Conformational differences between linear alpha (2----8)-linked homosialooligosaccharides and the epitope of the group B meningococcal polysaccharide

The alpha-(2----8)-linked sialic acid oligosaccharides (NeuAc)n exhibit an unusual degree of heterogeneity in the conformation of their linkages. This was diagnosed by observation in their 13C NMR spectra of an equivalent and unique heterogeneity in the chemical shifts of their anomeric carbons and subsequently confirmed by more comprehensive 1H and 13C NMR studies. In these studies both one-dimensional and two-dimensional experiments were carried out on the trisaccharide (NeuAc)3 and colominic acid. In addition to the unambiguous assignment of the signals in the spectra, these experiments demonstrated that both linkages of (NeuAc)3 differed in conformation from each other and from the inner linkages of colominic acid. The NMR data indicate that these conformational differences extend to both terminal disaccharides of oligosaccharides larger than (NeuAc)5, a result that has considerable physical and biological significance. In the context of the group B meningococcal polysaccharide, it provides an explanation for the conformational epitope of the group B meningococcal polysaccharide, which was proposed on the evidence that (NeuAc)10, larger than the optimum size of an antibody site, was the smallest oligosaccharide able to bind to group B polysaccharide specific antibodies. Because the two terminal disaccharides of (NeuAc)10 differ in conformation to its inner residues, the immunologically functional part of (NeuAc)10 resides in its inner six residues. This number of residues is now consistent with the maximum size of an antibody site.     

Cleavage of the polysialosyl units of brain glycoproteins by a bacteriophage endosialidase. Involvement of a long oligosaccharide segment in molecular interactions of polysialic acid

Polysialosyl chains containing alpha 2-8-linked N-acetylneuraminic acid have been suggested to modulate the biological activity of a neural cell adhesion molecule. Polysialosyl glycopeptides isolated from developing brain were incubated with a bacteriophage containing endosialidase. Sialic acid oligomers up to 7 residues long were liberated both from the glycopeptides and colominic acid. The substrate specificity of the endosialidase was studied with sialic acid oligomers of different sizes prepared from colominic acid. It was found that the endosialidase required the simultaneous presence adjacent to the site of cleavage a minimum of 3 sialic acid residues on the distal side and a minimum of 5 sialic acid residues on the proximal (reducing end) side. From the fragments liberated by the enzyme the existence of polysialic acid chains up to at least 12 residues long in the glycopeptides were concluded. This was also supported by the interaction of the glycopeptides with a meningococcal group B polysaccharide antiserum, which was found to require 10 residues or more for binding. The results indicate that the brain polysialosyl glycopeptides contain a long polysialic acid segment, which is also specifically needed for certain molecular interactions. The implications of the findings for the biological properties of the neural cell adhesion molecule are discussed.     

Conformational aspects critical to the immunospecificity of the type III group B streptococcal polysaccharide

Immunization of rabbits with group B type III streptococcus organisms induces two distinct populations of antibodies with a specificity for determinants on the native capsular polysaccharide antigen of these organisms. Some of the structural and conformational features of the two determinants responsible for the formation of these antibodies were elucidated by (13)C NMR and serological studies on the native type III polysaccharide and some of its structurally modified analogues. The specificity of the determinant corresponding to the major population of antibodies is dependent of the presence of sialic acid residues on the native type III antigen, and although these residues are not an integral part of the determinant, they exert conformational control over it. The carboxylate groups of the sialic acid residues are an important factor in this control mechanism which could possibly involve intramolecular hydrogen bonding. The terminal sialic acid residues control the orientation of the penultimate beta-d-galactopyranose residues with respect to the backbone of the native antigen. The orientation of these residues is critical to the determinant because the determinant is probably small and is located precisely at the junction of the same beta-d-galactopyranose residues with the backbone of the native type III antigen. The determinant corresponding to the other population of antibodies is not sialic acid dependent. This determinant is located on the backbone of the native antigen in the vicinity of the other determinant but on the opposite side to the oligosaccharide branches. In this position, its conformation is unaffected even by the removal of the oligosaccharide branches from the native antigen.     

