Structural differences in the outer core region of lipopolysaccharides derived from members of the genus Salmonella

Molecular insights into the assembly and diversity of the outer core oligosaccharide in lipopolysaccharides from Escherichia coli and Salmonella

In the Enterobacteriaceae, the core oligosaccharide provides the junction between the highly conserved lipid A and the remarkably diverse polysaccharide O antigen. The basic structure of the inner (lipid A-proximal) core is well conserved, perhaps reflecting constraints imposed by its involvement in the structural integrity of the outer membrane. However, non-stoichiometric modifications do create some structural variants. The outer core may show more variation. Efforts to develop immunoprophylactic strategies based on the core oligosaccharide require a detailed understanding of core immunochemistry, the accessibility of specific epitopes in the LPS, and the distribution of specific structures within natural populations. The availability of sequences for the waa (core biosynthesis) loci and functional data for the gene products provide a molecular basis for the known structural diversity in Escherichia coli and Salmonella core oligosaccharide. Surveys of waa-locus organization have established the distribution of these core types in natural populations and have identified genetic variants that provide candidates for additional novel structures.

Investigation of the structural requirements in the lipopolysaccharide core acceptor for ligation of O antigens in the genus Salmonella: WaaL "ligase" is not the sole determinant of acceptor specificity

The ligation of O antigen polysaccharide to lipid A-core oligosaccharide is a late step in the formation of the complex glycolipid known as lipopolysaccharide. Although the process has been localized to the periplasmic face of the inner membrane, details of the ligation mechanism have not been resolved. To date, there is only one gene product (WaaL, often referred to as "ligase") known to be required. There exists a requirement for a specific lipid A-core oligosaccharide acceptor structure for ligation activity, and it has been proposed that the WaaL protein imparts this acceptor specificity. Here the structural requirements in the core oligosaccharide acceptor for O antigen ligation are investigated in prototype serovars of Salmonella enterica. Complementation experiments in mutants with defined core oligosaccharide structure indicate that the specificity of the ligation reaction for a particular core oligosaccharide structure is not dependent on the WaaL protein alone. The data provide the first indication of a more complicated recognition process involving additional cellular components.

Molecular diversity of the genetic loci responsible for lipopolysaccharide core oligosaccharide assembly within the genus Salmonella

The waa locus on the chromosome of Salmonella enterica encodes enzymes involved in the assembly of the core oligosaccharide region of the lipopolysaccharide (LPS) molecule. To date, there are two known core structures in Salmonella, represented by serovars Typhimurium (subspecies I) and Arizonae (subspecies IIIA). The waa locus for serovar Typhimurium has been characterized. Here, the corresponding locus from serovar Arizonae is described, and the molecular basis for the distinctive structures is established. Eleven of the 13 open reading frames (ORFs) are shared by the two loci and encode conserved proteins of known function. Two polymorphic regions distinguish the waa loci. One involves the waaK gene, the product of which adds a terminal alpha-1,2-linked N-acetylglucosamine residue that characterizes the serovar Typhimurium core oligosaccharide. There is an extensive internal deletion within waaK of serovar Arizonae. The serovar Arizonae locus contains a novel ORF (waaH) between the waaB and waaP genes. Structural analyses and in vitro glycosyltransferase assays identified WaaH as the UDP-glucose:(glucosyl) LPS alpha-1,2-glucosyltransferase responsible for the addition of the characteristic terminal glucose residue found in serovar Arizonae. Isolates comprising the Salmonella Reference Collections, SARC (representing the eight subspecies of S. enterica) and SARB (representing subspecies I), were examined to assess the distribution of the waa locus polymorphic regions in natural populations. These comparative studies identified additional waa locus polymorphisms, shedding light on the genetic basis for diversity in the LPS core oligosaccharides of Salmonella isolates and identifying potential sources of further novel LPS structures.

Heterogeneity in expression of lipopolysaccharide by strains of Salmonella enterica serotype Typhimurium definitive phage type 104 and related phage types

AIMS

To investigate lipopolysaccharide (LPS) expression in Salmonella enterica serotype Typhimurium definitive phage type 104 (Salmonella Typhimurium DT104) and related phage types.

METHODS AND RESULTS

Isolates were examined for the expression of LPS by SDS-PAGE and silver staining and subtyped by Pulsed Field Gel Electrophoresis (PFGE). The 100 isolates expressed one of two LPS profiles designated A (72%) and B (28%). LPS profiling was able to discriminate between isolates of identical PFGE type. Among 10 groups of outbreak isolates examined, each group was of a single LPS profile: A, 8/10 and B, 2/10. All 10 outbreaks were identical by PFGE analysis.

