Reversible acyl-homoserine lactone binding to purified Vibrio fischeri LuxR protein.

The Vibrio fischeri LuxR protein is the founding member of a family of acyl-homoserine lactone-responsive quorum-sensing transcription factors. Previous genetic evidence indicates that in the presence of its quorum-sensing signal, N-(3-oxohexanoyl) homoserine lactone (3OC6-HSL), LuxR binds to lux box DNA within the promoter region of the luxI gene and activates transcription of the luxICDABEG luminescence operon. We have purified LuxR from recombinant Escherichia coli. Purified LuxR binds specifically and with high affinity to DNA containing a lux box. This binding requires addition of 3OC6-HSL to the assay reactions, presumably forming a LuxR-3OC6-HSL complex. When bound to the lux box at the luxI promoter in vitro, LuxR-3OC6-HSL enables E. coli RNA polymerase to initiate transcription from the luxI promoter. Unlike the well-characterized LuxR homolog TraR in complex with its signal (3-oxo-octanoyl-HSL), the LuxR-30C6-HSL complex can be reversibly inactivated by dilution, suggesting that 3OC6-HSL in the complex is not tightly bound and is in equilibrium with the bulk solvent. Thus, although LuxR and TraR both bind 3-oxoacyl-HSLs, the binding is qualitatively different. The differences have implications for the ways in which these proteins respond to decreases in signal concentrations or rapid drops in population density.

The HilA box and sequences outside it determine the magnitude of HilA-dependent activation of P(prgH) from Salmonella pathogenicity island 1.

Salmonella requires genes on the Salmonella pathogenicity island 1 (SPI1) for the intestinal phase of infection in several models of pathogenesis. In Salmonella enterica serovar Typhimurium, most SPI1 genes are arranged in operons that are coordinately regulated by the SPI1-encoded protein HilA. In the past, it has been shown that HilA directly activates two promoters on SPI1, P(invF-1) and P(prgH). P(invF-1) contains a HilA binding site, termed a HilA box, that is necessary and sufficient for activation by HilA. The HilA box is 17 nucleotides long and contains a direct repeat comprised of two hexamers separated by 5 nucleotides, centered at -45 relative to the start site of transcription. P(prgH) also contains a HilA box, and here we investigate its role at P(prgH). We have found that the HilA box is necessary, but not sufficient, for HilA-dependent activation of P(prgH). Instead, half-site-like hexamers outside the HilA box appear to be required for HilA-dependent activation of P(prgH), even though HilA binds to the HilA box in the absence of these hexamers. Thus, although HilA-dependent activation of P(invF-1) and P(prgH) coordinates the expression of the structural genes for a type III secretion apparatus and the effectors secreted by that apparatus, it is also possible that mechanisms not apparent under in vitro inducing conditions could separate the expression of invFGEABC-spaMNOPQRS-sicA-sipBCDA-iacP-sicP-sptP and prgHIJK-orgABC.

The Salmonella pathogenicity island-1 type III secretion system.

Salmonella pathogenicity island 1 (SPI1) encodes a type III secretion system that is required for virulence during the intestinal phase of infection. The expression of SPI1 genes is controlled by many global regulatory pathways that affect the expression/activity of transcriptional regulators encoded on SPI1.

The cis requirements for transcriptional activation by HilA, a virulence determinant encoded on SPI-1.

In several models of pathogenesis, Salmonella requires genes encoded on Salmonella pathogenicity island 1 (SPI-1) for virulence. In Salmonella enterica serovar Typhimurium (S. typhimurium), most SPI-1 genes are arranged in operons and are co-ordinately regulated in response to environmental signals via the SPI-1-encoded protein HilA. In order to understand how HilA controls the transcription of SPI-1 genes, we have analysed the invF and prgH promoters. We have reconstituted HilA-dependent activation of both promoters in Escherichia coli by supplying hilA on a plasmid, strongly suggesting that HilA acts directly on the promoters. By analysing the HilA-dependent activity of deletions and mutations in PinvF, we identified cis elements necessary for HilA-dependent activation. Through biochemical studies, we have defined a probable HilA-binding sequence in the invF promoter. This 'HilA box' is intact in the minimal promoter identified through deletion analysis, and it is disrupted in one class of PinvF mutants that has reduced activation by HilA. The prgH promoter also contains a HilA box in the same position relative to the +1 of transcription. This work is the first to connect HilA-dependent environmental regulation with a specific sequence in a SPI-1 virulence gene promoter.

Multiple factors independently regulate hilA and invasion gene expression in Salmonella enterica serovar typhimurium.

HilA activates the expression of Salmonella enterica serovar Typhimurium invasion genes. To learn more about regulation of hilA, we isolated Tn5 mutants exhibiting reduced hilA and/or invasion gene expression. In addition to expected mutations, we identified Tn5 insertions in pstS, fadD, flhD, flhC, and fliA. Analysis of the pstS mutant indicates that hilA and invasion genes are repressed by the response regulator PhoB in the absence of the Pst high-affinity inorganic phosphate uptake system. This system is required for negative control of the PhoR-PhoB two-component regulatory system, suggesting that hilA expression may be repressed by PhoR-PhoB under low extracellular inorganic phosphate conditions. FadD is required for uptake and degradation of long-chain fatty acids, and our analysis of the fadD mutant indicates that hilA is regulated by a FadD-dependent, FadR-independent mechanism. Thus, fatty acid derivatives may act as intracellular signals to regulate hilA expression. flhDC and fliA encode transcription factors required for flagellum production, motility, and chemotaxis. Complementation studies with flhC and fliA mutants indicate that FliZ, which is encoded in an operon with fliA, activates expression of hilA, linking regulation of hilA with motility. Finally, epistasis tests showed that PhoB, FadD, FliZ, SirA, and EnvZ act independently to regulate hilA expression and invasion. In summary, our screen has identified several distinct pathways that can modulate S. enterica serovar Typhimurium's ability to express hilA and invade host cells. Integration of signals from these different pathways may help restrict invasion gene expression during infection.