To successfully infect a host and cause the diarrheal disease cholera, Vibrio cholerae must penetrate the intestinal mucosal layer and express virulence genes. Previous studies have demonstrated that the transcriptional regulator HapR, which is part of the quorum sensing network in V. cholerae, represses the expression of virulence genes. Here, we show that hapR expression is also modulated by the regulatory network that governs flagellar assembly. Specifically, FliA, which is the alternative -factor ( 28 ) that activates late-class flagellin genes in V. cholerae, represses hapR expression. In addition, we show that mucin penetration by V. cholerae is sufficient to break flagella and so cause the secretion of FlgM, the anti-factor that inhibits FliA activity. During initial colonization of host intestinal tissue, hapR expression is repressed because of low cell density. However, full repression of hapR expression does not occur in fliA mutants, which results in attenuated colonization. Our results suggest that V. cholerae uses flagellar machinery to sense particular intestinal signals before colonization and enhance the expression of virulence genes by modulating the output of quorum sensing signaling.
Bacterial pathogens have evolved sophisticated signal transduction systems to coordinately control the expression of virulence determinants. For example, the human pathogen Vibrio cholerae is able to respond to host environmental signals by activating transcriptional regulatory cascades. The host signals that stimulate V. cholerae virulence gene expression, however, are still poorly understood. Previous proteomic studies indicated that the ambient oxygen concentration plays a role in V. cholerae virulence gene expression. In this study, we found that under oxygen-limiting conditions, an environment similar to the intestines, V. cholerae virulence genes are highly expressed. We show that anaerobiosis enhances dimerization and activity of AphB, a transcriptional activator that is required for the expression of the key virulence regulator TcpP, which leads to the activation of virulence factor production. We further show that one of the three cysteine residues in AphB, C 235 , is critical for oxygen responsiveness, as the AphB C235S mutant can activate virulence genes under aerobic conditions in vivo and can bind to tcpP promoters in the absence of reducing agents in vitro. Mass spectrometry analysis suggests that under aerobic conditions, AphB is modified at the C 235 residue. This modification is reversible between oxygen-rich aquatic environments and oxygen-limited human hosts, suggesting that V. cholerae may use a thiol-based switch mechanism to sense intestinal signals and activate virulence. thiol-modification | virulence activatorsT he Gram-negative bacterium Vibrio cholerae, the causative agent of the acute, dehydrating diarrheal disease cholera, has figured prominently in the history of infectious diseases as a cause of periodic, deadly pandemics. V. cholerae resides in aquatic environments between epidemics, and human infection normally starts with the ingestion of contaminated food or water. Vibrio cells surviving passage through the acidic gastric environment enter the small intestine, where they must produce an array of virulence factors including cholera toxin (CT) and the toxin co-regulated pilus (TCP) that are transcriptionally regulated by multiple systems (1). The primary, direct transcriptional activator of virulence genes is ToxT, whose transcription is regulated by the ToxRS and TcpPH proteins. Two additional activators encoded by unlinked genes, AphA and AphB, regulate the transcription of tcpPH.The environmental cues within the host and their effect on the expression of virulence genes in V. cholerae in vivo remain poorly characterized. It has been shown that anaerobiosis serves as one of the host environmental factors that modulate virulence factor production (2). This is not surprising because it is generally presumed that the oxygen concentration in the intestine is low (3). A recent report showed that under anaerobic conditions, tcpP expression is higher and this effect depends on AphB (4). However, whether and how this AphB-mediated tcpP expression contributes to anaerobic virulence indu...
The quorum-sensing pathway in Vibrio cholerae controls the expression of the master regulator HapR, which in turn regulates several important processes such as virulence factor production and biofilm formation. While HapR is known to control several important phenotypes, there are only a few target genes known to be transcriptionally regulated by HapR. In this work, we combine bioinformatic analysis with experimental validation to discover a set of novel direct targets of HapR. Our results provide evidence for two distinct binding motifs for HapR-regulated genes in V. cholerae. The first binding motif is similar to the motifs recently discovered for orthologs of HapR in V. harveyi and V. vulnificus. However, our results demonstrate that this binding motif can be of variable length in V. cholerae. The second binding motif shares common elements with the first motif, but is of fixed length and lacks dyad symmetry at the ends. The contributions of different bases to HapR binding for this second motif were demonstrated using systematic mutagenesis experiments. The current analysis presents an approach for systematically expanding our knowledge of the quorum-sensing regulon in V. cholerae and other related bacteria.
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