Vi-Suppressed wild strain Salmonella typhi cultured in high osmolarity is hyperinvasive toward epithelial cells and destructive of Peyer's patches

Salmonella typhi GIFU10007-3 which lost a viaB locus on its chromosome became highly invasive in our previous study. To investigate the phenomenon, we controlled Vi expression in wild strain S. typhi GIFU10007, and studied the invasive phenotype both in vitro and in vivo. When the wild strain of S. typhi was cultured in 300 mM NaCl containing Luria-Bertani broth (LBH), the expression of Vi antigen was suppressed, but secretion of invasion proteins (SipC, SipB and SipA) was increased. In this condition, wild strain S. typhi became highly invasive toward both epithelial cells and M cells of rat Peyer's patches. When GIFU10007 was cultured under conditions of high osmolarity, the bacteria disrupted Peyer's patches and induced massive bleeding in these structures only 20 min after inoculation into the ileal loop. In contrast, Vi-encapsulated wild strain GIFU10007 cultured under low osmolarity was not destructive, even after 60 min. To understand the role of the type III secretion system under conditions of high osmolarity, we knocked out the invA and sipC genes of both GIFU10007 and GIFU10007-3. Neither invA nor sipC mutants could invade epithelial cells or M cells in a high osmolarity environment. Our data show that the highly invasive phenotype was only expressed when the wild strain S. typhi was cultured under high osmolarity, which induced a state of Vi suppression, and in the presence of the type III secretion system.     

Functional conservation of the Salmonella and Shigella effectors of entry into epithelial cells

A Salmonella typhi chromosomal locus composed of five adjacent genes, designated sipEBCDA , was identified by transposon mutagenesis as being essential for cell invasion. Products of the sip genes exhibit extensive sequence similarities to the effectors of Shigella entry into epithelial cells encoded by the virulence plasmid-borne ipa operon. Expression of sipE and sipB in a Shigella non-invasive ipaB mutant restored the ability to invade epithelial cells. The structural and functional conservation of the Sip and Ipa proteins suggests that Salmonella and Shigella entry processes are promoted by similar effectors.     

SopE, a secreted protein of Salmonelladublin, is translocated into the target eukaryotic cell via a sip-dependent mechanism and promotes bacterial entry

The entry of Salmonella into cultured epithelial cells is dependent on genes located in several adjacent chromosomal loci. One of these loci encodes the recently identified secretory proteins, denoted Sips ( Salmonella invasion proteins). SipB,C,D proteins are essential for the ability of the pathogen to invade epithelial cells. To examine if additional invasion-associated proteins were secreted by Salmonella dublin , the genes encoding already characterized secretory proteins were inactivated to facilitate this analysis. The proteins produced and secreted by a double fliM /polar sipB mutant of S. dublin were analysed; this revealed a set of novel secreted proteins. These proteins, which we denoted Sops ( Salmonella outer proteins), formed large filamentous aggregates in the medium of bacterial culture growing at 37°C. These aggregates contained five predominant proteins. Here we report the identification and characterization of one of these proteins, SopE, which is a novel invasion-associated secretory protein of S. dublin . A specific sopE mutant of S. dublin was found to be defective for invasion into epithelial cells. Upon interaction of Salmonella with HeLa cells, SopE was found to be translocated into the cytoplasm of the target cell by extracellular bacteria. The translocation of SopE was shown to be dependent on the Sip proteins because a polar sipB mutant did not translocate SopE across the HeLa cell membrane.     

Growth Phase-Regulated Induction of Salmonella-Induced Macrophage Apoptosis Correlates with Transient Expression of SPI-1 Genes

Invasive Salmonella has been reported to induce apoptosis in a fraction of infected macrophages within 2 to 14 h from the time of infection by a mechanism involving the type III secretion machinery encoded by the Salmonella pathogenicity island 1 (SPI-1). Here, we show that bacteria in the transition from logarithmic to stationary phase cause 90% of the macrophages to undergo phagocytosis-independent, caspase-mediated apoptosis within 30 to 60 min of infection. The ability of Salmonella to induce this rapid apoptosis was growth phase regulated and cell type restricted, with epithelial cells being resistant. Apoptosis induction was also abrogated by disruption of the hilA gene (encoding a regulator of SPI-1 genes) and by the expression of a constitutively active PhoPQ. hilA itself and a subset of SPI-1 genes were transiently expressed during aerobic growth in liquid medium. Interestingly, however, hilA was found to be required only for the expression of the prgH gene, while sipB, invA, and invF were expressed in a hilA-independent manner. The expression of SPI-1 genes and the secretion of invasion-associated proteins correlated temporally with the induction of apoptosis and are likely to represent its molecular basis. Thus, growth phase transition regulates the expression and secretion of virulence determinants and represents the most efficient environmental cue for apoptosis induction reported to date.     

