Structural relatedness of enteric bacterial porins assessed with monoclonal antibodies to Salmonella typhimurium OmpD and OmpC.

The immunochemistry and structure of enteric bacterial porins are critical to the understanding of the immune response to bacterial infection. We raised 41 monoclonal antibodies (MAbs) to Salmonella typhimurium OmpD and OmpC porin trimers and monomers. Enzyme-linked immunosorbent assays, immunoprecipitations, and/or Western immunoblot techniques indicated that 39 MAbs (11 anti-trimer and 28 anti-monomer) in the panel are porin specific and one binds to the lipopolysaccharide; the specificity of the remaining MAb probably lies in the porin-lipopolysaccharide complex. Among the porin-specific MAbs, 10 bound cell-surface-exposed epitopes, one reacted with a periplasmic epitope, and the remaining 28 recognized determinants that are buried within the outer membrane bilayer. Many of the MAbs reacting with surface-exposed epitopes were highly specific, recognizing only the homologous porin trimers; this suggests that the cell-surface-exposed regions of porins tends to be quite different among S. typhimurium OmpF, OmpC, and OmpD porins. Immunological cross-reaction showed that S. typhimurium OmpD was very closely related to Escherichia coli NmpC and to the Lc porin of bacteriophage PA-2. Immunologically, E. coli OmpG and protein K also appear to belong to the family of closely related porins including E. coli OmpF, OmpC, PhoE, and NmpC and S. typhimurium OmpF, OmpC, and OmpD. It appears, however, that S. typhimurium "PhoE" is not closely related to this group. Finally, about one-third of the MAbs that presumably recognize buried epitopes reacted with porin domains that are widely conserved in 13 species of the family Enterobacteriaceae, but apparently not in the seven nonenterobacterial species tested. These data are evaluated in relation to host immune response to infection by gram-negative bacteria.     

Genetic Transfer of Salmonella typhimurium and Escherichia coli Lipopolysaccharide Antigens to Escherichia coli K-12

Escherichia coli K-12 varkappa971 was crossed with a smooth Salmonella typhimurium donor, HfrK6, which transfers early the ilv-linked rfa region determining lipopolysaccharide (LPS) core structure. Two ilv(+) hybrids differing in their response to the LPS-specific phages FO and C21 were then crossed with S. typhimurium HfrK9, which transfers early the rfb gene cluster determining O repeat unit structure. Most recombinants selected for his(+) (near rfb) were agglutinated by Salmonella factor 4 antiserum. Transfer of an F' factor (FS400) carrying the rfb-his region of S. typhimurium to the same two ilv(+) hybrids gave similar results. LPS extracted from two ilv(+),his(+), factor 4-positive hybrids contained abequose, the immunodominant sugar for factor 4 specificity. By contrast, his(+) hybrids obtained from varkappa971 itself by similar HfrK9 and F'FS400 crosses were not agglutinated by factor 4 antiserum, indicating that the parental E. coli varkappa971 does not have the capacity to attach Salmonella O repeat units to its LPS core. It is concluded that the Salmonella rfb genes are expressed only in E. coli varkappa971 hybrids which have also acquired ilv-linked genes (presumably rfa genes affecting core structure or O-translocase ability, or both) from a S. typhimurium donor. When E. coli varkappa971 was crossed with a smooth E. coli donor, Hfr59, of serotype O8, which transfers his early, most his(+) recombinants were agglutinated by E. coli O8 antiserum and lysed by the O8-specific phage, Omega8. This suggests that, although the parental E. coli K-12 strain varkappa971 cannot attach Salmonella-specific repeat units to its LPS core, it does have the capacity to attach E. coli O8-specific repeat units.     

Surface topology of the Escherichia coli K-12 ferric enterobactin receptor.

