Immunochemical and structural analysis of the O polysaccharides of Salmonella zuerich [1,9,27,(46)]

Salmonella zuerich [1,9,27,(46)] has been shown to exhibit two levels of structural heterogeneity. The bacterium carries two distinct O-polysaccharide molecules with and without O:factor 1. Both sets of molecules (1+ and 1-) carry the two O:factors 27 and 46 on the same O chain, but they are expressed unevenly; in contrast to factor 27, O:factor 46 is always weakly expressed. Part of this weak expression was thought to be due to strong inhibition of factor 46 by factor 1. In this study, serological analysis gave more detailed information on the sizes of the different O:factor epitopes. Structural analysis of S. zuerich O polysaccharides showed that they are constructed of the expected chemical sequences characteristic of factors 1, 9, 27, and 46. No modification in the sugar sequence could account for the weak expression of O:factor 46. Factors 27 and 46 are present on oligosaccharides carrying either an alpha-Man (factor 27) or a beta-Man (factor 46) residue. In S. zuerich, the alpha-Man configuration is predominant, corroborating the expression of strong factor 27 and weak factor 46 on the bacteria. Questions raised by the existence of such heterogeneous O polysaccharides on the specificity of the O chain polymerase, as well as the place of S. zuerich in Salmonella evolution, are dicussed in this paper.     

Distribution and antigenic properties of the O-determinants of Salmonella zuerich (1, 9, 27 46)

Fractionation of the O-polysaccharide derived from Salmonella zuerich (1, 9, 27, 46) on a concanavalin A polymer permitted immunological and chemical analysis on the different fractions. The S. zuerich O-polysaccharide preparation is composed of two distinct populations of molecules: one, ZB1-, devoid of O-antigenic determinant 1, and the other, ZB1+, carrying the determinant 1. This determinant is linked to the presence of D-glucosyl residues on the side chain. O-polysaccharide molecules 1-, devoid of D-glucose, are shown to carry simultaneously both determinants 27 and 46. These determinants are not evenly distributed on the molecules. The expression of determinants 46 (-[Tyv]-betaMan-, where Tyv = tyvelose) seems to be restricted to a distinct specific configuration, and it is altered by the presence of either determinant 27 (-[Tyv]-alphaMan-) or determinant 1 (Glc-Gal-) in the close neighbourhood. Molecules 1+ are partially or completely substituted by glucosyl residues and react with anti-1 antibodies. They are characterized by the same uneven distribution of determinants 27 and 46 as molecules ZB1-. In conclusion, the O-polysaccharide chains are heterogeneous. They contain simultaneously factors 27, 46, and often also 1.     

Separation of two Salmonella O-antigen polysaccharides by means of a glutaraldehyde-concanavalin-A polymer. Primary studies on the separated fractions.

The Salmonella zuerich (1,9,12,(46),27) cell wall O-polysaccharides have been characterized as a mixture of two immunologically distinct fractions differing in the presence or absence of the antigenic determinant 1 usually carried by side chains of an alpha-D-glucosyl residue. In this paper, we describe the use of concanavalin A in separating the two O-polysaccharides. The procedure involves polymerization of concanavalin A with glutaraldehyde, followed by selective adsorption of the polysaccharide containing O factor 1 and elution with D-glucose. Immunological and chemical analyses showed that the separation was successful and demonstrated chemical differences between these two fractions in relation to their immunological behaviour.     

On the serological specificity of the Escherichia coli O8 and O9 antigens.

The O8 and O9-specific lipopolysaccharides of Escherichia coli lost their serological activity during liberation of the polysaccharide moieties (alpha-mannans) by mild acid hydrolysis, as tested by passive haemagglutination and haemagglutination inhibition. The serological activities and specificities were restored by substitution of the polysaccharides with 1 to 2 stearoyl groups per polysaccharide chain. The mannans obtained by biosynthesis in vitro were serologically active only when bound to the membrane-associated hydrophobic carrier molecule. Liberation of the polysaccharides from the carrier by treatment with aqueous phenol resulted in loss of the serological activity. The O8- and O9-specific mannans of E. coli are thus serologically active when they are part of an amphiphilic molecule and not as free polysaccharides.     

