistent with the view that RF from
unrelated RA patients share common idiotypic determinants. the PG-PS
internal image of a streptococcal antigenic epitope, appear
have
to react with anti-PG-PS antibody.
Such RF may carry since both RF
and
As this structure is
not
present on non-RF Ig, it is assumed to be an idiotypic determinant of RF; the
fact
that an anti-PG-PS response can be raised with either IgM-RF or
IgG-RF
would further support this supposition. This
data
adds
immunoregulatory
weight to the concept that RF is part
of
the
normal
system for modulating certain anti-bacterial responses
and
would put forward an explanation, other than autoreactivity with IgG(Fc), for the genetic conservation of common RF idiotypes.
Uncontrolled RF production
in
perhaps due to
RA may represent an imbalance in this system,
infection
or
continued
presence
of
peptidoglycan.
peptidoglycans exhibit some common antigenicity,
Since
persistent
Gram-positive
this could explain the lack
of association of any single bacterial agent with RF production in RA (8).
Acknowledgements This also
work
thank
was supported by the Arthritis and Rheumatism
Professor
H.R.
Perkins for advice in
the
Council.
production
We
of
streptococcal PG-PS preparations.
References 1.
Williams, R.C. Jr. 1977. In: Autoimmunity: Genetic, Immunologic, Virologie and Clinical Aspects (Talal N. ed.), New York, Academic Press, pp. 457.
2.
Johnson, P.M. 1981.
3.
Johnson, P.M., Phua, K.K., Perkins, H.R., Hart, C.A., Bucknall, R.C. 1984. Clin. exp. Immunol., 55, 115.
4.
Bokisch, V.A., Chio, Med. , 1_38, 1 1 84.
5.
Barnes, R.M.R., Barton, P.G., Doig, J.E., Finn, R., Harvey, M.M. and Johnson, P.M. 1983. J. Clin. Lab. Immunol., 12, 175.
6.
Johnson, 373.
7.
Hammarstrom, L., Granstr'om, M. , Oxelius, C.I.E. 1984. Clin. exp. Immunol. 55^, 593.
8.
Bennett, J.C. 1978.
P.M.,
Clin. Immunol. Allergy 1, 103.
J.W., Bernstein, D., Krause, R.M. 1973.
Phua, K.K., Evans, H.B. 1985.
Arthr. Rheum., 21, 531.
J. exp.
Clin. exp. Immunol., 61, V., Person, M.A.A., Smith,
ANTIBODIES AGAINST A SYNTHETIC PEPTIDOGLYCAN-PRECURSOR PENTAPEPTIDE CONTAINING LYSINE CROSS-REACT WITH SOLUBLE PEPTIDOGLYCAN CONTAINING DIAMI NOPIMELIC ACID
Allen
R.
Zeiger
Department of P h i l a d e l p h i a , PA
Biochemistry, 19107
Thomas
Jefferson
University,
Int r o d u c t i o n Antibodies
have
D-Ala-D-Ala found
In
glycans grown
been
In
that
the
are
titers
elevated
are
juvenile
arthritis
been
employed reagents
an
SPG
from
glycans the
or
could
which
narrow
presence
search The
rheumatic
fever
and
spondyl-
evidence
assay
in
C6).
the The
distinguish
SPG
bacterial by
bacteremia Impli-
urine ELISA
in
like
next
of
for
cell
these the
the
presence
antibiotic
such
as t h e
penultimate
bacteria
peptldonature
differences In t h i s
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin New York - Printed in Germany
(8).
D-alanlne
responsible
answered
(7)
synthetic
wall-linked
structural
to b e
man
utilized
the
completely
differences to
question
the
has
p e p t I d o g 1 y e a n - 1 I ke
weight
a
(ELISA)
(A1 a - y - D - G 1 u - L y s - D - A l a - D - A l a ) 5 ' 1
distinguish
the
in m a n .
SPG
V
elicited
structural
present
their
(5).
low m o l e c u l a r
bacteria,
contain
diaminoacid
Reagents
A1 a 4 0
different C9),
a
population
(Gl'u b 0
to
of
transpeptidated
vancomycin,
antibody
Immunogen,
presence
These
since
ankylosing
immunosorbent
penicillin
able
with
and
Immunogen
of
(5).
Importance
serological
the
were
peptidobacteria
antibiotics
Cl)
been
soluble
endocarditis
mounting
natural
the
towards
have
gram-positive
patients
arthritis
Is
dose
which
e.g.,
of
reactive
sequences
in
some
aureau-caused
show
oral
hydrolyzed
sera
are
medical
enzyme-linked
to
an
and
beta-lactam
in t h e
There
a unique
products; and
of
that latter
by
considerable
S P G as t h e m a j o r
following of
of
rheumatoid
(3).
Recently,
two
be
Staphylococcus
cating
man The
secreted
presence
may
(2),
in
(1-4).
peptI dog 1 y c a n - p r e c u r s o r s (SPG)
antibodies
(1),
found
sequences
for
of
(5).
in
SPG
their
manuscript
96 Is w h e t h e r SPG t h a t
the
reagents
in
Materials
and
ELISA.
The
described
previously
ELISA
are
(GIu60
capable
(A2pm)
of
recognizing
in p l a c e of
ELISA
for
the
(5-6)
rabbit
detection
has
of
SPG
been modified
antibody
to
the
that
However,
instead
of
antibody
was
alkaline
an
immunoglobulin a
using
synthetic
purchased
1:500
biotIn-avIdIn phosphatase
Co.) was
The
(Sigma
Chem.
buffer,
pH
9.8,
containing
Absorbances
were
read
Multlskan MC
SPG.
The
(Flow
SPG
(10)
and
the
were
prepared
Included
In
added
polypeptide,
at
1 mg 0.01%
p e r ml
goat
(St.
p-nItropheny1
periodically
was
used.
the
second
at
anti-rabbit
Louis,
phosphate
of
10%
MgCl2 1 GrOUp
0-5 Years
IgM Titer > 3
6-17 Years
0-5 years
6-17 Years
I. LUTI
1/6
6/18
1/6
9/18
II.PN
3/6
4/7
3/6
6/7
2/22
0/3
7/22
IV.Control 0/3
A more precise differentiation of UTI and PN in infants led to the same results as before, although the differences were no longer so pronounced in the case of the lower limit. The titer-limits seem to be a little bit too low and the titer level seems also to depend on the age. Table 9:
ELISA OF IgG AND IgM ANTIBODY TO LIPID A IN HEALTHY ADULTS AND PATIENTS WITH GRAM-NEGATIVE SEPSIS IgG titer 0 1 Patients(adults) (n=6) Healthy adults (n=113)
3
3
100
13
0
IgM titer 1 2 3
1 2 95
0
18> 1
4
1 2
128 Table 9
shows the lipid A antibody titers in healthy individuals.
The determinations were made only a short time ago.
In order to investigate the antitoxic effect of the anti-lipid A titers, we are now performing a double-blind study im Klinikum Großhadern. This is being carried out with high-titered anti-lipid A sera. We were able to show that this effect is pharmacokinetically possible using lipid A antibody sera in sepsis patients and controls - one case with placebo and the other a healthy individual. By means of this study we hope to be able to show the same improved antitoxic effect which is being shown in the USA and Switzerland using the J5 mutant of E.coli.
References
1. Galanos, C., Lüderitz, 0., Westphal 0. 1971. Preparation and properties of antisera against the lipid A component of bacterial lipopolysaccharides. Eur.J.Biochem. 24, 116-122 2. Simon, G., Reindke, B., Marget, W.: Lipoid-A-Antikörpertiter bei Pyelonephritis und anderen Infektionen mit gram-negativen Bakterien. Infection 2 (174) 178-184 3. Marget, W., Schüßler, P., Kruis, W., Weinzierl, M., Rindfleisch, G.: Is the pathogenesis of Crohn's disease similar to that of juvenile recurrent pyelonephritis? Infection 4 (1976) 2-4. 4. Westenfelder, M., Galanos, C., Madsen, P.O., Marget, W.: Pathological activities of lipid A: Experimental studies in relation to chronic pyelongephritis. In: Schlesinger D. (ed.): Microbiology. American Society for Microbiology, Washington, D.C.1977, pp.277-279 5. Schüßler, P., Kruis,W. Marget, W.: Lipoid-A-Antikörper bei Morbus Crohn. Klin.Wschr.54 (1976) 1055 6. Schüßler, P., Kruis, W., Marget, W.: Lipoid-A-Antikörpertiter und O-Antikörpertiter bei Enterocolitis Croh, Colitis ulcerosa und akuter Enteritis. Med.Klin.71(1976, 1898-1902 7. Marget, W., Weiß, M., Ruhland, B.: Lipid A antibody determinations using ELISA on patients at a children's hospital: a preliminary report.Infectior 11 (1983) 82-84
ELECTRON MICROSCOPIC LOCALIZATION OP PEPTIDOGLYCAN IN THE CELL WALL OP STREPTOCOCCUS PYOGENES BY MEANS OP LABELLED ANTIBODIES AND LYSOZYME M. Wagner Central Institute of Microbiology and Experimental Therapy, Jena German Democratic Republic M. Rye Institute of Hygiene and Epidemiology, Prague, Czechoslovakia B. Wagner Central Institute of Microbiology and Experimental Therapy, Jena German Democratic Republic
Introduction Based on the morphological appearance of the cell wall in ultrathin sections and some other evidences it has been believed for a long time that the cell wall of streptococci, as other Grampositive bacteria too, is constructed from several layers, each of them consisting of one defined chemical component. The peptidoglycan was supposed to be the innermost layer forming the rigid basal structure of the wall (1 - 3)« However, phage absorption experiments have shown, that at least parts of the peptidoglycan macromolecule should be accessible on the cell surface (4). The aim of our investigations was to localize the peptidoglycan in the cell wall of group A streptococci by electron microscopic labelling methods. The present review summarizes the results of our previous papers (5 - 8). Materials and Methods Bacteria. Group A Streptococcus strain NY5 (M type 12), lacking the IgG*Pc-binding receptor (9), from the collection of the Central Institute of Microbiology and Experimental Therapy, Jena was used for all experiments. Cell Walls and Peptidoglycan. Cell walls were prepared by mechanical disintegration and differential centrifugation (6). In some experiments the walls were also treated with trypsin. Peptidoglycan was isolated from cell walls by extraction with 10% trichloroacetic acid (4h at 60 C) or by hot forraamide extraction. Peptidoglycan antibodies and ferritin conjugates. Peptidoglycan antibodies from antisera raised against Group A variant streptococci (strains T 12 and T 50) were isolated by absorption to group A peptidoglycan followed by extraction with 0.1M glycine-
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
130 H C 1 buffer, pH 2.5, and n e u t r a l i z a t i o n (6). F e r r i t i n c o n j u g a t i o n of the a n t i b o d i e s was performed w i t h g l u t a r a l d e h y d e (6). L y s o z y m e - p e r o x i d a s e c o n j u g a t e s . Lysozyrae was conjugated w i t h h o r se-radish p e r o x i d a s e by g l u t a r a l d e h y d e . R e s i d u e s of uncoupled lys o z y m e w e r e separated by c h r o m a t o g r a p h y on C o n A - S e p h a r o s e (Pharm a c i a , U p p s a l a ) . The conjugate showed both the a c t i v i t y of lysozyme (lysis of M i c r o c o c c u s f l a v u s ) and of the p e r o x i d a s e . Inhibition E x p e r i m e n t s . The f o l l o w i n g peptides w e r e used f o r a n t i b o d y i n h i b i t i o n e x p e r i m e n t s : D i a l a n i n e ( D - A l a - D - A l a ) , trialanine (D-Ala-D-Ala-D-Ala), t e t r a p e p t i d e ( L - A l a - D - i G l n - L - L y s - D A l a ) , p e n t a p e p t i d e ( L - A l a - D - i G l n - L - L y s - D - A l a - D - A l a ) and the M 24 p r o t e i n p e p t i d e L - A l a - L - G l u - L - L y s - L - A l a - L - A l a (10). F e r r i t i n conjugated a n t i b o d i e s against p e p t i d o g l y c a n w e r e incubated w i t h the peptides f o r 30 m i n at 37 C followed by 18 h at 4 C, and slight p r e c i p i t a t e s w e r e removed by c e n t r i f u g a t i o n . I n h i b i t o r y concentrations of the synthetic p e p t i d e s w e r e calculated as double those causing 5 0 % i n h i b i t i o n of the p r e c i p i t a t i o n w i t h p e p t i d o g l y c a n (11). Incubation of Cells and Cell F r a g m e n t s w i t h C o n j u g a t e s . To about 0.1 ml of sedimented cells, cell w a l l s or p e p t i d o g l y c a n inhibited or n o n i n h i b i t e d f e r r i t i n - c o n j u g a t e s (0.2 - 0.3 m l ) w e r e added and incubated at 37 C w i t h shaking f o r 1 h . Incubation w i t h l y s o z y m e - p e r o x i d a s e conjugates was done at 0 C i n an ice bath overnight. A f t e r w a s h i n g w i t h ice-cooled v e r o n a l a c e tate b u f f e r the s a m p l e s w e r e fixed w i t h g l u t a r a l d e h y d e , incubated w i t h 3 , 3 ' - d i a m i n o b e n z i d i n e and H ^ O p , and processed f o r t r a n s m i s s i o n electron m i c r o s c o p y (6). A s controls cells and cell f r a g m e n t s w e r e incubated w i t h p e r o x i d a s e and f u r t h e r processed in the same w a y . E l e c t r o n M i c r o s c o p y . U l t r a t h i n sections w e r e examined without p o s t - s t a i n i n g . F o r the e v a l u a t i o n of the inhibition experiments on w h o l e cells, w a l l s and p e p t i d o g l y c a n f r a g m e n t s one h u n d r e d segments of 0 . 2 ;um l e n g t h w e r e selected f o r counting the n u m b e r of f e r r i t i n particles using parts of a n t i t a n g e n t i a l l y sectioned objects. I n h i b i t i o n was calculated in percent of the counts on n o n i n h i b i t e d controls. Results Localization
of p e p t i d o g l y c a n
by f e r r i t i n - c o n j u g a t e d
A l l investigations w e r e carried walls
out on w h o l e cells,
(treated w i t h t r y p s i n and R N a s e ) and isolated
can. W h o l e cells displayed f e r r i t i n particles cell s u r f a c e as w e l l as specificity
of the l a b e l l i n g was
confirmed
2, 3). T h e f e r r i t i n p a r t i c l e s
peptidoglythe
(Fig. 1). The
by n e g a t i v e
results
n o r m a l IgG. Isolated w a l l s
p e p t i d o g l y c a n bound labelled antibodies res p r o t r u d i n g from both sides
isolated
directly on
on f i l a m e n t o u s p r o t r u s i o n s
obtained w i t h f e r r i t i n - c o n j u g a t e d
antibodies
on both surfaces
labelled short f i l a m e n t o u s of the
fragments.
and
(Figs. structu-
131
Pigs. 1-3. Strept.pyogenes, strain NY5, labelled with ferritinconjugated peptidoglycan antibodies. All bar markers represent 0.2 jam. (1) "/hole cell. (2) Cell wall. (3) Peptidoglycan Characterization of the peptidoglycan immunodeterminants The nature of the peptidoglycan immunodeterminants demonstrated by ferritin-conjugated antibodies was investigated in inhibition experiments (Table 1). Table 1: Inhibition of Ferritin-Conjugated Peptidoglycan Antibodies Demonstrated on Group A Streptococcus Cells, Cell Walls and Peptidoglycan Inhibition by Reduction of Particle Count (%) in Comparison to Noninhibited Controls Whole Cells Cell Walls Peptidoglycan Dialanine
76.6
83.8
Trialanine Tetrapeptide Pentapeptide
49.0 41.2 92.6
77.7
87.7 77.0
64.5 98.2 11.2
44.7 97.1 7.6
M Protein Sequence
7.3
The results of these studies clearly show that the pentapeptide exhibited the highest inhibition activity. In the experiments with cell walls and peptidoglycan it inhibited practically all antibody activity. The tetrapeptide had only the half of this activity. The M protein sequence used in the same concentration as the pentapeptide was practically ineffective. The figs. 4-6 show that after inhibition by synthetic peptides labelling was abolished or reduced on both sides of isolated cell walls.
132
Figs. 4-6. Strept.pyogenes, strain NY5• Labelling of cell walls w i t h antibody-ferritin conjugate was inhibited by synthetic peptides. Bar markers represent 0.2 ¿im. (4) N o inhibition. (5) Inhibition by tetrapeptide. (6) Inhibitor) by dialanine Localization of peptidoglycan by peroxidase-conjugated
lysozyme
Incubation of isolated peptidoglycan w i t h lysozyme-peroxidase followed by the reaction w i t h 3,3'-diaminobenzidine and HgC^ led to a heavy labelling on both sides of the fragments (Pig. 7). Similarly, isolated trypsinized cell walls were also labelled to a lesser extent on both aides (Pig. 8). Incubation of peptidoglycan or walls w i t h peroxidase alone h a d no such effect
(Pig.9).
On the other hand, whole cells exhibited only a weak labelling after incubation w i t h lysozyme-peroxidase (Pig. 10).
Pigs. 7-10. Strept.pyogenes, strain NY5. Labelling w i t h lysozymeperoxidase. Bar markers represent 0.2 ^pm. (7) Peptidoglycan. (8) Cell wall. (9) Cell wall, control w i t h peroxidase alone. (10) Whole cell.
133
Discussion The use of iramunoelectron microscopic methods allows a direct proof of the location of antigenic cell components. In our investigations two approaches have been applied to study the location of peptidoglycan in the cell wall of group A streptococci: The accessible immunodeterminant groups were detected by antibodies raised in rabbits against group A variant streptococci and purified by absorption to group A streptococcal peptidoglycan. The location of the glycan portion of the molecule was demonstrated by means of lysozyme conjugated to peroxidase. Ferritin-conjugated peptidoglycan antibodies labelled isolated cell walls and peptidoglycan fragments on both sides. The ferritin particles were mainly bound to filamentous structures. Whole cells were also labelled on their surface. These results contradict models in which peptidoglycan forms the innermost layer of the cell wall (1-3) and support concepts of a more complicated mosaic structure. Inhibition experiments with synthetic peptides demonstrated that the immunodeterminant groups demonstrated in this investigation are predominantly of pentapeptide nature. Interestingly, the distribution of these determinants was found to be similar on both sides of walls and peptidoglycan fragments. Recently, Seidl et al. (12) using antibodies against the D-alanyl-D-alanine moiety of the non-crosslinked pentapeptide also localized pentapeptide subunits of peptidoglycan on the surface of whole cells of Streptococcus pyogenes and some other Gram-positive bacteria. These results confirm our observation that the peptidoglycan of group A streptococci is accessible from the cell surface. The use of lysozyme-peroxidase conjugate based on the finding that conjugates of lysozyme with peroxidase or fluorescent dyes (5, 13) remain the properties of lysozyme to bind to the glycan strand and to lyse the peptidoglycan. Near 0°C, however, only binding to the peptidoglycan takes place. Using this probe both peptidoglycan and trypsinized cell walls were heavily labelled on both sides whereas the surface of whole cells seems to be lesser accessible for the lysozyme. Summarizing, our results show that the peptidoglycan of Streptococcus pyogenes does not form a separate inner layer of the cell
134
wall but must be present throughout the whole wall as a network. This conception is in agreement with contemporary models of the architecture of peptidoglycan of Gram-positive bacteria. Acknowledgement We thank Dr. R. Straka, Prague, for the synthesis of peptides and Dr.E.H.Beachey, Memphis, for providing us the M protein peptide. References 1. Krause, R.M. 1972. In: Streptococci and Streptococcal Diseases. Recognition, Understanding and Management (L.W.Wannamaker and J.M.Mats en, eds.) Academic Press, Hew York, p.3. 2. Davis, B.D., R.Dulbecco, H.N.Eisen, H.S.Ginsburg, W.B.Wood, M.McCarty. 1973. Microbiology, 2nd edn., Harper and Row, Hagerstown, Maryland, p. 708. 3. Kasper, Group B sen and Karger,
D.L., C.J.Baker, H.J.Jennings, 1985. In: Neonatal Streptococcal Infections (K.K.Christensen, P.ChristenP.Perrieri, eds.) Antibiotics and Chemotherapy, 35. Basel, p. 90.