Heterologous expression of Escherichia coli porin genes in Salmonella typhi Ty2: regulation by medium osmolarity, temperature and oxygen availability

Abstract Electrophoretic analysis of outer membrane proteins showed that Salmonella typhi OmpC expression is not reciprocally regulated relative to OmpF as described for Escherichia coli and S. typhimurium . When bacteria were grown in minimal media, both OmpC and OmpF were repressed as the osmolarity increased. However, in Luria broth, expression of OmpC was slightly induced by osmolarity up to 0.3 osmM. Plasmids bearing E. coli ompC-lacZ or ompF-lacZ gene fusions were studied for their expression in S. typhi and E. coli . Under anaerobic growth conditions, expression of ompC-lacZ in S. typhi was maximal at 0.16 osmM, while in E. coli expression was maximal at 0.7 osmM. ompF-lacZ expression was similarly repressed by medium osmolarity and anaerobiosis in both species. In contrast, a drastic difference in the regulation of OmpF by temperature was observed; at 37 °C ompF-lacZ expression was repressed in E. coli . while in S. typhi it was induced.     

Genetic Basis of Vi Antigen Expression in Salmonella paratyphi C

Analysis of hybrids formed in a cross between a Salmonella paratyphi C Hfr and an S. typhimurium recipient indicated that the structural genetic determinants of the S. paratyphi C Vi antigen are located closely adjacent to the mel determinant, between this marker and purA. A similar location was indicated for the structural genetic determinants of the S. typhi Vi antigen (the viaB locus) by the results of a mating in which a hybrid S. typhimurium Hfr bearing the S. typhi viaB determinants was used to transfer these genes to an S. typhimurium recipient. Mating experiments with a Vi-antigen-expressing S. typhi Hfr and an S. typhimurium hybrid recipient expressing the Vi antigen of S. paratyphi C yielded no recombinants in which loss of Vi antigen expression occurred, indicating that the chromosomal locus occupied by the genetic determinants of the S. paratyphi C Vi antigen is the same one at which, in S. typhi, the viaB genes reside. Introduction of a mutant S. typhi viaA gene into an S. typhimurium hybrid expressing the Vi antigen, as the consequence of prior receipt of the S. paratyphi C viaB determinants, resulted in that hybrid's loss of Vi antigen expression, demonstrating that the viaA determinant plays a role in Vi antigen expression in S. paratyphi C, as well as in S. typhi. Although the percentages of coinheritance of the viaB and mel determinants in the mating experiments suggested that their linkage is sufficiently close to allow cotransduction by P22, attempts to accomplish this with lysates prepared on S. typhimurium hybrids expressing either S. typhi or S. paratyphi C viaB determinants were not successful.     

Protective efficacy and immunogenicity of Vi-porin conjugate against Salmonella typhi.

A conjugate vaccine against Salmonella typhi was prepared by covalently binding capsular polysaccharide (Vi) with porin, both isolated from S. typhi. First, Vi and porins were extracted. The Vi was purified from S. typhi Ty2. The purified Vi conformed to the requirements of the World Health Organization. Porins were purified from S. typhi 0901. The Vi was bound to the porins by a heterobifunctional cross-linking reagent, N-succinimidyl-3-(2-pyridyl dithio)-propionate (SPDP). After preparing the Vi-porin conjugate, its protective ability and immunogenicity were studied in mice following systemic immunization. The results showed that the conjugate is 6.5-fold more protective than Vi alone against S. typhi. The mice immunized with conjugate elicited higher anti-Vi antibody (IgG) levels (P < 0.01) than the mice immunized with Vi alone. Anti-porin antibodies were also induced by the conjugate. To study the mucosal immune responses, secretory IgA (sIgA) in the intestinal fluid was measured. Conjugate-immunized mice showed the induction of sIgA as compared to Vi alone. The results showed that when Vi is bound to porins, both isolated from same organism, the resultant conjugate induced both systemic and mucosal immune responses and provided better protection against S. typhi than Vi alone.     

The Vi antigen of Salmonella typhi: molecular analysis of the viaB locus.

Strains of Salmonella typhi isolated from the blood of patients with typhoid fever invariably express a capsular polysaccharide, termed the Vi antigen. Vi antigen expression is controlled by two separate chromosomal loci, viaA and viaB. The viaA locus is commonly found in enteric bacteria. In contrast, the viaB locus appears to be specific to Vi-expressing strains of Salmonella and Citrobacter. Here the cloning, expression and analysis of viaB determinants from S. typhi Ty2 is described. Whole-cell DNA from strain Ty2 was size-fractionated and cloned into the pLA2917 cosmid vector. A recombinant cosmid, pVT1, conferring a Vi-positive phenotype upon Escherichia coli and upon the Vi-non-expressing strain Ty21a of S. typhi, was characterized and used for further studies. Transposon Tn5 insertion mutagenesis demonstrated that the Vi-antigen-encoding region on pVT1 consisted of a 15 kb fragment. A subclone, designated pVT3, which contained an 18 kb insert, was sufficient to confer Vi antigen expression upon E. coli and S. typhi Ty21a. Results of recombination experiments indicated that this DNA sequence was the viaB locus of S. typhi Ty2. In E. coli SE5000 maxicells, the viaB determinants encoded at least eight polypeptides, with molecular masses of 80, 65, 59, 48, 44, 39, 35 and 28 kDa. Functional characterization of viaB mutations in S. typhi Ty2 suggested that the 80 and 65 kDa proteins were required for cell-surface localization of the Vi antigen.     