Structural and immunochemical studies of the lipopolysaccharides of Salmonella strains with both antigen O4 and antigen O9.

Two Salmonella hybrid strains, SL5313 (Salmonella typhimurium with a D.rfb+ gene cluster) and SL5396 (S. enteritidis with a B.rfb+ gene cluster), each expressing both O-antigen 4 (of serogroup B) and O-antigen 9 (of serogroup D) were studied by immunofluorescence using a mixture of O4-specific mouse monoclonal and O9-specific rabbit polyclonal antibodies. Bound antibodies, detected by anti-mouse antibody labelled with fluorescein isothiocyanate and anti-rabbit antibody labelled with tetramethylrhodamine isothiocyanate showed that more than 98% of the bacteria expressed both the O4 and O9 epitopes. Phenol-water-extracted lipopolysaccharide from batch-grown cultures subjected to sugar and methylation analyses by gas-liquid chromatography and mass spectrometry were shown to contain abequose (of the O4 epitope) and tyvelose (of the O9 epitope) in ratios of 1:1.5 and 1:2.5 for SL5313 and SL5396, respectively. Isolated polysaccharide chains, obtained by weak-acid hydrolysis of the lipopolysaccharides, were found to contain both O4 and O9 specificities in the same molecule, since polysaccharide bound to O4 antibody attached to a solid-phase-adsorbed O9-specific antibody and vice versa. This demonstrates that in strains SL5313 and SL5396 O chains containing both O4 repeating units (from S. typhimurium) and O9 units (from S. enteritidis) are present.     

Determination of specificities of rabbit antisera against the O-antigenic polysaccharide from Escherichia coli O126

Abstract Rabbit polyclonal antibodies against the lipopolysaccharide of Escherichia coli O126 were serologically characterized by ELISA. The antibody specificities were determined by studying the inhibitory effects of the methyl glycosides of both anomeric configurations of the constituent monosaccharides and the oligosaccharides derived from the O-antigenic polysaccharides of E. coli O126. It was found that, amongst the monosaccharides, β- d -N-acetyl glucosamine was the most effective inhibitory sugar in the O126 polysaccharide and the major specificity of the polyclonal antibodies was found to be directed against the trisaccharide having the structure α- D -Gal p (1 → 3)-β- D -Glc pNAc(1→2)- D -Man p.     

Monoclonal antibodies with specificities for Streptococcus pneumoniae group 9 capsular polysaccharides

Streptococcus pneumoniae group 9 includes four capsular polysaccharide types: 9A, 9L, 9N and 9V. We have generated four mouse monoclonal antibodies against group 9 polysaccharide using heat-treated S. pneumoniae strains of different capsular polysaccharides types as immunogens. The specificities of the monoclonal antibodies were determined by ELISA using capsular polysaccharide directly coated to the wells as antigens and by dot blotting with heat-treated bacteria. Two groups of monoclonal antibodies were found. The first group included two monoclonal antibodies which were found to be capsular type specific. The second group was monoclonal antibodies that bound to epitopes shared by two or three pneumococcal group 9 types. The monoclonal antibody 204,A-4 (IgM) was found to be specific for S. pneumoniae type 9N. The binding of the type 9V specific monoclonal antibody 206,F-5 (IgG1) was found to be dependent upon O-acetyl groups. Monoclonal antibody 205,F-3 (IgM) reacted also with type 9V, but was found to cross-react with types 9A and 9L. The binding of this monoclonal antibody to polysaccharide 9V was not dependent upon O-acetyl moieties. The fourth monoclonal antibody (214,G-5, isotype IgM) did not show any correlation between reactivity with isolated polysaccharides and dot blotting with relevant bacteria. The monoclonal antibody reacted with polysaccharides 9A and 9L in ELISA, but not with the homologous bacteria.     

Origin of the heterogeneity of cell wall O-polysaccharides from Salmonella zuerich (1,9,12,(46),27).