4. Cleary, P.P., L.W.Wannamaker, M.Fischer, N.Laible. 1977. J.Exp.Med. 578. 5. Wagner, M., B.Wagner. 1978. Zbl.Bakt.Hyg., I.Abt.Orig.A 240, 302. 6. Wagner, M., B.Wagner, M.Rye.1978. J.Gen.Microbiol. 108, 283. 7. Rye, M., M.Wagner, B.Wagner. 1979. In: Pathogenic Streptococci (M.T.Parker, edit.) Reedbooks Ltd., Chertsey, England, p. 4 6 . 8. Rye, M., B.Wagner, M.Wagner, R.Straka. 1982. Current Microbiology 7, 187. 9. Rye, M., M.Wagner, B.Wagner, J.HavliXek. 1982.Microbios 34. 7. 10.Beaehey, E.H., J.M.Seyer, A.H.Kang. 1978. Proc.Natl.Acad.Sei. U.S. 75, 3163. 11.Schleifer, K.H., R.M.Krause. 1971. J.Biol.Chem. 2 4 6 . 986. 12.Seidl, P.H., J.R.Golecki, N.Pranken, K.H.Schleifer. 1985. Arch.Microbiol. 142. 121. 13.Gould, G.W., D.L.Georgala, A.D.Hitchins. 1963. Nature (Lond.) 200. 385.
IMMUNOELECTRON MICROSCOPIC STUDIES ON PEPTIDOGLYCAN FROM GRAM POSITIVE BACTERIA: SPECIFIC REACTIONS WITH THE GLYCAN MOIETY, THE PENTAPEPTIDE SUBUNIT AND THE INTERPEPTIDE BRIDGE
Norbert Franken Boehringer Mannheim GmbH, Forschungszentrum Tutzing, 8132 Tutzing, FRG Jochen R. Golecki Institut für Biologie II, Mikrobiologie, Albert-Ludwigs-Universität, 7800 Freiburg, FRG Peter H. Seidl, Peter Zwerenz, Karl H. Schleifer Lehrstuhl für Mikrobiologie, Technische Universität München, Arcisstraße 21, D-8000 München 2, FRG
Introduction The peptidoglycan molecule reveals at least five independent antigenic epitopes, i.e. a) the glycan moiety, b) the pentapeptide subunit, c) N-terminal and d) C-terminal sequences of the interpeptide bridge and e) the tetrapeptide subunit (1; Seidl and Schleifer, this book). This report deals with immunoelectron microscopic studies of the glycan moiety, the pentapeptide subunit and N-terminal interpeptide bridge epitopes in the cell wall of several gram positive bacteria.
Materials and Methods Specific antibodies to peptidoglycan epitopes. The isolation of antibodies to the glycan moiety by affinity chromatography techniques was recently reported (2). Antisera to the C-terminal Dalanyl-D-alanine moiety of H-L-Ala-D-Glu(L-Lys-D-Ala-D-Ala-OH)-NH2 were elicited in rabbits by immunization with synthetic immunoaen albumin-(CH 2 CO-Gly-L-Ala-D-Ala 2 -OH) (3). Antibodies to N-terminal sequences of the pentaglycine interpeptide bridge or of the tri-L-alanine interpeptide bridge were produced as previously described by immunization with tGly^-t-Ahx) »„-albumin or (L-Ala-.-&b J Ahx) 22 -albumin (4). Radioactive hapten binding assays and enzyme immunoassays. Antibodies to the tetrapeptide or to the pentapeptide subunit were determined by radioactive hapten binding assays (5,6) and by an en-
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
136
zyme-linked immunosorbent assay (ELISA) (7). Glycan strand specific antibodies were measured by a radioactive hapten binding assay (2) or by an appropriate ELISA (Zauner et al., this book). Binding inhibition studies for proving antibodies' specificity were carried out as previously described for the radioactive hapten binding assays (5-7) or for the ELISAs (7; Zauner et al., this book). Bacterial strains used. The origin of Streptococcus pyogenes Avariant A486, Staphylococcus aureus 52A5 and of Bacillus subtilis W23 is given in a recent paper (8). Indirect immunoferritin technique and electron microscopy. Labelling of cells in the indirect immunoferritin technique and electron microscopy were carried out as recently described in detail (8).
Analytical methods. Gas chromatography, quantitative determination of phosphate and protein, amino acid analyses, determination of C-terminal amino acids and of the L-alanine/D-alanine ratio in peptidoglycans were carried out as described (8).
Results and Discussion Specificity of Antibodies to the Glycan Moiety, Pentapeptide Subunit and Interpeptide Bridge Epitopes Antibodies with specificity to the glycan moiety of peptidoglvcan were isolated from antisera to whole cells of Micrococcus luteus CCM 169, known to contain high levels of glycan strand specific antibodies (9). Removal of minor antibody levels in those sera with specificity to the pentapeptide subunit (1,9) was achieved by affinity chromatography on Sepharose-(Gly2-L-Ala-D-Ala-D-Ala-OH)n (10). Glycan strand specific antibodies in the eluent were then prepared by affinity chromatography (2). Peptidoglvcan of Bacillus subtilis NCIB 8060 was used as an immunoadsorbent (2) for the isolation of glycan strand specific antibodies since it lacks as antigenic epitopes interpeptide bridges, pentapeptide subunits or non-crosslinked tetrapeptide subunits (1, 6-9,11). Specificity of the isolated antibody fraction for the glycan moiety was verified by immunoassays for measuring glycan strand specific antibodies (1,2, 9; Zauner et al., this book), and by excluding binding specificity to the tetrapeptide or to the pentapeptide subunit (1,2,5-7). Specific antibodies to the C-terminal D-alanyl-D-alanine moiety of non-crosslinked pentapeptide subunit H-L-Ala-D-Glu(L-Lvs-DAla-D-Ala-OH)-NH0 (10) were elicited in rabbits using as an immuno-
137
gen albumin-(CH2CO-Gly-L-Ala2-D-Ala-D-Ala-OH)3g (3). Exclusive specificity of these antibodies for non-crosslinked peptide subunit pentapeptides was demonstrated in detail by appropriate precipitin and precipitin inhibition studies (3) and by Farr type hapten binding or binding inhibition studies (5,6,8). Specific antibodies to the N-terminal sequences of the pentaglycine interpeptide bridge or to the tri-L-alanine interpeptide bridge were obtained by immunization with synthetic immunogens (Gly^-f-Ahx)2Q~albumin or with (L-Ala^-fc-Ahx)22-albumin, respectively (4). Selective specificity of the particular antiserum for the pentaglycine interpeptide bridge of staphylococci or against the oligo-L-alanine interpeptide bridge typical for many micrococci or pyogenic streptococci was demonstrated in detail by appropriate precipitin and precipitin inhibition studies (4,12) and by latex agglutination (13). Immunoelectron Microscopic Detection of the Glycan Moiety, the Pentapeptide Subunit and of the Interpeptide Bridge Epitope in Gram Positive Bacteria The results obtained from the immunoelectron microscopic studies employing specific antibodies to the particular peptidoglycan epitopes are schematically summarized in Table 1, p. 138. Whole trypsinized cells of Streptococcus pyogenes, incubated with specific antibodies to the glycan moiety followed by incubation with ferritin-labelled anti-rabbit IgG were specifically labelled with ferritin particles as was evident from these sections comparing untreated controls (not depicted) with antibody coated cells (Fig. 1, p. 138). Heavy specific labelling with ferritin particles (data not depicted) was also obtained with trypsinized cells of Staphylococcus aureus and of Bacillus subtilis, compare Table 1 and (2) . Employing in the indirect ferritin technique specific antisera to the pentapeptide subunit (3) , Bacillus subtilis remained completely unlabelled however (Fig. 2a, p. 139 and Table 1), due to missing pentapeptide subunits in its peptidoglycan (3,8). On the contrary, heavy specific labelling was obtained with cells of Streptococcus pyogenes (Fig. 2b, p. 139) or of Staphylococcus aureus (Fig. 2c, p. 139), compare Table 1. These results fully
138
Table 1. Labelling of trypsinized cells of Streptococcus pyogenes, Staphylococcus aureus and of Bacillus subtilis with specific antibodies to the glycan moiety, to the pentapeptide subunit and to the interpeptide bridge epitope (indirect immunoferritin technique). +++, heavy labelling; -, no labelling.
STR. PYOGENES A-VARIANT A486
S. AUREUS 52A5
B. SUBTILIS W23
SPECIFIC ANTIBODIES TO THE GLYCAN MOIETY
+++
+++
+++
SPECIFIC ANTIBODIES TO THE R-D-ALA2 MOIETY OF THE PENTAPEPTIDE SUBUNIT
+++
+++
-
-
+++
-
+++
-
-
SPECIFIC ANTIBODIES TO THE G L Y 5 INTERPEPTIDE BRIDGE
SPECIFIC ANTIBODIES TO THE L - A L A 3 INTERPEPTIDE BRIDGE
Fig. 1. Labelling of trypsinized cells of Streptococcus pyogenes with specific antibodies to the glycan moiety (2) of peptidoglycan (indirect ferritin technique). Bar represents 200 nm.
139
Fig. 2. Labelling of trvpsinized cells of a) Bacillus subtilis W23, b) Staphylococcus aureus 52A5, c) Streptococcus pyogenes A-variant A486 with specific antibodies to the pentapeptide subunit (3) of peptidoglycan (indirect ferritin technique). Bar represents in all Figs. 200 nm.
140
correspond with our previous precipitin studies (3), and with the peptidoglycan structures of bacteria investigated. Due to missing D,D-carboxy-peptidases (14), pentapeptide subunits with C-terminal D-alanyl-D-alanine occur frequently among staphylococci or streptococci (6,7) and were chemically demonstrated in the peptidoglycans of Str. pyogenes A486 or S. aureus 52A5, used in this study (8) .
Employing in the indirect ferritin technique specific antisera to the interpeptide bridge (4), trypsinized cells of Staphylococcus aureus were specifically labelled with antisera to the pentaglycine interpeptide bridge of staphylococci (Fig. 3a) but not with antisera to the tri-L-alanine interpeptide bridge (Fig. 3b). On the other hand, cells of Streptococcus pyogenes were heavily labelled with antiserum to the tri-L-alanine interpeptide bridge but not when using antisera to the pentaglycine interpeptide bridge (not depicted, compare Table 1). Neither interpeptide bridge specific antiserum resulted in labelling of Bacillus sub-
Fig. 3. Labelling of trypsinized cells of Staphylococcus aureus 52A5 with specific antibodies to the interpeptide bridge (4) of peptidoglycan (indirect immunoferritin technique). Bar represents 200 nm. a) ultrathin sections of S. aureus incubated with antiserum to (Gly^-fcrAhx)-Q-albumin; b) ultrathin sections of £3. aureus incubated with antiserum to (L-Ala^-f.Ahx) 00 -albumin.
141
tilis. This selective binding was in excellent agreement with our previous data (4,13) and corresponded to the peptidoglycan structures of strains investigated (11). Immunoelectron Microscopic Controls and Exclusion of Non-Specific Binding Cells not incubated with specific antibodies missed any labelling (8), and incubation of cells with ferritin conjugate alone did not result in any labelling either (8). Non-specific binding of rabbit IgG to possible Fc-binding factor of Str. pyogenes A-variant A486 (15) or traces of protein A of S. aureus 52A5 was ruled out study125 ing direct binding of iodine labelled rabbit IgG to cells of Str. pyogenes A486 or aureus 52A5 (8), and could in addition be excluded from selective binding when using interpeptide bridge specific antibodies (compare Table 1). Application of Specifically Detecting Particular Peptidoglycan Epitopes in the Electron Microscope We have now a tool for specifically detecting particular peptidoglycan epitopes in the electron microscope. For example, pentapeptide subunits represent a precursor sequence from peptidoglycan biosynthesis and accumulate in the wall under sublethal concentrations of penicillin (16) or decrease under cycloserine (17). Recent immunoelectron microscopic studies to localize the points of attack of penicillin revealed for Streptococcus pyogenes the accumulation of pentapeptide subunits close to the septum (18). On the contrary, the rod-shaped Lactobacillus gasseri DSM 20243 (strain AM63) accumulates non-crosslinked pentapeptide subunits at the poles under sublethal concentrations of penicillin (unpublished) . Studies on growing cells of Streptococcus pyogenes revealed secretion or incorporation (?) of pentapeptide subunits near the wall band (unpublished) and studies with reverting spheroblasts are under current research.
142
References 1. Heymer, B., P.H. Seidl and K.H. Schleifer. 1985. Immunochemistry and biological activity of peptidoglycan. In: Immunology of the bacterial cell envelope (Stewart-Tull DES, ed). John Wiley, Chichester, U.K. 2. Seidl, P.H., P. Zwerenz, J.R. Golecki, N. Franken and K.H. Schleifer. 1986. Isolation of specific antibodies to the glycan moiety of peptidoglycan and their application in the indirect immunoferritin technique. FEMS Microbiol. Letters, in press. 3. Schleifer, K.H. and P.H. Seidl. 1974. The immunochemistry of peptidoglycan. Antibodies against a synthetic immunogen crossreacting with peptidoglycan. Eur. J. Biochem. 509-519. 4. Seidl, P.H. and K.H. Schleifer. 1978. Specific antibodies to the N-termini of the interpeptide bridges of peptidoglycan. Arch. Microbiol. 118, 185-192. 5. Heymer, B., D. Bernstein, K.H. Schleifer and R.M. Krause. 1975. A radioactive hapten-binding assay for measuring antibodies to the pentapeptide determinant of peptidoglycan. J. Immunol. 114, 1191-1196. 6. Seidl, P.H. and K.H. Schleifer. 1985. Secretion of fragments from bacterial cell wall peptidoglycan. In: Environmental regulation of microbial metabolism (Kualev IS, Severin AT, Dawes EA, eds). Academic Press, London, 443-450. 7. Franken, N., P.H. Seidl, E. Zauner, H.J. Kolb, K.H. Schleifer, L. Weiss. 1985. Quantitative determination of human IgG antibodies to the peptide subunit determinant of peptidoglycan by an enzyme-linked immunosorbent assay. Mol. Immunol. 22.< 57 3579. 8. Seidl, P.H., J.R. Golecki, N. Franken and K.H. Schleifer. 1985. Immunoelectron microscopic studies on the localization of peptidoglycan peptide subunit pentapeptides in bacterial cell walls. Arch. Microbiol. 142, 121-127. 9. Schleifer, K.H. and P.H. Seidl. 1977. Structure and immunological aspects of peptidoglycans. In: Microbiology (D. Schlesinger, ed). American Society for Microbiology, Washington, U.S.A. 10. Schleifer, K.H. and R.M. Krause. 1971. The immunochemistry of peptidoglycan. The immunodominant site of the peptide subunit and the contribution of each of the amino acids to the binding properties of the peptides. J. Biol. Chem. 246, 986-993. 11. Schleifer, K.H. and 0. Kandier. 1972. Peptidoglycan types of bacterial cell walls and their taxonomic implications. Bacteriol. Rev. 36, 407-477.
143
12. Seidl, P.H. and K.H. Schleifer. 1979 . The immunochemistry of peptidoglycan. Serological detection of a difference in a single N-terminal amino acid. Mol. Immunol. J_6, 385-388. 13. Seidl, P.H. and K.H. Schleifer. 1978. Rapid test for the serological separation of staphylococci from micrococci. Appl. Environ. Microbiol. 35.' 479-482. 14. Rogers, H.J., H.R. Perkins and J.B. Ward. 1980. Microbial cell walls and membranes. Chapman and Hall, London, U.K. 15. Wagner, B., M. Wagner, M. Rye. 1983. Morphological evidence for different types of IgG-Fc receptors in group A streptococci. Zbl. Bakt. Hyg. I. Abt. Orig. A 256, 61-71. 16. Munoz, E., J.M. Ghuysen, M. Leyh-Bouille, J.F. Petit, H. Heymann, E. Bricas, P. Lefrancier. 1966. The peptide subunit N0*-(L-alanyl-D-isoglutaminyl)-L-lysyl-D-alanine in cell wall peptidoglycans of Staphylococcus aureus, strain Copenhagen, Micrococcus roseus R2 7, and Streptococcus pyogenes group A type 14. Biochemistry 5, 3748-3763. 17. Spahn, K.F. 1977. Die Wirkung von D-Cycloserin auf die Biosynthese des Mureins. Thesis. University of Munich. 18. Seidl, P.H., P. Zwerenz, J.R. Golecki and K.H. Schleifer. 1985. Streptococcus pyogenes grown under sublethal concentrations of penicillin G accumulates close to the septum pentapeptide subunits of peptidoglycan. FEMS Microbiol. Lett. 30, 325-329.
SOLUBLE PEPTIDOGLYCANS: F O U N D IN M A N
A l l e n R.
LYMPHOCYTE-ACTIVATING
Introduction are
cell
thankful
wall
ten
had
from
yet (PG)
is d e f i n e d
water-soluble
by
be s h o w n ,
in
a
is
usually
exclusion sugar
to
products
in
products that
are
since the
their
bacterial the
First
progress
since
peptI d o g 1 y e a n s
literature.
and
It
between
cell
what
am
I
is wall
calling
(non-dia 1yzab1e),
secreted
into
the
medium
in the p r e s e n c e o f p e n i c i l l i n .
structural
and
from PG-turnover
immunological
cell the
Cl),
wall
amino
profile
growth
acids
including
identified from
a
a by
Sephadex
and
its
through
produced
by
medium
found
in
labeled
As
products
properties.
its G-100
lysozyme Sephadex
incubated
one
The
in t h i s e x p e r i m e n t w a s
hour
at
37°C
with
i n c u b a t i o n of containing the
PG,
chromatographic gel,
Its
G-100 50
of
the
a
of
beta-lactam salts
precursor. acid
Figure spent
aureus cells ug/ml
bacteria
and
Biological Properties of P e p t i d o g l y c a n © 1 9 8 6 W a l t e r d e G r u y t e r & Co., Berlin • N e w York - Printed in G e r m a n y
its amino
1 shows
the
minimal
cell
t h a t had
been
penicillin
14C-a1 a n i n e .
and SPG
immobility,
amino
sensitivity.
the
glucose,
PG-synthetic
growth medium from Staphylococcus label
the
differentiate
incubated
is g e n e r a l l y
analysis
elution wall
of
for
of
SPG
minimal
cofactors
markedly
S P G c a n be d i s t i n g u i s h e d
In v i t ro, S P G antibiotic,
Seidl
review, the soluble
degradation
its p h y s i o l o g i c a l ,
D e t e c t i o n of
Dr.
as the h i g h m o l e c u l a r w e i g h t
PG-like
University,
knowledge
measure
reported
outset
by s o m e b a c t e r i a w h e n will
One
and
Our
progressed ago.
been
the
peptidog 1 yean SPG
Schleifer
Workshop.
has
years
Jefferson
SPG
the t o p i c of t h i s not
important
Dr.
this
polymers
over
is that
CSPG),
SPG.
to
in o r g a n i z i n g
Workshop then
a n d d e f i n i t i o n of
all
effort
PRODUCTS
Zeiger
Department of Biochemistry, Thomas Philadelphia, Pennsylvania 19107
We
BACTERIAL
G
(2).
146
3
in I O x
2
QQ 1
0 0
20
40
60
80
100
120
140
F R A C T I O N NUMBER F i g u r e 1. Fractionation through a Sephadex m i n i m a l cell w a l l m e d i u m (4 M C i o f L - ( 1 4 C ) a C2x10 CFU/ml) incubated with penicillin G 60 m i n . The first peak coincides with Elution was with distilled water. 4
G - 1 0 0 c o l u m n of spent 1 a n i n e ) f r o m S^. a u r e u s (50 u g / m l ) at 3 7 ° C f o r the void v o l u m e , VQ.
3
«
I o x
2
Q. Q 1
0 0
20
40
60
80
100
1 20
140
F R A C T I O N NUMBER Figure 2. Fractionation through a Sephadex G-100 column of 14C-alanine-1abe1ed SPG (peak 1 in Fig. 1) w h i c h had been digested overnight with lysozyme. Elution was with 0.15 M phosphate buffered saline (pH 7.2).
147 Figure gel
2
is an
following
migrated intact pletely
as
low
to SPG
profile
Figure of
S^.
weight
residues,
immobilized
of
digestion.
molecular
D-Ala-D-Ala
antibodies. labeled
elution 1ysozyme
the
same
SPG
through
At
least
85%
of
components.
