During infection of their hosts, salmonellae enter intestinal epithelial cells. It has been proposed that when Salmonella typhimurium is present in the intestinal lumen, several environmental and regulatory conditions modulate the expression of invasion factors required for bacterial entry into host cells. We report here that the expression of six different S. typhimurium invasion genes encoded on SPI1 (Salmonella pathogenicity island 1) is co-ordinately regulated by oxygen, osmolarity, pH, PhoPQ, and HilA. HilA is a transcriptional activator of the OmpR/ToxR family that is also encoded on SPI1. We have found that HilA plays a central role in the co-ordinated regulation of invasion genes by environmental and regulatory conditions. HilA can activate the expression of two invasion gene-lacZY fusions on reporter plasmids in Escherichia coll, suggesting that HilA acts directly at invasion-gene promoters in S. typhimurium. We have found that the regulation of invasion genes by oxygen, osmolarity, pH, and PhoPQ is indirect and is mediated by regulation of hilA expression by these environmental and regulatory factors. We hypothesize that the complex and co-ordinate regulation of Invasion genes by HilA is an important feature of salmonella pathogenesis and allows salmonellae to enter intestinal epithelial cells.
Horizontal gene transfer contributes to the evolution of bacterial species. Mobile genetic elements play an important role in horizontal gene transfer, and characterization of the regulation of these elements should provide insight into conditions that influence bacterial evolution. We characterized a mobile genetic element, ICEBs1, in the Gram-positive bacterium Bacillus subtilis and found that it is a functional integrative and conjugative element (ICE) capable of transferring to Bacillus and Listeria species. We identified two conditions that promote ICEBs1 transfer: conditions that induce the global DNA damage response and crowding by potential recipients that lack ICEBs1. Transfer of ICEBs1 into cells that already contain the element is inhibited by an intercellular signaling peptide encoded by ICEBs1. The dual regulation of ICEBs1 allows for passive propagation in the host cell until either the potential mating partners lacking ICEBs1 are present or the host cell is in distress.conjugation ͉ horizontal gene transfer ͉ quorum sensing ͉ peptide signaling ͉ DNA microarrays
We have examined the effect of different growth conditions on the ability of Salmonella to interact with Madin-Darby canine kidney cells. Two growth conditions that affect the expression of Salmonella adherence and invasiveness have been identified. First, bacteria lose their invasiveness in the stationary phase of growth. Second, bacteria growing in oxygen-limited growth conditions are induced for adherence and invasiveness, whereas those growing aerobically are relatively nonadherent and noninvasive. Salmonella from cultures aerated with gas mixtures containing 0% or 1% oxygen were 6-to 70-fold more adherent and invasive than those from cultures aerated with a gas mixture containing 20% oxygen.The Salmonella typhimurium oxrA gene that is required for the anaerobic induction of many proteins is n1 involved in the regulation of Salmonella invasiveness. We speculate that oxygen limitation might be an environmental cue that triggers the expression of Salmonella invasiveness within the intestinal lumen and other tissues.
During infection of its hosts, Salmonella enters intestinal epithelial cells. Many Salmonella typhimurium genes required for bacterial entry into host cells are encoded on a 40 kb 'pathogenicity island'. We report here the identification of hilA, a gene within the 'island' that appears to encode an activator of invasion gene expression. By using a set of lacZY transcriptional fusions to S. typhimurium invasion genes, we found that hilA activates the expression of invasion genes located on the 'pathogenicity island'. hilA is required for efficient entry into HEp-2 cells in vitro. The predicted amino acid sequence of hilA shares significant homology with the DNA-binding domains of the OmpR-ToxR family of transcriptional activators. However, unlike OmpR and ToxR, HilA contains neither a phosphoryl acceptor nor a membrane-spanning domain, and, therefore, its activity may be modulated by a novel mechanism. Many environmental conditions modulate the ability of Salmonella to enter non-phagocytic mammalian cells. It has been proposed that induction of Salmonella invasion proteins in response to a combination of environmental cues ensures that bacterial entry is limited to specific sites and times during infection. Our results are consistent with the hypothesis that hilA plays a key role in the regulation of Salmonella invasion during infection.
Salmonella typhimurium penetrate intestinal epithelial cells during infection. In vitro studies reveal that the availability of oxygen during bacterial growth decreases their capacity to adhere to and enter cultured epithelial cells. To identify S. typhimurium genes involved in epithelial cell entry, mutants were selected that entered HEp-2 cells when grown under repressing, aerobic culture conditions. Two types of transposons were used to generate bacterial mutationstransposons that disrupt genes (TnlO and TnS) and one transposon (Tn5B50) that, in addition to disrupting genes, can cause constitutive expression of genes from the neo promoter at one end of the transposon. Three classes of mutations were found that increased the ability of aerobically grown S. typhimurium to enter HEp-2 cells. One class of mutations disrupts the che operons and results in a nonchemotactic phenotype. The second class of mutations revealed that defects in rho, which encodes an essential transcription termination factor, result in hyperinvasiveness. The third class of mutations was obtained only from mutagenesis with Tn5B50, suggesting that their increased invasiveness is due to constitutive expression of a gene(s) from the exogenous neo promoter. Analysis of this third class of mutations identified a S. typhimurium locus hil (hyperinvasion locus), which is essential for bacterial entry into epithelial cells. The results suggest that hil encodes an invasion factor or an activator of invasion factor expression. hil maps between srl and mutS near minute 59.5 of the S. typhimurium chromosome, a region adjacent to other loci that have been identified as required for S. typhimurium invasiveness and virulence.
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