Rate, mechanism, and immunochemical studies of lactonisation in serogroup B and C polysaccharides of Neisseria meningitidis

Meningococcal Serogroup B polysaccharide and colominic acid, which are (2----8)-alpha-linked homopolymers of sialic acid, undergo lactonisation at low pH at a rate which is dependent upon the molecular size and upon the salt form (Na+ or Ca2+). Meningococcal Serogroup C polysaccharide, a (2----9)-alpha-linked homopolymer of sialic acid with acetyl groups present at O-7 and/or O-8, reacts with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide to give an O-acylisourea. The rate of formation of O-acylisourea does not differ substantially between O-acetylated (O-Ac+) C, non-O-acetylated (O-Ac-) C, and B polysaccharide. 13C-N.m.r. spectroscopy shows that, in the absence of O-acetyl groups, the majority of the activated carboxyl groups of C polysaccharide condense with an adjacent HO-8 to form a delta-lactone. Immunochemical studies show that the antigenicity of B polysaccharide is markedly reduced on lactonisation of less than 20%, as measured by a radioimmunoassay using an anti-B monoclonal antibody, and that low-molecular-weight colominic acid is poorly antigenic both before and after lactonisation, suggesting the presence of conformational determinants on B polysaccharide. In contrast, lactonisation and/or formation of O-acylisourea groups in the (O-Ac+)-C polysaccharide does not cause a significant decrease in the antigenicity, which is consistent with a sequential (structural) determinant on the molecule.     

Structural determination of the sialic acid polysaccharide antigens of Neisseria meningitidis serogroups B and C with carbon 13 nuclear magnetic resonance.

The application of 13-C nuclear magnetic resonance to the analysis of some sialic acid-containing meningococcal polysaccharide antigens is described. Complete assignments of the spectra of both the native serogroup B and the de-O-acetylated serogroup C polysaccharides have been made. These assignments were based on the corresponding data for some related monomers (sialic acid and its alpha-and beta-methylglycosides) and on supportive chemical evidence. The data indicate that the serogroup B polysaccharide is a 2 yields 8-alpha-linked homopolymer of sialic acid, identical in structure with colominic acid from Escherichia coli, whereas the de-O-acetylated serogroup C polysaccharide is a 2 yield 9-alpha-linked homopolymer. The native serogroup C polysaccharide is O-acetylated (1.16 mol of O-acetyl per sialic acid residue), all the O-acetyl substituents being located only at C-7 and C-8 of the sialic acid residues, and in addition contains unacetylated residues (24%). The polysaccharide contains di-O-acetylated residues (O-acetyl on C-7 and C-8), and at least one of the possible monoacetylated residues at C-7 or C-8.     

Development and evaluation of a rapid multianalyte particle-based flow cytometric assay for the quantification of meningococcal serogroup B-specific IgM antibodies in sera for nonculture case confirmation

Serogroup-specific antibody has been shown to be present in the sera of patients recovering from meningococcal disease, and thus the detection of such antibodies may aid in the confirmation of disease. There are currently no standard methods for measuring meningococcal serogroup B-specific antibody in sera. Here, we report the development of a microsphere-based immunoassay which utilizes colominic acid from Escherichia coli 07:K1 (L):NM to detect immunoglobulin M directed against serogroup B polysaccharide. The serogroup B assay was incorporated into a multiplex assay which also detects serogroup-specific immunoglobulin M for meningococcal serogroups A, C, Y and W-135. Using the method of cross-standardization, serogroup B-specific immunoglobulin M concentrations were assigned to the standard serum CDC 1992. The assay is able to detect increases in specific immunoglobulin M concentrations from acute to convalescent phase serum from serogroup B cases, and can be utilized in conjunction with the previously developed tetraplex immunoglobulin G detection assay for serogroups A, C, Y and W-135.     

