The suckling mouse model of cholera.

Vibrio cholerae colonization of the suckling mouse intestine is a commonly used animal model for the human diarrheal disease cholera. This model has a number of advantages as well as disadvantages, and has been extremely useful in the identification and characterization of proven and putative virulence factors involved in human cholera.

Glutamate at the site of phosphorylation of nitrogen-regulatory protein NTRC mimics aspartyl-phosphate and activates the protein.

The NTRC protein of enteric bacteria is an enhancer-binding protein that activates transcription by the sigma 54-holoenzyme form of RNA polymerase under nitrogen-limiting conditions. In vitro NTRC must be phosphorylated to catalyze ATP hydrolysis and activate transcription. The site of phosphorylation of NTRC from Salmonella typhimurium is Aspartate 54, which lies in the amino-terminal regulatory domain of the protein. We used site-directed mutagenesis to make "conservative" substitutions at residue 54 to alanine, asparagine, and glutamate, and examined the properties of the mutant NTRC proteins in vitro and in vivo. In vitro none of them was detectably phosphorylated, as expected if D54 is, in fact, the sole site of phosphorylation. D54A and D54N did not activate transcription of glnA but, interestingly, D54E activated constitutively. Activation by D54E was partial compared to that by phosphorylated wild-type NTRC. Combining D54A or D54N with S160F, a change in the central domain of NTRC that partially bypasses the requirement for phosphorylation, yielded doubly mutant proteins that were as active as a form carrying S160F alone, indicating that the changes in D54 did not adversely affect the function of the remainder of NTRC. Combining D54E with S160F increased the levels of constitutive ATPase activity and transcriptional activation above those of mutant NTRC proteins carrying either single change alone. We conclude that phosphorylation of aspartate 54 is required to activate NTRC and postulate that the D54E mutation mimics phosphorylation, thereby allowing NTRC to hydrolyze ATP and activate transcription. Phenotypes of mutant strains encoding NTRC proteins with substitutions at D54 indicated that phosphorylation of NTRC at position 54 was necessary for normal growth in the absence of glutamine and that such phosphorylation occurred to some extent even in the absence of NTRB.

The major dimerization determinants of the nitrogen regulatory protein NTRC from enteric bacteria lie in its carboxy-terminal domain.

The NTRC protein (nitrogen regulatory protein C) of enteric bacteria is an enhancer-binding protein that activates transcription by the sigma54-holoenzyme form of RNA polymerase. NTRC is a homodimeric protein that binds to a dyad-symmetrical site in DNA. To activate transcription NTRC must be phosphorylated and must form an appropriate oligomeric species at an enhancer. In order to study subunit exchange between NTRC dimers, we constructed a fusion of the maltose-binding protein (MBP) to the amino-terminal end of NTRC (MBP-NTRC) and visualized the formation of heterodimers between MBP-NTRC and wild-type NTRC by a gel-mobility shift assay for DNA-binding. When MBP-NTRC is mixed with wild-type NTRC at 37 degrees C, subunit exchange occurs rapidly. The apparent half-life for dissociation of homodimers of NTRC is two to three minutes at 37 degrees C and is not changed by phosphorylation. The isolated carboxy-terminal domain of NTRC (91 amino acid residues) forms heterodimers with both wild-type NTRC and MBP-NTRC, indicating that the C-terminal domain is sufficient for dimerization. The apparent rate of dissociation of homodimers of the C-terminal domain is essentially the same as that of full-length NTRC, indicating that the major dimerization determinants of the protein lie in its C-terminal domain. Congruent with this, a truncated form of NTRC from which the last 58 amino acid residues were removed is a monomer in solution. Moreover, truncated forms of NTRC from which the last 16 or 26 amino acid residues were removed are predominantly monomeric in solution, as is a mutant form with the amino acid substitution A410E in its C-terminal domain. Monomerization of the above mutant forms of NTRC can be rationalized on the basis of homology between the C-terminal region of NTRC and a 50 amino acid residue region of the factor for inversion stimulation (FIS) protein.

Mast cell/IL-4 control of Francisella tularensis replication and host cell death is associated with increased ATP production and phagosomal acidification.