SPG
has
vancomycin
3 shows aureus
been
or
an e l u t i o n through
to
By shown
the
virtue to
same now
of
bind
D-Ala-D-Ala
p r o f i l e of t h e a
the label
its com-
specific
14C-a1 a n i n e
vancomyc i n-Sepharose
4B
co1umn. 4
\ i o
Q. o
— O O O O OO0OOO0—I— 5 10 15
20
_°oU 25
FRACTION NUMBER Figure. 3. Fractionation through a vancomycin-Sepharose c o l u m n of 1 4 C - a 1 an i ne-1 abe 1 ed SPG f r o m j>. a u r e u s • The r e p r e s e n t s a c h a n g e f r o m 0.15 M p h o s p h a t e - b u f f e r e d s a l i n e 7 . 2 ) to N H ^ O H (pH 1 0 . 2 ) .
'tB arrow (pH
148 These
specificities
an e n z y m e - 1 i n k e d illustrated with
in
of
purified Ala-D-Ala)
SPG, rabbit 5
'
1
),
first
antibody
avidin
plus
allowed
Figure
vancomycin,
amount
have
immunosorbent the
Plastic fluid
antibody
species
biotlnylated
as
4 U
horseradish
biotin
SPG _i_ri v i v o whose
coated
)
n
steps an
case,
unknown affinity-
'—(A1 a - y - D - G 1 u - L y s - D -
Immunoglobulin Is
covalently
peroxidase
and
of
substrate.
SPG
Rabbit Anti- S P G
Biotinylated A n t i - R a b b i t IgG
E-Jlf-E
'ABC"
• O
Enzyme Substrate
#
•• o
Figure.
4.
Sequential
steps
in the ELISA
to detect
the
bound,
Vancomycin
O
by are
successively
containing
Cin this
against
which
of
(3)
are
urine
( G l u A l a
antibody to
(ELISA)
D-Ala-D-Ala
to
second
detection
wells
such
to
antibody a
the
assay
SPG.
149 Physiological SPG
is
properties
secreted
exposed
to
1uteus
CO,
(6-7).,
S.
by
aureus (9), SPG
gram-negative PG-turnover
(2), and
has
for
(12).
organism
has
been
incubation medium
by
penicillin
trigger
SPG
G,
amounts.
mecilllnam,
by
yet,
from
the
SPG.
St r.
no d e t e c t a b l e G,
SPG
reported in t h e
PG
this (6-7).
to h a v e
secreted
grown
of
no
in w h i c h
penicillin
is
Bac i 1 1 us
any
secreting
SPG
that
by
is
1 uteus
S e c r e t i o n of
cillin occurred
into
PG the
presence
of
pg/ml)
S^. a u r e u s
to
very
from
(2).
be
not (2)
cells
synthesis
on
the
the
penicillin-class amplcillin
mainly that
of
trigger
One
beta-
secretion
on
was
gram-negative
most the
beta-lactam secretion
of
cells.
of on
and
SPG
Is d e p e n d e n t
1 hr.
dependent
dependent
can
cefoxitin.
cause
act
did
In a p p r o x i m a t e l y
antibiotics
approximately
methlclllin and
to
to
different
Maximal
shown not
unable
reported
in
semisynthetic
( 4 ) or S^. a u r e u s
S P G by
cells
oxacillin,
Vancomycin
5 (2).
beta-lactam
cephalothin was
a mechanism (14).
of
S^. a u r e u s
include
like
which
antibiotics
(10-200
of
has been
no
As
is o n e w a y
to h a v e
of
hand, or
variety
like n a f c l l l i n ,
antibiotic
been
secreted
bacteria when
from
These
cephalosporins
although
a
secretion
antibiotics
also
(10).
source
reported
(8),
(10).
Besides
Figure
be
capable
little these
to
presence
on the other Yet,
a n a e robi s
faec i um
Streptococcus
differentiatab1e
the
reported
(10),
when
M i c rococcus
Streptococcus
1 i chen i form i s
bacterial
has been in
bacteria
include
(5),
pyogenes
are c l e a r l y
Yet,
(13).
pen icillin
in
bacteria
reported The
instance,
Escheri ch i a co1i,
S P G by M .
These Bac i 1 1 us
been
products
faec i um,
bacteria
gram-positive
Peptococcus
bacteria.
turnover
lactam
G.
of
Streptococcus
(11)
detectable
and
variety
penicillin
p n e u m o n i ae
same
a
SPG
Brev i b a c t e r i um d i var icatum
s u b t i1i s
turnover
of
SPG
in
Maximal the
on time 50
yg/ml
SPG
density
penicillin
G
as
shown
of
peni-
secretion of
has
bacteria
concentration
150 A. 12 I " 4.5 X 10®DPM 10 £ = 2.7 X 105DPM
x 5
£ = 3.8 X 10SDPM £ = 1.1 X 105DPM
I
V 20
J 20
40
J
L i L 40 20 40 FRACTION NUMBER •
I
20
L
40
F i g u r e . 5. F r a c t i o n a t i o n t h r o u g h a S e p h a d e x G - 1 0 0 c o l u m n of equal portions of s p e n t minimal c e l l , wall medium Ct vCI of L - ( 1 4 C ) - a l a n I n e ) f r o m S^ a u r e u s (2x10 CFU/ml) incubated with p e n i c i l l i n G ( 5 0 y g / m l ) at 3 7 ° C f o r d i f f e r e n t t i m e s . Only the Initial p e a k ( p e a k 1) f r o m e a c h i n c u b a t i o n is s h o w n . P a n e l A , 15 m i n ; Panel B, 30 m i n ; panel C, 60 m i n ; panel D, 120 m i n . T h e VQ is i n d i c a t e d in p a n e l A . T h e t o t a l r a d i o a c t i v i t y r e c o v e r e d in e a c h p e a k is s h o w n in e a c h p a n e l . Elution was with distilled w a t e r.
Studies (11)
have
cillin at
with
G
taining was of
shown
that
treatment.
least
filtered
S^. a u r e u s
four and
evidence
that PG.
s u b t ills
is one
generations
incorporated
derived
SPG In
Incubated
3H-labeled
synthesis
(2),
alanine
into
similar SPG
in
is
SPG to
not
St r.
synthesized
jde n o v o
S^. a u r e u s
in and
over a
and
experiment, the
minimal
that
(9)
presence cell
wall
penicillin a
120
minute
In F i g u r e
5.
degradation
following was
of Only
period This
peni-
grown
for
L-l'tC-a 1 a n I n e ,
growth
G.
p n e u m o n I ae
medium
3H-label
with
kinetics
provides
product
con-
the
of
cell
further wall-
151 Structure
of
Figure
6
depicts
ported
as
40,000
d
for
(5), (63
that
SPG
from
1 uteus
M. and
a
Str.
typical
d for St r. (4),
which
relatively
peptide
however,
results
in t h e
secreted
- NAG
of
lowering
to 5 pg/ml SPG
high
- NAM
SPG
SPG
from
to
modification to
of
be
Shockman of t h e
faec i um
f a e c i urn
lysozyme-
the
glycan
(>_10pg/ml),
highly, has
concentration
hydrolysis
re-
50,000
Str. be
concentrations
appears
been
B_r. d i v a r i c a t u m
shown
if
not
evidence,
from
50
D-Ala-D-Ala
vig/ml
sequence
(7).
NAG - NAM Ca)
- NAG - NAM - NAG | Ala I - y - DA(b,c) etc. I D-Al a I D-Al a
I Ala I D-Glu I (e)
has
(4) and
subt i 1 i s (9),
(4,7,9).
Str.
SPG
1uteus
been
little
the
in s o m e
-
have
of
M.
The B.
the p e n i c i l l i n
by
size
from
penicillin
uncross-1inked
that
The
(2),
(11)
indicates
portion
completely,
aureus
p n e u m o n i ae
sensitive, the
SPG. product
f a e c i urn ( 7 ) . S^
chain.
At
the
- NAM | Ala I etc.
(d)
NAG = N-acety1-D-g1ucosamine NAM = N-acety1-D-muramic acid DA = D i am i no acid Figure. There 6),
are
many
cell
Most
although
contain
The general
structural
of w h i c h
wall.
chain, (5)
some
6.
reflect SPG
the
amide the
SPG
SPG
from
not have
although (4).
appear
acid.
The to
However, been
respectively
in t h e
d i a m i n o p i m e 1 ic
tion
glycine
among
differences
have
a
at
acid. the from M.
SPG
reported
to
at
the
from have
"peptide
SPG
D-glutamic M.
1 uteus (4)
bridge"
S^. a u r e u s
(a-e
in t h e 3 of
and have
in
the
peptide
B_r. d i v a r i c a t u m either
a
acid
residue
is
peptidated
attached (2)
and and
Fig.
bacterial
at
a n d _B. s u b t i1 i s
pentaglycine bridge".
SPG. SPG
PG
position
Most
1uteus
"peptide
the
in t h e i r
lysine
of
f r o m j3. s u b t i 1 i s ( 9 )
a 1pha-carboxy 1 or 2,
differences
contain SPG
structure
to Str.
the
free posi-
with
a
(9)
do
diamino
faec i um
(7)
D-isoasparagine
152 The
muramic
fully to
SPG
only
from
knowledge, (15-16) been
shown
possible
from
substituted lysozyme, was
able
weight an
showed body in
eluant
seen all
all
peptide the
of and
peptide
further
does
been
been
Since
for
for
M.
PG
be
contrast acids
(4,9).
peptide
respective
in
to
muramic
To
described
PG
with
appear
is
reported
the
to
not
95%
of
about
Figure SPG
in
my St r.
M.
1uteus
1 uteus (18),
has
It
in t e r m s o f
Is
their
in
the
glycan
low
The
Into
of
among was
(20).
and
PG
a
chromatothat
SPG
bound The
by
studies an
first of
there
strands. antichange
tripeptide
in e l u a n t w a s
peptide.
This
from
The M.
to
with
arrangement
1 uteus
a
indicates
least m o n o s u b s t i t u t e d
multi-substituted. SPG
the
T4
(19),
molecular
chromatographic
change
the at
as
suggest
concentration
second
randomly
activity small
glycan
1ut e u s
sequences
either
for
This would
strands were the
of
M.
concentration
that most were
be
ha 1 f - u n s u b s t I t u t e d .
peptide
affinity
relatively
the g l y c a n strands
35%
from
D-Ala-D-Ala
higher
the
(19). 7,
to
substitution
unsubstItuted the
a
appear
substituted,
product
in
of
for
study.
This whose
peptide
not
have
peptide
Lys-D-Ala-D-Ala.
hundred-fold that
leaving
fully
was
containing
about
immobile
specific
have
their
half-fully requires
products,
as
with
substituted
1 uteus
nor
that
(7).
faec i um
s u b t i1i s.
(17).
poorly
to d i g e s t
However,
chains
enzymes
SPG m i m i c
M.
almost
St r.
substitution.
which
graphically was
be
from
and
amidases
these
the
peptide
SPG
peptide
s u b t ¡lis
to
that
SPG
substituted
L-alanine B.
of
1ut e u s
half
whereas and
overall
with M.
about
faec i um,
The
moieties
substituted
the
are
acid
must
of
await
153
12
16
20
TUBE NUMBER
15 _
B
10
&
5
12
16
20
TUBE NUMBER F i g u r e 7. Affinity chromatography on purified rabbit antibodies to s y n t h e t i c PG-precursor pentapeptide bound to S e p h a r o s e 4B. The top panel is a n e l u t i o n profile of 580, 000 c p m of l'+Ca 1 an i ne-1 abe 1 ed SPG f r o m M. 1 u t e u s a n d the b o t t o m panel is a n elution profile of 62, 000 c p m 1'tC-g 1 y e a n - 1 a b e 1 e d SPG from M. 1uteus. The f i r s t a r r o w r e p r e s e n t s a c h a n g e to 0.02 m M t - b u t y l o x y c a r b o n y 1 - L y s - D - A l a - D - A l a. The two pronged arrow represents a c h a n g e to 2 m M of t h i s t r i p e p t i d e .
Digestion left
of
10-15%
the
when
produced
and
14C-labeled
covalently not
the
containlng
that
Even
portions
that
no
their
sodium
the
non-SPG
was
of
properties
In
belong
glycerol
sulfate
from
an and
to
recently
the
the
the
affinity Shockman SPG
be
portion
from SPG
rhamnose-
biological
must
SPG
could
obtained
cova1ent1y-attached
to
aureus,
molecule
Barrett
precautions
lysozyme
acid-like dodecyl
investigating
SPG,
S^.
3H-labeled
attached
has
white
from
molecule
Although
laboratory
(22).
egg
SPG
teichoic
1.5% of
hen
The
containing
a
St r . f a e c i u m w i t h
properties the
had
with
CO.
vancomycin.
saccharide
immunological
1uteus
medium
(21).
two
(7), from
M.
material
alanine,
reported
faec i um
preparations
ensure
from
a minimal
containing
originally S t r.
in
attached
separate
column
SPG
undigested
taken of
and to the
154 molecule.
The
saccharide
complexes
this
precaution
a s to h o w SPG
review
the
of by
(23).
the Dr.
inflammatory Schwab
It r e m a i n s
structure
of
properties
should
reinforce
an o p e n
S P G will
field
influence
of the
for
PG-polyneed
for
investigation
their
properties.
in m a n
The
ELISA
man
(24).
mentioned
penicillin within pletely
6
used
to d e t e c t
volunteers
V,
seven
positive
hours
of t h e 1.
had
(test
abolished
Table
was
13 h e a l t h y
Lys-D-Ala-D-Ala none
above
Of
column
with
In
titers Table
a synthetic
(control
SPG
V
of
250 mg d o s e s
of
for
in
1).
Before
in U r i n e
Penicillin
urine
ingested
SPG
in t h e
SPG The
trlpeptide,
column).
pat i ents had d e t e c t a b l e Study of
that
urines
was
com-
t-buty1oxycarbony1 -
penicillin
levels of
ingestion,
in t h e i r
SPG
Samples S i x
Treatment
their
binding
urine.
Hours after
•
A b s o r b a n c e at
490
nm
Subject Sex
and Age
(yr)
M 41
Pre-- t r e a t m e n t
Post- treatment
Test
C o n t ro1
Test
.010
.009
. 043a
.011
a
.015
F 36
.014
.013
. 16 7
F 13
.010
.010
,110a
.009
.010
.013
M 40
C o n t ro1
.0 12 .012 a
.013
F 37
.010
. 007
. 157
F 50
.015
.017
. 042a
.011
M 36
.012
.012
.009
.011
M 27
.010
.013
.012
. 016
F 47
.011
. 014
. 2 3 33
. 021
M
34
.013
.012
.013
.012
M 36
.015
. 014
.013
.015
F 58
.010
.011
. 028a
.0 10
M
26
.007
.009
.008
.009
a
Considered
positive.
155 The
diversity
flects
what
bodies
in
observed
has
been
humans
(25-27).
the t w o o b s e r v a t i o n s SPG Dr.
has
many
Seidl
Figure
of
has
D-Ala-D-Ala
among
found
the
are
several
It
is
related.
criteria
already
portion
individuals
in
discussed
8, t i t e r s of a n t i b o d i e s
sera from patients with
SPG
the
a
anti-
speculate
that
is e v i d e n c e
that
natural
In a d d i t i o n ,
from
patients
who
Furthermore,
there
bodies
correlated
with
that
the
antibody caused
onset titers
of to
was
were
an
endocarditis
treated
increase
with
infection.
of
antibiotic Figure
D-Ala-D-Ala
with
in t h e
of
the
patients
in t h e in the (27).
these rather
time
with
antithan
course S^.
in
bacter-
but not
treatment,
9 shows
among
and
vancomycin
titers
the
as s e e n
to D - A l a - D - A l a a r e e l e v a t e d
S-. a u r e u s - c a u s e d
emia who were treated with beta-lactam antibiotics sera
immunogen.
immunodominance
in SPG.
re-
anti-PG
to
there
for
detection
of
interesting Indeed,
expected
so p r e v a l e n t
in
reports
of
aureus-
bacteremia.
NORMAL BLOOD DONORS (31)
VANCOMYCIN TREATED PATIENTS (14)
p- LACTAM ANTIBIOTIC TREATED PATIENTS (33)
F i g u r e 8. P e r c e n t a g e of b i n d i n g of P G - p r e c u r s o r a n t i g e n by h u m a n sera. T h e h o r i z o n t a l bar r e p r e s e n t s the a v e r a g e p e r c e n t a g e of binding. T h e v e r t i c a l line s h o w s the s t a n d a r d d e v i a t i o n .
156
60 - A. Rb NAFC
40 • •
20
••
•
0
I
I
I
1
1
60 - B. Rw
NAFC
40
•
•
•
•
• •
•
i o 20 z
S 5
o tr
> 0
60 -
1 1 C. Lu
1 1
1 1
|
|
1
40
1
•
20 t
m
• 1 1
0 60 "
OX AC, DAY 0 KEFLIN, DAY 12 KEFLEX, DAY 41
1 1
1 1
i 20
i 30
1 1
•
D. Wa
•
| 1
•
PEN
40
•
20 i 10
i 40
i 50
60
T I M E (days) F i g u r e 9. P e r c e n t a g e o f b i n d i n g of P G - p r e c u r s o r a n t i g e n by s e r a from four staphylococcal bacteremia patients at v a r i o u s times after the initiation of a n t i b i o t i c therapy. N A F C is n a f c i l l i n ; 0XAC is oxacillin; Keflin is cephalothin and Keflex is cephalexin.
At
least
SPG
three
found
genous
in
the
bacteria
appreciable (28). have
possibilities
On
the
SPG
D
other
There
can
colonization
group
secrete
urine. that
hand,
A
account may
be
secrete
by
streptococci
(28).
can
virtually
variation
of
a
SPG.
aureus
which
for
in the
have this
the
diversity
diversity Not
all
their
the
have tract
population
reported
possibility
is
able that
the
indi-
humans
intestinal
entire been
of
of
does to not
157 all
bacterial
amount
of
vitro The of
l o c a t i o n of the
seven were
played
a
across
the
individuals
is
in
host
active
to
The
exclude
host
or
include
genetic
the
the
first
the
random
and
(30). mice the of
Table
antibody
polymer.
for No
may
be
SPG
of
the
for
SPG
concentra-
more
vary
or
less
in
the
exposure
to
SPG-like
Peptidog 1 yeans,
with
synthetic
host
Dr.
poly
polymer
but
random
shows the
not
polymer the
poly
in
humoral (Glu^"
against In
the
H2-q H2-b
random to
in
were
the
observed
of
mice
Low
the
to
titers The
correlated
immunogenic In
the
inbred
obtained.
polymer
the
haplotype
response
polymer.
to
conCGlu^"
in m i c e
the
the
to
poly
in a n y
peptide
was
of
immunogenic
Ala^")
response
titers
of
the
begun
bound
and
and
noted
control
immunogenic
mice
is n o t
PG-precursor humoral
is
PG,
immunogens
Ala^)
to
above,
immunogens.
I have
covalently
(Glu^"
to
Krause
PG-like
pentapeptide
response
mentioned
(29).
Increase
of
possibilities
antibody
reasons
genetic
the
have
in m a n
possible
2
The
These
peptides
on
their
lysozyme may
response
random
the
as
the
titers obtained
found
b1eeds.
to
passage
PG-precursor
haplotypes,
(30).
in may
structure.
the host. such
Six
SPG-secretIng
early
carriers,
latter
the
its
macrophage
SPG
of
on
question
PG-precursor
higher that
d
The
the
immune
from
former
SPG
in
(2).
important. of
of
secretion.
diversity
PG-precursor
The
of
S^. a u r e u s
bacteria
but on
enzymes
the
with
investigating
sequence
Tyr*").
tract,
enzyme
the
the
to
location
same
SPG
further.
Workshop
of
this
taining
H2-b
of
response
examine
for
resulting
importance immune
or
levels
the
secrete
be
vaginal
interplay
diversity
control
tolerance
the
perhaps
cross-reactive
possibilities
PG
that
is d e p e n d e n t
the
secrete to
isolates of
positive
SPG-degrading
can
ability
bacteria may
intestinal
investigated
Antibodies
with
barrier
in o p s o n i z a t i o n
to be
clinical
suggesting
the
potential
organism
in t h e
Alternatively,
also cannot
need
given
SPG-secret1ng
the mucosal
tion of from
a
diversity
female,
role.
bacteria
One
of
Such
has been observed with
urine
At
strains
SPG.
with
random
secondary
158 Table
Dose
2.
