Hervé Waxin

The RcsB-RcsC regulatory system of Salmonella typhi differentially modulates the expression of invasion proteins, flagellin and Vi antigen in response to osmolarity.

Entry into intestinal epithelial cells is an essential feature in the pathogenicity of Salmonella typhi, which causes typhoid fever in humans. This process requires intact motility and secretion of the invasion‐promoting Sip proteins, which are targets of the type III secretion machinery encoded by the inv, spa and prg loci. During our investigations into the entry of S. typhi into cultured epithelial cells, we observed that the secretion of Sip proteins and flagellin was impaired in Vi‐expressing strains. We report here that the production of Sip proteins, flagellin and Vi antigen is differentially modulated by the RcsB–RcsC regulatory system and osmolarity. This regulation occurs at both transcriptional and post‐translational levels. Under low‐osmolarity conditions, the transcription of iagA, invF and sipB genes is negatively controlled by the RcsB regulator, which probably acts in association with the viaB locus‐encoded TviA protein. The cell surface‐associated Vi polysaccharide, which was maximally produced under these growth conditions, prevented the secretion of Sip proteins and flagellin. As the NaCl concentration in the growth medium was increased, transcription of iagA, invF and sipB was found to be markedly increased, whereas transcription of genes involved in Vi antigen biosynthesis was greatly reduced. The expression of iagA, whose product is involved in invF and sipB transcription, occurred selectively during the exponential growth phase and was maximal in the presence of 300 mM NaCl. At this osmolarity, large amounts of Sips and flagellin were secreted in culture supernatants. As expected from these results, and given the essential role of Sip proteins and motility in entry, RcsB and osmolarity modulated the invasive capacity of S. typhi. Together, these findings might reflect the adaptive response of S. typhi to the environments encountered during the different stages of pathogenesis.

Role of the viaB locus in synthesis, transport and expression of Salmonella typhi Vi antigen.

The Vi antigen is a capsular polysaccharide expressed by Salmonella typhi, the agent of human typhoid fever. Expression of this antigen is controlled by the viaA and viaB chromosomal loci. The viaB locus is composed of 11 genes designated tviA-tviE (typhi Vi), vexA-vexE (Vi antigen export) and ORF11. We constructed S. typhi Ty2 strains carrying non-polar mutations in ten genes located at the viaB locus and examined the individual contribution of each gene to Vi phenotype. Phenotypes of the mutants and complementation experiments suggested that synthesis of Vi antigen monomer was catalysed by the TviB and TviC polypeptides. Subsequent polymerization of the polysaccharide might be catalysed by the TviE protein, but required functional TviD product. Proteins encoded by vexA, vexB and vexC directed transport of the polymer to the bacterial cell surface. Anchoring of the Vi antigen at the bacterial cell surface was dependent of the VexE protein. The TviA protein was not essential for Vi polymer synthesis. However, disruption of the tviA gene on S. typhi Ty2 chromosome strongly decreased expression of Vi antigen. This defect was fully complemented by providing tviA in trans on a recombinant plasmid. By using lacZ transcriptional fusions, it was shown that the TviA product positively regulated co-transcription of the tviA and tviB genes from a promoter located upstream of tviA. Moreover, we showed that a tviAB-lacZ fusion was not expressed in a viaA (rcsB) mutant of S. typhi.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Molecular characterization of the Salmonella typhi StpA protein that is related to both Yersinia YopE cytotoxin and YopH tyrosine phosphatase.

Analysis of the nucleotide sequence of a 4-kb DNA fragment located between the sip and iag loci on Salmonella typhi chromosome revealed three open reading frames, termed sipF, ctpA and stpA. The 82-amino-acid (aa) sipF product showed extensive similarity to the lacP protein from S. typhimurium. The StpA protein (535 aa) exhibited significant similarity to both Yersinia enterocolitica YopE cytotoxin and YopH tyrosine phosphatase. The CtpA polypeptide (130 aa) might be the molecular chaperone of the StpA protein.

Lsd1 and Lsd2 Control Programmed Replication Fork Pauses and Imprinting in Fission Yeast

In the fission yeast Schizosaccharomyces pombe, a chromosomal imprinting event controls the asymmetric pattern of mating-type switching. The orientation of DNA replication at the mating-type locus is instrumental in this process. However, the factors leading to imprinting are not fully identified and the mechanism is poorly understood. Here, we show that the replication fork pause at the mat1 locus (MPS1), essential for imprint formation, depends on the lysine-specific demethylase Lsd1. We demonstrate that either Lsd1 or Lsd2 amine oxidase activity is required for these processes, working upstream of the imprinting factors Swi1 and Swi3 (homologs of mammalian Timeless and Tipin, respectively). We also show that the Lsd1/2 complex controls the replication fork terminators, within the rDNA repeats. These findings reveal a role for the Lsd1/2 demethylases in controlling polar replication fork progression, imprint formation, and subsequent asymmetric cell divisions.

Molecular signature of the imprintosome complex at the mating-type locus in fission yeast

Genetic and molecular studies have indicated that an epigenetic imprint at mat1, the sexual locus of fission yeast, initiates mating type switching. The polar DNA replication of mat1 generates an imprint on the Watson strand. The process by which the imprint is formed and maintained through the cell cycle remains unclear. To understand better the mechanism of imprint formation and stability, we characterized the recruitment of early players of mating type switching at the mat1 region. We found that the switch activating protein 1 (Sap1) is preferentially recruited inside the mat1M allele on a sequence (SS13) that enhances the imprint. The lysine specific demethylases, Lsd1/2, that control the replication fork pause at MPS1 and the formation of the imprint are specifically drafted inside of mat1, regardless of the allele. The CENP-B homolog, Abp1, is highly enriched next to mat1 but it is not required in the process. Additionally, we established the computational signature of the imprint. Using this signature, we show that both sides of the imprinted molecule are bound by Lsd1/2 and Sap1, suggesting a nucleoprotein protective structure defined as imprintosome.