Mast cells are now recognized as effective modulators of innate immunity. We recently reported that mast cells and secreted interleukin-4 (IL-4) effectively control intramacrophage replication of Francisella tularensis Live Vaccine Strain (LVS), and that mice deficient in mast cells or IL-4 receptor (IL-4R(-/-)) exhibit greater susceptibility to pulmonary challenge. In this study, we further evaluated the mechanism(s) by which mast cells/IL-4 control intramacrophage bacterial replication and host cell death, and found that IL-4R(-/-) mice exhibited significantly greater induction of active caspase-3 within lung macrophages than wild-type animals following intranasal challenge with either LVS or the human virulent type A strain SCHU S4. Treatment of LVS-infected bone-marrow-derived macrophages with a pancaspase inhibitor (zVAD) did not alter bacterial replication, but minimized active caspase-3 and other markers (Annexin V and propidium iodide) of cell death, whereas treatment with both rIL-4 and zVAD resulted in concomitant reduction of both parameters, suggesting that inhibition of bacterial replication by IL-4 was independent of caspase activation. Interestingly, IL-4-treated infected macrophages exhibited significantly increased ATP production and phagolysosomal acidification, as well as enhanced mannose receptor upregulation and increased internalization with acidification, which correlated with observations in mast cell-macrophage co-cultures, with resultant decreases in F. tularensis replication.

Regulation of virulence in Vibrio cholerae.

Vibrio cholerae causes the diarrheal disease cholera primarily because it expresses a colonization factor (toxin-coregulated pilus; TCP) and a potent toxin (cholera toxin; CT) within the human intestine. While the true environmental signals that induce CT and TCP expression within the intestine remain unknown, much progress has been made identifying the regulatory factors that modulate their expression. Transcriptional regulation of the genes encoding TCP and CT involves a cascade consisting of a number of regulatory factors located on recently acquired mobile genetic elements as well as others residing within the ancestral Vibrio genome. In vivo studies have revealed interesting differences between the regulation of TCP and CT expression in the laboratory and within the intestine.

Altered expression of the ToxR-regulated porins OmpU and OmpT diminishes Vibrio cholerae bile resistance, virulence factor expression, and intestinal colonization.

The transmembrane transcriptional activators ToxR and TcpP modulate expression of Vibrio cholerae virulence factors by exerting control over toxT, which encodes the cytoplasmic transcriptional activator of the ctx, tcp, and acf virulence genes. However, ToxR, independently of TcpP and ToxT, activates and represses transcription of the genes encoding two outer-membrane porins, OmpU and OmpT. To determine the role of ToxR-dependent porin regulation in V. cholerae pathogenesis, the ToxR-activated ompU promoter was used to drive ompT transcription in a strain lacking OmpU. Likewise, the ToxR-repressed ompT promoter was used to drive ompU transcription in a strain lacking both ToxR and OmpT. This strategy allowed the generation of a toxR(+) strain that expresses OmpT in place of OmpU, and a toxR(-) strain that expresses OmpU in place of OmpT. Growth rates in the presence of bile salts and other anionic detergents were retarded for the toxR(+) V. cholerae expressing OmpT in place of OmpU, but increased in toxR(-) V. cholerae expressing OmpU in place of OmpT. Additionally, the toxR(+) V. cholerae expressing OmpT in place of OmpU expressed less cholera toxin and toxin-coregulated pilus, and this effect was shown to be caused by reduced toxT transcription in this strain. Finally, the toxR(+) V. cholerae expressing OmpT in place of OmpU was approximately 100-fold reduced in its ability to colonize the infant-mouse intestine. Our results indicate that ToxR-dependent modulation of the outer membrane porins OmpU and OmpT is critical for V. cholerae bile resistance, virulence factor expression, and intestinal colonization.

Simultaneous prevention of glutamine synthesis and high-affinity transport attenuates Salmonella typhimurium virulence.

In Salmonella typhimurium, transcription of the glnA gene (encoding glutamine synthetase) is under the control of the nitrogen-regulatory (ntr) system comprising the alternate sigma factor sigma54 (NtrA) and the two-component sensor-transcriptional activator pair NtrB and NtrC. The glnA, ntrB, and ntrC genes form an operon. We measured the virulence of S. typhimurium strains with nitrogen-regulatory mutations after intraperitoneal (i.p.) or oral inoculations of BALB/c mice. Strains with single mutations in glnA, ntrA, ntrB, or ntrC had i.p. 50% lethal doses (LD50s) of <10 bacteria, similar to the wild-type strain. However, a strain with a delta(glnA-ntrC) operon deletion had an i.p. LD50 of >10(5) bacteria, as did delta glnA ntrA and delta glnA ntrC strains, suggesting that glnA strains require an ntr-transcribed gene for full virulence. High-level transcription of the glutamine transport operon (glnHPQ) is dependent upon both ntrA and ntrC, as determined by glnHp-lacZ fusion measurements. Moreover, delta glnA glnH and delta glnA glnQ strains are attenuated, similar to delta glnA ntrA and delta glnA ntrC strains. These results reveal that access of S. typhimurium to host glutamine depends on the ntr system, which apparently is required for the transcription of the glutamine transport genes. The delta(glnA-ntrC) strain exhibited a reduced ability to survive within the macrophage cell line J774, identifying a potential host environment with low levels of glutamine. Finally, the delta(glnA-ntrC) strain, when inoculated at doses as low as 10 organisms, provided mice with protective immunity against challenge by the wild-type strain, demonstrating its potential use as a live vaccine.