I m m u n i z a t i o n of C 5 7 B L / 6 M i c e
CH-2b) with S 1 (A1a-y-D-Glu-Lys-D-Ala-D-Ala) .
(yg)
Bleed
Anti-pentapeptide
(%)
(Glu60
Ala't0)L n
Anti-carrier
C%)
100
primary
22.6 + 3.6
56.9 +
4.7
1
primary
14.6 + 8.0
24.5 +
14.0
100
secondary
19.2 + 5.5
60.8 +
8.2
1
secondary
7.5 + 6.3
The
results
with
the
same
immunogen against
3.
observed
in t h e s e H 2 - d m i c e at
mice.
The
Immunogen
humoral was
immunogen
at
primary
response similar
to
response
again
alone.
especially the
higher
titers
in T a b l e
Secondary
the
1 yg
dose
bleedings.
The
the
to w h a t
PG-precursor has
random polypeptide
Table
3.
been
In H 2 - d the
100
that
responses
to
mice
portion
reported
polymer
portion
of
random
the
of
for
be
higher
did
not
the the
shown
than
mount
were
in H 2 - b of
the
polymer
to the P G - p r e c u r s o r
appeared H2-q
is
peptide
1 yg d o s e s t h a n
random
to
Inbred m i c e
PG-precursor
yg a n d
to the
equivalent
33.8
portion those
an
immunogen.
This
immunogen1city
of
immune of
was the
alone.
I m m u n i z a t i o n of
BALB/c Mice
(H2-d) with CGlu 5 1 .
Ala
n
CA1a-y-D-Glu-Lys-D-Ala-D-Ala) Dose
(yg)
Bleed
Ant 1-pentapeptide
(%)
Anti-carrier
100
primary
36.5 + 10.9
69.5 +
4.5
1
primary
26.4 + 12.3
63.6 +
3.0
100
secondary
47.8 +
14.3
74.9 +
3.4
1
secondary
53.2 +
11.6
69.9 +
4.4
(%)
159 With
a
100
sera
yg
of
H2-b
appears
hapten
and
H2-d
for
the
that
to
of
the
the
one
the g l y c a n
and/or
As
previously
aureus
Infections,
of
PG w o u l d
above
diseases
indigenous important patient disease.
This
associated this
the
ant I-PG
has
done
not
been will
inspire
of
such
as i>.
rheumatoid serology
Some of
the
either
by
these
antibiotics.
Since
be
quite
capable
antibiotics, history
most
previous
with
In the
Often,
with
a
titers
the
titers
with
governed SPG.
infection,
therapeutic
anti-PG-tI ters
review
properties
observation of
should
to
from
murine ability inbred
as
of S^.
a
of
Is
of
the
particular studies
pathogenic
renewal
of
It
our
that
bacteria. efforts
in
can
of
be
its
properties
testimony
PG
are
aureus
SPG
SPG
SPG
study
lymphocytes of
of
that
the
biological stand
properties SPG
specify
anti-PG
the
field.
dimension trum
and
be
Importance.
to
had
classic
with
Thus,
beta-lactam
correlating
elevated
this
Biological The
know
to
organisms.
shown
to
the
with
and adult
beta-lactam
been
exposed
a
diseases,
to b a c t e r i a l
with
have
when
to
linked
as
relationship
juvenile
gram-negative
poly
In
what
analogy
of a
spondylarthritis.
treated
when
Perhaps,
been
or
SPG
reports
to v a r i o u s
to
acting By
associated
to be o f s o m e m e d i c a l
bacteria
secreting
Is
indicated
fever,
to
mice.
immunogenIcIty
are
sera
linked
similar
carrier.
have
rheumatic
have
are
also
in t h e s e
peptide
the
there
ankylosing
gram-positive
was
non-PG material
In h u m a n
appear
Infections
expect
any
reports
antl-SPG and
This
peptide
titers were observed
polymer
polypeptide
mentioned, These
of
arthritis,
mice.
would
titers
antibody
PG-precursor
SPG m o l e c u l e ,
sera.
PG-precursor
random
random
by
human
the
no d e t e c t a b l e
been observed It
dose
Tyr1"),
(Glu^"
has
of
the
related been
In
S^.
aureus
mice.
humans
cell
to
wall-derived
to
effects
Interactions
shown
capable act
gives
properties.
potential
_i_n v i t ro a n d J_n v i v o
from
and c o n g e n l c
to
found
biological
as
of
C31). a
of
with
PG
an
added
The
spec-
and
SPG.
lymphocytes.
Interacting Table
mitogen
MDP Many
4 In
with
shows
the
outbred,
160 Table
4.
Mitogenicity
of
SPG
splenocyte Add i -
Conen
t i on
BALB/c
Cyg/mO
cpm
None
f r o m S^
aureus
in m u r i n e
cultures. Swiss Webster
SI
a
cpm
4, 569
BIO .M
SI
cpm
SI
4, 888
6, 142
1
183,152
40.. 1
Not
LPS
30
111,301
24..4
134,037
2 1,.8
19,103
3.. 9
SPG
100
127,518
27..9
131,978
2 1..5
45,419
9.. 3
SPG
33
177,823
38,.9
119,439
19.. 5
25,010
5., 2
SPG
11
32,488
7. 1
19,254
3. 1
24,003
4,. 9
24,447
5 ,4 .
Con
A
SPG a
3.8
SI,
Stimulation
Table
5 shows
days
1 or
remove activity LPS
Treatment
(Table
indicating cell
that
5.
the
with
did
6).
not
The
murine
mitogens
Table
the m i t o g e n i c
lymphocytes
(another
B
Add i t i on
B cell
of
in e u 1 tu re
effect
Not
is g r e a t e r
anti-theta result
mitogen)
of
(Table
and
any
loss
SPG
gave
done
done
from
day
3
than
complement of
S^. a u r e u s
synergistic stimulated
to
mitogenic with
responses,
by t h e
two
7).
the M i t o g e n i c by
at
serum
in
subpopulations
are different Kinetics
Stimulation
SPG from
1
of
BALB/c
S^. a u r e u s .
2
3
Conen (yg/ml)
None Con
done
combination
cell
Splenocytes Day
Not
Not
index.
that
2.
T
done
cpm
SI
cpm
5,851
1. 9
5 8 , 109
5.. 5
150,371
9.. 6
36,239
3..4
126,886
8.. 1
22,049
2, . 1
SI
cpm
SI
3, 169 A
1
LPS
30
8,549
2 .7
SPG
100
3,532
1 .1
SPG
50
SPG
25
Not done 2,319
0 .7
Not
done
24,097
2. 3
85,782
5. 5
101,125
6.. 5
33,635
2. 2
B
161 Table
6.
Mitogenicity Depleted
of
S P G f r o m JS. a u r e u s
Swiss Webster Complement
Add!-
Conen
tion
on 1 y
Cyg/ml)
+
ant i -6 SI
cpm
1,478
C o n .A
T-cell
Complement
a
cpm
None
in
Cultures.
SI
2,069
1
98,000
66.3
5,522
2.7
LPS
34
12,500
8.5
75,963
36.7
SPG
25
14,674
9.9
24,108
11.7
3
k
C o m p 1 e m e n t o n 1 y resu1 t e d
in a 10%
C o m p l e m e n t + a n t i-6 C a n t i- t h e t a of
loss of
c e l l u l a r v i ab i1 1ty.
serum) resulted
i n a 45%
loss
c e l l u l a r v i a b i1 Ity.
Table Thereof
7.
Effects
on the
Add i t i on
3H-TdR
None
M itogen
cpm
None
of
B Lymphocyte Incorporation C10
SPG
Mitogens by
Combinations
Swiss Webster
ug/ml) add i t i ve
cpm
and
LPS cpm
Splenocytes. C10
ug/ml)
a d d i t i ve
5,333
SPG
11,030
LPS
27,124
46, 0 9 6
CT-G-A-G)
20,049
26,452
Dext ran
17,212
21,077
36,218
23,598
a
46,096
32,821
25,746
57,304
23,800
22,909
61,696
39,003
41,915
72,510
58,009
32,821
sulfate
a
Poly
I.
Poly
C
Underlined
v a l u e s s i g n i fy
ag r e a t e r
than add i t i ve response.
162 SPG
from
Table
S^
aureus
8 shows
secreting blood
the
cells.
cells
immunoglobulin shows
that also
globulin the
SPG has
Antibody
hand
will
a
increases
are
column
are
again,
Effect
of
SPG
effect
to t h e
LPS
Conen
11 o n
(yg/ml)
1
2
None
0 30
5,250
000
SPG
33
7,750
5,250
PG
ND
400
a
ND,
k
The c o n c e n t r a t i o n
The
Not
to p l a s m a c e l l s 100 were
the
pg o f
PBA.
SPG
number
cells
from
of
immuno-
a n d no p r o t e i n A rather
to
In
SRBC.
coupling
significant
cells.
PFC R e s p o n s e
of
Cultures. eel 1 s IgM
IgG
(expt
1) C e x p t
1) C e x p t
2) ( e x p t
52
1,603 NDa
ND
S^.
as w e l l .
immune
secreting
a
column
1,081
ND
2) 17
ND
ND
49,725
4, 492
38,076b
50,808
7,814
73,747
6,263b 17,956
determined.
proliferation
9 shows
as
hand
IgG
0
LPS
giving
nearby left
IgM
Expt
Expt
red
SRBC
a u r e u s on the
Splenocyte
sheep
secreting
the
PFC/106 Addi-
A-coupled
lymphocytes
produce
immunoglobulin
(PBA).
Immunoglobulin-
splenocytes
with
SRBC
activator
of
in t h e
on
immunized
from
BALB/c
the
equivalent
SPG and
of
of
results
directly
Once
protein
The data
both
among
number
Those
lysis
stimulatory
In t h e n u m b e r
8.
a
B cell
the
utilizes
field.
cells
bind
is n e c e s s a r y .
Table
LPS
secreting
right
SRBC
and
polyclonal
SPG on
complement.
cause
the
a
of
assay
and
will
plaque on
also
The
(SRBC)
clear aureus
is
effect
of
of m u r i n e
by
SPG
results of
SPG
or
examined.
mitogens
and
compared
to t h e
SPG for
LPS. SPG
B cell
this
experiment
splenocytes
f r o m S^. a u r e u s iv
inoculations
After
and
three
LPS w e r e
activators,
control.
or
and their
75
pg/ml.
differentiation
a l s o o c c u r s _i_n v i v o . of
Swiss Webster
four
equivalent giving
was
about
days,
the
In t h e i r fivefold
mice
Table with
splenocytes abilities
as
stimulation
163 Table
9.
J_n V i v o
Prol i f e r a t i o n
Lymphocytes with Treat-
Animal
Cells/spleen
ment 1 C o n t ro1
SPG
LPS
st i m u 1 a t e s. factor
SPG as
Further uate
the
term
or
of M u r i n e
PFC/2
cells)
1, 147
-4) -ff-acety lmuramyl-Lalanyl-D-isoglutamine, or GMDP, has been chemically synthesized (1,2). It was found to possess a higher immunoadjuvant activity in comparison to that of MDP (Ai-acetylmuramyl-L-alanyl-D-isoglutamine)
(3). Recently GMDP has been obtained
by an enzymatic degradation of the peptidoglycan of Actinomaduva
R 39 (4). The
structure of the peptidoglycan was demonstrated in (5) and is given in Fig. 1. The peptidoglycan was successively hydrolyzed in jT] by the lysozyme, in [T| by the DD-carboxypeptidase G from Streptomyces albus G and in [3] by the Y - D - g l u ~ tamyl-meso-diaminopimelate endopeptidase I from Bacillus sphaerieus 9602. The enzymes were used in their soluble form.
V
Mur NAc
/
0
Glc NAc X
^/rNAc
ms Azpm
Glc NAc
MurNAc MurNAc
m
Q ] Glc NAc
GlcNAc I ^ Q ] GlcNAc L-Ala-D-GluNHj
Qlpr Glc NAc L-Ala-D-GluNHj H ?
m / Glc NAc
«
I3J "
L-Ala-D-GluNH, I3JD-Ala
j_
ms A2pm
ms Azpm
H]
Fig. 1 : Peptidoglycan of Ae.tinomadura R 39 (from M. Guinand et al. 4).
Biological Properties of P e p t i d o g l y c a n © 1986 Walter d e G r u y t e r & Co., Berlin N e w York - Printed in G e r m a n y
390 We managed to improve the method by immobilization of two of the enzymes, DDcarboxypeptidase G and endopeptidase I, and we produced substantial amounts of GMDP and of related glycopeptides whose chemical synthesis is difficult if not impossible (submitted for publication). A survey of the method is now reported as well as a preliminary study of the biological properties of the glycopeptides.
Immobilization of DD-carboxypeptidase G and properties of the bioreactor. The DD-carboxypeptidase G (EC 3.4.17.8) was purified as described in (6) and 12 units of enzyme were obtained from 25 liters of Streptomyces
albus G. They were
immobilized on Ultrogel AcA 22 treated with glutaraldehyde as recommended in (7); two reactors were prepared : the first one was saturated in enzyme with 0.9 unit of DD-carboxypeptidase G linked to 1 ml of gel and it was used to study the properties of the immobilized enzyme. The second reactor was made with 11.1 units of DD-carboxypeptidase G immobilized on 60 ml of gel ; it was packed inacolumn (2.6 x 12 cm) and it was used for the digestion of the peptidoglycan. The properties of the saturated gel were studied with Ac2 _ L-Lys-D-Ala-D-Ala as substrate. The heat stability of immobilized DD-carboxypeptidase G was examined in comparison with that of the free enzyme. At the inactivation temperature, where the remaining activity is half of the original activity,the immobilized enzyme is more stable than the free enzyme by 10°C. It was also found that the immobilized enzyme retained roughly its initial activity even after one year. The kinetic constant, K' > of the immobilized enzyme was studied at 37°C in a small packed bed reactor of 0.3 ml. Various S q concentrations of Ac^-L-Lys-D-AlaD-Ala we're pulsed through the column at various flow rates and samples were taken out for enzymatic assays of released D-Ala (8) until the maximum substrate conversion rate was obtained. K ' m has been determined according to the MichaelisMenten equation : P . S n
o
- K1
m
. Log(1-P) = V / V (9). S is the initial con6 m s o
centration of substrate and P the maximum substrate conversion rate. The different P . S q datas were plotted versus - Log(1-P). Straight and parallel lines were obtained at the different space velocities and a K' m of 2 mM was calculated from the slopes. It is only 6 times greater than that for the free enzyme (10). Thus the properties of the immobilized DD-carboxypeptidase G (stability towards heat and time as well as kinetic constants) are all suitable to its permanent use as a bioreactor, at any flow rates experimented.
391 Utilization of the immobilized DD-carboxypeptidase G Over a culture of 70 1 of Actinomadura R 39, 7 g of cell walls were obtained as described in (4). They were solubilized by the lysozyme by portion of 1 g and the solutions were separately pulsed and recycled through the reactor thermostated at 37°C at a flow rate of 6 cm.h
Samples have been analysed for amino ter-
minal groups (11) until the completion of the reaction. The products were then eluted and separated through Sephadex G50-G25 columns according to a classical procedure. A disaccharide-peptide monomer (K av 0.60) and a disaccharide-peptide dimer (K^O.42) were subsequently desalted on Trisacryl GF 05. From the 7 g of walls the yield was 750 mg of monomer and 250 mg of dimer. The monomer or GMTP : N-acetyl-B_D-glucosaminyl-( 1->-4)-N-acetylmuramyl-L-alanyl-D-isoglutaminyl-(L) meeo-diaminop ime lyl(L)-(D-alanine) was shown to be a mixture of disaccharidetetrapeptide (87%) and disaccharide-tripeptide (13%) ; the dimer, di-GMTP, possess an osidic linkage (MurNAc-KJlcNac) between two moles of GMTP.
Immobilization of endopeptidase I and properties of the
immobilized enzyme
The endopeptidase I was obtained from 100 liters of Bacillus sphaerieus. The enzyme was extracted from the sporulation medium and from the spores and was purified as described in (12). Five units of enzyme were obtained. We previously demonstrated that endopeptidase I was firmly bound to phenyl-Sepharose by hydrophobic interactions(12) ; the purified enzyme solution was then simply loaded at pH 8 on a phenyl-Sepharose column (2.6 x 12 cm) and the properties of the gel were studied with GMTP as substrate. The conversion of GMTP into GMDP was analysed by quantitative reversed phase HPLC in an ammonium phosphate buffer at pH 5.5. The inactivation temperature which is already very high, 80°C, for the free enzyme is maintained but not enhanced by immobilization. The time stability is constant over several months. A K' of 2.5 mM was determined as described m above in a small packed bed reactor of 0.3 ml. It is smaller than that (4.34 mM) for the free enzyme. This oan be due to the fact that endopeptidase I is naturally particulate and acts better in its immobilized form than in its soluble form. So, the immobilization of endopeptidase I is particularly compatible for its permanent use.
Production of glyco-dipeptides with immobilized endopeptidase I The compounds GMTP (256 mg) or di-GMTP (151 mg) were pulsed and recycled through
392 the reactor of endopeptidase I at a flow rate of 6 cm.h ^. Aliquots w e r e
remo-
v e d and analysed by HPLC until the completion of the reaction. The purification of the resulting compound GMDP or di-GMDP was
achieved by chromatography in w a -
ter o n a Dowex-50 (H + ) column as described previously (4). The yield was 136 m g of GMDP and 95 m g of di-GMDP.
Biological
activities
In the present paper two assays are only reported : the phagocytic activity of macrophages (Table 1)and the antibody
Table 1
production in mice'
Effect of Glycopeptides o n Carbon Clearance by System of Mice*.
Material tested
Amount m g / kg
Phagocytic index(.10 - 4)
(Table 2).
Reticuloendothelial
T95 SEM (.10-4)
Statistical significance
Control MDP MDP
200 2.000
272 378 579
38 115 109
NS S
Control MDP MDP
200 2.000
293 410 715
117 77 88
NS S
Control GMDP GMDP
200 2.000
272 405 459
38 59 92
S S
Control GMDP GMDP
200 2.000
293 443 505
117 67 100
200 2.000
297 213 436
51 74 1 10
Control GMTP GMTP
200 2.000
360 291 436
80 90 120
NS NS
Control di-GMDP di-GMDP
200 2.000
293 531 357
117 90 99
NS
Control di-GMDP di-GMDP
200 2.000
297 297 353
51 51 74
NS NS
Coritrol di-GMTP di-GMTP
200 2.000
360 216 279
80 40 40
S NS
Control GMDP GMDP
- The amount of injected carbon is 80 mg/kg - E a c h assay was performed o n 10 male mice (24 to 26 g).
S
s NS
s
s
393 The phagocytic activity of macrophages was assayed by measuring the rate of clearance of colloidal carbon by the reticuloendothelial system according to the method of Biozzi et at. (13). The phagocytic index K was calculated and K was statistically analysed using Student's test. The compound GMDP seemed to cause a significant increase in the phagocytic activity of macrophages as compared with the injection of MDP. The antibody
production was studied with the plaque-forming-cell (PFC) antibo-
dy response of mice and
the results were statistically analysed using Student's
test. They are presented in Table 2. Only the compound di-GMDP seemed to be an activator of the antibody Table 2
production.
Plaque-Torming-Gell Antibody Response of Mice to the Glycopeptides
Compound
Amount pg/kg
Number of plaques/spleen (mean)
795 SEM
Statistical significance
Control MDP MDP
500 5..000
71 .404 . 120.,301 61 ,545 .
17..762 21..697 13.,639
S NS
Control MDP MDP MDP
50 500 5..000
89.,036 95.,129 93..563 99..439
36.. 139 28..218 36.,860 38..068
NS NS NS
Control GMDP GMDP GMDP
50 500 5..000
73.,131 125.,089 89..684 101..877
22..759 32..689 37..213 29..581
S NS NS
Control GMDP GMDP
500 5..000
71..404 120..745 74.,890
17..762 19..657 14..111
S NS
Control GMTP GMTP GMTP
50 500 5..000
64..611 101..853 94..451 80..473
16..205 26..960 35..514 38..208
S NS NS
Control di-GMDP di-GMDP di-GMDP
50 500 5..000
66..562 123.,878 127..228 151..911
24,.406 41 .838 , 37,.310 34,.950
S S S
Control di-GMTP di-GMTP di-GMTP
50 500 5 .000
64..611 70.478 107,.678 122.,592
16,.205 32,.737 33,.158 45..113
NS S NS
Each assay was performed on 10 female mice (20 to 22 g)
*
394 In conclusion, we managed to perfect a system of bioreactors. It can be used for the production of large amounts of various glycopeptides from bacterial cell-walls. Preliminary assays have shown the interest of those glycopeptides which possess various biological activities.