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.     

Three-dimensional structural analysis of the group B polysaccharide of Neisseria meningitidis 6275 by two-dimensional NMR: the polysaccharide is suggested to exist in helical conformations in solution

The solution conformations of the group B polysaccharide of Neisseria meningitidis were analyzed by DQF-COSY and pure absorption 2D NOE NMR with three mixing times. The pyranose ring of the sialic acid residue was found to be in the 2C5 conformation. The DQF-COSY analysis indicated that the orientations of H6 and H7 and of H7 and H8 are both gauche. In order to overcome the difficulties in analyzing the NOE data due to the two sets of proton overlaps, molecular modeling of alpha-2,8-linked sialic acid oligomers was carried out to investigate possible conformers, and theoretical NOE calculations were performed by using CORMA (complete relaxation matrix analysis). Our analysis suggests that the polysaccharide adopts helical structures for which the phi (defined by O6-C2-O8-C8) and psi (C2-O8-C8-C7) angles are in the following ranges: phi -60 to 0 degrees, psi 115-175 degrees or phi 90-120 degrees, psi 55-175 degrees. The weak affinity of anti-B antibodies for smaller alpha-2,8-linked oligosaccharides may be due to the fact that such oligomers are more flexible and may not form an ordered structure as the poly(sialic acid) does.     

Induction of meningococcal group B polysaccharide-specific IgG antibodies in mice by using an N-propionylated B polysaccharide-tetanus toxoid conjugate vaccine

Conjugation of the group B meningococcal polysaccharide to tetanus toxoid failed to substantially enhance its immunogenicity in mice. Therefore, additional chemical manipulation of the basic structure of the group B meningococcal polysaccharide was attempted, on the premise that a synthetically derived artificial antigen might be capable of modulating the immune response in mice to produce elevated levels of cross-reactive group B meningococcal polysaccharide-specific antibodies. To achieve this, the antigenicity of the modified polysaccharide to group B meningococcal polysaccharide-specific antibodies had to be preserved, and this criterion could only be satisfied in modifications in which the carboxylate and N-carbonyl groups of the sialic acid residues of polysaccharide remained intact. Therefore, the most successful modifications were accomplished by N-deacetylation of the group B meningococcal polysaccharide with strong base to yield a precursor that could then be N-acetylated or N-arylated with different substituents. For example, the introduction of N-propionyl groups, followed by conjugation of the resultant N-propionylated group B meningococcal polysaccharide to tetanus toxoid, yielded an antigen that when injected in mice induced in them high levels of cross-reactive group B meningococcal polysaccharide-specific IgG antibodies. The T cell dependency of this antigen was established when it was demonstrated that the levels of these B polysaccharide-specific antibodies could be significantly boosted by using both the N-propionylated- and native N-acetylated-group B meningococcal polysaccharide-tetanus toxoid conjugates.     

Helical epitope of the group B meningococcal alpha(2-8)-linked sialic acid polysaccharide.

The immunological properties of the group B meningococcal alpha(2-8)-linked sialic acid polysaccharide have been rationalized in terms of a model where the random coil nature of the polymer can be described by the presence of local helices. The conformational versatility of the alpha NeuAc(2-8)alpha NeuAc linkage has been explored by NMR studies at 600 MHz in conjunction with potential energy calculations for colominic acid, an alpha(2-8)NeuAc polymer, and the trisaccharide alpha NeuAc(2-8)alpha NeuAc(2-8)beta NeuAc. Potential energy calculations were used to estimate the energetically favorable conformers and to describe the wide range of helices which the polymer can adopt. No unique conformer was found to satisfy all NMR constraints, and only ensemble averaged nuclear Overhauser enhancements could correctly simulate the experimental data. Conformational differences between the polymer and the trisaccharide could be best explained in terms of slight changes in the relative distribution of conformers in solution. Similar helical parameters for the alpha(2-8)NeuAc polymer and poly(A) were proposed as the basis for their cross-reactivity to a monoclonal antibody IgMNOV. The unusual length dependency for binding of oligosaccharide to group B specific antibodies was postulated to arise from the recognition of a high-order local helix with an extended conformation which was not highly populated in solution.     