A region of the transmembrane regulatory protein ToxR that tethers the transcriptional activation domain to the cytoplasmic membrane displays wide divergence among Vibrio species.

The virulence regulatory protein ToxR of Vibrio cholerae is unique in that it contains a cytoplasmic DNA-binding-transcriptional activation domain, a transmembrane domain, and a periplasmic domain. Although ToxR and other transmembrane transcriptional activators have been discovered in other bacteria, little is known about their mechanism of activation. Utilizing degenerate oligonucleotides and PCR, we have amplified internal toxR gene sequences from seven Vibrio and Photobacterium species and subspecies, demonstrating that toxR is an ancestral gene of the family Vibrionaceae. Sequence alignment of all available ToxR amino acid sequences revealed a region between the transcriptional activation and transmembrane domains that displays wide divergence among Vibrio species. We hypothesize that this region merely tethers the transcriptional activation domain to the cytoplasmic membrane and thus can tolerate wide divergence and multiple insertions and deletions. The divergence in the tether region at the nucleotide level may provide a useful tool for the distinction of Vibrio and Photobacterium species.

Environmental signals modulate ToxT-dependent virulence factor expression in Vibrio cholerae.

The regulatory protein ToxT directly activates the transcription of virulence factors in Vibrio cholerae, including cholera toxin (CT) and the toxin-coregulated pilus (TCP). Specific environmental signals stimulate virulence factor expression by inducing the transcription of toxT. We demonstrate that transcriptional activation by the ToxT protein is also modulated by environmental signals. ToxT expressed from an inducible promoter activated high-level expression of CT and TCP in V. cholerae at 30 degrees C, but expression of CT and TCP was significantly decreased or abolished by the addition of 0.4% bile to the medium and/or an increase of the temperature to 37 degrees C. Also, expression of six ToxT-dependent TnphoA fusions was modulated by temperature and bile. Measurement of ToxT-dependent transcription of genes encoding CT and TCP by ctxAp- and tcpAp-luciferase fusions confirmed that negative regulation by 37 degrees C or bile occurs at the transcriptional level in V. cholerae. Interestingly, ToxT-dependent transcription of these same promoters in Salmonella typhimurium was relatively insensitive to regulation by temperature or bile. These data are consistent with ToxT transcriptional activity being modulated by environmental signals in V. cholerae and demonstrate an additional level of complexity governing the expression of virulence factors in this pathogen. We propose that negative regulation of ToxT-dependent transcription by environmental signals prevents the incorrect temporal and spatial expression of virulence factors during cholera pathogenesis.

Distinct roles of an alternative sigma factor during both free-swimming and colonizing phases of the Vibrio cholerae pathogenic cycle.

Vibrio cholerae, the bacterium that causes cholera, has a pathogenic cycle consisting of a free-swimming phase outside its host, and a sessile virulent phase when colonizing the human small intestine. We have cloned the V. cholerae homologue of the rpoN gene (encoding sigma54) and determined its role in the cholera pathogenic cycle by constructing an rpoN null mutant. The V. cholerae rpoN mutant is non-motile; examination of this mutant by electron microscopy revealed that it lacks a flagellum. In addition to flagellar synthesis, sigma54 is involved in glutamine synthetase expression. Moreover, the rpoN mutant is defective for colonization in an infant mouse model of cholera. We present evidence that the colonization defect is distinct from the non-motile and Gln phenotypes of the rpoN mutant, implicating multiple and distinct roles of sigma54 during the V. cholerae pathogenic cycle. RNA polymerase containing sigma54 (sigma54-holoenzyme) has an absolute requirement for an activator protein to initiate transcription. We have identified three regulatory genes, flrABC (flagellar regulatory proteins ABC) that are additionally required for flagellar synthesis. The flrA and flrC gene products are sigma54-activators and form a flagellar transcription cascade. flrA and flrC mutants are also defective for colonization; this phenotype is probably independent of non-motility. An flrC constitutive mutation (M114-->I) was isolated that is independent of its cognate kinase FlrB. Expression of the constitutive FlrCM114-->I from the cholera toxin promoter resulted in a change in cell morphology, implicating involvement of FlrC in cell division. Thus, sigma54 holoenzyme, FlrA and FlrC transcribe genes for flagellar synthesis and possibly cell division during the free-swimming phase of the V. cholerae life cycle, and some as yet unidentified gene(s) that aid colonization within the host.