Acknowledgement Support for research grants from CNRS (UA 528) is gratefully acknowledged.
References 1.
Kusumoto, S., Yamamoto, K. , Shiba, T. (1978) Tetrahedron Lett.45,4407-4410.
2.
Durette, P.L. , Meitzner, E.P., Shen, T.Y. (1979) Carbohydr.Res.77, C1-C4.
3.
Tsujimoto, M. Kinoshita, F. Okunnaga, T., Kotani, S., Kusumoto, S., Yamamoto, K., Shiba, J. (1979) Microbiol. Immunol. 23, 933-936.
4.
Guinand, M., Françon, A.,Vacheron, M.J., Michel G., (1984), Eur. J.Biochem., 143, 359-362.
5.
Ghuysen, J.M., Leyh-Bouille, M., Campbell, J.M., Moreno, R., Frère, J.M., Duez, C., Nieto, M. , Perkins, H.R. (1973) Biochemistry, 2_2, 1243-1251.
6.
Duez, C., Frère, J.M., Geurts, F., Ghuysen, J.M., Dierickx, L., Delcambe, L. , (1978), Biochem. J., 175, 793-800.
7.
Weston, P.D., Avrameas, S., (1971), Biochem., Biophys. Res. Commun. 45, 1574-1580.
8.
De Cohen, J., Lamotte-Brasseur, J., Ghuysen, J.M., Frère, J.M., Perkins, H.R., (1981), Eur. J. Biochem., 121, 221-232.
9.
Tosa,T., Mori ,T., Chibata, I., (1971), J. Ferment, Technol. ,
522-528.
10.
Leyh-Bouille, M., Ghuysen, J.M., Bonaly, R., Nieto, M. , Perkins, H.R., Schleifer, K.H. , Kandler, 0., (1970), Biochemistry,: 9, 2961-2970.
11.
Ghuysen, J.M., Tipper, D.J., Strominger, J.L., (1966). In Methods in Enzymology, (Neufeld, E.T. and Ginsburg V. ed.) Vol. 8, pp.685-699, Academic Press, New-York.
12.
Garnier, M., Vacheron, M.J., Guinand, M., Michel, G., (1985), Eur. J. Biochem., J«S, 539-543.
13.
Biozzi, G., Bennacerraf, 34, 441-457.
B., Halpern, B.N. (1953) Brit. J. Exp. Pathol.,
ADJUVANT ACTIVE PEPTIDOGLYCANS
I N D U C E T H E S E C R E T I O N O F A C Y T O T O X I C F A C T O R BY
MACROPHAGES
F . V a c h e r o n , M. G u e n o u n o u ,
C.
Laboratoire de Microbiologie, Garches, France
Nauciel F a c u l t é de M é d e c i n e de P a r i s - O u e s t ,
92380
Introduction.
Previous studies have shown that peptidoglycans on immune responses growth
in r a t (2) a n d m o u s e
relationship
b e t w e e n the s t r u c t u r e o f P G a n d t h e i r
the P G - i n d u c e d r e s i s t a n c e
to
effect
tumor
(3). It h a s a l s o b e e n o b s e r v e d t h a t t h e r e is a
(3, 4 ) . T h e a i m o f the p r e s e n t s t u d y w a s
Materials and
(PG) e x e r t a n a d j u v a n t
(1) a n d c a n s t i m u l a t e n o n s p e c i f i c r e s i s t a n c e
to t u m o r
immunomodulating
properties
to a n a l y s e the r o l e o f m a c r o p h a g e s
in
growth.
Methods
Activating agents. PG from Bacillus megaterium, Staphylococcus aureus, M i c r o c o c c u s lysodeikticus a n d Corynebact.erium p o i n s e t t i a e w e r e p u r i f i e d as p r e v i o u s l y d e s c r i b e d (4). P e p t i d e s u b u n i t s t r u c t u r e s a r e r e p o r t e d in T a b l e 1. L i p o p o l y s a c c h a r i d e (LPS) from S a l m o n e l l a typhimurium w a s purchased from D i f c o Laboratories. Macrophage cytotoxic activity. P e r i t o n e a l e x s u d a t e c e l l s (PEC) w e r e h a r v e s t e d f r o m 7 to 10 w e e k s o l d D B A / 2 m i c e , 3 d a y s a f t e r the i n t r a - p e r i t o n e a l i n j e c t i o n o f 2 m l o f t h i o g l y c o l l a t e b r g t h . P E C w e r e w a s h e d w i t h H a n k s b a l a n c e d s o l u t i o n ( H B S S ) a d j u s t e d at 1 . 2 5 x 10 /ml in t i s s u e cult.ure m e d i u m (TCM) c o n s i s t i n g o f R P M I 1 6 4 0 s u p p l e m e n t e d w i t h 2 m M glut.amine, a n t i b i o t i c s a n d 10 % f o e t a l c a l f s e r u m (FCS). A v o l u m e o f 0 . 2 ml o f c e l l s u s p e n s i o n w a s d i s t r i b u t e d in 9 6 - w e l l f l a t - b o t t o m e d m i c r o t i t e r p l a t e s . A f t e r a 2 h i n c u b a t i o n at 3 7 ° C , n o n a d h e r e n t c e l l s w e r e r e m o v e d by 3 w a s h e s w i t h H B S S . P 8 1 5 m a s t o c y t o m a c e l l s , m a i n t a i n e d by s e r i a l p a s s a g e s in the p e r i t o n e a l c a v i t y of D B A / 2 m i c e , w e r e w a s h e d in H B S S a n d a d j u s t e d at 1 . 2 5 x 10 /'ml in T C M . T h e n 0 . 2 ml o f this c e l l s u s p e n s i o n w a s a d d e d to the m a c r o p h a g e m o n o l a y e r s . C u l t u r e s ^ e r e i n c u b a t e d a t 3 7 ° C in a 5 % C O ^ a t m o s p h e r e for 24 h . T r i t i a t e d t h y m i d i n e ( H - t h y m i d i n e , 0 . 2 jaCi p e r w e l l ) w a s a d d e d f o r the f i n a l 4 h of i n c u b a t i o n a n d P 8 1 5 c e l l s w e r e c o l l e c t e d w i t h an a u t o m a t i c h a r v e s t e r . I n c o r p o r a t e d r a d i o a c t i v i t y w a s m e a s u r e d by l i q u i d s c i n t i l l a t i o n s p e c t r o p h o t o m e t r y . E a c h d e t e r m i n a t i o n w a s c a r r i e d o u t in t r i p l i c a t e .
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
396 Table 1. Peptide Subunit Structure of PG
Bacterium
Peptide sequence
B. megaterium
L-Ala-D-Glu-m-A2pm-D-Ala
S. aureus
L-Ala-D-Glu(NH 2 )-L-Lys-D-Ala
M.
lysodeikticus
C. poinsettiae
L-Ala-D-Glu(Gly)-L-Lys-D-Ala Gly-D-Glu-L-Hsr-D-Ala
Cytotoxic factor on. PEC adjusted at 0^5 x 10 /ml in TCM were plated in 16-mm wells (0.5 ml per well) or in 25 cm flasks (5 ml per flask) and incubated for 2 h at 37°C. Nonadherent. cells were removed by washing. Adherent cells were cultured in serumfree RPMI 1640 medium containing 25 mM HEPES. Various concentrations of activating agents were added and culture supernatants were harvested 24 h later. The cytotoxic activity of supernatants was assayed on L - 9 2 9 cells. Target cells in TCM were seeded in microtiter plates (40,000 cells/well) in the presence of actinomycin D (1 yg/ml) and various dilutions of supernatants in a final volume of 0.2 ml. In control wells target cells were incubated w i t h TCM instead of macrophage supernatant. After 18 h of incubation at 37°C, the nonadherent (dead) cells were removed by washing and the remaining adherent cells were stained with crystal violet (5). Absorbance was read at 545 nm . Each determination was carried out in triplicate. Cytotoxic factor characterization. A sample of 100 ml of supernatants from macrophage cultures stimulated with 100 jig/ml of PG from B. megaterium was concentrated by ammonium sulfate precipitation (at a saturation of 80 %) dialysed against 0.1 M Tris-HCl buffer (pH 7.3) applied to a column of Ultrogel AcA 54 (Pharmacia) (2.6 x 90 cm) and eluted w i t h the same buffer. Fractions of 7.5 ml were collected, sterilized by filtration, diluted 1:50 in TCM and tested for cytotoxic activity on L-929 cells. Another sample of concentrated supernatants was dialysed against 0.025 M imidazole-HCl buffer (pH 7.4) and fractionated by chromatofocusing on a PBE 94 column (Pharmacia) (1 x 35 cm) with 300 ml of polybuffer 74 pH 7.4. Fractions of 7.5 ml were collected, dialysed against RPMI 1640, sterilized by filtration, diluted 1:4 in TCM and assayed for cytotoxic activity.
Results
Activation of macrophages for cytotoxicity by PG. Thioglycollate induced macrophages were not cytotoxic for P815 cells. In the presence of PG they inhibit the growth of the target cells. PG from B. megaterium and S. aureus were more active than PG from M. lysodeikt.icus and C. poinsettiae (Table 2).
397 Table 2 Growth Inhibition of P815 Mastocytoma Cells by PG-Stimulated Macrophages
Macrophages
PG
/ i fJg/ml
H-thymidine incorporation
,„. (% growth
-
-
-
19,088 + 2,724
+
-
-
19,606 + 3,505 18,339 + 1,115
\ inhibition)
-
B. megaterium
100
+
B. megaterium
10
5,433 + 735
(71)
+
B. megaterium
100
2,654 + 345
(86)
(4)
+
S. aureus
10
3,485 + 472
(82)
+
S. aureus
100
461 + 135
(97)
+
M. lysodeikticus
10
+
M. lysodeikticus
100
12,550 + 1,577 (34)
C. poinsettiae
10
12,707 + 2,650 (33)
C. poinsettiae
100
7,121 + 1,628 (62)
+
19,539 + 2,023
(0)
Release of a cytotoxic factor by macrophages stimulated by PG. Macrophages incubated with 1 to 10 |ig/ml of PG from B. megaterium or S. aureus released cytotoxic activity in supernatants. PG from M. lysodeikticus
and
C• poinsettiae were active only at higher concentration (100 jig/ml) and the level of activity released w a s low (Table 3).
Properties of the cytotoxic factor. The factor was not inactivated by heating at 56°C for 30 min, but destroyed at 80°C. Cytotoxic activity w a s not inhibited by serum or trypsin inhibitors such as soja bean trypsin inhibitor. The cytotoxic factor was however not stable in the presence of serum. After gel filtration a major peak of cytotoxic activity w a s observed in the range of 60-70,000 daltons (Fig. 1). After chromatofocusing a single peak of activity was present at pH 4.8.
Discussion.
The data presented here show that PG activate the cytotoxic activity of
398
Table 3. Cytotoxic Activity on L-929 Cells
of Supernatants from Macrophage
Cultures Stimulated by PG or LPS.
Stimulant -
B. megaterium PG
S. aureus PG
M. lysodeikticus PG
C. poinsettiae PG
LPS
jjg/ml -
% cytotoxicity
*
0
1
74
10
92
100
89
1
0
10
84
100
93
1
0
10
2
100
25
1
0
10
2
100
32
0.1
77
1
88
* Supernatants were assayed at 1:10 dilution
macrophages and induce the release of a cytotoxic factor. PG from B. megaterium and S• aureus were very active. Previous studies have shown that these preparations exerted immunoenhancing activities, including the ability to inhibit tumor growth (3, 4). Adjuvant inactive PG from M. lysodeikticus or C. poinsettiae have only a slight effect on macrophage cytotoxicity. Several studies have shown that macrophages can release cytotoxic factors after stimulation by various inducers such as LPS. Different factors have been described. Some of them are low molecular weight components : oxygen metabolites (6), thymidine (7) or C3a (8). Arginase is of a molecular weight higher than the factor described in the present study (9). Factors with protease activity have also been reported (10). Unlike these factors the cytotoxic factor we have found is not inhibited by serum or trypsin inhibitors. It shares several properties with a factor released by macrophages after induction by calcium ionophore (11) or BCG and LPS (12). Its relationship with tumor necrosis factor has been suggested (12).
399 Figure 1. Ultrogel AcA 54 Chromatography of Cytotoxic Factor
BSA I
OVA I
FRACTION
CHYM i
NUMBER
Molecular weight markers were bovine serum albumin (BSA), ovalbumin (OVA) and chymotrypsinogen (CHYM)
The ability of PG from some bacterial species to induce the secretion of a cytotoxic factor by macrophages may explain, at least in part, their activity against experimental tumors. Furthermore our results confirm that macrophages are an important target of PG (13).
References
1. Nauciel, C., J. Fleck, J.P. Martin, M. Mock, H. Nguyen-Huy. 1974. Eur.J. Immunol. 4, 352. 2. Nauciel, C., A.F. Goguel. 1977. J.Natl.Cancer Inst. 59, 1723. 3. Goguel, A.F., G. Lespinats, C. Nauciel. 1982. J.Natl.Cancer Inst. 68, 657.
400 4. Guenounou, M., A.F. Goguel, C. Nauciel. 1982. Ann.Immunol.(Paris).
133D, 3.
5. Fish, H . t G.E. Gifford. 1980. J.Immunol.Methods. 57, 311. 6. Nathan, C.F., S.C. Silverstein, L.H. BrUhner, Z.A. Cohn. 1979. J.Exp.Med. 149, 100. 7. Opitz, H.G., D. Niethammer, R.C. Jackson, H. Lemke, R. Huguet, H.D. Flad. 1975. Cell.Immunol. 18, 70. 8. Ferluga, J., H.U. Schorlemmer, L.C. Baptista, A.C. Allison. 1978. Clin.Exp. Immunol. 31, 512. 9. Currie, G.A. 1978. Nature. 273, 758. 10. Reidarson, T.H., G.A. Granger, J. Klostergaard. 1982. J.Natl.Cancer 69, 889.
Inst.
11. Drysdale, B., C.M. Zacharchuck, H.S. Shin. 1983. J.Immunol. 131, 2362. 12. Männel, D.N., R.N. Moore, S.E. Mergenhagen. 1980. Infect.Immun. 30, 523. 13. Vacheron, F., M. Guenounou, C. Nauciel, 1983. Infect. Immun. 42, 1049.
STIMULATION AND
OF N O N S P E C I F I C
BACTERIAL
TREHALOSE
RESISTANCE
BY M U R A M Y L
AGAINST
AEROGENIC
DIPEPTIDE
VIRAL
COMBINED
WITH
DIMYCOLATE
K.N. Masihi, Robert
INFECTIONS
Koch
W. B r e h m e r , Institute,
W.
Lange
Federal
Health
Office,
1000 Berlin 65, F.R.G.
Introduction There
are a m u l t i t u d e
animals.
Many
rubella,
rabies,
ted by ces,
of i n f e c t i o n s
infectious mumps,
and m o r t a l i t y . or a c c e p t a b l e for many
still
It is d i f f i c u l t
infections
like
factory.
For
instance,
the
inherent
problems.
face
antigens
of the
of the
vaccine
possessing
WHO
report
influenza
tion light host
completely
(No. 6 9 8 , epidemics
achieved...
of d e v e l o p i n g of this
defence
Biological
emphasis
vaccines
different mechanisms
avenue
response
against for
modifiers
u s e d as i m m u n o s t i m u l a n t s
of
this, presur-
annual
influenza when A
yet
on the
specificity
viru-
recent
control
h a s not
of
or v a r i a n t s " .
of e n h a n c i n g
infections
satis-
of the an
appear.
be p l a c e d
A viruses
the c o n c e p t
future serotypes
viruses
drift
"effective
infections
should
vaccines
to
situation
antigens
that
100
necessitates
The e f f i c a c y
advan-
morbidity
near
over
influenza
with a wide
influenza
background,
and an a t t r a c t i v e
stated
individual
of
not c o m p l e t e l y
in a s h i f t
different
1983) or
Particular
against
limited
preven-
specific
in the
antigenic
viruses
composition.
is p a r t i c u l a r l y
ses
frequent
influenza
source
that
domestic fever,
major
In a d d i t i o n
are
of the
and
yellow
B can be
with
23 t y p e s .
vaccines
man
despite
an i m p o r t a n t
nature
The
but
rhinoviruses
viral
sent
vaccines
and h e p a t i t i s
be d e v e l o p e d
B viruses with
of the c u r r e n t
affect
smallpox,
to e n v i s a g e
will
the
which
like
vaccines,
constitute
chemotherapy
or the c o x s a c k i e certain
bility
measles,
the use of a p p r o p r i a t e
infections
review
diseases
of been
feasiprotecIn
offers
an
alternative
origin
are
widely
of h o s t
immune
research. of b a c t e r i a l
to e n h a n c e
a variety
the
nonspecific
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin • New Y o r k - Printed in Germany
402 responses. teria, tion
Detailed
of t h e i r
cell
moieties.
The
vanticity
is t h e
u/alls are
structure
structure
glycolipids
the
to
nonspecific
virus
NMRI
and
mice
pretreated
treatment
and
employed,
no
was
observed
nor
TDM,
were long
infection.
1).
restrict
the
slightly
increased
the
in were
adjuthis
on
of t r e h a l o s e .
We
response
modifiers
aerogenic
influenza
and
obtained
combination
with
A greater
to
of
TDM w i t h
desmethyl-MDP.
of
of
mouse-viru-
between MDP
virus
the
MDP
of the
aerosol against
or
on of
analogs
protection
tested, the
bacteria.
two
were
infections influenza of
virusM.tuin
of c o l o n i e s
analogs
preparations
lipophilic
analog infection
multiplication number
pre-
that were
multiplication both
the
organisms.
of the
a mixture
6-0- acyl
degree
or
of M. t u b e r c u l o s i s ;
reduced
when
TDM,
aerosol
analogs
protection
the
only
an
MDP
or
resistance by
natural
influenza
the
1 % squalane-in-water
of M D P . of
to
present
of 3 - 4 w e e k s
against
Significant
obtained
were
TDM,
ineffective
mortality
by
to
growth
of M D P ,
the
analog
bacterial
M.tuberculosis
of the
they
indicated
vative
the
In a d d i t i o n
Regardless
None
to be
TDM
acid-arabinoga-
components
MDP,
interval
(Table
shown).
results
mycobacidentifica-
infections.
infected
pathogenic
b e r c u l o s i s , as with
synthetic
resistance
not
lung,
MDP.
against
tuberculosis
or
aerosol
suspensions
induced
for
biological
detectable
found
(data
these
the
immunopotentiating
6,6-diesters
could
contrary, also
virus
u/as a r e l a t i v e l y
Aqueous
monomer
resistance
with
of M D P + T D M
influenza
There
to
as a m y c o l i c contains
essential
like
of
led
Discussion
combination lent
ability
and M y c o b a c t e r i u m
Results
have
immunopotentiating
investigated stimulate
which
peptidoglycan
other
on a d j u v a n t - a c t i v e
nocardia
complex
minimum
glycopeptide,
and
wall
lactan-mucopeptide
cell
investigations
corynebacteria,
were
(Table
and
combined 1).
Similar
ubiquinone
was
derivatives
induced like
deri-
by
the
seryl
403 Table 1.
Effect of MDP and Analogs Alone and in Combination with TDM Against Influenza Virus and fl^ tuberculosis Infections in Mice.
MDP analog
TDM
% surviving influenza infection
MDP
0 60
0.001
7.43 5.74
0.05
+
0 55
0.001
7.20 5.36
0.01
+
0 80
0.001
7.17 5.19
0.01
+
0 58
0.001
7.30 6.50
0.05
MDP-Abu
Groups
15 0
+
vehicle control (1 squalane)
of 1 0 - 2 0
mice
virus
or
after
intravenous
tions
containing
enza,
150
were
6.86 6.61
were
given
tuberculosis, MDP
or
analog
with
300+150
H 3 7Rv , respectively
(300
^.g), T D M
(75 ng
or M D P + T D M
influenza
3 or 4
squalane-in-water
p.g for
respective
of A / P R / 8 / 3 4
with
tuberculosis)
influenza,
compared
an a e r o s o l
strain
pretreatment
^.g for
75 p.g for
P
+
MDP-seryl MDP-des-seryl
Viable median count of tuberculosis per lung (log 10)
P
for
influ-
combination
(150+
t u b e r c u l o s i s ) . MDP
MDP+TDM
group
for
the
weeks
prepara-
groups
statistical
analysis.
