Long polar fimbriae 1 (Lpf1) of Escherichia coli O157:H7 is a tightly regulated adhesin, with H-NS silencing the transcriptional expression of the lpf1 operon while Ler (locus of enterocyte effacement-encoded regulator) acts as an antisilencer. We mapped the minimal regulatory region of lpf1 required for H-NS-and Ler-mediated regulation and found that it is 79% AT rich. Three putative sites for H-NS binding were identified. Two of them, named silencer regulatory sequence 1 (SRS1) and SRS2, are located on a region that covers both of the lpf1 promoters (P1 and P2). The third putative H-NS binding site is located within the lpfA1 gene in a region extending from ؉258 bp to ؉545 bp downstream of ATG; however, this site does not seem to play a role in lpfA1 regulation under the conditions tested in this work. Ler was also found to interact with Ler binding sites (LBSs). Ler binding site 1 (LBS1) and LBS2 are located upstream of the two promoters. LBS1 overlaps SRS1, while LBS3 overlaps the P1 promoter and SRS2. Based on the experimental data, we propose that H-NS silences lpf1 expression by binding to both of the SRSs on the promoter region, forming an SRS-H-NS complex that prevents RNA polymerase-mediated transcription. A model of the regulation of the lpfA1 operon of E. coli O157:H7 by H-NS and Ler is discussed.
LeuO is a LysR-type transcriptional regulator (LTTR) that has been described to be a global regulator in Escherichia coli and Salmonella enterica, since it positively and negatively regulates the expression of genes involved in multiple biological processes. LeuO Together, these data demonstrate that not only the C terminus but also the DBD of LeuO is involved in oligomer formation; therefore, each LeuO domain appears to act synergistically to maintain its regulatory functions in Salmonella enterica serovar Typhi.
The molecular mechanisms controlling expression of the Long Polar Fimbriae 2 (Lpf2) of enterohemorrhagic E. coli (EHEC) O157:H7 were evaluated. Primer extension was used to locate the lpfA2 transcriptional start site in EHEC strain EDL933 at 171 bp upstream of the lpfA2 start codon. Semi-quantitative RT-PCR demonstrated that the highest lpfA2 expression occurs between an OD600 of 1.0 and 1.2 in DMEM at pH 6.5 and 37°C. The level of lpfA2 transcription at OD600 1.2 and pH 6.5 was 4-times greater than that at pH 7.2. Although lpfA2 expression was decreased under iron-depleted conditions, its expression was increased in a Ferric-uptake-regulator (Fur) mutant strain. The lpfA2 transcript was 0.7 and 2-times more abundant in wt EHEC grown in DMEM pH 6.5 plus iron and MacConkey broth at 25°C, respectively, than in DMEM at pH 6.5. The lpf2 expression in DMEM pH 6.5 plus iron and bile salts was 2.7-times more abundant and similar to MacConkey. Further, transcription in the EDL933Δfur was 0.6 and 0.8-times higher as compared to the wt strain grown in DMEM pH 6.5 plus iron and MacConkey broth, respectively. Electrophoretic mobility shift assays (EMSA) showed that purified Fur interacts with the lpf2 regulatory region, indicating that Fur-repression is exerted by direct binding to the promoter region. In summary, we demonstrated that the EHEC lpf2 operon is regulated in response to temperature, pH, bile salts and iron, during exponential phase of growth, and controlled by Fur.
Enteropathogenic E. coli virulence genes are under the control of various regulators, one of which is PerA, an AraC/XylS-like regulator. PerA directly promotes its own expression and that of the bfp operon encoding the genes involved in the biogenesis of the bundle-forming pilus (BFP); it also activates PerC expression, which in turn stimulates locus of enterocyte effacement (LEE) activation through the LEE-encoded regulator Ler. Monomeric PerA directly binds to the per and bfp regulatory regions; however, it is not known whether interactions between PerA and the RNA polymerase (RNAP) are needed to activate gene transcription as has been observed for other AraC-like regulators. Results showed that PerA interacts with the alpha subunit of the RNAP polymerase and that it is necessary for the genetic and phenotypic expression of bfpA. Furthermore, an in silico analysis shows that PerA might be interacting with specific alpha subunit amino acids residues highlighting the direction of future experiments.
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