The heterogeneity of the cell wall O-polysaccharide of Salmonella zuerich (factor 1 present or absent) is probably not due to mutations in the stock since it was seen in essentially similar fashion (proportion one 1+ to four 1-forms) in four separate lots of polysaccharide extracted from separate culture batches. The results of indirect fluorescent antibody studies suggest that form variation of factor 1, occurring at an unusually high rate, is the most probable basis of the heterogeneity.     

Monoclonal antibodies to Streptococcus mutans serotype f polysaccharide cross-react with the 'mutans group' of oral streptococci

Abstract Eleven stable clones producing monoclonal antibodies (MAbs) against serotype polysaccharide f were generated from rat IR 983F myeloma cells and splenocytes from rats immunized with formalin-killed whole Streptococcus mutants OMZ 175. These MAbs were IgG 2b, they had different affinities towards polysaccharide f and all but three were able to inhibit saliva binding to S. mutants OMZ 175 cells. Two specificities were recognized on S. mutans serotype f polysaccharide. One MAb (K24) recognized an epitope on the poly-rhamnose core, as determined by competitive ELISA using different sugars. The ten other MAbs recognized an epitope which seems principally formed of glucose subunits. Purified polysaccharides from other 'mutans streptococci' were able, to different extents, to inhibit the binding of the MAbs to polysaccharide f, confirming the presence of common epitopes in the different strains.     

Structural analysis of the O-antigen side chain polysaccharides in the lipopolysaccharides of Klebsiella serotypes O2(2a), O2(2a,2b), and O2(2a,2c).

The lipopolysaccharide (LPS) of Klebsiella serotype O2 is antigenically heterogeneous; some strains express multiple antigenic factors. To study this heterogeneity, we determined the structure of the O-antigen polysaccharides in isolates belonging to serotypes O2(2a), O2(2a,2b), and O2(2a,2c), by using composition analysis, methylation analysis, and both 1H and 13C nuclear magnetic resonance spectroscopy. The repeating unit structure of the 2a polysaccharide was identified as the disaccharide [----3)-beta-D-Galf-(1----3)-alpha-D-Galp-(1----] and was identical to D-galactan I, one of two O polysaccharides present in the LPS of Klebsiella pneumoniae serotype O1 (C. Whitfield, J. C. Richards, M. B. Perry, B. R. Clarke, and L. L. MacLean, J. Bacteriol. 173:1420-1431, 1991). LPS from serotype O2(2a,2b) also contained D-galactan I as the only O polysaccharide, suggesting that the 2b antigen is not an O antigen. The LPS of serotype O2(2a,2c) contained a mixture of two structurally distinct O polysaccharides and provides a second example of this phenomenon in Klebsiella spp. One polymer was identical to D-galactan I, and the other polysaccharide, the 2c antigen, was a polymer with a disaccharide repeating unit structure, [----3)-beta-D-GlcpNAc-(1----5)-beta-D-Galf-(1----]. The 2c structure does not resemble previously reported O polysaccharides from Klebsiella spp. Periodate oxidation confirmed that D-galactan I and the 2c polysaccharide are distinct glycans, rather than representing domains within a single polysaccharide chain. Monoclonal antibodies against the 2c antigen indicated that only LPS molecules with the longest O-polysaccharide chains contained the 2c epitope.     

