Víctor H. Bustamante

Transcriptional regulation of type III secretion genes in enteropathogenic Escherichia coli: Ler antagonizes H-NS-dependent repression.

Secretion of effector proteins in enteropathogenic Escherichia coli (EPEC) is mediated by a specialized type III secretion system whose components are encoded in the LEE1, LEE2 and LEE3 operons. Using cat transcriptional fusions and primer extension analysis, we determined that the LEE2 and LEE3 operons are expressed from two overlapping divergent promoters, whose expression is negatively regulated by flanking common upstream and downstream silencing regulatory sequences (SRS1 and SRS2). In the absence of either SRS1 or SRS2, expression of the LEE2 and LEE3 operons became independent of Ler, a positive regulatory protein encoded by the first gene of the LEE1 operon. Similarly, in the absence of the histone‐like protein H‐NS, expression from both promoters became Ler independent even if both SRSs were present. In addition, the efficient expression of both the LEE2 and the LEE3 promoters required PerC (BfpW), a protein coded by the third gene of the per (bfpTVW) locus, but only in the presence of the EAF plasmid. Our deletion analysis also showed that the negative regulation observed in the presence of ammonium or at temperatures above 37°C (e.g. 40°C) required the SRSs or elements located therein. In contrast, the negative regulation observed in LB or at temperatures below 37°C (e.g. 25°C) was still observed even in the absence of both SRSs and seems to act only on the promoters. Together, these results suggest that Ler acts as an antirepressor protein that overcomes the H‐NS‐mediated silencing on the LEE2/LEE3 divergent promoter region, which is probably caused by the formation of a repressing H‐NS–nucleoprotein complex.

CLONING AND CHARACTERIZATION OF BFPTVW, GENES REQUIRED FOR THE TRANSCRIPTIONAL ACTIVATION OF BFPA IN ENTEROPATHOGENIC ESCHERICHIA COLI

Expression of the bundle‐forming pilus (BFP) of enteropathogenic Escherichia coli (EPEC) is regulated at the transcriptional level by growth phase, temperature, calcium and ammonium. Genes required for the transcriptional activation of bfpA were localized to a 1.8 kb fragment of the enteroadherent factor (EAF) plasmid of EPEC that is separated from the bfp operon by 6 kb. Within this fragment three identically oriented and closely spaced open reading frames (ORFs) were identified and designated bfpT, bfpV and bfpW. bfpT is predicted to encode a 31.8 kDa protein that shares homology with the AraC family of transcriptional regulators, including the presence of a conserved C‐terminal DNA‐binding helix‐turn‐helix motif. Insertional inactivation of bfpT led to the loss of bfpA transcription, BfpA protein production and the localized adherence (LA) phenotype; this mutant phenotype could be complemented by introduction of bfpTVW and, on separate plasmids, bfpT + bfpW. However, introduction of bfpT + bfpV, bfpV alone, bfpW alone, or bfpV + bfpW did not enable recovery of the wild‐type phenotype. Maximal efficiency of bfpA transcription required all three genes, but bfpV and bfpW each enhanced transcription providing bfpT was also present. A series of deletions of the bfpA upstream promoter region was prepared; with respect to the bfpA transcription start site, sequence between nucleotides −94 and −55 was found to bind bfpT. BfpT also bound a DNA fragment containing the eaeA promoter region on the EPEC chromosome. From these results we conclude that bfpTVW causes transcriptional activation of bfpA, and possibly eaeA, by a trans‐acting mechanism that may co‐ordinately regulate the expression of EPEC virulence determinants.

A Positive Regulatory Loop Controls Expression of the Locus of Enterocyte Effacement-Encoded Regulators Ler and GrlA

The formation of attaching and effacing (A/E) lesions on intestinal epithelial cells is an essential step in the pathogenesis of human enteropathogenic and enterohemorrhagic Escherichia coli and of the mouse pathogen Citrobacter rodentium. The genes required for the development of the A/E phenotype are located within a pathogenicity island known as the locus of enterocyte effacement (LEE). The LEE-encoded transcriptional regulators Ler, an H-NS-like protein, and GrlA, a member of a novel family of transcriptional activators, positively control the expression of the genes located in the LEE and their corresponding virulence. In this study, we used C. rodentium as a model to study the mechanisms controlling the expression of Ler and GrlA. By deletion analysis of the ler and grlRA regulatory regions and complementation experiments, negative and positive cis-acting regulatory motifs were identified that are essential for the regulation of both genes. This analysis confirmed that GrlA is required for the activation of ler, but it also showed that Ler is required for the expression of grlRA, revealing a novel regulatory loop controlling the optimal expression of virulence genes in A/E pathogens. Furthermore, our results indicate that Ler and GrlA induce the expression of each other by, at least in part, counteracting the repression mediated by H-NS. However, whereas GrlA is still required for the optimal expression of ler even in the absence of H-NS, Ler is not needed for the expression of grlRA in the absence of H-NS. This type of transcriptional positive regulatory loop represents a novel mechanism in pathogenic bacteria that is likely required to maintain an appropriate spatiotemporal transcriptional response during infection.