The
efficacy
measurement by
the
hemadsorption
cultures. the
of M D P + T D M of
Peak
MDP+TDM
of v i r u s cured
the
earlier
MDP+TDM
group. ted
challenge strain
was
guinea-pig
this
pretreated
showed of
group mice
(Figure but
only
that
for
later,
even
on
all
day
the
7 in the
rechallenge.
virus on
oc-
day
5 in
control
of the
against
if a h e t e r o l o g o u s
3 but
levels
hemagglutina-
already
survivors
resistance
the
tissue
on day
infectious
detected
by
lungs
on B H K - 2 1
decreased
1). A l s o ,
be
checked
infected
attained
markedly
detectable
a long-lasting
6 months
were
could
be m e n t i o n e d
showed used
mice
further in the
erythrocytes
concentrations
antibodies
It s h o u l d
groups
was
concentration
clearance
in
t i o n - ! nh i bi t ing the
with
virus
pretreated
and
combination
virus
pretrea-
lethal
influenza
reA
404
DAYS AFTER INFLUENZA CHALLENGE
Figure 1. Comparison of lung virus titers and serum hemagglutination-inhibiting antibodies of mice pretreated with 1 % squalane-in-water preparation alone (•) or containing HDP+TDM combination (o). The
mechanisms
killer
cell
nificantly the
MDP+TDM
activity
the
role
of the
combination, the
killer for
the
2-4 weeks
macrophage
in
the
immunostimulants
were
given
hours
activity
MDP+TDM Natural
the
animals
time
of
macrophages pretreatment.
resistance
pretreated
later,
silica,
an a e r o s o l
of
not
sig-
to
be
activity
of
To
induced
21 d a y s
dextran
was
infection. appear
immunopotentiating
were
24
at
after
that
and
of
experiments.
pretreated
cells,
animals
carrageenan,
further
from c o n t r o l s
cells
combination
protective in
of 3 - 4 w e e k
to n a t u r a l
target
in t h e
investigated
different
In c o n t r a s t among
involved
were
combination
elucidate by
MDP+TDM
earlier
sulfate, influenza
with and virus.
405 The
results
influenza gated
by
inhibit
presented
virus
that
treatment or
impair
in T a b l e was
with
2 show
induced all
the
that
the
by M D P + T D M three
the m a c r o p h a g e
agents
function
resistance
combination known
in
to
to
was
abro-
selectively
vivo.
Effects of Macrophage Inhibitory Agents on the In Vivo Resistance
Table 2.
of MDP+TDM Combination Against Influenza Virus Infection Pretreatment
Compound
Dose
(150+75 p.g)
% survival
P
(mg)
MDP+TDM
-
-
90
MDP+TDM
silica
3
10
0.01
MDP+TDM
carrageenan
1
10
0.01
MDP+TDM
dextran sulfate
1
20
0.01
Groups
of 10 m i c e
preparations influenza
3 weeks
pretreated
before
with
aerosol
1 %
infection
compounds
were
administered
experiments
were
functional
alterations
in the m a c r o p h a g e s
ted
animals.
the
phagocytic shunt
A/PR/8/34
intravenously
Phagocytosis cells
stimulates
which
the from
oxidative
in i n c r e a s e d
aim
of
h
of a c t i v a t e d
superoxide
anion,
hyaroxyl
radical
with
the
of
light
form
dent
chemiluminescence.
with
the
combination
miluminescence aureus
zymosan.
of M D P + T D M
activity (Figure
Spleen
can
be
cells
exhibited
in r e s p o n s e
2) a n d
detected
similar
to
by
animals markedly
stimulation
results
were
of
monophos-
oxygen
hydrogen
of p h o t o n s .
from
pretrea-
hexose
generation emission
detecting
MDP+TDM
the
coccus
24
metabolism
oxygen,
in t h e
and
results
with
singlet
of e n e r g y
activity
performed
like
bolites and
with
infection.
Additional
phate
squalane-in-water
virus.
Anti-macronhage before
were
The
meta-
peroxide, release
luminol-depenpretreated enhanced by
che-
Staphylo-
obtained
with
406
1
2
3 t
4
5
6 7 TIME Imial
8
9
10
11
12
S.aureus
F i g u r e 2. C h e m i l u m i n e s c e n c e r e s p o n s e o f s p l e e n c e l l s from mice p r e t r e a t e d w i t h 1 % s q u a l a n e - i n - w a t e r p r e p a r a t i o n a l o n e o r c o n t a i n i n g MDP+TDM c o m b i n a t i o n .
In and
summary,
the
nonspecific
intracellular
biological
bacterial
response
host
defence
infections
modifiers
and
mechanisms
can
warrants
be
against
enhanced
further
by
viral potent
investigation.
INCREASED ADJUVANT ACTIVITY OF MDP BY DIRECT COUPLING OF MDP TO THE IMMUNOGEN
M. Jolivet, F. Audibert, L. Chedid Immunothérapie Expérimentale, Institut Pasteur, Paris, France E.R. Clough International Minerals and Chemical Corporation, Northbrook, Illinois 60062
Introduction It is generally assumed that synthetic antigens and vaccines require the addition of an adjuvant. Fifteen years ago several investigators identified the active cell wall structure that can substitute the Mycobacteria in Freund's complete adjuvant (1,2). This molecule is N-acetylmuramyl-L-Ala-D-isoGln, designated muramyl dipeptide or MDP (3). This glycopeptide was effective in stimulating the immune response in vivo even when administered in saline (4) . However, after intravenous injection of labelled MDP solution about 65 % of the injected dose was recovered in the urine within 30 min (5). In order to delay its elimination, MDP can be conjugated to the immunogen (6). In our study, we coupled MDP derivatives to different immunogens including a natural vaccine (diphtheria toxoid) and two synthetic vaccines (carboxy terminal peptide of HCG beta subunit and a synthetic malarial peptide copying a part of the circumsporozoite protein coupled to tetanus protein).
Results 1. Diphtheria toxoid Toxin was treated with formalin or with glutaraldehyde in presence of L-lysine or a derivative of MDP, the MDP-L-lysine (MDP-Lys) which has a reactive amino group and the same activities as MDP.
Biological Properties of Peptidoglycan © 1986 Walter de Gruyter & Co., Berlin • New York - Printed in Germany
408 The conjugates contained 8 to 11 molecules of MDP per molecule of diphtheria toxoid and presented a single band by SDS PAGE (data not shown). Table 1. Antibody Response to Toxoids Conjugated to MDP-L-Lysine. Immunogen Coupling agent Primary response Secondary response formalin 2.5 1,357 A B formalin 4.5 2,833 C D E F
formalin glutaraldehyde glutaraldehyde glutaraldehyde
15 6.5 12 17
7,071 2,218 3,500 8,722
Toxoid was formed according to the method of Relyveld (7) with the addition of MDP-Lys to the reaction mixture. (A) Toxin treated by formalin (3Lf = 7 . 5 yg protein), (B) Toxoid (3Lf) mixed with 0.5 yg of MDP, (C)Toxoid (3Lf) linked to 0.5 yg of MDP, (D) Toxin treated by glutaraldehyde (3Lf) , (E)Toxoid (3Lf) mixed with 0.8 yg of MDP, (F)Toxoid (3Lf) linked to 0.8 yg of MDP. Mice (eight per group) received subcutaneously 3 Lf toxoids in PBS. On day 30, animals were boosted with the same amount of toxoid without adjuvant. Mice were bled at days 21 and 36. Sera were titrated by passive hemagglutination and the results meaned. Protein content in each conjugate was measured by Folin reaction and MDP content by a colorimetric method (8). As can be seen on Table 1, in secondary response 0.5 yg of MDP-Lys derivative mixed with the toxoid enhanced the antibody titer, but a more marked increase was observed in the case of MDP-Lys conjugated to the protein with formalin or glutaraldehyde. In this case, MDP was not immunogenic because anti-MDP antibody was not detected using ELISA. 2. Synthetic vaccines Synthetic vaccines are usually constructed with a synthetic antigen coupled to a protein carrier and administered with adjuvants. In laboratory models, tetanus toxoid is often used as a carrier and Freund's complete adjuvant as an adjuvant. However, FCA is unacceptable for human use because of its unwanted side effects. Thus, we have constructed two hapten-carriers with or without MDPLys coupled to the conjugate. The first example is constructed from synthetic carboxy terminal peptide of HCG beta subunit (residues 109-145). This peptide is lacking in the human luteinizing hormone (hLH) and other pituitary derived glycoprotein hormone (9).
409 Table 2. Antibody Response of Rabbits Injected with Synthetic Beta HCG subunit peptide-tetanus toxoid. „ response 2 Primary response 2 Secondary Rabbit Immunogen Adjuvant anti-ßhCG anti-TT anti-ßhCG anti-TT 1
pep-TT
2
pep-TT-MDP
3
pep-TT
4
pep-TT
5
pep-TT-MDP
MDP FCA FIA + MDP
37
1
6
4
82
4
50
32
53
52
100
256
25
8
32
128
94
26
97
64
The 109-145 synthetic peptide was conjugated to tetanus toxoid (TT) with glutaraldehyde used as the coupling agent, according to a previously described method (10). Fourteen pg of MDP are present in 200 pg of conjugate. Five rabbits received 200 yg of conjugate (multiple intradermal sites) in PBS without or with adjuvants (MDP 100 yg, FCA or FIA). On day 75, animals were boosted with the same amount of conjugates in PBS. Rabbits were bled on days 40 and 97 and sera tested. Anti-BhCG antibodies were measured by a radioimmunoassay (RIA) and results were expressed in percentage of binding. Anti-tetanus antibodies titers are expressed as the inverse of the maximal dilution of serum agglutaning tetanus-sensitized sheep erythrocytes x lO - ^. As can be seen on Table 2, a strong primary response was observed against HCG beta subunit when MDP was coupled to the conjugate. In aqueous medium, the percentage of binding with the B-subunit is of 8 2 % when MDP is coupled compared to 37 % when MDP is only mixed with the conjugate.
The same results were obtained in oil medium
(rabbits 4 and 5). Analysis of the secondary response show that a strong antibody response is obtained against the carrier and all the rabbits. Nevertheless, the carrier antibody reponses of rabbits treated with the MDP conjugates were only slightly elevated as compared to rabbits treated with pep-TT mixed with adjuvant. The second example of a synthetic vaccine is constituted by a synthetic 24 amino acid peptide representing the immunodominant epitope of the sequence of the circumsporozoite protein of P.knowlesi (12). This peptide contains two additional amino acids : tyrosine at the N-terminus and cystein at the C-terminus. Moreover, Gysin (13) has shown that antibodies to the peptide react with the surface membrane of sporozoites and that they neutralize the infectivity of the parasite.
410
In our study, we have made conjugates containing different substitution ratios of the synthetic malarial peptide and MDP-Lys on tetanus toxoid. Figure 1.
15H
10-
V) a.
UJ
< if)
5'
Anti
P
26
Anti
TT
This peptide (P26) represents 24 amino acids present in the natural sequence of the P.knowlesi circumsporozoite protein and two additional amino acids. Pep-TT was made according to a previously described method (10). For conjugates L (low), H (high) varying amounts of the peptide and MDP-Lys were cross-linked to tetanus toxin using glutaraldehyde. Amino equivalents peptide/MDP-Lys ratio are the following : L 1/0.5, H 1/2. Six adult female BALB/c mice received pep-TT (50 yg in PBS) ( ) or in presence of MDP (100 pg) ( ) or conjugate L(L) or conjugate H(H). On day 21, animals were boosted with the same amount of conjugate in PBS. Mice were bled on day 28. Sera from animals in each group were pooled and tested for total anti-peptide and anti-tetanus toxoid antibodies by ELISA as previously described (11). Titers
411
are expressed as inverse of the dilution of serum giving an O.D. in ELISA of two times background x 10~3. The results in Figure 1 show that the mice treated with conjugates containing MDP-Lys had higher antibody responses to both the peptide and the carrier. Moreover, the secondary antibody response of the conjugate containing 0.3 |ig of MDP-Lys is about the same as when the same quantity of antigen is mixed with 100 ng of this adjuvant. Antibodies were tested in circumsporozoite protein assay and were shown to be effective.
Discussion These experiments demonstrate that the covalent linkage of MDP-Lys to an immunogen molecule increases the adjuvant activity of MDP. In addition, it does not seem that MDP-Lys became a hapten since no anti-MDP antibody was detected by ELISA. Pharmacokinetic studies showed that 5 % of MDP was recovered in urine 30 minutes after the injection of MDP linked to the macromolecule in comparison with 65 % of free MDP. If synthetic peptides are to be used for the production of future vaccines, methods of increasing the immunogenicity of conjugates must be found. Our results demonstrated that very low doses of adjuvant can stimulate the production of protective antibodies. Finally, we have constructed a synthetic vaccine with three parts which can provoke protective antibodies : an antigenic (synthetic peptide copying part of protein natural sequence), an immunogenic (protein carrier) and adjuvant (MDP derivative). This type of vaccine excludes the parts of conventional vaccines which provoke side effects. Acknowledgements We thank Dr. Jean Choay and Dr. Pierre Lefrancier for the samples of synthetic compounds. We are grateful to M. Hattab for his technical assistance, and to C. de Champs for typing the manuscript .
412
References 1. Lederer, E. 1971. J.Med.Chem. 23^, 819. 2. Azuma, I., S. Kishimoto, Y. Yamamura, J.F. Petit. 1971. Jap.J. Microbiol. 1_5, 193. 3. Ellouz, F., A. Adam, R. Ciorbaru, E. Lederer. 1974. Biochem. Biophys.Res.Com. 59, 1317. 4. Audibert, F., L. Chedid, P. Lefrancier, J. Choay. 1976. Cell. Immunol. 21_, 243. 5. Parant, M., F. Parant, L. Chedid, A. Yapo, J.F. Petit, E. Lederer. 1 979. Int. J. Immunopharmac. 1_, 35. 6. Arnon, R., M. Sela, M. Parant, L. Chedid. 1980. Proc.Natl.Acad. Sei. USA 77, 6769. 7. Relyveld, E.H. 1973. C.R.Acad.Sc.Paris 277, 613. 8. Reissig, J.L., J.L. Strominger, L.F. Leloir. 1956. J.Biol.Chem. 217, 959. 9. Morgan, F.J., S. Birken, R.E. Canfield. 1975. J.Biol.Chem. 250, 5247 . 10. Audibert, F., M. Jolivet, L. Chedid, R. Arnon, M. Sela. 1982. Proc.Natl.Acad.Sei. USA 7_9, 5042. 11. Jolivet, M., F. Audibert, E.H. Beachey, A. Tartar, H. Gras-Ma Masse, L. Chedid. 1983. Biochem.Biophys.Res.com. 117, 359. 12. Godson, G.N., J. Ellis, P. Svec, D.H. Schlesinger, V. Nussenzweig. 1983. Nature 305, 29. 13. Gysin, J., J. Barnwell, D.H. Schlesinger, V. Nussenzweig, R.S. Nussenzweig. 1984. J.Exp.Med. 160, 935.
CONTRIBUTORS AND PARTICIPANTS
R. Barot-Ciorbaru Université Paris Sud, Institut de Biochimie, Bât 432, 91405 Orsay, France
G. Barratt Université Paris Sud, Institut de Biochimie, Bât 432, 91405 Orsay, France
G. Baschang CIBA-GEIGY Limited, K-122.4.39, Postfach, CH-4002 Basel, Switzerland
H. Bauer Institut für Kristallographie, Takustr. 6, D-1000 Berlin 33 Germany
W.G. Bessler Arbeitsbereich Mikrobiologie und Immunologie Universität Tübingen, Auf der Morgenstelle 28 D-7400 Tübingen Germany
U. Bläsi Institut für Genetik und Mikrobiologie der Universität München, Maria-Wardstr. 1a D-8000 München 19. Germany
H. Brade and L. Brade Forschungsinstitut Borstel, Parkallee 4b D-2061 Borstel, Germany
E. Bräutigam Institut für Biologie II, Mikrobiologie, AlbertLudwigs-Universität, Schänzlestr. 1, Germany
H. Brunner Bayer AG, Pharma-Forschungszentrum, Institut für Chemotherapie , D-5600 Wuppertal, Germany
B. Christensson Department of Infectious Diseases, University Hospital, S-221 85 Lund, Sweden
R. Dziarski Indiana University School of Medicine, Northwest Center for Medical Education, 3400 Broadway, Gary, IN 46408, U.S.A.
J. Endl Soehringer Mannheim GmbH, Bahnhofstr. 9-15, D-0132 Tutzing, German"
H.B. Evans Department of Immunology, Royal Liverpool Hospital, P.O. Box 147, Liverpool, L69 3BX, U.K.
H. Feucht Institut für Immunologie der Universität München, Schillerstr. 42, D-8000 München 2, Germany
414
F. Fiedler Institut für Mikrobiologie und Genetik der Universität München Maria-Ward-Str. 1a D-8000 München 19 Germany
H. Finger Städtische Krankenanstalten Krefeld, Institut für Hygiene und Laboratoriumsmedizin, Lutherplatz 40, D-4150 Krefeld 1 Germany
A. Fleer Department of Clin. Bacteriology, University Hospital, Utrecht, Netherlands
H. Formanek Botanisches Institut der Universität München Menzingerstr. 67 D-8000 München 19, Germany
S. Formanek Botanisches Institut der Universität München Menzingerstr. 67 D-8000 München 19, Germany
A. Fox Department of Microbiology and Immunology, USC School of Medicine, Columbia SC 29208, U.S.A.
N. Franken Boehringer Mannheim GmbH Bahnhofstr. 9-15 D-8132 Tutzing, Germany
K. Gadilhe Lehrstuhl für Mikrobiologie Technische Universität München, Arcisstr. 21, D-8000 München 2, Germany
I. Ginsburg Department of Oral Biology Hebrew University, Hadassah School of Medicine, Ein Kerem, Jerusalem, Israel
J. Gmeiner Institut für Mikrobiologie Technische Hochschule Darmstadt Schnittspahnstr. 9 D-6100 Darmstadt, Germany
P. Goroncy-Bermes Institut für Medizinische Mikrobiologie und Immunologie Ruhr-Universität Universitätsstr. 150 D-4630 Bochum 1, Germany
M. Guinand Université Cl. Bernard Laboratoire de Biochimie microbienne, Lyon I 4 3 Bd du 11 novembre 1918 69622 Villeurbanne, France
F. Hagen Lehrstuhl für Mikrobiologie Technische Universität München, Arcisstr. 21 D-8000 München 2, Germany
R. Hakenbeck Max-Planck-Institut für Molekulare Genetik Ihnestr. 63-73 D-10 0 0 Berlin 33, Germany
415 A. Hartinger Städtisches Krankenhaus München-Bogenhausen Institut für Medizinische Mikrobiologie, Immunologie und Krankenhaushygiene Englschalkingerstr. 77 D-8000 München 81 Germany
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B. Henkel Lehrstuhl für Mikrobiologie Technische Universität München Arcisstraße 21, D-8000 München 2 Germany
C. Herzog Department für Innere Medizin Universitätskliniken CH-4 0 31 Basel Switzerland
B. Heymer Universität Ulm Abteilung für Pathologie Oberer Eselsberg D-7900 Ulm, Germany
J.-V. Höltje Max-Planck-Institut für Entwicklungsbiologie Abteilung Biochemie Spemannstr. 35 D-7400 Tübingen, Germany
K. Huber Fachbereich Biologie (10) Mikrobiologie, Technische Hochschule Darmstadt Schnittspahnstr. 9 D-6100 Darmstadt, Germany
L. Johannsen Robert-Koch-Institut Nordufer 20 D-10 00 Berlin 65 Germany
M. Jolivet Immunothérapie Expérimentale Institut Pasteur, 28, rue du Dr. Roux, 75724 Paris cedex 15 France
U.J. Jürgens Institut für Biologie II Mikrobiologie, AlbertLudwigs-Universität Schänzlestr. 1 D-7800 Freiburg, Germany
0. Kandier Botanisches Institut der Universität München Menzingerstr. 67 D-8000 München 19 Germany
H.J. Kolb Städtisches Krankenhaus München-Harlaching Klinisch-chemisches Institut, Sanatoriumsplatz 2 D-8000 München 90 Germany
T. Komuro Max-Planck-Institut für Immunbiologie Stübeweg 51 D-7800 Freiburg Germany
416
S. Kotani Department of Microbiology and Oral Microbiology Osaka University Dental School 1-8 Yamadoakoa, Suita Osaka 565, Japan
H.P. Kroll Bayer AG Pharma-ForschungsZentrum Institut für Chemotherapie D-5600 Wuppertal Germany
J.M. Krueger Department of Physiology The Chicago Medical School 3333 Green Bay Road North Chicago, IL 60064 U.S.A.