Differential regulation of multiple flagellins in Vibrio cholerae.

Vibrio cholerae, the causative agent of the human diarrheal disease cholera, is a motile bacterium with a single polar flagellum. Motility has been implicated as a virulence determinant in some animal models of cholera, but the relationship between motility and virulence has not yet been clearly defined. We have begun to define the regulatory circuitry controlling motility. We have identified five V. cholerae flagellin genes, arranged in two chromosomal loci, flaAC and flaEDB; all five genes have their own promoters. The predicted gene products have a high degree of homology to each other. A strain containing a single mutation in flaA is nonmotile and lacks a flagellum, while strains containing multiple mutations in the other four flagellin genes, including a flaCEDB strain, remain motile. Measurement of fla promoter-lacZ fusions reveals that all five flagellin promoters are transcribed at high levels in both wild-type and flaA strains. Measurement of the flagellin promoter-lacZ fusions in Salmonella typhimurium indicates that the promoter for flaA is transcribed by the sigma54 holoenzyme form of RNA polymerase while the flaE, flaD, and flaB promoters are transcribed by the sigma28 holoenzyme. These results reveal that the V. cholerae flagellum is a complex structure with multiple flagellin subunits including FlaA, which is essential for flagellar synthesis and is differentially regulated from the other flagellins.

Identification of multiple sigma54-dependent transcriptional activators in Vibrio cholerae.

In the pathogenic bacterium Vibrio cholerae, the alternate sigma factor sigma54 is required for expression of multiple sets of genes, including an unidentified gene(s) necessary for enhanced colonization within the host. To identify sigma54-dependent transcriptional activators involved in colonization, PCR was performed with V. cholerae chromosomal DNA and degenerate primers, revealing six novel and distinct coding sequences with homology to sigma54-dependent activators. One sequence had high homology to the luxO gene of V. harveyi, which in that organism is involved in quorum sensing. Phenotypes of V. cholerae strains containing mutations in each of the six putative sigma54-dependent activator genes identified one as a probable ntrC homologue. None of the mutant strains exhibited a defect in the ability to colonize infant mice, suggesting the presence of additional sigma54-dependent activators not identified by this technique.

The novel sigma54- and sigma28-dependent flagellar gene transcription hierarchy of Vibrio cholerae.

The human pathogen Vibrio cholerae is a highly motile organism by virtue of a polar flagellum. Flagellar transcriptional regulatory factors have been demonstrated to contribute to V. cholerae virulence, but the role these factors play in the transcription hierarchy controlling flagellar synthesis has been unclear. The flagellar genes revealed by the V. cholerae genome sequence are located in three large clusters, with the exception of the motor genes, which are found in three additional locations. It had previously been demonstrated that the alternative sigma factor sigma54 and the sigma54-dependent activators FlrA and FlrC are necessary for flagellar synthesis. The V. cholerae genome sequence revealed the presence of a fliA gene, which is predicted to encode the alternative flagellar sigma factor sigma28. A V. cholerae DeltafliA mutant strain is non-motile, and synthesizes a truncated flagellum. Vibrio cholerae FliA complements both V. cholerae and Salmonella typhimurium fliA mutants for motility, consistent with its function as an alternative flagellar sigma factor. Analysis of lacZ transcriptional fusions of the V. cholerae flagellar promoters in both V. cholerae and S. typhimurium identified sigma28-, sigma54-, FlrA- and FlrC-dependent promoters, as well as promoters that were independent of all these factors. Our results support a model of V. cholerae flagellar gene transcription as a novel hierarchy composed of four classes of genes. Class I is composed solely of the gene encoding the sigma54-dependent activator FlrA, which along with the sigma54-holoenzyme form of RNA polymerase activates expression of Class II genes. These genes include structural components of the MS ring, switch and export apparatus, as well as the genes encoding both FliA and FlrC. FlrC, along with sigma54-holoenzyme, activates expression of Class III genes, which include basal body, hook and filament genes. Finally, sigma28-holoenzyme activates expression of Class IV genes, which include additional filament genes as well as motor genes. Thus, this novel V. cholerae flagellar hierarchy has incorporated elements from both the sigma54-dependent Caulobacter crescentus polar flagellar hierarchy and the sigma28-dependent S. typhimurium peritrichous flagellar hierarchy.