Human prorenin has "gate and handle" regions for its non-proteolytic activation

We investigated the mechanism for non-proteolytic activation of human prorenin using five kinds of antibodies. Each of the antigens, L1PPTDTTTFKRI11P, T7PFKRIFLKRMP17P, I11PFLKRMPSIRESLKER26P, M16PPSIRESLKER26P, and G27PVDMARLGPEWSQPM41P, was designed from the tertiary structure of predicted prorenin. These antibodies were labeled anti-01/06, anti-07/10, anti-11/26, anti-16/26, and anti-27/41, respectively, for their binding specificities. Inactive recombinant human prorenin (0.1 nM) bound to various concentrations of anti-01/06, anti-11/26, and anti-27/41 antibodies at 4 degrees C with equilibrium dissociation constants of 138, 41, and 22 nM, respectively. However, intact prorenin (0.1 nM) did not show significant binding to 200 nM anti-07/10 and anti-16/26 antibodies for 20 h. Ninety percent of prorenin (0.1 nM) was found to be non-proteolytically activated by incubation with anti-11/26 antibodies (200 nM) at 4 degrees C for 20 h. Prorenin was not active even under complex with either anti-01/06 or anti-27/41 antibodies. Prorenin was also reversibly activated at pH 3.3 and 4 degrees C for 25 h. The acid-activated prorenin bound to anti-07/10 and anti-16/26 antibodies as well as to anti-01/06, anti-11/15, and anti-27/41 antibodies at neutral pH and 4 degrees C in 2 h. Their dissociation constants were 13, 40, 8.6, 3.6, and 14 nM, respectively. The acid-activated prorenin was re-inactivated by incubation at pH 7.4 and 4 degrees C in 50 h. Anti-07/10 and anti-11/26 antibodies inhibited such re-inactivation at 25 degrees C by more than 90% and 50%, respectively, whereas other kinds of antibodies did not prevent the re-inactivation at 25 degrees C. These results indicate that prorenin has "gate" (T7PFKR10P) and "handle" (I11PFLKR15P) regions critical for its non-proteolytic activation.     

Immunological cross reactions between polysaccharides of Streptococci groups A and L]

Antibodies on sepharose immunosorbents containing A-polysaccharide-sepharose or synthetic beta-N-acetylglucosamine, were isolated from the sera of rabbits immunized with streptococci, group A, by means of affinity chromatography. Antibodies obtained from some sera with both immunosorbents reacted with streptococcus, group A and L polysaccharides. Partial identity of these polysaccharides was revealed by the immunodiffusion test. Absorption of antibodies with polysaccharides, group A and L, showed their different specificities. These antibodies could apparently be directed against the end parts of molecules of streptococcus, group A polysaccharide.     

The crystal struture of monoclinic ribonuclease-S at six angstroms resolution.

An independent structure analysis has been made of ribonuclease-S crystallized in a monoclinic space group C2 at 6 Å resolution. The conformations of the two crystallographically independent molecules (molecule ZA and ZB) were compared with that of a chemically identical molecule (molecule Y) crystallized in a trigonal space group P3₁21, the structure of which has been solved to 2.0 Å resolution by Wyckoff et al. (1970). The N-terminal tail of the S-protein of molecule ZA assumes a unique conformation somewhat resembling that of ribonuclease-A, while the corresponding part of molecule ZB assumes about a similar conformation to that of molecule Y. Apart from the solvated terminal region, the overall arrangements of various features of the three structures are very similar, although possibilities of local conformational differences are not considered at this stage of the analysis. The environments of the three molecules in the crystal lattice are compared in detail. Two of the four molecules in the primitive cell are related to each other by a crystallographic 2-fold axis very similar to a 2-fold relationship found in the Y-form. All other relationships are quite different.     

抗稻瘟病体细胞突变体的抗性遗传分析

以ZA_(15)和ZB_(11)等2个致病小种对6个抗稻瘟病体细胞突变体进行了抗性遗传分析。结果表明,86-S1、88-86、88-42和88-40等4个突变体对ZA_15、ZB_(11)小种的抗性分别由1个显性基因控制,同时这2个抗性基因还存在紧密的连锁关系。88-127和88-145对ZA_15的抗病性受2个重复显性基因控制;而对ZB_(11)的抗性则分别受2个互补显性基因和1个显性基因控制。等位性测定表明,86-S1、88-42和8B-86等3个突变体具有的抗性基因是等位的,可能是Pi-(?)或与之等位的抗性基因。     

Monoclonal antibodies demonstrate multiple epitopes on the O antigens of Salmonella typhimurium LPS