Monoclonal antibodies (MAb) were raised to the Escherichia coli K-12 ferric enterobactin receptor, FepA, and used to identify regions of the polypeptide that are involved in interaction with its ligands ferric enterobactin and colicins B and D. A total of 11 distinct FepA epitopes were identified. The locations of these epitopes within the primary sequence of FepA were mapped by screening MAb against a library of FepA::PhoA fusion proteins, a FepA deletion mutant, and proteolytically modified FepA. These experiments localized the 11 epitopes to seven different regions within the FepA polypeptide, including residues 2 to 24, 27 to 37, 100 to 178, 204 to 227, 258 to 290, 290 to 339, and 382 to 400 of the mature protein. Cell surface-exposed epitopes of FepA were identified and discriminated by cytofluorimetry and by the ability of MAb that recognize them to block the interaction of FepA with its ligands. Seven surface epitopes were defined, including one each in regions 27 to 37, 204 to 227, and 258 to 290 and two each in regions 290 to 339 and 382 to 400. One of these, within region 290 to 339, was recognized by MAb in bacteria containing intact (rfa+) lipopolysaccharide (LPS); all other surface epitopes were susceptible to MAb binding only in a strain containing a truncated (rfaD) LPS core, suggesting that they are physically shielded by E. coli K-12 LPS core sugars. Antibody binding to FepA surface epitopes within region 290 to 339 or 382 to 400 inhibited killing by colicin B or D and the uptake of ferric enterobactin. In addition to the FepA-specific MAb, antibodies that recognized other outer membrane components, including Cir, OmpA, TonA, and LPS, were identified. Immunochemical and biochemical characterization of the surface structures of FepA and analysis of its hydrophobicity and amphilicity were used to generate a model of the ferric enterobactin receptor's transmembrane strands, surface peptides, and ligand-binding domains.     

The rfaS gene, which is involved in production of a rough form of lipopolysaccharide core in Escherichia coli K-12, is not present in the rfa cluster of Salmonella typhimurium LT2.

Partial sequencing of the rfa cluster of Salmonella typhimurium LT2 indicated a region of 336 bp between rfaP and rfaB in the site occupied by the rfaS gene in Escherichia coli K-12. This region does not contain a functional rfaS gene, although DNA analysis suggests that the region may have contained an ancestral gene. This conclusion that S. typhimurium LT2 lacks rfaS is supported by its lipopolysaccharide (LPS) gel phenotype, since LT2 does not make the lipooligosaccharide band characteristic of LPS from smooth strains of E. coli K-12.     

Evolution of the ferric enterobactin receptor in gram-negative bacteria.

Using sodium dodecyl sulfate-polyacrylamide gel electrophoresis of iron-deficient and replete cell envelopes, 59Fe-siderophore uptake studies, and Western immunoblots and cytofluorimetric analyses with monoclonal antibodies (MAbs), we surveyed a panel of gram-negative bacteria to identify outer membrane proteins that are structurally related to the Escherichia coli K-12 ferric enterobactin receptor, FepA. Antibodies within the panel identified FepA epitopes that are conserved among the majority of the bacteria tested, as well as epitopes present in only a few of the strains. In general, epitopes of FepA that are buried in the outer membrane bilayer were more conserved among gram-negative bacteria than epitopes that are exposed on the bacterial cell surface. The surface topology and tertiary structure of FepA are quite similar in E. coli and Shigella flexneri but differ in Salmonella typhimurium. Of the 18 different genera tested, 94% of the bacteria transported ferric enterobactin, including members of the previously unrecognized genera Citrobacter, Edwardsiella, Enterobacter, Haemophilus, Hafnia, Morganella, Neisseria, Proteus, Providencia, Serratia, and Yersinia. The ferric enterobactin receptor contains at least one buried epitope, recognized by MAb 2 (C. K. Murphy, V. I. Kalve, and P. E. Klebba, J. Bacteriol. 172:2736-2746, 1990), that is conserved within the structure of an iron-regulated cell envelope protein in all the bacteria that we have surveyed. With MAb 2, we identified and determined the Mr of cell envelope antigens that are immunologically related to E. coli FepA in all the gram-negative bacteria tested. Collectively, the library of anti-FepA MAbs showed unique patterns of reactivity with the different bacteria, allowing identification and discrimination of species within the following gram-negative genera: Aeromonas, Citrobacter, Edwardsiella, Enterobacter, Escherichia, Haemophilus, Hafnia, Klebsiella, Morganella, Neisseria, Proteus, Providencia, Pseudomonas, Salmonella, Serratia, Shigella, Vibrio, and Yersinia.     

Role of Escherichia coli K-12 rfa genes and the rfp gene of Shigella dysenteriae 1 in generation of lipopolysaccharide core heterogeneity and attachment of O antigen.