Transcriptional Regulation of the orf19 Gene and the tir-cesT-eae Operon of Enteropathogenic Escherichia coli

To establish an intimate interaction with the host epithelial cell surface, enteropathogenic Escherichia coli (EPEC) produces Tir, a bacterial protein that upon translocation and insertion into the epithelial cell membrane constitutes the receptor for intimin. The tir gene is encoded by the locus for enterocyte effacement (LEE), where it is flanked upstream by orf19 and downstream by the cesT and eae genes. With the use of a series of cat transcriptional fusions and primer extension analysis, we confirmed that tir, cesT, and eae form the LEE5 operon, which is under the control of a promoter located upstream from tir, and found that the orf19 gene is transcribed as a monocistronic unit. We also demonstrated that the LEE-encoded regulator Ler was required for efficient activation of both the tir and the orf19 promoters and that a sequence motif located between positions -204 and -157 was needed for the Ler-dependent activation of the tir operon. Sequence elements located between positions -204 and -97 were determined to be required for the differential negative modulatory effects exerted by unknown regulatory factors under specific growth conditions. Upon deletion of the upstream sequences, the tir promoter was fully active even in the absence of Ler, indicating that tir expression is subject to a repression mechanism that is counteracted by this regulatory protein. However, its full activation was still repressed by growth in rich medium or at 25 degrees C, suggesting that negative regulation also occurs at or downstream of the promoter. Expression of orf19, but not of the tir operon, became Ler independent in an hns mutant strain, suggesting that Ler overcomes the repression exerted by H-NS (histone-like nucleoid structuring protein) on this gene.

HilD-mediated transcriptional cross-talk between SPI-1 and SPI-2

The acquisition of new genetic traits by horizontal gene transfer and their incorporation into preexisting regulatory networks have been essential events in the evolution of bacterial pathogens. An example of successful assimilation of virulence traits is Salmonella enterica, which acquired, at distinct evolutionary times, Salmonella pathogenicity island 1 (SPI-1), required for efficient invasion of the intestinal epithelium and intestinal disease, and SPI-2, essential for Salmonella replication and survival within macrophages and the progression of a systemic infection. A positive regulatory cascade mainly composed of HilD, HilA, and InvF, encoded in SPI-1, controls the expression of SPI-1 genes, whereas the two-component regulatory system SsrA/B, encoded in SPI-2, controls expression of SPI-2 genes. In this study, we report a previously undescribed transcriptional cross-talk between SPI-1 and SPI-2, where the SPI-1–encoded regulator HilD is essential for the activation of both the SPI-1 and SPI-2 regulons but at different times during the stationary phase of growth in Luria-Bertani medium. Our data indicate that HilD counteracts the H-NS–mediated repression exerted on the OmpR-dependent activation of the ssrAB operon by specifically interacting with its regulatory region. In contrast, HilD is not required for SPI-2 regulon expression under the in vitro growth conditions that are thought to resemble the intracellular environment. Our results suggest that two independent SPI-2 activation pathways evolved to take advantage of the SPI-2–encoded information at different niches and, in consequence, in response to different growth conditions.

Integration of a complex regulatory cascade involving the SirA/BarA and Csr global regulatory systems that controls expression of the Salmonella SPI‐1 and SPI‐2 virulence regulons through HilD

Salmonella pathogenicity islands 1 and 2 (SPI‐1 and SPI‐2) play key roles in the pathogenesis of Salmonella enterica. Previously, we showed that when Salmonella grows in Luria–Bertani medium, HilD, encoded in SPI‐1, first induces the expression of hilA, located in SPI‐1, and subsequently of the ssrAB operon, located in SPI‐2. These genes code for HilA and the SsrA/B two‐component system, the positive regulators of the SPI‐1 and SPI‐2 regulons respectively. In this study, we demonstrate that CsrA, a global regulatory RNA binding protein, post‐transcriptionally regulates hilD expression by directly binding near the Shine–Dalgarno and translation initiation codon sequences of the hilD mRNA, preventing its translation and leading to its accelerated turnover. Negative regulation is counteracted by the global SirA/BarA two‐component system, which directly activates the expression of CsrB and CsrC, two non‐coding regulatory RNAs that sequester CsrA, thereby preventing it from binding to its target mRNAs. Our results illustrate the integration of global and specific regulators into a multifactorial regulatory cascade controlling the expression of virulence genes acquired by horizontal transfer events.

