Interplay among cyclic diguanylate, HapR, and the general stress response regulator (RpoS) in the regulation of Vibrio cholerae hemagglutinin/protease

Vibrio cholerae secretes the Zn-dependent metalloprotease hemagglutinin (HA)/protease (mucinase), which is encoded by hapA and displays a broad range of potential pathogenic activities. Expression of HA/protease has a stringent requirement for the quorum-sensing regulator HapR and the general stress response regulator RpoS. Here we report that the second messenger cyclic diguanylic acid (c-di-GMP) regulates the production of HA/protease in a negative manner. Overexpression of a diguanylate cyclase to increase the cellular c-di-GMP pool resulted in diminished expression of HA/protease and its positive regulator, HapR. The effect of c-di-GMP on HapR was independent of LuxO but was abolished by deletion of the c-di-GMP binding protein VpsT, the LuxR-type regulator VqmA, or a single-base mutation in the hapR promoter that prevents autorepression. Though expression of HapR had a positive effect on RpoS biosynthesis, direct manipulation of the c-di-GMP pool at a high cell density did not significantly impact RpoS expression in the wild-type genetic background. In contrast, increasing the c-di-GMP pool severely inhibited RpoS expression in a ΔhapR mutant that is locked in a regulatory state mimicking low cell density. Based on the above findings, we propose a model for the interplay between HapR, RpoS, and c-di-GMP in the regulation of HA/protease expression.     

Regulation of virulence gene expression in Vibrio cholerae by quorum sensing: HapR functions at the aphA promoter

Quorum sensing negatively influences virulence gene expression in certain toxigenic Vibrio cholerae strains. At high cell densities, the response regulator LuxO fails to reduce the expression of HapR, which, in turn, represses the expression of the virulence cascade. A critical regulatory step in the cascade is activation of tcpPH expression by AphA and AphB. We show here that HapR influences the virulence cascade by directly repressing aphA expression. In strain C6706, aphA expression was increased in a delta hapR mutant and decreased in a delta luxO mutant, indicating a negative and positive influence, respectively, of these gene products on the promoter. Overexpression of HapR also reduced aphA expression in both C6706 and Escherichia coli. DNase I footprinting showed that purified HapR binds to the aphA promoter between -85 and -58. Although it appears that quorum sensing does not influence virulence gene expression in strain O395 solely because of a frameshift in hapR, overproduced HapR did not repress expression from the O395 aphA promoter in either Vibrio or E. coli, nor did the protein bind to the promoter. Two basepair differences from C6706 are present in the O395 HapR binding site at -85 and -77. Introducing the -77 change into C6706 prevented HapR binding and repression of aphA expression. This mutation also eliminated the repression of toxin-co-regulated pilus (TCP) and cholera toxin (CT) that occurs in a delta luxO mutant, indicating that HapR function at aphA is critical for density-dependent regulation of virulence genes.     

In situ grazing resistance of Vibrio cholerae in the marine environment

Previous laboratory experiments revealed that Vibrio cholerae A1552 biofilms secrete an antiprotozoal factor that prevents Rhynchomonas nasuta from growing and thus prevents grazing losses. The antiprotozoal factor is regulated by the quorum-sensing response regulator, HapR. Here, we investigate whether the antiprotozoal activity is ecologically relevant. Experiments were conducted in the field as well as under field-like conditions in the laboratory to assess the grazing resistance of V. cholerae A1552 and N16961 (natural frameshift mutation in hapR) biofilms to R. nasuta and Cafeteria roenbergensis. In laboratory experiments exposing the predators to V. cholerae grown in seawater containing high and low glucose concentrations, we determined that V. cholerae biofilms showed increased resistance towards grazing by both predators as glucose levels decreased. The relative resistance of the V. cholerae strains to the grazers under semi-field conditions was similar to that observed in situ. Therefore, the antipredator defense is environmentally relevant and not lost when biofilms are grown in an open system in the marine environment. The hapR mutant still exhibited some resistance to both predators and this suggests that V. cholerae may coordinate antipredator defenses by a combination of density-dependent regulation and environmental sensing to protect itself from predators in its natural habitat.     

Differential response of Vibrio cholerae planktonic and biofilm cells to autoinducer 2 deficiency

The formation of biofilm communities enhances the persistence of Vibrio cholerae in aquatic environments. Biofilm production is repressed by the quorum-sensing regulator HapR in response to the accumulation of CAI-1 and AI-2. CAI-1 is the strongest input signal activating HapR, whereas the role of AI-2 remains ill-defined. In the present study, we show that a V. cholerae luxS (AI-2-defective) mutant made increased biofilm. Interestingly, cells in the biofilm were more responsive to AI-2 deficiency than cells from the planktonic population.     

The PhoB regulatory system modulates biofilm formation and stress response in El Tor biotype Vibrio cholerae

The PhoBR regulatory system is required for the induction of multiple genes under conditions of phosphate limitation. Here, we examine the role of PhoB in biofilm formation and environmental stress response in Vibrio cholerae of the El Tor biotype. Deletion of phoB or hapR enhanced biofilm formation in a phosphate-limited medium. Planktonic and redispersed biofilm cells of the Δ phoB mutant did not differ from wild type for the expression of HapR, suggesting that PhoB negatively affects biofilm formation through an HapR-independent pathway. The Δ phoB mutant exhibited elevated expression of exopolysaccharide genes vpsA and vpsL compared with the wild type. Deletion of hapR enhanced the expression of the positive regulator vpsT , but had no effect on the expression of vpsR . In contrast, deletion of phoB enhanced the expression of the positive regulator vpsR , but had no effect on the expression of hapR and vpsT . The Δ phoB mutant was more sensitive to hydrogen peroxide compared with the wild type and with an isogenic Δ rpoS mutant. Conversely, the Δ phoB mutant was more resistant to acidic conditions and high osmolarity compared with the wild type and with an isogenic Δ rpoS mutant. Taken together, our data suggest that phosphate limitation induces V. cholerae to adopt a free-swimming life style in which PhoB modulates environmental stress response in a manner that differs from the general stress response regulator RpoS.