The rfp gene of Shigella dysenteriae 1 and the rfa genes of Escherichia coli K-12 and Salmonella typhimurium LT2 have been studied to determine their relationship to lipopolysaccharide (LPS) core heterogeneity and their role in the attachment of O antigen to LPS. It has been inferred from the nucleotide sequence that the rfp gene encodes a protein of 41,864 Da which has a structure similar to that of RfaG protein. Expression of this gene in E. coli K-12 results in the loss of one of the three bands seen in gel analysis of the LPS and in the appearance of a new, more slowly migrating band. This is consistent with the hypothesis that Rfp is a sugar transferase which modifies a subset of core molecules so that they become substrates for attachment of S. dysenteriae O antigen. A shift in gel migration of the bands carrying S. dysenteriae O antigen and disappearance of the Rfp-modified band in strains producing O antigen suggest that the core may be trimmed or modified further before attachment of O antigen. Mutation of rfaL results in a loss of the rough LPS band which appears to be modified by Rfp and prevents the appearance of the Rfp-modified band. Thus, RfaL protein is involved in core modification and is more than just a component of the O-antigen ligase. The products of rfaK and rfaQ also appear to be involved in modification of the core prior to attachment of O antigen, and the sites of rfaK modification are different in E. coli K-12 and S. typhimurium. In contrast, mutations in rfaS and rfaZ result in changes in the LPS core but do not affect the attachment of O antigen. We propose that these genes are involved in an alternative pathway for the synthesis of rough LPS species which are similar to lipooligosaccharides of other species and which are not substrates for O-antigen attachment. All of these studies indicate that the apparent heterogeneity of E. coli K-12 LPS observed on gels is not an artifact but instead a reflection of functional differences among LPS species.     

Associations of Escherichia coli K-12 OmpF trimers with rough and smooth lipopolysaccharides.

The associations of both rough and smooth lipopolysaccharides (LPS) with the OmpF porin of Escherichia coli K-12 were examined in galE strains deleted for ompC. Transformation with pSS37 and growth with galactose conferred the ability to assemble a Shigella dysenteriae O antigen onto the core oligosaccharide of E. coli K-12 LPS. The association of LPS with OmpF trimers was assessed by staining, autoradiography of LPS specifically labeled with [1-14C]galactose, and Western immunoblotting with a monoclonal antibody specific for OmpF trimers. These techniques revealed that the migration distances and multiple banding patterns of OmpF porin trimers in sodium dodecyl sulfate-polyacrylamide gels were dictated by the chemotype of associated LPS. Expression of smooth LPS caused almost all of the trimeric OmpF to run in gels with a slower mobility than trimers from rough strains. The LPS associated with trimers from a smooth strain differed from the bulk-phase LPS by consisting almost exclusively of molecules with O antigen.     

Escherichia coli outer membrane protein K is a porin.

Protein K is an outer membrane protein found in pathogenic encapsulated strains of Escherichia coli. We present evidence here that protein K is structurally and functionally related to the E. coli K-12 porin proteins (OmpF, OmpC, and PhoE). Protein K was found to cross-react with antibody to OmpF protein and to share 8 out of 17 peptides in common with the OmpF protein. Strains that are OmpC porin- and OmpF porin- and contain protein K as their major outer membrane protein have increased rates of uptake of nutrients and a faster growth rate relative to the parental porin- strain. The protein K-containing strains are at least 1,000-fold more sensitive to colicins E2 and E3 than is the porin -deficient strain. These data suggest that protein K is a functional porin in E. coli. The porin function of protein K was also demonstrated in vitro, using black lipid membranes. Protein K increased the conductance in these membranes in discrete, uniform steps characteristic of channels with a size of about 2 nS.     

Detection of porin antigen in serum for early diagnosis of mouse infections with Salmonella typhimurium

Abstract The monoclonal antibodies to porin, an outer membrane protein isolated from Salmonella typhimurium and sandwich enzyme linked immunosorbent assay (ELISA) has made possible the detection of porin from sera of S. typhimurium -infected mice. The specificity of the monoclonal antibodies was ascertained based on their cross-reactivity with porins isolated from S. typhi, Shigella flexneri and Escherichia coli and lipopolysaccharide (LPS) of S. typhimurium and E. coli . Serum samples were found to be positive for porin as early as 3 days after intravenous and 5 days after oral infection. In addition, a positive correlation was observed between the bacterial load and the concentration of porin detected in the sera. On the other hand, analysis of sera for anti-porin antibody showed diametrically opposite time kinetics with antigenaemia. These results indicate that porin accumulates in the serum of infected mice much earlier than the appearance of antibodies to porin. Thus detection of porin holds promise for early diagnosis of typhoid.     

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.     