Cell-free biosynthesis of the O-acetylated N-acetylneuraminic acid capsular polysaccharide of group C meningococci.

A cell-free system was established to study the biosynthesis of group C meningococcal capsular polysaccharide, an alpha-2 leads to 9-linked N-acetylneuraminic acid (NeuAc) homopolymer containing O-acetyl groups at either C7 or C8. Sialyltransferase activity, isolated from group C meningococcus strain C-11, catalyzed incorporation of [14C]NeuAc from CMP (CMP--[14C]NeuAc) into polymeric form. This sialyltransferase was stimulated by addition of meningococcus group C and Escherichia coli K92 capsular polysaccharides, the latter being an alpha-2 leads to 8- and alpha-2 leads to 9-linked NeuAc heteropolymer. Group C meningococcal sialyltransferase did not require divalent ions but was stimulated by Mn2+. Attempts to demonstrate a lipid-soluble intermediate in the biosynthesis of this NeuAc polymer were unsuccessful. Meningococcal group C sialyltransferase incorporated NeuAc into a membrane-associated product. The polysaccharide can be extracted from the membrane-bound fraction with Triton X-100. The newly synthesized polysaccharide coprecipitates with authentic group C antigen in meningococcal group C antiserum and is degraded by sodium metaperiodate, indicating that the NeuAc polymer synthesized by the cell-free system consists of alpha-2 leads to 9 linkage. Meningococcal group C spheroplast membranes contain an O-acetylase that can catalyze the transfer of acetyl groups from acetyl coenzyme A to the in vitro-synthesized polysaccharide.     

Detection, isolation, and characterization of oligo/poly(sialic acid) and oligo/poly(deaminoneuraminic acid) units in glycoconjugates.

We have evaluated methods for separation, preparation, and characterization of alpha-2----8-linked oligomers of sialic acids (Neu5Ac and Neu5Gc) and deaminated neuraminic acid (KDN; 2-keto-3-deoxy-D-glycero-D-galacto-nononic acid) recently found as a naturally occurring novel type of sialic acid analogue. (A) We examined preparative anion-exchange chromatography for fractionation and preparation of oligo(Neu5Ac), oligo(Neu5Gc), and oligo(KDN). (B) We also examined the TLC method for separation and differentiation of the partial acid hydrolysates of colominic acid, as well as polysialoglycoproteins (PSGP) and poly(KDN)-glycoproteins (KDN-gp) isolated from rainbow trout eggs, and for discrimination of lower oligomers of Neu5Ac, Neu5Gc, and KDN. (C) We developed the high-performance adsorption-partition chromatographic method for (a) separation of monomers and oligomers of three nonulosonates according to the difference in substituents at C-5 and the presence or absence of 9-O-acetyl groups in oligo(KDN) and (b) separation of three homologous series of lower oligomers according to the degree of polymerization. (D) We examined and compared high-performance anion-exchange chromatographic separation of 3H-labeled oligo(Neu5Ac), oligo(Neu5Gc), and oligo(KDN) alditols by using Mono-Q HR 5/5 resin. (E) We examined a method of selective and quantitative microprecipitation for separation and purification of oligomers and polymers of Neu5Ac by treating them with cetylpyridinium chloride. We also used PSGP and KDN-gp to test both the sensitivity and the selectivity of this method.     