To investigate the complexity of the antigenic determinants presented on the surface of Salmonella typhimurium, a panel of murine monoclonal antibodies was generated and characterized. Hybridomas specific for S. typhimurium (strain TML, O antigens 1, 4, 12) were produced by immunization with acetone-killed and dried bacteria and standard fusion procedures. In this report, 15 such monoclonal antibodies, all of which bind lipopolysaccharide (LPS) extracted from S. typhimurium, are described. The fine specificity of these antibodies was assessed by examining the differential binding of each antibody to a panel of Salmonella strains, which selectively express different O antigenic determinants. This analysis defined several distinct categories of monoclonal antibodies of varying isotypes. Four anti-O:4-specific antibodies were identified. Two were specific for O:1. One antibody appears to react with the core polysaccharide of S. typhimurium LPS. Several of the monoclonal antibodies recognized LPS determinants that are presumably created by a combination of O antigens. For instance, one bound only to Salmonella strains that expressed both O:1 and O:12, whereas another bound only to those strains which expressed both O:4 and O:12. A group of three antibodies bound to any strain that simultaneously expressed O:1, O:4, and O:12. A distinct group of three monoclonal antibodies also bound strains that expressed O:1, O:4, and O:12, but only when the O:5 antigenic determinant was not present. The latter are, in that respect, S. typhimurium strain TML LPS-specific. The results of this analysis suggest that the epitopes of the S. typhimurium LPS molecule that are recognized by the host are considerably more complex than has been previously indicated by classical serology.     

Idiotypy of antibodies against human serum albumin in immunized rabbit serum, which are directed against different regions of this antigen

Idiotypy has been studied in rabbit antibodies against human serum albumin. Antibodies which are directed against three different regions of serum albumin have similar idiotypic specificities. The molecular distribution of idiotypic determinants may be different in antibodies with specificity for different determinants as revealed for example by their precipitability or non precipitability by the same anti-idiotypic antibodies. The anti-albumin antibodies which are not precipitable by the anti-idiotypic antibodies, though they do combine with them, become precipitable after being mildly polymerized. Similar idiotypic specificities may be found in antibodies to serum albumin and in immunoglobulins apparently devoid of anti-serum albumin antibody function.     

A role for sulfated polysaccharide recognition in sponge cell aggregation

Molecules binding sulfated polysaccharides were detected as lectins in cholate lysates of cells from twelve sponge species. Each species exhibited a unique binding profile. The pattern of binding indicated that the specificity was most probably determined by the orientation of the sulfate groups on the polysaccharide chains. Cells from each of the three species examined in more detail were found to express sulfated polysaccharide-binding molecules at their surface and at least one of the polysaccharides recognized was found to inhibit the reaggregation of cells from each species. Moreover, in all but one instance, lectins for the inhibitory polysaccharide were both detected in cell lysates and shown to be expressed at the cell surface. Sulfated polysaccharides, therefore, appeared to be involved in cell interaction events in the Porifera. This conclusion was confirmed by the isolation via ion exchange chromatography of an endogenous polysaccharide from an O. tenuis cell extract. This molecule contained uronic acid and hexose units in a ratio of 2:1, 11.9% sulfur and less than 0.5% protein. It inhibited the aggregation of O. tenuis cells and the agglutination of dextran-sulfate- and polyvinyl-sulfate-coupled erythrocytes by O. tenuis cell lysates. O. tenuis cell aggregation was also inhibited by polyvinyl sulfate and dextran sulfate and molecules binding these compounds were expressed on the surface of O. tenuis cells. Thus, is was probable that the cell surface receptor for polyvinyl sulfate and dextran sulfate and isolated sponge sulfated polysaccharide are one and the same. Finally, using a dextran sulfate affinity procedure, a 35 kD dextran-sulfate-binding protein was isolated from the surface of O. tenuis cells. The possibility that the polysaccharide isolated from O. tenuis cell extracts in the absence of calcium is the monomeric form of a cell aggregation-enhancing factor is discussed.     