抗脂多糖单克隆抗体特性及纯化的研究

用Ｅ．ｃｏｌｉ０１１１：Ｂ４死菌体及其脂多糖（ＬＰＳ）免疫ＢＡＬＢ／Ｃ小鼠,取其脾细胞与ＳＰ２／０细胞融合获得６株稳定分泌抗ＬＰＳ特异性单克隆抗体细胞株,其中一株为ＩｇＧ２ａ类,５株为ＩｇＭ类,轻链均为Ｋ型;染色体数目为９０－９８条;５株ＩｇＭ类单克隆抗体识别５种不同的抗原表位;相对亲和力在１０~８～１０~（１０）之间;１Ｂ１２单抗经ＳｅｐｈａｄｅｘＧ－１５０纯化后,经还原性ＳＤＳ－ＰＡＧＥ显示只有７０ＫＤ的重键和２５ＫＤ的轻链。     

Antigenic polymorphism of the LamB protein among members of the family Enterobacteriaceae.

In this study we demonstrate that most members of the family Enterobacteriaceae possess a maltose-inducible outer membrane protein homologous to the LamB protein of Escherichia coli K-12. These proteins react with polyclonal antibodies raised against the LamB protein of E. coli K-12. We compared the antigenic structure of the LamB protein in members of the family Enterobacteriaceae with six monoclonal antibodies raised against the LamB protein of E. coli K-12. Four of them reacted with epitopes located at the outer face of the membrane, and two reacted with epitopes located at the inner face of the membrane. A great degree of variability was observed for the external epitopes. Even in a single species, such as E. coli, an important polymorphism was present. In contrast, the internal epitopes were more conserved.     

Monoclonal antibodies that distinguish inner core, outer core, and lipid A regions of Pseudomonas aeruginosa lipopolysaccharide.

In order to examine the immunochemistry of the core-lipid A region of Pseudomonas aeruginosa lipopolysaccharide (LPS), monoclonal antibodies (MAbs) specific for this region were produced in mice. Immunogen was prepared by coating a rough mutant of P. aeruginosa with column-purified core oligosaccharide fractions in order to enhance the immune response to the LPS core-lipid A region. Fourteen hybridoma clones were isolated, characterized, and further divided into three groups on the basis of their reactivities to rough LPS antigens in both enzyme-linked immunosorbent assays and Western immunoblots. In addition, another MAb, 18-19, designated group 1, was included in this study for defining core-lipid A epitopes. MAb 18-19 recognizes the LPS core-plus-one O-repeat unit of the serologically cross-reactive P. aeruginosa O2, O5, and O16. Group 2 MAbs are specific for the LPS outer core region and reacted with P. aeruginosa O2, O5, O7, O8, O10, O16, O18, O19, and O20, suggesting that these serotypes share a common outer core type. Group 3 MAbs recognize the inner core region and reacted with all 20 P. aeruginosa serotypes as well as with other Pseudomonas species, revealing the conserved nature of this region. Group 4 MAbs are specific for lipid A and reacted with all gram-negative organisms tested. Immunoassays using these MAbs and well-defined rough mutants, in addition to the recently determined P. aeruginosa core structures, have allowed us to precisely define immunodominant epitopes within the LPS core region.     

Identification of TonB homologs in the family Enterobacteriaceae and evidence for conservation of TonB-dependent energy transduction complexes.

The transport of Fe(III)-siderophore complexes and vitamin B12 across the outer membrane of Escherichia coli requires the TonB-dependent energy transduction system. A set of murine monoclonal antibodies (MAbs) was generated against an E. coli TrpC-TonB fusion protein to facilitate structure and function studies. In the present study, the epitopes recognized by these MAbs were mapped, and their distribution in gram-negative organisms was examined. Cross-species reactivity patterns obtained against TonB homologs of known sequence were used to refine epitope mapping, with some epitopes ultimately confirmed by inhibition experiments using synthetic polypeptides. Epitopes recognized by this set of MAbs were conserved in TonB homologs for 9 of 12 species in the family Enterobacteriaceae (including E. coli), including previously unidentified TonB homologs in Shigella, Citrobacter, Proteus, and Kluyvera species. These homologs were also detected by a polyclonal alpha-TrpC-TonB serum that additionally recognized the known Yersinia enterocolitica TonB homolog and a putative TonB homolog in Edwardsiella tarda. These antibody preparations failed to detect the known TonB homologs of either Pseudomonas putida or Haemophilus influenzae but did identify potential TonB homologs in several other nonenteric gram-negative species. In vivo chemical cross-linking experiments demonstrated that in addition to TonB, auxiliary components of the TonB-dependent energy transduction system are broadly conserved in members of the family Enterobacteriaceae, suggesting that the TonB system represents a common system for high-affinity active transport across the gram-negative outer membrane.     

