Salmonella typhimurium secreted invasion determinants are homologous to Shigella lpa proteins

Salmonella typhimurium secreted proteins (Ssp) were previously implicated in epithelial cell invasion. Here we describe four genes ( sspB , sspC , sspD , and sspA ), located between spaT and prgH , which encode proteins of 63, 42, 36, and 87 kDa, respectively. These Ssp are homologous to Shigella flexneri secreted proteins lpaB, lpaC, lpaD and lpaA. A non-invasive mutant with a transposon insertion in sspC lacks Ssp of 87,42 and 36 kDa. Complementation analyses show that sspC and sspD encode the 42 and the 36 kDa Ssp, while the 87 kDa Ssp is encoded by sspA . sspC and sspD , but not sspA are required for invasion. Amino-terminal sequencing shows that SspC and SspA are secreted without amino-terminal processing. We further demonstrate that Ssp secretion requires proteins encoded by prgHIJK , homologous to the Shigella lpa secretion system, since SspA is abundantly secreted by wild-type bacteria but is completely retained within the cellular fraction of a prgHIJK mutant. A precipitate containing abundant SspC and three other major Ssp of 63,59 and 22 kDa was isolated from culture supernatants of wild-type bacteria. These data indicate that major secreted invasion determinants of S. typhimurium are structurally and functionally homolgous to S. flexneri lpa proteins.     

A PhoP/PhoQ-induced Lipase (PagL) that catalyzes 3-O-deacylation of lipid A precursors in membranes of Salmonella typhimurium

Pathogenic bacteria modify the structure of the lipid A portion of their lipopolysaccharide in response to environmental changes. Some lipid A modifications are important for virulence and resistance to cationic antimicrobial peptides. The two-component system PhoP/PhoQ plays a central role in regulating lipid A modification. We now report the discovery of a PhoP/PhoQ-activated gene (pagL) in Salmonella typhimurium, encoding a deacylase that removes the R-3-hydroxymyristate moiety attached at position 3 of certain lipid A precursors. The deacylase gene (pagL) was identified by assaying for loss of deacylase activity in extracts of 14 random TnphoA::pag insertion mutants. The pagL gene encodes a protein of 185 amino acid residues unique to S. typhimurium and closely related organisms such as Salmonella typhi. Heterologous expression of pagL in Escherichia coli on plasmid pWLP21 results in loss of the R-3-hydroxymyristate moiety at position 3 in approximately 90% of the lipid A molecules but does not inhibit cell growth. PagL is synthesized with a 20-amino acid N-terminal signal peptide and is localized mainly in the outer membrane, as judged by assays of separated S. typhimurium membranes and by SDS-polyacrylamide gel analysis of membranes from E. coli cells that overexpress PagL. The function of PagL is unknown, given that S. typhimurium mutants lacking pagL display no obvious phenotypes, but PagL might nevertheless play a role in pathogenesis if it serves to modulate the cytokine response of an infected animal host.     

Characterization of the Salmonella typhimurium pagC/pagD chromosomal region.

The PhoP/PhoQ two-component system regulates Salmonella typhimurium genes that are essential to bacterial virulence and survival within macrophages. The best characterized of these PhoP-activated genes (pag) is pagC, which encodes a 188-amino-acid envelope protein (W. S. Pulkkinen and S. I. Miller, J. Bacteriol. 173:86-93, 1991). We here report the identification of four genes (pagD, envE, msgA, and envF) located 5' to pagC. Each gene is transcribed from its own promoter, two of which (msgA and pagD) were defined by primer extension analysis. Three of these genes (pagD, envE, and envF) are predicted to encode envelope proteins. The pagD gene is transcribed in a direction opposite from that of and adjacent to pagC and is positively regulated by PhoP/PhoQ. Transposon insertions within pagD and msgA attenuate bacterial virulence and survival within macrophages; however, deletion of pagD has no effect on virulence. The product of the envF gene is predicted to be a lipoprotein on the basis of the presence of a consensus lipid attachment site. The low G + C content of these genes and the homology of msgA to Shigella plasmid DNA suggest that this region may have been acquired by horizontal transmission.     

Molecular analysis of the Escherichia coli phoP-phoQ operon.

The phoP-phoQ operon of Salmonella typhimurium is a member of the family of two-component regulatory systems and controls expression of the phoN gene that codes for nonspecific acid phosphatase and the genes involved in the pathogenicity of the bacterium. The phoP-phoQ operon of Escherichia coli was cloned on a plasmid vector by complementation of a phoP mutant, and the 4.1-kb nucleotide sequence, which includes the phoP-phoQ operon and its flanking regions, was determined. The phoP-phoQ operon was mapped at 25 min on the standard E. coli linkage map by hybridization with the Kohara mini set library of the E. coli chromosome (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). The predicted phoP and phoQ gene products consist of 223 and 486 amino acids with estimated molecular masses of 25,534 and 55,297 Da, respectively, which correspond well with the sizes of the PhoP and PhoQ proteins identified by the maxicell method. The amino acid sequences of PhoP and PhoQ of E. coli were 93 and 86% identical, respectively, to those of S. typhimurium.     

Second monomer binding is the rate-limiting step in the formation of the dimeric PhoP-DNA complex

PhoP, the response regulator of the PhoP/PhoQ system, regulates Mg(2+) homeostasis in Salmonella typhimurium. Dimerization of PhoP on the DNA is necessary for its regulatory function, and PhoP regulates the expression of genes in a phosphorylation-dependent manner. Higher PhoP concentrations, however, can activate PhoP and substitute for phosphorylation-dependent gene regulation. Activation of PhoP by phosphorylation is explained by self-assembly of phosphorylated PhoP (PhoP-p) in solution and binding of the PhoP-p dimer to the promoter. To understand the mechanism of PhoP dimerization on the DNA, we examined the interactions of PhoP with double-stranded DNAs containing the canonical PhoP box (PB). We present results from multiple biophysical methods, demonstrating that PhoP is a monomer in solution over a range of concentrations and binds to PB in a stepwise manner with a second PhoP molecule binding weakly. The affinity for the binding of the first PhoP molecule to PB is more than ～17-fold higher than the affinity of the second PhoP monomer for PB. Kinetic analyses of PhoP binding reveal that the on rate of the second PhoP monomer binding is the rate-limiting step during the formation of the (PhoP)(2)-DNA complex. Results show that a moderate increase in PhoP concentration can promote dimerization of PhoP on the DNA, which otherwise could be achieved by PhoP-p at much lower protein concentrations. Detailed analyses of PhoP-DNA interactions have revealed the existence of a kinetic barrier that is the key for specificity in the formation of the productive (PhoP)(2)-DNA complex.