T. Kuchenbauer Kinderklinik Josefinum Kapellenstr. 30 D-8900 Augsburg Germany
E. Kwa Robert-Koch-Institut Nordufer 20 D-1000 Berlin 65 Germany
H. Labischinski Robert-Koch-Institut Nordufer 20 D-1000 Berlin 65 Germany
H. Leying Institut für Medizinische Mikrobiologie und Immunologie Ruhr-Universität Universitätsstr. 150 D-4 630 Bochum 1, Germany
M. Loos Institut für Medizinische Mikrobiologie Universität Mainz Obere Zahlbacherstr. 67 D-6500 Mainz, Germany
W. Lubitz Institut für Genetik und Mikrobiologie Universität München Maria-Ward-Str. 1a D-8000 München 19, Germany
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H.H. Martin Fachbereich Biologie (10) Mikrobiologie Technische Hochschule Darmstadt Schnittspahnstr. 9 D-6100 Darmstadt, Germany
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K.N. Masihi Robert-Koch-Institut Nordufer 20 D-1000 Berlin 65, Germany
J.v. Mayenburg Technische Universität München Fakultät für Medizin Ismaningerstr. 22 D-8000 München 80, Germany
417
C. Nauciel Immunochimie des Protéines Institut Pasteur 75724 Paris Cedex 15 France
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R.S. Rosenthal Department of Microbiology and Immunology Indiana University School of Medicine Indianapolis, IN 46223, USA
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H. Takada Max-Planck-Institut für Immunbiologie Stübeweg 51 D-7800 Freiburg, Germany
J.P. Tenu Institut de Biochimie, Bat 432, Université de Paris Sud 91405 Orsay, France
J. Tomasic Institute of Immunology Department of Radioimmunology Rockefellerova 10 41000 Zagreb, Yugoslavia
T. Torsvik Institute of Microbiology and Plant Physiology Allegaten 70 University of Bergen 5000 Bergen, Norway
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419
H.I. Wergeland Department of Microbiology and Immunology The Gade Institute MFH-Bygget 5016 Haukeland Sykehus Norway
C.H. Wirsing von Koenig Städtische Krankenanstalten Krefeld Institut für Hygiene und Laboratoriumsmedizin Lutherplatz 40 D-4150 Krefeld 1, Germany
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AUTHOR INDEX
Adkinson,N.F., 83 Anderle,S.K., 273 Audibert,F., 407 Berger,R., 113 Bessler,W.G., 335 Biemann,K., 49 Bläsi,U., 215 Brade,H., 341 Brade,L.f 341 Brase,A., 267 Brehmer,W., 401 Briese,T., 83 Brown,R.R., 273 Chedid,L., 353, 407 Christensson,B., 21 Clough,E.R., 407 Cox,M., 335 Cromartie,W.J., 273 Duoassieu,P. , 389 Dzlarski,R., 229 Ellerbrok,H., 83 Endresen,C., 99 Evans,H.B., 89 Farkas,J., 379, 383 Feucht,H.E., 267 Finger,H., 371 Fleer,A., 261 Fleming,T.J., 313 Formanek,H., 43 Fox,A., 61 Franken,N., 135 Giesbrecht,P., 191, 197 Gilbart, J. , 61 Ginsburg,I., 167, 197 Golecki,J.R., 135 Guenounou,M., 3 95 Guinand,M., 389 Hagen,F., 221 Hakenbeck,R., 83 Halfmann,G., 215 Hammer,M., 61 Harkness,R.E., 215 Harrison,J., 61 Haslberger,H., 121 Herzog,Ch., 113 Heymer,B., 291, 305
Höltje,J.-V., 209 Hrsak, I. , 203 Huber,K., 187 Huber,M., 121 Ishikawa,Y., 61 Janusz,M.J., 27 3 Jaspers,F.C.A., 261 Jezek,J., 379, 383 Johannsen,L., 37, 197 Johnson,P.M., 89 Jolivet,M., 407 Jürgens,U.J., 55 Jung,G., 335 Just,M., 113 Just,V., 113 Kawahara,K., 341 Kleine,B., 335> Krueger,J.M., 329 Kuchenbauer,T., 105 Kwa,E., 197 Labischinski,H., 37, 191 Ladesic,B., 203 Lahav,M., 197 Lange,W., 401 Ledvina,M., 379, 383 Leitherer,G., 75, 221 Lex,A. , 335 Loo s,M., 319 Ludewitz,H., 209 Lüderitz,Th., 341 Luwitz,W., 215 Mar,P., 121 Marget,W., 121 Martin,H.H., 187 Martin,S.A., 49 Martinez-Alonso,C., 335 Masihi,K.N., 401 v. Mayenburg,J., 291, 305 Michel,G., 389 Montoya,F.R., 313 Morel,P., 389 Morgan,S.L., 61 Nauciel,C., 395 Nogami,W., 313 Nolibe,D., 249 O'Neill,G.J., 267
422 Parant,M., 353 Pararajasegaram,G., 61 Pekarek, J. , 383 Petit,J.-F., 249 Phua,K.K., 89 Reissenweber,S., 75 Riethmüller,G., 267 Rietschel,E.Th., 341 Rosenthal,R.S., 49, 313 Rotta,J., 379, 383 Ryc,M., 129, 379, 383 Schade,U., 341 Schleifer,K.H., 1, 67, 75, 105, 1 35 , 221 , 31 9 Schumann,G., 255 Schwab,J.H., 27 3 Seidl,J., 67 Seidl,P.H., 1, 67, 75, 105, 135, 221, 267, 319 Stimnson,S.A., 273 Straka,R., 383 Suhr,B., 335 Tacken,A., 341
Tenu,J.-P., 249 Tomasic,J., 20 3 Tympner,K.-D., 105 Vacheron,F., 395 Vacheron,M.J., 389 Valinqer,Z., 203 Verhoef, J., 261 Wagner,B., 129 Wagner,M., 129 Wecke,J., 197 Weckesser,J., 55 Wells,A., 61 Wergeland,H.I., 99 Whiton, R. , 61 Wiesmüller,K.-H., 335 Wirsing von Koenig,C.H. Witte,A., 215 Yang ,C.H. , 61 Yavordios,D., 389 Zahringer,U., 341 Zaoral,M., 379, 383 Zauner,E., 7 5 Zeiger,A.R., 95, 145 Zwerenz,P., 135, 221
SUBJECT INDEX The abbreviation of Peptidoglycan is PG.
N-ACETYLATION partial lack of, among bacilli 2, 7, 76, N-ACETYLGLUCOSAMINE 211, G-N-ACETYLGLUCOSAMINIDASE
206,
N-ACETYLMURAMIC ACID 211, antibodies to 5, N-ACETYLMURAMYL-L-ALANINE AMIDASE 205, O-ACETYLATION biological properties of PG, effects on 197, of gonococcal PG 313-317, of staphylococcal PG 191, 1 97 , ACTINOMADURA 389, ACTIVATION of B-cells 213, 298, 299, of T-cells 231 , of complement 264, 284, 298, 299, 319, 323, of macrophages 298, 299, of neutrophils 298, 299, polyclonal, of lymphocytes 232 , polyclonal, by soluble PG 162, polyclonal, of B-cells 299, 339, ACTIVITY adjuvant 231, 236, 371, 381 , antimetastatic, of PG 204, 206, antitumor, of MTP-PE 256, antiviral, of MTP-PE 256-258, biological, of lipopolysaccharide 341 , biological of PG, in man 291, 305,
cancerostatic, of MDP analogs 37 9, immunomodulating 230, 236, 249, 255, 395, inflammatory, of soluble PG 163, mitogenic, of lipoprotein 335, 336, mitogenic, of soluble PG 159, of PG, in man 291, 305, pyrogenic, of MDP analogs 37 9, 381 , 383, 384, somnogenic, of MDP 329, synovial activator activity 230 , ACUTE PHASE PROTEINS 231, ADJUVANT ACTIVITY 231, 236, 371, 381, 407, AGAMMAGLOBULINEMIA TYPE BRUTON 107, AGE DEPENDENCY of antibodies to lipid A 127, of antibodies to peptidoglycan 106, AIDS-HTLV III INFECTION 305, ALLERGIC bronchitis 298, diseases 295, 298, 305, encephalitis, experimental 384, 387, rhinitis 298, vasculitis 298, ALPHATOXIN 25, ALTERNATE PATHWAY MENT activation of, by 319, 323, activation of, by activation of, by acid 319,
OF COMPLEcell walls PG 264, 319, teichoic
424 AMIDASE 3, in human serum 205, 209, ANAPHYLAXIS 373, 1,6-ANHYDROMURAMIC ACID 212, 314, 315, 331, ANIONIC POLYELECTROLYTES 168, ANTIBODIES age dependency of titers 106, 127, IgE antibodies to S. aureus cell walls 67, IgG antibodies to S. aureus PG 24, reacting with soluble PG 157, to A polysaccharide of streptococci 6, to A variant polysaccharide of streptococci 10, to ß-lactam antibiotics 83, diagnostic role of 21 , to di-alanine 10-14, 135, to the glycan moiety 4, 5, 75 to interpeptide bridge 8, 9, to lipase 27, to lipid A 121, to lipopolysaccharide 127, 342, to Lys—D-Ala-D-Ala 95, 148, in man 5, 1 1 , 99, 105, 310, to MDP 5, 6, to Micrococcus luteus 5, 136, to muramic acid 5, 6, 354, to pentapeptide subunit 5, 11, 95, 105, 136, 310, to PG, ferritin conjugated 130, to PG, in animals 4, 99, to PG-polysaccharide polymers 90, to Staphylococcus aureus 113, to Staphylococcus aureus cell walls 67, to Staphylococcus aureus PG 24, to Streptococcus pyogenes A-variant 10, to streptococcal PG 90, to Streptolysin 0 107, to teichoic acid 43, 113, to tetanus toxoid 267, to the tetrapeptide subunit 5, ANTIBODY DEFICIENCY SYNDROME 308, ANTIGENIC EPITOPES OF PG 4, 131, 133, 135,
ANTIGENICITY of lipopolysaccharide 342, of peptidoglycan 4, ANTI—IDIOTYPE 90, ANTI-INFLAMMATORY EFFECT of MDP 281, ANTI-METASTATIC ACTIVITY of peptidoglycan 204, 206, ANTI-TUMOR ACTIVITY of peptidoglycan 204, 249, 255, of liposome-entrapped MTP-PE 256, ANTI—STREPTOLYSIN-0 107, ANTI-VIRAL ACTIVITY of liposome-entrapped MTP-PE 256-258, ARACHIDONIC METABOLITE PRODUCTION induction by MDP 283, 285, induction by PG-polysaccharide polymers 283, ARTHRITIS 173, 174, 176, induction of 277-279, 314, 315, 317, reaction of, induced by MDP 279, ATOPIC DERMATITIS 109, diseases 305, AUTOLYSINS 170, 171, 215, AZTREONAM 188
B BACILLI lack of N-acetylation 7, BACILLUS LICHENIFORMIS secretion of soluble PG 149, BACILLUS SPHAERICUS endopeptidase I 389,
425 BACILLUS SUBTILIS carboxypeptidase of 11, glycopeptides of 6, 75, immunoelectronmicroscopy 136, PG of, as immunoadsorbent 136, secretion of PG 149, 224,
BREVIBACTERIUM DIVARICATUM biological activity 203, metabolic fate of PG monomer 203 , PG monomer 203, secretion of soluble PG by 149,
BACTEREMIA 113, 115,
BRONCHITIS allergic 298, bacterial 297,
BACTERIAL bronchitis 297, hypersensitivity 306, lysis 215, morphogenesis 209, rhinitis 297 , sinusitis 2 97,
C
BACTERICIDAL REACTIONS 167, BACTERIOLYSIS 167, BACTERIOPHAGE PHI-X-17 4
215,
BASOPHILS effect of PG on 283, B-CELLS activation of 213, 298, 299, B-LACTAM ANTIBIOTICS action on Proteus mirabilis 187 antibodies to 83, aztreonam 188, cefotaxime 188, cefoxitin 188, ceftizoxime 188, functional damage of PG 190, growth of bacterial spheroblasts in the presence of 189, imipenem 188, inhibition of PG synthesis 190, latamoxef 188, penicillin 187, secretion of soluble PG 145, BIOLOGICAL ACTIVITY of lipopolysaccharide 341, of PG in man 291, 305, BIOREACTORS 390, B-LYMPHOCYTE MITOGENS 335, BOOSTER REACTION 37 4, BORDETELLA PERTUSSIS 371,
C4B2.9 IMMUNOGENETIC MARKER 268, CANCEROSTATIC ACTIVITY of MDP analogs 37 9, A-CARBOHYDRATE of streptococci, antibodies to 6 , CARBON CLEARANCE by reticuloendothelial system 392 , CARBOXYPEPTIDASE 4, 11, 13, of Bacillus subtilis 11 , of Staphylococcus aureus 11 of Streptomyces albus 389, lack of 4, 140, CARCINOMA 204, CATIONIC POLYELECTROLYTES 169, 171 , CEFOTAXIME 188, CEFOXITIN 188, CEFTIZOXIME 188, CELL CHEMILUMINESCENCE 231, 262, 299, 405, 406, CELLULAR RESPONSE to PG 267, CELL WALL models 129, 133, structure 37, 129, 341,
426
CEPHALOSPORIN 13,
CYANOBACTERIUM 55,
CHEMILUMINESCENCE 231, 262, 299, 405, 406,
CYTOCHROME P-450
CHEMOTACTIC FACTOR 230, CHEMOTAXIS for macrophages 229, 262, COLITIS 125, COLONY STIMULATING FACTOR 230, COLLAGENASE release of 231, COMPLEMENT activation of 262, 284, 298, 299, 319, 323, alternate pathway 264, 319, 323, genotype 267, CONFORMATION 37, CONJUGATES glycopeptide-protein 6, 75, lysozyme-peroxidase 130, MDP-carrier 6, MDP-immunogen 407, peptide-polypeptide 95, 148, peptide-protein 8, 10, 11, 135, 137, CONTACT ECZEMA 2 38. CORE of LPS 343, COUNTERIMMUNOELECTROPHORESIS 113,
207,
CYTOSTATIC ACTIVITY 230, CYTOTOXIC ACTIVITY 230, 249, CYTOTOXIC FACTOR 395,
D DEGRADATION of PG 191, 197, 215, 230, resistance of PG to 313-315, DELAYED HYPERSENSITIVITY 206, 375, 383, 385, DERMATITIS, ATOPIC 109, DIAGNOSTIC ROLE of PG antibodies 21, DI-ALANINE 131, antibodies to 10-14, 135, DIPHTERIATOXOID 407, DISACCHARIDE MDP ANALOGS biological properties 379, 384 , preparation 379, DISACCHARIDE PEPTIDE MONOMERS 314, 315, 317,
CROHN'S DISEASE 125,
E
CROSSLINKAGE of PG 2,
EDEMA 276, 278, 279, 300,
CROSSREACTIVITY between B-lactams and R-D-Ala2 12, 13, between different PGs 95, 101, between L-Lys and meso-A2pm 95, between rheumatoid factor and PG-polysaccharide 89, CULTURE FILTRATES 79, 221,
ELECTRON DIFFRACTION 43, ELECTRON MICROSCOPY 43, 129, 1 71 , 200 , 201 , 293 , 385 , ELISA 11, 75, 113, see also: enzyme immunoassay ENCEPHALITIS, ALLERGIC 384, 387 , ENDOCARDITIS 24, 115,
427
ENDOGENOUS PYROGEN 230,
G
ENDOPEPTIDASE 3, 210, 389,
GAS CHROMATOGRAPHY-MASS SPECTROMETRY levels of muramic acid in tissue 64, levels of rhamnose in tissue 64,
ENDOPEPTIDASE I from Bacillus sphaericus 389, ENDOTOXIN 341, ENTERITIS 125, ENTEROCOCCUS FAECALIS secretion of PG 223, ENTEROCOCCUS FAECIUM PG-polysaccharide polymers of 275, 276, secretion of soluble PG 149, ENZYME IMMUNOASSAY antibodies to glycan moiety of PG 75, antibodies to pentapeptide subunit of PG 11, antibodies to PG-polysaccharide 90, antibodies to teichoic acid 113, levels of PG-polysaccharide complexes in vivo 62, levels of soluble PG 95, 148, EPITOPES of PG 4, 131, 133, 135, ERYTHEMA 300, ESCHERICHIA COLI carboxypeptidase of 11, glycan strands released 209,
F FAST ATOM BOMBARDMENT MASS SPECTROMETRY 49, 20 3, FERRITIN-CONJUGATED PG-ANTIBODIES 130, FERRITIN TECHNIQUE, INDIRECT 135, FEVER induction of 213, FIBROBLAST ACTIVATING FACTOR 2 30, FIBROBLAST PROLIFERATION 231 ,
GENE lysis gene 215, GENETIC CONTROL of immune response 267, GENOTYPE of comnlement 267, GLOMERULONEPHRITIS 267, GLUCOSAMINIDASE 3, GLYCAN MOIETY OF PG antibodies to 4, 5, 75, detection of, by RIA 221, immunoelectron microscopic studies 132, 135, structure of 2, GLYCAN STRANDS length distribution 209, unsubstituted by peptides 78, GLYCOPEPTIDES from Actinomadura 389, from Bacillus subtilis 6, 75, synthetic 379, 383, GONOCOCCAL PG 313-317, GRAM NEGATIVE BACTERIA cell wall structure of 341, PG of 2, GRAM POSITIVE BACTERIA PG of 2, GROUP A STREPTOCOCCI 129, GROUP A POLYSACCHARIDE antibodies to 6, edema induced by 274-276, 278, effect on mast cells 283, intraarticular injection with 278,
428
GROUP A-VARIANT STREPTOCOCCI 129, a n t i b o d i e s to 10,
IMMUNOGENICITY of P G 4, of s o l u b l e P G 159, I M M U N O G L O B U L I N A 17, 373,
H HEMAGGLUTINATION, HEMORRHAGE i n d u c e d by P G
INDIRECT
113,
283,
HERPES SIMPLEX VIRUS
I M M U N O G L O B U L I N E 37 3, to P G 17, 67, t o t a l levels of 297, 310,
256,
HISTAMINE RELEASE i n d u c e d by P G 283, HISTONE
IMMUNOGLOBULINEMIA
HISTOMORPHOLOGY
IMMUNOGLOBULIN M
293,
IMMUNOHISTOLOGY
H L A - R E G I O N 26 7,
HYDROGEN FLUORIDE action on cell walls HYPERSENSITIVITY
209,
319,
306,
IMMUNOSUPPRESIVE of P G 235,
384, EFFECT
IMMOBILIZED ENZYMES
390,
IMMUNOCHEMISTRY Of P G 1,
401-405,
INHIBITION of m a c r o p h a g e m i g r a t i o n 230, of P G s y n t h e s i s 190, of p h a g o c y t o s i s 230,
113,
IMMUNOELECTRON MICROSCOPY 129, 132, 135, 136, 141, of S. a u r e u s 137, of Str. p y o g e n e s 129, 137, IMMUNOFERRITIN TECHNIQUE 1 29, 1 35 , 1 41 , IMMUNOGENETIC MARKER
2 97,
I N F L A M M A T I O N 172, 296, b y s o l u b l e P G 163, INFLUENZA VIRUS
107,
268,
113,
21,
INFECTIOUS DISEASES
188,
230,
401,
INDIRECT HEMAGGLUTINATION
I
IMMUNODIFFUSION
295,
IMMUNOSTIMULATION
INFECTIONS b y S. a u r e u s
IMMUNODEFICIENCY 297, 308,
373,
IMMUNOMODULATING ACTIVITY 236, 249, 255, 395,
305,
H U M A N S E R U M A M I D A S E 205,
IMIPENEM
108,
I M M U N O G L O B U L I N G-j 37 3,
171,
H T L V III V I R U S
IMMUNOGLOBULIN CLASSES of a n t i b o d i e s to L i p i d A 126, of a n t i b o d i e s to P G 11, 16, 75,
INTERLEUKIN
230, 283,
229,
285,
INTERPEPTIDE BRIDGE OF PG s t r u c t u r e 2, a n t i b o d i e s to 5, 8, 137,
429
INTRAARTICULAR INJECTION with MDP 278, with PG-polysaccharide polymers 278,
LIPID A 121, 341, antibodies to 121, synthetic 347,
INTRADERMAL INJECTION of bacterial substances 306,
LIPOPEPTIDES polyclonal B-cell activation 339", synthetic 335,
J JOB'S SYNDROME 68,
K KAWASAKI SYNDROME 109, KILLER CELLS 404, KLEBSIELLA PNEUMONIAE resistance to 375,
L LACTAM see: S-lactam LACTOBACILLUS ACIDOPHILUS secretion of PG 224, LACTOBACILLUS CASEI PG-polysaccharide polymers of 275, 276, LACTOBACILLUS GASSERI immunoelectron microscopic studies 141, point of attack of penicillin 141 , secretion of PG 224, LATAMOXEF 188, LEUCOCYTOSIS 231, 265, LEUCOPENIA 231, 265, LEWIS LUNG CARCINOMA 204, LIPASE antibodies to 27,