Outer Membrane Proteins of Escherichia coli IV. Differences in Outer Membrane Proteins Due To Strain and Cultural Differences

When the 42,000-dalton major outer membrane protein of Escherichia coli O111 is examined on alkaline polyacrylamide gels containing sodium dodecyl sulfate, it is resolved into three distinct bands designated as proteins 1, 2, and 3. Band 3 consists of two distinct polypeptides, proteins 3a and 3b. E. coli K-12 does not make any protein 2, but makes proteins similar to 1, 3a, and 3b as indicated by comparison of cyanogen bromide peptide patterns. Several Shigella species and most other strains of E. coli resemble E. coli K-12 in that they lack protein 2, whereas Salmonella typhimurium is more similar to E. coli O111. In addition to these species and strain differences, cultural differences resulted in differences in the outer membrane protein profiles. Under conditions of catabolite repression, the level of protein 2 in E. coli O111 decreased while the level of protein 1 increased. An enterotoxin-producing strain similar to E. coli O111 produced no protein 1 and an elevated level of protein 2 under conditions of low catabolite repression. The levels of proteins 1 and 3 are also different in different phases of the growth curve, with protein 1 being the major species in the exponential-phase cells and protein 3 being the major species in stationary-phase cells. A multiply phage-resistant mutant of E. coli K-12 with no obvious cell wall defects produced no protein 1 or 2, but made increased amounts of protein 3. Thus, the major outer membrane proteins of E. coli and related species may vary considerably without affecting outer membrane integrity.     

Structures of the rfaB, rfaI, rfaJ, and rfaS genes of Escherichia coli K-12 and their roles in assembly of the lipopolysaccharide core.

Analysis of the sequence of a 4.1-kb rfa region downstream from rfaP revealed four genes. The first of these encodes a basic protein of 36,730 Da and does not correspond to any known rfa gene. It has been designated rfaS. The second gene was identified as rfaB on the basis of its ability to complement a Salmonella typhimurium rfaB mutant and encodes a 42,060-Da protein. The third and fourth genes encode proteins of 39,423 and 36,046 Da which are strongly homologous to the RfaI and RfaJ proteins of S. typhimurium. Escherichia coli K-12 restriction fragments carrying these genes complement an S. typhimurium rfaI mutant and, at lower efficiency, an rfaJ mutant. The difference in complementation efficiency suggests that the rfaI and rfaJ genes of E. coli K-12 have sugar and acceptor specificities different from those of S. typhimurium, as predicted from the different lipopolysaccharide (LPS) core structures of the two organisms. Defined mutations affecting all four genes were constructed in vitro and crossed onto the chromosome. The phenotypes of these mutations suggest that extension of the core may require protein-protein interactions between the enzymes involved in core completion as well as the interaction of these enzymes with their specific acceptor molecules. Mutants blocked at rfaI or genes encoding earlier steps in core biosynthesis exhibited a single predominant LPS band on gels while mutants blocked at rfaJ or genes encoding later steps produced multiple strong bands, indicating that one of the processes generating core heterogeneity requires a functional rfaI gene.     

Genetic analysis of the genes involved in synthesis of the lipopolysaccharide core in Escherichia coli K-12: three operons in the rfa locus.

The region of the Escherichia coli K-12 chromosome encoding the enzymes responsible for the synthesis of responsible for the synthesis of the lipopolysaccharide (LPS) core has been cloned in vivo by using a mini-Mu vector. This region, formerly known as the rfa locus, comprises 18 kb of DNA between the markers tdh and rpmBG. Results of in vitro mutagenesis of this region with MudII1734 indicate the presence of at least 17 open reading frames or genes, a number considerably higher than expected on the basis of genetic and biochemical studies. Specific insertions in different genes have been recombined into the chromosome, and the mutations have been phenotypically characterized. Complementation analysis indicates that these genes are arranged in three different operons transcribed in opposite directions. A detailed physical map of this region has been constructed on the basis of complementation analysis, fusion protein data, and phenotypic characterizations. Additionally, the role of some genes in the synthesis of LPS has been defined by complementation analysis with known Salmonella typhimurium LPS mutants. The genetic organization of this locus seems to be identical in E. coli K-12 and S. typhimurium.     

Verification of the protein in the outer membrane of Bdellovibrio bacteriovorus as the OmpF protein of its Escherichia coli prey.