Analysis of the Frz signal transduction system of Myxococcus xanthus shows the importance of the conserved C-terminal region of the cytoplasmic chemoreceptor FrzCD in sensing signals

The Frz chemosensory system controls directed motility in Myxococcus xanthus by regulating cellular reversal frequency. M. xanthus requires the Frz system for vegetative swarming on rich media and for cellular aggregation during fruiting body formation on starvation media. The Frz signal transduction pathway is formed by proteins that share homology with chemotaxis proteins from enteric bacteria, which are encoded in the frzA‐F putative operon and the divergently transcribed frzZ gene. FrzCD, the Frz system chemoreceptor, contains a conserved C‐terminal module present in methyl‐accepting chemotaxis proteins (MCPs); but, in contrast to most MCPs, FrzCD is localized in the cytoplasm and the N‐terminal region of FrzCD does not contain transmembrane or sensing domains, or even a linker region. Previous work on the Frz system was limited by the unavailability of deletion strains. To understand better how the Frz system functions, we generated a series of in‐frame deletions in each of the frz genes as well as regions encoding the N‐terminal portion of FrzCD. Analysis of mutants containing these deletions showed that FrzCD (MCP), FrzA (CheW) and FrzE (CheA–CheY) control vegetative swarming, responses to repellents and directed movement during development, thus constituting the core components of the Frz pathway. FrzB (CheW), FrzF (CheR), FrzG (CheB) and FrzZ (CheY–CheY) are required for some but not all responses. Furthermore, deletion of ≈ 25 amino acids from either end of the conserved C‐terminal region of FrzCD results in a constitutive signalling state of FrzCD, which induces hyper‐reversals with no net cell movement. Surprisingly, deletion of the N‐terminal region of FrzCD shows only minor defects in swarming. Thus, signal input to the Frz system must be sensed by the conserved C‐terminal module of FrzCD and not the usual N‐terminal region. These results indicate an alternative mechanism for signal sensing with this cytoplasmic MCP.

LeuO antagonizes H-NS and StpA-dependent repression in Salmonella enterica ompS1

The ompS1 gene encodes a quiescent porin in Salmonella enterica. We analysed the effects of H‐NS and StpA, a paralogue of H‐NS, on ompS1 expression. In an hns single mutant expression was derepressed but did not reach the maximum level. Expression in an stpA single mutant showed the same low repressed level as the wild type. In contrast, in an hns stpA background, OmpS1 became abundant in the outer membrane. The expression of ompS1 was positively regulated by LeuO, a LysR‐type quiescent regulator that has been involved in pathogenesis. Upon induction of the cloned leuO gene into the wild type, ompS1 was completely derepressed and the OmpS1 porin was detected in the outer membrane. LeuO activated the P1 promoter in an OmpR‐dependent manner and P2 in the absence of OmpR. LeuO bound upstream of the regulatory region of ompS1 overlapping with one nucleation site of H‐NS and StpA. Our results are thus consistent with a model where H‐NS binds at a nucleation site and LeuO displaces H‐NS and StpA.

PerC and GrlA independently regulate Ler expression in enteropathogenic Escherichia coli

Ler, encoded by the locus of enterocyte effacement (LEE) of attaching and effacing (A/E) pathogens, induces the expression of LEE genes by counteracting the silencing exerted by H‐NS. Ler expression is modulated by several global regulators, and is activated by GrlA, which is also LEE‐encoded. Typical enteropathogenic Escherichia coli (EPEC) strains contain the EAF plasmid, which carries the perABC locus encoding PerC. The precise role of PerC in EPEC virulence gene regulation has remained unclear, mainly because EPEC strains lacking the pEAF still express the LEE genes and because PerC is not present in other A/E pathogens such as Citrobacter rodentium. Here, we describe that either PerC or GrlA can independently activate ler expression and, in consequence, of LEE genes depending on the growth conditions. Both PerC and GrlA, with the aid of IHF, counteract the repression exerted by H‐NS on ler and can also further increase its activity. Our results substantiate the role of PerC and GrlA in EPEC virulence gene regulation and suggest that these convergent regulatory mechanisms may have represented an evolutionary adaptation in EPEC to co‐ordinate the expression of plasmid‐ and chromosome‐encoded virulence factors needed to successfully colonize its intestinal niche.

Thermosensing coordinates a cis-regulatory module for transcriptional activation of the intracellular virulence system in Salmonella enterica serovar Typhimurium.

The expression of bacterial virulence genes is tightly controlled by the convergence of multiple extracellular signals. As a zoonotic pathogen, virulence gene regulation in Salmonella enterica serovar Typhimurium must be responsive to multiple cues from the general environment as well as from multiple niches within animal and human hosts. Previous work has identified combined magnesium and phosphate limitation as an environmental cue that activates genes required for intracellular virulence. One unanswered question is how virulence genes that are expressed within the host are inhibited in non-host environments that satisfy the phosphate and magnesium limitation cues. We report here that thermosensing is the major mechanism controlling incongruous activation of the intracellular virulence phenotype. Bacteria grown at 30 °C or lower were unable to activate the intracellular type III secretion system even under strong inducing signals such as synthetic medium, contact with macrophages, and exposure to the murine gut. Thermoregulation was fully recapitulated in a Salmonella bongori strain engineered to contain the intracellular virulence genes of S. enterica sv. Typhimurium, suggesting that orthologous thermoregulators were available. Accordingly, virulence gene repression at the nonpermissive temperature required Hha and H-NS, two nucleoid-like proteins involved in virulence gene control. The use of combined environmental cues to control transcriptional “logic gates” allows for transcriptional selectivity of virulence genes that would otherwise be superfluous if activated in the non-host environment. Thus, thermosensing by Salmonella provides integrated control of host niche-specific virulence factors.