Salt-responsive outer membrane proteins of Vibrio anguillarum serotype O1 as revealed by comparative proteome analysis

Aims:  Vibrio anguillarum is a universal marine pathogen causing vibriosis. Vibrio anguillarum encounters different osmolarity conditions between seawater and hosts, and its outer membrane proteins (OMPs) play a crucial role in the adaptation to changes of the surroundings. In the present study, proteomic approaches were applied to investigate the salt-responsive OMPs of V. anguillarum .
Methods and Results:  Lower salinity (0·85% NaCl) is more suitable for growth, survival and swimming motility of the bacterium. Comparative two-dimensional electrophoresis (2-DE) analysis reveals six differentially expressed protein spots among three different salinities, which were successfully identified as OmpU, maltoporin, flagellin B, Omp26La, Omp26La and OmpW respectively.
Conclusions:  OmpW and OmpU were highly expressed at 3·5% salinity, suggesting their role in the efficient efflux of NaCl. Maltoporin was downregulated in higher salinity, indicating that higher osmolarity inhibits carbohydrate transport and bacterial growth. Omp26La, the homologue of OmpV, functions as a salt-responsive protein in lower salinity.
Significance and Impact of the Study:  To the best of our knowledge, this is the first report describing salt stress-responsive proteins of V. anguillarum using proteomic approaches. Our results provide a useful strategy for delineating the osmoregulatory mechanism of the marine pathogens.     

Release of Vi antigens from Salmonella typhi: implications for virulence and diagnosis

The release of Vi antigens from three clinical isolates of Salmonella typhi was measured by a Vi-specific monoclonal antibody. Large quantities of Vi antigens were detected in the culture supernates from all three strains using either passive latex agglutination or rocket immunoelectrophoresis. Vi antigens were also detected in broth cultures of S. typhi containing about 10(5) cells/ml using the sandwich enzyme linked immunosorbent assay. The significance of this finding in relationship to the virulence and the diagnosis of S. typhi was discussed.     

Molecular cloning of the ViaB region of Salmonella typhi

The ViaB region required for Vi antigen production in Salmonella typhi was cloned. The plasmid pGBM124 containing a 14-kb S. typhi chromosomal DNA fragment conferred the ability to produce Vi antigen on Escherichia coli HB101 and ViaB-deleted S. typhi GIFU10007-3. Tn5 insertion analysis showed that the 14-kb DNA was split into three regions. Region 1 and region 2 are involved in the biosynthesis of Vi polysaccharide. Region 3 is involved in translocation of the Vi polysaccharide to the cell surface. Southern blot hybridization showed that regions 2 and 3 but not region 1, were considerably homologous to the DNA of Vi-positive Citrobacter freundii.     

Release of Vi antigens from Salmonella typhi: implications for virulence and diagnosis

Abstract The release of Vi antigens from three clinical isolates of Salmonella typhi was measured by a Vi-specific monoclonal antibody. Large quantities of Vi antigens were detected in the culture supernates from all three strains using either passive latex agglutination or rocket immunoelectrophoresis. Vi antigens were also detected in broth cultures of S. typhi containing about 10⁵ cells/ml using the sandwich enzyme linked immunosorbent assay. The significance of this finding in relationship to the virulence and the diagnosis of S. typhi was discussed.     

Genetic regulation of variable Vi antigen expression in a strain of Citrobacter freundii.

Certain strains of the genus Citrobacter exhibit a variable expression of the Vi surface antigen that appears to involve a special mechanism for regulation of gene expression. Two nonlinked chromosomal loci, viaA and viaB, are known to determine nonvariable Vi antigen expression in strains of Salmonella. To confirm the presence of analogous loci in Citrobacter and to ascertain whether either of them is involved in variable Vi antigen expression in this organism, donor strains were constructed from Citrobacter freundii WR7004 and used to transfer their Vi antigen-determining genes to ViaA- and ViaB- Salmonella typhi recipient strains. Vi antigen expression in C. freundii was found to be controlled by loci analogous to the Salmonella via genes. S. typhi recipients of the C. freundii viaA+ genes were restored to the full, continuous expression of the Vi antigen normally seen in S. typhi. Thus, the C. freundii viaA genes appeared to play no role in the variable expression of the Vi antigen. In contrast, S. typhi recipients of the C. freundii viaB+ genes exhibited the rapid, reversible alternation between full Vi antigen expression and markedly reduced Vi antigen expression that was seen to occur in the C. freundii parent. The C. freundii viaB locus was thus identified as the one whose genes are regulated so as to produce variable Vi antigen expression. Genes determining another C. freundii surface antigen, the synthesis of which is not affected by the mechanism regulating Vi expression, were coinherited with the C. freundii viaB+ genes. An invertible, insertion sequence element located within the C. freundii viaB locus is proposed to account for the regulation of variable Vi antigen expression.