Immunochemical analysis of the types Ia and Ib group B streptococcal polysaccharides

The types Ia and Ib group B streptococcal type-specific polysaccharides have remarkable immunologic differences despite a great deal of structural similarity. Although these two complex polysaccharides differ only by a single glycosidic linkage, they are antigenically distinct. Furthermore, terminal sialic acid residues appear to be critical to the immunodeterminant on the type Ia polysaccharide, whereas the antigenicity of the type Ib polysaccharide does not show this dependence on sialic acid. In the current investigation we defined better the immunodeterminant of these polysaccharides. With homologous rabbit antiserum, the type Ia native and core polysaccharides demonstrated partial serologic identity, whereas the type Ib native and core polysaccharides demonstrated complete serologic identity. Surprisingly, the type I degalactosylated polysaccharide, degraded structure, was capable of reacting with a population of antibodies present in type Ia antiserum similar to the complete type Ia native polysaccharide, although demonstrating a reduced level of immunodeterminant expression. Unlike the reactions of the type Ia polysaccharides with homologous rabbit antiserum, the Ib native and core polysaccharides were able to react with identical populations of antibodies in type Ib-specific antiserum. A minor population of antibodies was demonstrated in the type Ib antiserum, which was reactive with the degalactosylated polysaccharide. That a population of antibodies reactive toward the degalactosylated polysaccharide is present in both type Ia and type Ib antisera suggests that the Iabc cross-reacting determinant is due to the presence of serum antibodies reactive with this trisaccharide repeating unit, which is shared by both the type Ia and the type Ib native and core polysaccharides.     

Structural changes in myosin subfragment 1 by mild denaturation and proteolysis probed by antibodies

The perturbations in the structure of myosin subfragment 1 (S1) by mild denaturation or proteolysis were investigated by measuring the inhibition of the binding of antibodies to immobilized S1 by treated S1 in a solution-phase competitive immunochemical assay. The structural changes in S1 were probed by using anti-50-kDa segment, anti-N-terminus, anti-27-kDa segment, and anti-A1 light chain monoclonal antibodies (MAbs). Methanol and heat denaturation increased MAb binding to the 50-kDa segment. MAb binding to regions in the 27-kDa segment was also promoted, slightly by methanol and more drastically by heat. Proteolysis also induced structural alterations in 50- and 27-kDa segments as shown by increased MAb binding to these regions in cleaved S1. These results indicate that mild denaturation and proteolysis induce structural perturbations which alter the epitope accessibility in 50- and 27-kDa segments of S1 and that antibody binding studies afford a sensitive probe to such perturbations.     

Murine V kappa 25 and V kappa 27 amino-acid sequences of C57B1/6 origin: monoclonal antibodies 17S29.1 and 22S25.1 specific for the group A-streptococcal polysaccharide

Antibodies 17S29.1 and 22S25.1 are monoclonal, hybridoma-derived gamma 3 kappa murine immunoglobulins with specificity for N-acetyl-glucosamine beta 1----3-linked to the L-rhamnose backbone structure, the immunodeterminant of the streptococcal Group A polysaccharide. The VL 17S29.1 amino-acid sequence is the third complete one reported from an antibody with this specificity, the second fully determined V kappa 25 structure and the first complete V kappa sequence of C57B1/6 origin derived from a carbohydrate-specific antibody. VL22S25.1 is a member of the V kappa 27 isotype of murine immunoglobulin VL regions. V kappa 17S29.1 and the determined part of the V kappa 22S25.1 sequence are compared to the previously described V kappa regions of streptococcal Group A polysaccharide-specific antibodies and to 12 selected partial and complete V kappa regions of antibodies with other specificities, predominantly to carbohydrate antigens. Both V kappa 17S29.1 and V kappa 22S25.1 increase the variability of known murine V kappa regions. They are the most homologous to the other V kappa regions derived from antibodies with streptococcal Group A polysaccharide specificity and share with them the amino-acid residue Arg74, so far characteristic for V kappa regions from antibodies with this specificity. The analysis of groups of independently expressed, highly homologous V kappa regions, namely V kappa 17S29.1 and V kappa 2S1.3 as one and V kappa 7S34.1 and V kappa 22S25.1 as a second group, offers the possibility of estimating the minimal number of V kappa germline genes involved in the immune response to the structurally defined streptococcal Group A polysaccharide antigen.(ABSTRACT TRUNCATED AT 250 WORDS)