Two research groups showed that several Bdellovibrio strains incorporated into their outer membranes intact OmpF porin proteins derived from their Escherichia coli prey. These results could not be reproduced by another group using Bdellovibrio bacteriovorus 109J. They showed that a major protein appearing in the Bdellovibrio Triton X-100-insoluble outer membrane was coded for by the bdellovibrios. We reconciled these results by examining the strain used by this group and by reviving a freeze-dried culture of strain 109J which had been stored for almost 9 years. B. bacteriovorus 109J failed to acquire substantial amounts of the OmpF protein from E. coli ML35, and a protein coded for by the bdellovibrios was expressed in its place. However, B. bacteriovorus 109J incorporated the OmpF protein from rough K-12 strains of E. coli, and the revived 9-year-old culture of B. bacteriovorus 109J incorporated more of the OmpF protein from the smooth E. coli ML35 than did its contemporary counterpart. The protein isolated from the outer membrane of the bdellovibrios was identified as the OmpF protein of E. coli by its protease peptide profile on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by Western blot analysis. This confirmed that bdellovibrios relocalize outer membrane proteins from their prey, but relocalization may be an unstable trait which can be influenced by the prey.     

Monoclonal antibodies as probes to examine serotype-specific and cross-reactive epitopes of lipopolysaccharides from serotypes O2, O5, and O16 of Pseudomonas aeruginosa.

Serotypes O2, O5, and O16 of Pseudomonas aeruginosa are chemically related, and the O antigens of their lipopolysaccharides share a similar trisaccharide repeat backbone structure. Serotype-specific monoclonal antibodies (MAbs) MF71-3, MF15-4, and MF47-4 against the O2, O5, and O16 serotypes, respectively, were isolated. MAb 18-19, which is cross-reactive with all strains of this chemically related serogroup, was also produced. When column chromatography or sodium dodecyl sulfate-polyacrylamide gel electrophoresis-separated lipopolysaccharide (LPS) samples from each of the serotypes were probed with the MAbs in Western immunoblots, each of the serotype-specific MAbs interacted only with high-molecular-weight bands of the homologous LPS, with a minimum O-antigen chain length of at least 6 to 10 repeats. In contrast, cross-reactive MAb 18-19 was shown to interact in Western immunoblots with the entire LPS banding pattern except the fastest-running band, which lacks O antigen. Chemical modification of P. aeruginosa LPS by alkali treatment and carboxyl reduction abolished reactions between LPS and MAb 18-19, while reactions of modified LPS with serotype-specific MAbs were not affected. Therefore, cross-reactive MAb 18-19 likely recognizes the chemical backbone structure of the O repeat that is common to all three serotypes of the O2-O5-O16 group, while the O-specific MAbs appeared to recognize LPS epitopes that could be presented when 6 to 10 or more O-antigen repeat units are present on the LPS molecule. Thus, the O-specific LPS epitopes likely involve unique chemical structures, glycosidic linkages, and some order of folding of the O side chains.     

Detection of Shiga-like toxin on the outer membranes of Shigella species and Escherichia coli K-12

Abstract Outer membranes of Shigella species and E. coli K-12 carrying large invasive plasmids and isogenic non-invasive strains without plasmids were analyzed by SDS-PAGE. The immunoblotting analysis of the outer membrane proteins of these bacteria was performed with monoclonal antibody (mAb) made against A and B subunits of Shiga-like toxin (SLT). The SLT was detected in the outer membranes of S. dysenteriae 1 IDBM11, S. sonnei PNS20, S. flexneri M90T, S. dysenteriae 60R, and E. coli K-12 strain AB2463. The two other E. coli K-12 strains, C600 and 933J were included as controls for low and high toxin producers respectively. The outer membrane protein band of molecular weight 70 kDa was common to all bacterial strains studied. The most prominent band of 70 kDa protein was seen to be present in the high toxin producing plasmidless strain of S. dysenteriae 60R and the lysogenic strain of E. coli 933J. The invasive strains of S. dysenteriae 1 and S. flexneri M90T which carry the large invasive plasmids showed the least prominent band of 70 kDa protein.
The immunoblotting analysis of Shiga-toxin partially purified from the S. dysenteriae 60R strain revealed the absence of 70 kDa band on SDS-PAGE, instead the two dissociated subunits were seen. Furthermore, periplasmic Shiga-toxin proteins also showed the complete dissociation into A and B subunits. However, under the same denaturing conditions, the 70 kDa protein band cross-reacting with mAb against A and B subunits was still present in the outer membranes of all different strains.