Role of ToxS in the proteolytic cascade of virulence regulator ToxR in Vibrio cholerae

Two of the primary virulence regulators of Vibrio cholerae, ToxR and TcpP, function together with cognate effector proteins. ToxR undergoes regulated intramembrane proteolysis (RIP) during late stationary phase in response to nutrient limitation at alkaline pH; however, the specific function of its cognate ToxS remains unresolved. In this work, we found that ToxR rapidly becomes undetectable in a ΔtoxS mutant when cultures are exposed to either starvation conditions or after alkaline pH shock individually. A ΔtoxS mutant enters into a dormant state associated with the proteolysis of ToxR at a faster rate than wild‐type, closely resembling a ΔtoxR mutant. Using a mutant with a periplasmic substitution in ToxS, we found that the proteases DegS and DegP function additively with VesC and a novel protease, TapA, to degrade ToxR in the mutant. Overall, the results shown here reveal a role for ToxS in the stabilization of ToxR by protecting the virulence regulator from premature proteolysis.     

DNA binding and ToxR responsiveness by the wing domain of TcpP,an activator of virulence gene expression in Vibrio cholerae

Virulence in Vibrio cholerae requires activation of toxT by two membrane-localized activators, TcpP and ToxR. We isolated 12 tcpP activation mutants that fell into two classes: class I mutants were inactive irrespective of the presence of ToxR, and class II mutants exhibited near wild-type activity when coexpressed with ToxR. Most class I mutants had lesions in the wing domain predicted by homology with the winged helix-turn-helix family of activators. Class I mutants bound promoter DNA poorly and were largely unable to interact with ToxR in a crosslinking assay, whereas class II mutants retained physical interaction with ToxR. One mutant constructed in vitro bound DNA poorly but nevertheless responded to ToxR by activating toxT and also maintained ToxR interaction. We propose that ToxR interaction, but not DNA binding, is essential for TcpP function and that the wing domain of TcpP enables contact with ToxR required for productive TcpP-RNA polymerase association.     

The ToxR protein of Vibrio cholerae forms homodimers and heterodimers.

The ToxR protein of Vibrio cholerae regulates the expression of several virulence factors that play important roles in the pathogenesis of cholera. Previous experiments with ToxR-alkaline phosphatase (ToxR-PhoA) fusion proteins suggested a model for gene regulation in which the inactive form of ToxR was a monomer and the active form of ToxR was a dimer (V. L. Miller, R. K. Taylor, and J. J. Mekalanos, Cell 48:271-279, 1987). In order to examine whether ToxR exists in a dimeric form in vivo, biochemical cross-linking analyses were carried out. Different dimeric cross-linked species were detected depending on the expression level of ToxR: when overexpressed, ToxR+ToxR homodimers and ToxR+ToxS heterodimers were detected, and when ToxR was expressed at normal levels, exclusively ToxR+ToxS heterodimers were detected. The amount of overexpression was quantitated by using ToxR-PhoA fusion proteins and was found to correspond to 2.7-fold the normal level of ToxR. The formation of both homodimeric ToxR species and heterodimeric ToxR+ToxS species is consistent with previously reported genetic data that suggested that both types of ToxR oligomeric interactions occur. However, variation in the amount of either the homodimeric or heterodimeric form detectable by this cross-linking analysis was not observed to correlate with laboratory culture conditions known to modulate ToxR activity. Thus, genetic and biochemical data indicate that ToxR is able to interact with both itself and ToxS but that these interactions may not explain mechanistically the observed changes in ToxR activity that occur in response to environmental conditions.     

Genetic mapping of the regulatory gene determining the synthesis of enterotoxin in Vibrio cholerae

The data of genetic mapping of the cholera toxin regulatory gene by conjugation mating of Vibrio cholerae eltor donor strain with V. cholerae classica recipients are presented. The close genetic linkage of tox locus to pur-63 is shown. The gene order asp - cys - nal - pur-61 - trp - his - pur-63 - tox - ile of the chromosomal region examined is established.     

Cloning of the Vibrio cholerae recA gene and construction of a Vibrio cholerae recA mutant

A recombinant plasmid carrying the recA gene of Vibrio cholerae was isolated from a V. cholerae genomic library, using complementation in Escherichia coli. The plasmid complements a recA mutation in E. coli for both resistance to the DNA-damaging agent methyl methanesulfonate and recombinational activity in bacteriophage P1 transductions. After determining the approximate location of the recA gene on the cloned DNA fragment, we constructed a defined recA mutation by filling in an XbaI site located within the gene. The 4-base pair insertion resulted in a truncated RecA protein as determined by minicell analysis. The mutation was spontaneously recombined onto the chromosome of a derivative of V. cholerae strain P27459 by screening for methyl methanesulfonate-sensitive variants. Southern blot analysis confirmed the presence of the inactivated XbaI site in the chromosome of DNA isolated from one of these methyl methanesulfonate-sensitive colonies. The recA V. cholerae strain was considerably more sensitive to UV light than its parent, was impaired in homologous recombination, and was deficient in induction of a temperate vibriophage upon exposure to UV light. We conclude that the V. cholerae RecA protein has activities which are analogous to those described for the RecA protein of E. coli.     

Characterization of the small untranslated RNA RyhB and its regulon in Vibrio cholerae

Numerous small untranslated RNAs (sRNAs) have been identified in Escherichia coli in recent years, and their roles are gradually being defined. However, few of these sRNAs appear to be conserved in Vibrio cholerae, and both identification and characterization of sRNAs in V. cholerae remain at a preliminary stage. We have characterized one of the few sRNAs conserved between E. coli and V. cholerae: RyhB. Sequence conservation is limited to the central region of the gene, and RyhB in V. cholerae is significantly larger than in E. coli. As in E. coli, V. cholerae RyhB is regulated by the iron-dependent repressor Fur, and it interacts with the RNA-binding protein Hfq. The regulons controlled by RyhB in V. cholerae and E. coli appear to differ, although some overlap is evident. Analysis of gene expression in V. cholerae in the absence of RyhB suggests that the role of this sRNA is not limited to control of iron utilization. Quantitation of RyhB expression in the suckling mouse intestine suggests that iron availability is not limiting in this environment, and RyhB is not required for colonization of this mammalian host by V. cholerae.