An integrity assay for a meningococcal type B conjugate vaccine

The development of an analytical procedure for the evaluation of a conjugate vaccine's structural wholeness or integrity is described. The principle component of the vaccine was the N-propionylated group B meningococcal polysaccharide (NPr-GBMP) covalently attached to a carrier protein. The goal of the procedure was to determine whether any whole polysaccharide, oligosaccharide, or monosaccharide, from minute to moderate levels, became detached off the conjugate. Free saccharide was isolated from the formulation, which included an aluminum hydroxide adjuvant for analysis. Due to its linkage, the NPr-GBMP did not release sialic acid efficiently with acid hydrolysis to the extent necessary for accurate quantitation. To accomplish depolymerization, the NPr-GBMP was subjected to methanolysis, 3N hydrochloric acid in methanol for 16h at 80 degrees C. The main product of the methanolysis reaction was a de-N-acylated methyl glycoside of sialic acid. N-acetylneuraminic acid oligomers and colominic acid were used to confirm the methanolysis depolymerization efficiency of the alpha(2 --> 8) saccharides; with the treatment all oligomers produced a common methyl glycoside. For this determination anion exchange chromatography and size exclusion chromatography were both interfaced to an integrated pulsed amperometric detector. Sensitivity and linearity were demonstrated to be sufficient for the application with vaccine dose formulations with low total saccharide concentrations.     

Isolation, characterization, and antitumor activities of the cell wall polysaccharides from Elsinoe leucospila.

A cell-wall preparation from the cells of Elsinoe leucospila, which produces elsinan extracellularly when grown on sucrose or glucose-potato extract medium, was fractionated systematically. The heteropolysaccharide that was released by treatment with Actinase E digestion, comprised D-mannose, D-galactose, and D-glucose (molar ratio, 1.5:1.0:0.1). Methylation, mild acid hydrolysis, and 13C-NMR studies suggested that the polysaccharide contains a backbone of alpha-(1----6)-linked D-mannose residues having two kinds of side chains, one attached at the O-4 with single or short beta-(1----6)-linked D-galactofuranosyl residues, and the other attached at O-2 with short side chains, most probably, of alpha-(1----3)-linked D-mannopyranosyl residues. A moderately branched D-glucan fraction, obtained from the cold alkali extract, was fractionated to give an antitumor-active purified beta-(1----3)-glucan having branches of single beta-D-glucosyl groups, one out of eight D-glucose residues being substituted at the O-6.     

Comparison of the conformational dynamics of the (1----4)- and (1----6)-linked alpha-D-glucans using 13C-NMR relaxation.

The conformational dynamics of alpha-(1----4)- and alpha-(1----6)-glucan homooligomers in the nanosecond time domain have been compared by measuring the 13C-nmr longitudinal relaxation times T1 for carbons of the terminal and interior sugar residues. Measurements are reported on monomeric glucose and on oligomers containing up to ten glucose residues at room temperature in aqueous solution at concentrations of 3 and 20 g/dL. The carbons of terminal residues display longer relaxation times than do those of interior residues, presumably as a consequence of a greater degree of conformational mobility of the chain ends. The T1s of the reducing terminal residues of all oligomers are significantly longer than those of the corresponding nonreducing termini, a phenomenon that we associate tentatively with the anomeric equilibrium at the reducing end. Carbons of the reducing terminal residues in the beta-anomeric form relax more slowly than their alpha-anomeric counterparts. At 20 g/dL the mean T1s for carbons of the terminal and interior residues attain asymptotic behavior with increasing chain length at a chain length of about six residues, and carbons of the alpha-(1----4)-linked maltooligomers relax significantly more slowly than those of the corresponding alpha-(1----6)-linked isomaltooligomers. The T1s of both glucan series increase with decreasing concentration. This concentration dependence disappears below 3 g/dL, where the T1s of the two series of homoligomers are no longer distinguishable. This suggests that in dilute aqueous solution at room temperature viscous damping effects predominate over contributions to the T1-sensitive conformational dynamics from structural differences in the glycosidic linkage region. At 3 g/dL the approach to long chain-length asymptotic behavior is more protracted than at 20 g/dL, and the T1s of carbons of interior oligomeric residues appear to match the corresponding high-polymer behavior at a chain length of eight and greater.     