CONCLUSIONS

Isolates of Salmonella Typhimurium DT104 and related phage types expressed one of two distinct LPS profiles. The two LPS profiles appear similar but shifted and in phase with one another, suggesting that the heterogeneity is due to changes in the LPS core region rather than among the repeating oligosaccharide units of the long-chain LPS. SIGNIFICANCE AND IMPACT OF THE SUTDY: LPS profiling provides a useful adjunct to PFGE and other molecular methods for the subtyping of this group of bacteria in epidemiological investigations.

Monoclonal antibodies specific for Campylobacter fetus lipopolysaccharides

Four monoclonal antibodies (mAbs) (M1357, M1360, M1823 and M1825) which reacted with Campylobacter fetus lipopolysaccharide (LPS) core region epitopes were produced and characterized. Reactivity of these mAbs with C. fetus core LPS epitopes was determined by enzyme-linked immunosorbent assay (ELISA) with whole cell proteinase K digests and phenol-water extracted LPS, and by immunoblotting with proteinase K digests. The specificities of the four mAbs were evaluated using an indirect ELISA. One of the mAbs reacted with 42 and three of the mAbs reacted with 41 of the 42 C. fetus strains examined. No reaction was observed between the four mAbs and 32 non-C. fetus bacteria tested, with the exception of one mAb with one organism. The four mAbs reacted with serotype A and B strains indicating the presence of shared epitopes in C. fetus LPS core oligosaccharides. The specificities of three mAbs previously produced to C. fetus LPS O-antigens (M1177, M1183 and M1194) were also evaluated and no reaction was observed with these mAbs and the 32 non-C. fetus bacteria tested. Strong immunofluorescence reactions were observed with the anti-O chain mAbs and selected C. fetus strains of the homologous serotype. These anti-LPS core oligosaccharide and anti-LPS O chain mAbs are highly specific for C. fetus and are potentially useful as immunodiagnostic reagents for detection, identification and characterization of C. fetus.

Identification of a novel core type in Salmonella lipopolysaccharide. Complete structural analysis of the core region of the lipopolysaccharide from Salmonella enterica sv. Arizonae O62

For the first time, the complete structure of a lipopolysaccharide (LPS) core region from Salmonella enterica has been identified that is different from the Ra core type generally thought to be present in all Salmonella LPS. The LPSs from two rough mutants and the smooth form of S. enterica sv. Arizonae IIIa O62, which all failed to react with an Ra core type-specific monoclonal antibody and were resistant to phage FO1, were analyzed after chemical modification using monosaccharide analysis, mass spectrometry, and NMR spectroscopy. In the novel core type, the terminal D-GlcNAc residue present in the Ra core type, is replaced by a D-Glc residue. The O-specific polysaccharide is alpha1-->4-linked to the second distal Glc residue of the core. Furthermore, phosphoryl substituents attached to O-4 of L-glycero-D-manno-heptose (Hep) I and II were identified as 2-aminoethyl diphosphate (on Hep I) and phosphate (Hep II). [structure: see text] Abbreviations in Structure I are as follows: Hepp, L-glycero-D-manno-heptopyranose; Kdo, 3-deoxy-D-manno-oct-2-ulopyranosonic acid; PPEA, 2-aminoethyl diphosphate; R, O-specific polysaccharide. The presence of this novel core type in LPS of S. enterica should be taken into account in the development of a general antibody-based diagnostic system for Salmonella.

Variation in Salmonella core lipopolysaccharide as detected by the monoclonal antibody M105

The lipopolysaccharide antigenicity of 22 Salmonella strains (representing nine serogroups) and four non-salmonellae Enterobacteriaceae to the Salmonella genus specific monoclonal antibody M105 was analysed. The monoclonal antibody M105 reacted with all 22 Salmonella strains. Probing SDS-PAGE separated LPS molecules with MAb M105 revealed that the antibody reacted with the core region of all Salmonella serovars. However, no reaction was obtained to the long-chain LPS of serovars O (Salm. adelaide and Salm. ealing), C1 (Salm. infantis, Salm. livingstone and Salm. virchow) or Salm. arizonae. It is plausible that the presence of a second core antigenic type results in the lack of reaction between long-chain LPS and the Salmonella genus specific monoclonal antibody M105.