LIPOPOLYSACCHARIDE 121, 249, 341 , antigenicity of 342, antibodies to 127, 342, biological activity of 341, chemical structure of 341347, core 343, O-specific chains 343, as pyrogen 204, 344, repeating units 343, LIPOPROTEIN interaction with lymphocytes 335, 336, PG associated 335, 336, mitogenic activity 335, 336, LIPOSOME-ENTRAPPED MTP-PE (MTP-PE/MLV) antitumor effects 256, antiviral effects 256-258, effects in virus models 256, effects in tumor models 256, induction of tumoricidal macrophages 256-258, induction of virucidal monocytes 256-258, LIPOTEICHOIC ACID 169, 172, and autolytic enzymes 171, LIQUOID 172, LISTERIA MONOCYTOGENES 375, LOCALIZATION OF PG immunoelectron microscopy 129, 135, in tissues 316, LUNG CARCINOMA 204, LYMPHOCYTES interaction with lipoprotein 335, 336, interaction with PG 229, 231, 232 ,
430 B-LYMPHOCYTE MITOGENS 335, polyclonal activation of 232, LYSIS, BACTERIAL 215, LYSIS GENE 215, LYSOSOMAL ENZYMES 167, LYSOSOMAL HYDROLASES 167, LYSOSTAPHIN 118, LYSOZYME 48, 167, 191, 206,
effect on PMN's 284, effect on REM sleep 330, effect on slow wave sleep 329, effect on T-cells 285, IL-2 production suppressed by 285, in vitro degradation 61, intraarticular injection with 278, oxygen radical production induced by 284, 357, reactivation of arthritis induced by 279, somnogenicity 32 9,
LYSOZYME-PEROXIDASE CONJUGATE 130,
MDP ANALOGS 353, 379, 383, immunoadjuvant activity of 379, 383, macrophage cytotoxicity of LYTIC ENZYMES 395 , of PG 3, 48, 118, pyrogenic activity of 379, 381, LYTIC MUREIN TRANSGLYCOSYLASE 212, 383, 384, MELANOMA M
B 16 melanoma 204, 257,
MACROPHAGES 173, 197, 404, 405, activation of 249, 284, 298, 299, 355-359, cytotoxicity by MDP analogs 395, inhibition of migration 229, 230, inhibitory agents 404, 405, interaction with PG 229, 231, 232,
MEDIATORS
MAMMARY CARCINOMA 204, MASS SPECTROMETRY 49, 20 3,
of inflammation 294, MEMBRANE perturbation 215, potential 215, protein 215, METABOLIC FATE of MDP 61, of PG monomers 204, METHANOBACTERIUM FORMICICUM 276,
MAST CELLS degranulation 294, effect of A polysaccharide on 283, effect of PG on 283,
MICELLAR STRUCTURE OF PG 45,
MDP 1 73 , 31 5 , 353 , 371 , 383, 401-406, adjuvanticity of, coupled to immunogen 407, antibodies to 5, 6, 354, anti-inflammatory effect of
MICROCOCCUS LUTEUS antisera to 5, 136, partial lack of peptide substitution in PG 3, 5, 7, secretion of PG 149,
280,
281,
arachidonic metabolite production induced by 283, 285, coupled to immunogen 407, effect on anti-PG antibody formation 289,
MICROCOCCI antibodies to interpeptide bridge of 8, 9,
MITOGENS of B-lymphocytes 335,
431
MITOGENIC ACTIVITY of lipoprotein 335, 336, of soluble PG 159, MODELS of cell wall structure 129, 133, of peptidoglycan 37, 44, MOLECULAR WEIGHT ANALYSIS 64, 65, MONOKINES secretion 229, MORPHOGENESIS, BACTERIAL 209, M-PROTEIN SEQUENCE 130, MTP-PE/MLV see: liposome entrapped MTP-PE MURALYTIC DIGESTION of PG-polysaccharide polymers 276, 278, 279, MURAMIC ACID antibodies to 5, 6, levels of, in tissues 64, MURAMINIDASE 3, MURAMYL PEPTIDES see: MDP and MDP analogs MUREIN see: peptidoglycan MUTANOLYSIN 276, 279, 280, MYCOBACTERIUM TUBERCULOSIS 402, 403,
N NATURAL KILLER CELLS 404, NEISSERIA GONORRHOE 313, 314, NEUTROPHILS activation of 298, 299, NMRI-MICE 372, NON-SPECIFIC RESISTANCE 372,
O O-ACETYLATION see: ACETYLATION O-specific chains of LPS 343, OXYGEN METABOLISM stimulation by PG 231, OXYGEN RADICALS 167, 168, 284, 357 , production of, induced by MDP 284, 357,
P PATHOMECHANISMS 305, PATIENT'S SERA 21, 22, 26-28, 99, 105, PBP 83, of Proteus mirabilis 188, PENICILLIN 170, 172, 187, 204, 225, see also: ß-LACTAM ANTIBIOTICS, antibodies to 83, cross-reactivity with R-D-Ala,, 13, growth of S. aureus 225, point of attack 141, PENICILLIN BINDING PROTEINS, see PBP, PENTAPEPTIDE SUBUNIT OF PG antibodies to 5, 11, 95, 105, 136, 310, as inhibitor, 131, detection of, by RIA 221, immunoelectron microscopic localization 135, structure of 2, PEPTIDE SUBSTITUTION OF PG partial lack in Micrococcus luteus 3, 5, 7 , PEPTIDOGLYCAN anti-metastatic activity of 204, 206, anti-tumor activity 204, 249, 255, 256,
432 arthritis induced by 277-279, 314, 317, biological activity of, in man 291, 305, biosynthesis 46, complement activation by 264, 284, 298, 299, 319, 323, crossreactivity between PGs 95, 101, degradation of 191, 197, 209, 215, 230, digestion of 48, disaccharide peptide monomers 314, 315, 317, effect on cells of the immune system 229, effect on human basophils 283, effect on mast cells 283, effect on phagocytic cells 261, effect on PMN function 26 3, glycan strand 2, 4, 5, 75, 78, 132, 135, 209, 221, hemorrhage in gut lympoid tissue induced by 283, histamine release induced by 283, inhibition of synthesis 190, interaction with lymphocytes 229, 231, 232, interleukin 1 production induced by 283, intraarticular injection with 278, immunochemistry of 1, 61, 95, 145, macrophage activation by 284, 298, 299, micellar structure of 45, models of 37, 44, molecular architecture of 37, 44, monomers, metabolic fate of 204, pentapeptide subunit of 2, 5, 11, 95, 105, 131, 136, 310, peptidoglycan types 2, persistence of 316, 317, phlogistic properties of 273-283, platelet aggregation or lysis induced by 284, 285, polar caps of 209, precursor sequence of 3, preparation of 320, 321, removal of teichoic acid from 320, 321, sacculus 209, self association of 46,
of staphylococci 7, 9, 191, 197, soluble PG 7, 79, 95, 145, 190, 221, spatial arrangement of 37, 43, stimulation of oxygen metabolism by 231, structure of 2, 37, 43, 49, 55, 61 , 209, structure-function relationship of 1-20, 37, 43, 145, 273, 285, synthesis 215, synthesis, inhibition of 190, synthetic analogs of 383, T-cell activation by 231, tetrapeptide subunit of 2, 5, 131 , thrombocytopenia, induced by 284, 285, tissue localization of 316, turnover products of 221 , ultrastructural localization of 130, 135, PEPTIDOGLYCAN-POLYSACCHARIDE POLYMERS 167, antibodies to 90, arachidonic acid metabolite production induced by 283, complement activation by 284, edema induced by low mol. wt. fragments of 276, 278, 279, effect on PMN's 284, effect on T-cells 285, from Streptococcus pyogenes (group A) 273-286, from Streptococcus faecium (group D) 275, 276, from Streptococcus agalactiae (group B) 275, 276, from Lactobacillus casei 275, 276, from Peptostreptococcus productus 275, 276, from Propionibacterium acnes 275, 276, intraarticular injection with 278, levels in vivo 62, molecular weight analyses of 64, 65, muralytic digestion of 276, 278, 279, N-acetylation or de-O-acetylation of 276, 278, 279,
phlogistic properties of 273-286, sedimentation field flow fractionation 64, 65, thrombocytopenia induced by 284, PEPTOCOCCUS ANAEROBIS secretion of soluble PG 149, PEPTOSTREPTOCOCCUS PRODUCTUS PG-polysaccharide polymers of 275, 276, PEROXIDASE-LYSOZYME CONJUGATES 1 30, PERSISTENCE of PG 316, 317, PHAGOCYTIC CELLS effects of PG on 261 , PHAGOCYTOSIS 405, inhibition of 229, 230, PHI X-174
215,
PHLOGISTIC PROPERTIES of PG 273-283, of PG-polysaccharide polymers 273-286, PLAQUE FORMING CELL ANTIBODY RESPONSE 393, PLASMIDS 215, PLATELET AGGREGATION induction by PG 284, 285, PLATELET LYSIS induction by PG 284, 285, POLYANETHOLE SULFONATE (LIQUOID) 172, POLAR CAPS of PG 209, POLYARTHRITIS 62, POLYCLONAL ACTIVATION of lymphocytes 232, POLYELECTROLYTE S anionic 168, cationic 169, 171,
POLY-L-ARGININE 171, PORES 215, POSTOPERATIVE WOUNDINFECTION 124, PRECURSOR SEQUENCE Of PG 3, PREDICTIVE VALUE of iS. aureus serology 28, PROPRIONIBACTERIUM ACNES PG-polysaccharide polymers of 275, 276, PROSTAGLANDINS 230, PROTEUS MIRABILIS action of ß-lactam antibiotics on 187, conversion to spheroplasts 1 defective cell walls of spheroblasts 190, growth in spheroplast form 189, penicillin binding proteins
188,
PYELONEPHRITIS 127, PYODERMA 297, PYROGEN 344, endogenous 2 30, PYROGENICITY of MDP derivatives 379, 381, 383, 384,
R RADIOACTIVE HAPTEN BINDING ASSAY 6, 105, 135, detection of secreted PG 221 inhibition of 11, RADIOIMMUNOASSAY see also: SPRIA levels of secreted PG 221 , levels of teichoic acid anti bodies 113,
434 RAPID EVE MOVEMENT 326, RAST 71 , REPEATING UNITS of LPS 343, RESPIRATORY BURST 168, 170, 263, RHAMNOSE gas chromatography-mass spectrometry, levels in tissue 64, RHEUMATOID FACTOR 89, RHINITIS, BACTERIAL 297, RIBITOL TEICHOIC ACID 118, RIFT VALLEY FEVER VIRUS 256,
S SARCOMA T 241 sarcoma 257, SALMONELLA ENTERITIS 125, SCARLET FEVER 109, SECRETION OF PG 145, 149, 189, 221, 223, 224, levels of, by RIA 221, SEDIMENTATION FIELD FLOW FRACTIONATION 64, 65, SELF ASSOCIATION of PG 46, SEPTICEMIA 24, 123, 127, 261, by S^. aureus 21 , SEPTUM 209, SHIGELLA ENTERITIS 125, SINUSITIS, BACTERIAL 297, SKIN REACTIONS induced by PG 292, 299, 308, 386, 387,
SKIN TUMOR UV induced 257, SLEEP see: SLOW WAVE SLEEP SLOW WAVE SLEEP 329, induction of 231, slow wave sleep promoting activity 230, SOLUBLE PG 7, 79, 95, 145, 190, 221, antibodies cross-reactive with 157, definition 145, detection 145, 148, 221, immunogenicity 159, inflammatory properties 163, in man 154, mitogenicity 159, physiological properties 149, polyclonal activation by 162, secretion 149, 221, 224, structure 151, SOMNOGENIC MURAMYLPEPTIDES 329, SPATIAL ARRANGEMENT of PG 37, 43, SPHEROBLASTS 187, 189, SPRIA, SOLID-PHASE-RADIOIMMUNOAS SAY levels of IgE antibodies to S. aureus cell walls 67, levels of IgG antibodies to S. aureus PG 24, levels of antibodies to teichoic acid 113, STAPHYLOCOCCAL PG O-acetylation 7, 191, 197, STAPHYLOCOCCAL SCALED SKIN SYNDROME 109, STAPHYLOCOCCI antibodies to interpeptide bridge of 9, degradation of PG 191, 197, STAPHYLOCOCCUS AUREUS 405, 406, antibodies to 113, bacteremia 113, 115, carboxypeptidase of 11,
435
degradation of PG 191, endocarditis 115, growth under penicillin G 225, immunoglobulin E antibodies to 67, immunoelectronmicroscopy 1 37, infections 21, 149, labelled with 14C-GlcNAC 171, 174, S. aureus 52A5 136, 319, S. aureus Cowan I 305, S. aureus H 114, S. aureus Wood 46 114, secretion of PG 223, septicemia 21 , serology 113, 114-116, serology, predictive value of 28, soluble PG from 145, teichoic acid 113,
STRUCTURE calculation- 45, of cell walls 37, 129, 341, determination 49, of glycan moiety of PG 2, of interpeptide bridge of PG 2, micellar, of PG 45, of PG 2, 37, 43, 55, 61, of soluble PG 151, structure-function relationship 1-20, 37, 61-66, 145-166, 341-352, 353-370, SYNECHOCYSTIS 55, SYNOVIAL ACTIVATOR ACTIVITY 230,
STAPHYLOCOCCUS EPIDERMIDIS 305,
SYNTHESIS of PG 215,
STEM PEPTIDE 2,
of PG, inhibition of 190,
STREPTOCOCCAL A-CARBOHYDRATE antibodies to 6,
SYNTHETIC immunogens 6, 8, 10, 11, 75, 95, 135, 137, 148, 190, lipid A 347 , lipopeptides 335, MDP analogs 37 9, vaccine models 408,
STREPTOCOCCUS AGALACTIAE PG-polysaccharide polymers of 275, 276, STREPTOCOCCUS FAECALIS see: ENTEROCOCCUS FAECALIS STREPTOCOCCUS FAECIUM see: ENTEROCOCCUS FAECIUM STREPTOCOCCUS PNEUMONIAE PBP from 84, secretion of soluble PG 149, STREPTOCOCCUS PYOGENES 129, 131, 136, immunoelectron microscopy 137, M-protein sequence 130, PG-polysaccharide polymers of 273-286, secretion of soluble PG 149, 223,
T T-CELL ACTIVATION by PG 231, T-CELL REPLACING (HELPER) ACTIVITY 231,
STREPTOLYSIN 0 antibodies to 107,
TEICHOIC ACID 113, 168, 180, activation of alternate pathway of complement 319, antibodies to 43, 113, counterImmunoelectrophoresis 113, ELISA 113, immunodiffusion 113, indirect hemagglutination 113, preparation of 114, radioimmunoassay 113, removal from PG 320, 321, ribitol teichoic acid 118,
STREPTOMYCES ALBUS D,D-carboxypeptidase 389,
TETANUS TOXOID antibodies to 267,
STREPTOCOCCUS PYOGENES A-VARIANT antibodies to 10,
436 TETRAPEPTIDE SUBUNIT OF PG 131 , antibodies to 5, structure of 2, THROMBOCYTOPENIA 2 65, induced by PG 284, 285, induced by PG-polysaccharide polymers 284, THYMOCYTE ACTIVATING FACTOR 230, TISSUE LOCALIZATION, OF PG 316, levels of muramic acid 64, levels of rhamnose 64, TRANSGLYCOSYLASE 212, TREHALOSE DIMYCOLATE 401-406, TRIALANINE 11, 131, TUMORICIDAL EFFECT 255, 258, TUMORS Lewis lung carcinoma 204, mammary carcinoma 204, B 16 melanoma 204, 257, T 241 sarcoma 257, skin tumors, UV-induced 257, TURNOVER OF PG 221, ULCEROUS COLITIS 125, ULTRASTRUCTURAL LOCALIZATION of PG 130, 135, URINARY TRACT INFECTION 123, 127, UVEITIS 62 VANCOMYCIN 148, VASCULITIS, ALLERGIC 298, VIRUSES Rift Valley Fever Virus 256, Herpes simplex virus 256, HTLV III 305, WOUND INFECTION 124, 127, X-RAY DIFFRACTION 4 3
The Target of Penicillin The Murein Sacculus of Bacterial Cell Walls Architecture and Growth Proceedings • International FEMS Symposium Berlin (West), Germany, March 13-18,1983 Editors
R. Hakenbeck, J.-V. Holtje, H. Labischinski
1983.17 cm x 24 cm. XXVIII, 663 pages. Numerous illustrations. Hardcover. DM 180,-; approx. US $85.70 ISBN 311009705 2
Immunoassay Technology Volume 1 Editor
S. B. Pal
1985.17 cm x 24 cm. VIII, 192 pages. Numerous illustrations. Softcover. DM 118,-; approx. US $56.20 ISBN 311010062 2 This is the first volume of a series on Immunoassay Technology which includes Review Articles and Methods and deals essentially with immunological methods of biological, commercial and environmental importance, without introducing radioactive isotopes.
Immunoassay Technology Volume 2 Editor
S. B. Pal
1986.17 cm x 24 cm; approx. US $70.50
ISBN 311010948 4
The second volume of this series, Immunoassay Technology, contains several articles which it is hoped readers will find as interesting, useful and thought-provoking as those presented in the previous volume, in particular to recent entrants in this field.
Prices are subject to change without notice
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WALTER DE GRUYTER • BERLIN • NEW YORK
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Verlag Wfeüter de Gruyter & Co., Genthiner Str. 13, D-1000 Berlin 30, Tel.: ( 0 3 0 ) , 2 6 0 0 5 - 0 , Telex 1 8 4 0 2 7 Walter de Gruyter, Inc., 200Saw Mill River Road, Hawthorne, N.Y. 10532, Tel. : (914) 747-0110, Telex 64 6677
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Concise ^yclopedia B i o c h
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s t r y Edited by Thomas Scott and Mary Brewer 2nd printing with corrections. 1983.14 cm x 21,5 cm. VI, 519 pp. Approx. 650 illustrations. Hardcover. DM 78,-; US $34.95 ISBN 3110078600
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The Concise Encyclopedia of Biochemistry, with more than 4,200 entries, is the foremost collection of current information in this rapidly expanding field. The contents are complemented by numerous structural formulas, metabolic pathways, figures and tables. All those interested in or working in the field of Biochemistry and Biology (Life Sciences), will profit from the information contained in this encyclopedia. This truly remarkable book is an essential reference for Biochemists, Clinical Chemists, Clinical Biochemists, Clinicians, Medical Researchers and Experimental Biologists. It will also serve as a very useful source of information for students.
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WALTER DE GRUYTER • BERLIN • NEW YORK Verlag Walter de Gruyter & Co., Genthiner Str. 13, D-1000 Berlin 30, Tel.: (030),26005-0, Telex 184027 Walter de Gruyter, Inc., 200Saw Mill River Road, Hawthorne, N.Y. 10532, Tel. : (914) 747-0110, Telex 64 6677