Enzymic degradation of the mycobacterial O-methyl-D-glucose polysaccharide by a Rhizopus-mold alpha amylase, an enzyme active on 6-O-methyl-amylo-oligosaccharides

An enzyme activity that catalyzes hydrolysis of an alpha-(1----4)-linked 6-O-methyl-D-glucan was detected in, and purified from, Rhizopus oryzae mold. The enzyme acts like an alpha amylase and digests unmodified amylo-oligosaccharides 10 to 15 times as fast as it does the 6-O-methyl and 6-deoxy derivatives. When the limit product obtained by digesting the mycobacterial O-methyl-D-glucose polysaccharide with pancreatic alpha amylase and Aspergillus glucoamylase was further digested with the Rhizopus alpha amylase, di-, tri-, and tetra-saccharide fragments composed of alpha-(1----4)-linked 6-O-methyl-D-glucose were released. The rest of the molecule was recovered as oligosaccharides terminated by two, or three, alpha-(1----4)-linked 6-O-methyl-D-glucose residues.     

Purification and properties of a Ca2+-independent sialic acid-binding lectin from human placenta with preferential affinity to O-acetylsialic acids

A Ca2+-independent sialic acid-specific lectin from two developmental stages of human placenta was similarly purified to apparent homogeneity by DEAE-cellulose chromatography, affinity chromatography on bovine submaxillary mucin, and gel filtration. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration disclosed a molecular mass of 53 kDa. The specificity of the lectin for O-acetylsialic acids was substantiated by the dependence of hemagglutination on the presence of acetylated sialic acids on the surface of mammalian erythrocytes of various sources, by hapten inhibition in hemagglutination assays with protease-treated rabbit erythrocytes and by hapten inhibition of binding of labeled N-acetylneuraminic acid-bovine serum albumin to the lectin in a solid-phase assay. Bovine and equine submaxillary mucins that contain 9(7,8)-O-acetyl and 4-O-acetylsialic acids were potent inhibitors in contrast to the non-acetylated sialic acids of ovine submaxillary mucin. Absence of inhibitory efficiency of other negatively charged substances like phosphorylated sugars, glucuronic acid, heparin, or oligodeoxynucleotides emphasized the importance of structural features instead of simple ionic interaction. In the presence of acetylation, the pattern of inhibition by gangliosides in the solid-phase assay indicated a preference to alpha-2,8- or alpha-2,6-linked sialic acids in comparison to alpha-2,3-linked moieties. Chemical modification of the lectin by group-specific reagents allowed to emphasize the role of primarily lysine residues, but also, although less pronounced, arginine, tryptophan, and carboxyl groups for ligand binding and/or maintenance of the active conformational state. Application of reagents, specific for histidine or tyrosine residues, failed to affect lectin activity.     

Structural studies on the sialic acid polysaccharide antigen of Escherichia coli strain Bos-12.

A polysaccharide, antigenically related to group C meningococcus, has been isolated from Escherichia coli strain Bos-12 (016; K92; NM). Like groups B and C meningococcal polysaccharide, the Bos-12 antigen is a pure polymer of sialic acid. 13C NMR studies on the meningococcal group B and C polysaccharides have indicated that the former consists of sialic acid units linked 2 leads to 8- alpha, whereas the latter contains the sialic acid residues linked 2 leads to 9-alpha (Bhattacharjee, A.K., Jennings, H.J., Kenny, C.P., Martin, A., and Smith, I.C.P. (1975), J. Biol. Chem. 250, 1926). Comparison of natural abundance 13C NMR spectra of the Bos-12 polysaccharide with group B and C meningococcal polysaccharides established that Bos-12 was either (a) an equimolar mixture of 2 leads to 8-alpha linked sialic acid homopolymers or (b) a 2 leads to 8-alpha/2 leads to 9-alpha heteropolymer. These possibilities were distinguished in the following manner. The fact that Bos-12 polysaccharide precipitated with anti-group C serum but not with anti-group B serum would seem to exclude a. Further, chemical studies (periodate oxidation followed by tritiated NaBH4 reduction) gave saccharides with a radioactive-labeling pattern expected for alternating 2 leads to 8-alpha/2 leads to 9-alpha sialic acid linkages. Bos-12 is thus an 2 leads to 8/2 lead to 9-alpha heteropolymer.     