Influence of CD14, LBP and BPI in the monocyte response to LPS of different polysaccharide chain length

In this study we examined the involvement of human serum, recombinant lipopolysaccharide binding protein (rLBP), recombinant (r)CD14, CD14 antibodies and recombinant bactericidal permeability-increasing factor (rBPI) in the induction of TNF by Salmonella minnesota LPS of different polysaccharide chain lengths. Soluble rCD14 and rLBP markedly enhanced LPS 6261 TNF production and to a lesser degree also enhanced TNF production from Re 595 LPS and lipid A DP. Addition of anti-CD14 antibodies resulted in nearly complete inhibition of LPS 6261-induced TNF production and partial inhibition of Re 595 LPS and lipid A DP-induced TNF release. The ability of lipid A MP to induce TNF production increased with addition of rCD14. Addition of rLBP or anti-CD14 antibodies had no detectable effect on lipid A MP-induced TNF production. The effect of rBPI was also tested and the results showed that only the TNF-inducing ability from smooth LPS was completely inhibited by rBPI. Recombinant BPI was considerably less effective in inhibiting Re 595 LPS-induced TNF production, and lipid A DP was not affected by rBPI. Our data suggest that the ability of rLBP, rCD14, CD14 antibodies and rBPI to modulate LPS induced TNF production is strongly dependent on the LPS polysaccharide chain length.

The sialic acid-containing lipopolysaccharides of Salmonella djakarta and Salmonella isaszeg (serogroup O: 48): chemical characterization and reactivity with a sialic acid-binding lectin from Cepaea hortensis

Lipopolysaccharides (LPS) of Salmonella djakarta and Salmonella isaszeg, as well as of a spontaneous R-mutant of S. djakarta were investigated as to their content in neuraminic acid (Neu) and its individual linkage. The two Salmonella serovars both belong to the O:48 serogroup of Salmonella, but to two different subgroups. LPS of both S-forms contained high amounts of Neu, although in different quantities, whereas the R-form was completely devoid of it. Methylation analysis indicated that Neu is exclusively terminally linked in S. djakarta whereas both terminal and 4-linked Neu were recognized in S. isaszeg. Although terminally linked, a sialidase from Arthrobacter ureafaciens was unable to split Neu even after prolonged incubation from both S-type LPSs. When LPS was first treated by mild alkali, however, the total amount of Neu from S. djakarta LPS and about 50% from that of LPS of S.isaszeg could be removed. In contrast, alkali-treated LPS, but also the non-treated one, proved to be effective inhibitors for a sialic acid-binding lectin from Cepaea hortensis. The resistance of terminal Neu towards sialidase may be due to the presence of an O-acetyl group which would be removed during the methylation analysis but would, especially when linked to C-4, not interfere with the reactivity of the lectin.

The influence of low growth temperature on the amount of free R lipopolysaccharide, on the expression of R-core determinants and on O-chain lengths in Salmonella S forms

Ten Salmonella strains belonging to five serological groups were cultivated both at 37 degrees C and close to their individual temperature minima at 12-14 degrees C and the composition of their cell wall lipopolysaccharides (LPS) was compared. When grown at low temperature, the proportion of unsubstituted (free) R-LPS in the total LPS moiety increased significantly in 6 strains, whereas in the other strains, no change or even a slight decrease in the R-LPS proportion was observed as judged from the analyses by SDS-PAGE. In the immunoblot, the R-LPSs from 9 out of 10 strains showed a modified reactivity against a set of specific Salmonella R antisera (anti-Ra, anti-Rb1, anti-Rb2, anti-Rc). In most cases, the decrease in Rb1 reactivity was paralleled by an increase in Rb2 reactivity and also by an increase in the total amount of free R-LPS. The electrophoretic mobility of free R-LPS was changed in 7 out of 10 strains, although the changes were not unidirectional. All changes occurred only in the range of the Ra-Rb1 chemotypes and no significant correlation to the serological grouping of the strains was evident. When grown at low temperature, the average number of O-repeating units was reduced in the majority of cases and in some cases, also the banding profile in SDS-PAGE in the S-LPS region was modified. The fatty acid spectra showed some changes which were in accordance with previous results, namely a decrease in the content of C-12:0 and C-16:0 and an increase in that of C-14:0 and C-16:1. The different influences of the growth temperature on the LPS biosynthesis of different Salmonella strains may be a result of the genetic diversity of this group of microorganisms.