Structure and immunochemistry of an oligosaccharide repeating unit of the capsular polysaccharide of type III group B Streptococcus. A revised structure for the type III group B streptococcal polysaccharide antigen

We have derived oligosaccharides from the capsular polysaccharide of type III group B Streptococcus by enzymatic hydrolysis of a specific backbone glycosidic bond utilizing an endo-beta-galactosidase from Flavobacterium keratolyticus. Enzymatic digestion of the polysaccharide produced oligosaccharide fragments of one or more pentasaccharide repeating units. On the basis of 13C NMR, 1H NMR, and methylation analyses, it was established that the smallest digestion fragment was alpha-D-NeupNAc-(2----3)-beta-D-Galp-(1----4)-[beta-D-Glcp-(1----6 )]- beta-D-GlcpNAc-(1----3)-beta-D-Gal. The isolation of this oligosaccharide is consistent with the susceptibility of the beta-D-Galp-(1----4)-beta-D-Glcp linkage in the backbone of the type III group B streptococcal polysaccharide and confirms that the polysaccharide is composed of a pentasaccharide repeating unit. High resolution 13C NMR spectroscopic studies indicated that, as in the case of the pentasaccharide, the terminal sialic acid residues of the type III group B streptococcal polysaccharide were linked to O-3 and not to O-6 of its branch beta-D-galactopyranosyl residues as had been previously reported (Jennings, H. J., Rosell, K.-G., and Kasper, D. L. (1980) Can. J. Chem. 58, 112-120). This linkage was confirmed in an independent methylation analysis of the type III group B streptococcal polysaccharide. Thin layer chromatogram binding assay and radioactive antigen binding assays with radiolabeled oligosaccharides demonstrated the single repeating unit pentasaccharide oligosaccharide to be poorly antigenic. Increasing oligosaccharide size to a decasaccharide consisting of two repeating units resulted in an 8-fold increase in antigen binding in the direct radioactive antigen binding assay. The results suggest that a region of the immunodeterminant site critical for antibody binding is located in the backbone of the polysaccharide and involves the beta-D-galactopyranose-(1----4) beta-D-glucopyranose bond.     

Alpha-(2----8)-polysialic acid immunoreactivity in voltage-sensitive sodium channel of eel electric organ

The voltage-sensitive sodium channel from eel electroplax is formed of a polypeptide of 208,321 Da, to which is attached ca. 85 kDa of carbohydrate. Sialic acid is a prominent constituent, contributing ca. 113 negative charges to the protein surface. We here demonstrate that antibodies raised against the bacterial antigen alpha-(2----8)-polysialic acid, specific for polymers of ten or more consecutive sialic acid residues, react specifically and with high affinity to the electroplax sodium channel. In extracts of electroplax membranes, the sodium channel is the only protein that demonstrates this immunoreactivity, suggesting the presence of a polysialosyl-sialyltransferase specifically committed to this unique post-translational modification of the sodium channel. Polysialic acid is rare in vertebrates, having previously been found only associated with neural-cell adhesion molecules, present in the developing neuromuscular system. The other prominent source is the capsular polysaccharide of highly pathogenic meningitis bacteria. Antibodies to the bacterial antigen thus provide highly specific affinity markers for the sodium channel. The high avidity of these antibodies and the ratio of sialic acid residues to consensus glycosylation sites suggest that the terminal chains are well over ten sialosyl residues in length, potentially extending 10-30 nm into the extracellular environment.