Characterization of the role of the ToxR-modulated outer membrane porins OmpU and OmpT in Vibrio cholerae virulence.

ToxR, the transmembrane regulatory protein required for expression of virulence factors in the human diarrheal pathogen Vibrio cholerae, directly activates and represses the transcription of two outer membrane porins, OmpU and OmpT, respectively. In an attempt to dissect the role of the OmpU and OmpT porins in viability and virulence factor expression, in-frame chromosomal deletions were constructed in the coding sequences of ompU and ompT of V. cholerae. Two separate deletions were introduced into ompU; the first (small) deletion, Delta ompU1, removed the coding sequence for 84 internal amino acids (aa), while the second (large) deletion, Delta ompU2, removed the coding sequence for the entire amino-terminal 274 aa. The Delta ompU1 strain had a growth defect that could not be complemented by episomal expression of full-length ompU. In contrast, a strain with Delta ompU2 displayed wild-type growth kinetics in rich media, suggesting that this is the true phenotype of a strain lacking OmpU and that the truncated OmpU protein, rather than the absence of OmpU, may be the cause for the Delta ompU1 phenotype. A large deletion removing the coding sequence for the entire N-terminal 273 aa of OmpT (Delta ompT) was also constructed in wild-type as well as Delta toxR and Delta ompU2 strains, and these strains displayed wild-type growth kinetics in rich media. However, the Delta ompU2 strain was deficient for growth in deoxycholate compared to wild-type, Delta ompT, and Delta ompU2 Delta ompT strains, reinforcing a positive role for the OmpU porin and a negative role for the OmpT porin in V. cholerae resistance to anionic detergents. The Delta ompU2, Delta ompT, and Delta ompU2 Delta ompT strains exhibited wild-type levels of in vitro virulence factor expression and resistance to polymyxin B and serum and in vivo colonization levels similar to a wild-type strain in the infant mouse intestine. Our results demonstrate that (i) OmpU and OmpT are not essential proteins, as was previously thought; (ii) these porins contribute to V. cholerae resistance to anionic detergents; and (iii) OmpU and OmpT are not essential for virulence factor expression in vitro or intestinal colonization in vivo.

Characterization of vibrio cholerae O1 antigen as the bacteriophage K139 receptor and identification of IS1004 insertions aborting O1 antigen biosynthesis.

Bacteriophage K139 was recently characterized as a temperate phage of O1 Vibrio cholerae. In this study we have determined the phage adsorption site on the bacterial cell surface. Phage-binding studies with purified lipopolysaccharide (LPS) of different O1 serotypes and biotypes revealed that the O1 antigen serves as the phage receptor. In addition, phage-resistant O1 El Tor strains were screened by using a virulent isolate of phage K139. Analysis of the LPS of such spontaneous phage-resistant mutants revealed that most of them synthesize incomplete LPS molecules, composed of either defective O1 antigen or core oligosaccharide. By applying phage-binding studies, it was possible to distinguish between receptor mutants and mutations which probably caused abortion of later steps of phage infection. Furthermore, we investigated the genetic nature of O1-negative strains by Southern hybridization with probes specific for the O antigen biosynthesis cluster (rfb region). Two of the investigated O1 antigen-negative mutants revealed insertions of element IS1004 into the rfb gene cluster. Treating one wbeW::IS1004 serum-sensitive mutant with normal human serum, we found that several survivors showed precise excision of IS1004, restoring O antigen biosynthesis and serum resistance. Investigation of clinical isolates by screening for phage resistance and performing LPS analysis of nonlysogenic strains led to the identification of a strain with decreased O1 antigen presentation. This strain had a significant reduction in its ability to colonize the mouse small intestine.

Characterization of Vibrio cholerae O1 El tor galU and galE mutants: influence on lipopolysaccharide structure, colonization, and biofilm formation.

Recently we described the isolation of spontaneous bacteriophage K139-resistant Vibrio cholerae O1 El Tor mutants. In this study, we identified phage-resistant isolates with intact O antigen but altered core oligosaccharide which were also affected in galactose catabolism; this strains have mutations in the galU gene. We inactivated another gal gene, galE, and the mutant was also found to be defective in the catabolism of exogenous galactose but synthesized an apparently normal lipopolysaccharide (LPS). Both gal mutants as well as a rough LPS (R-LPS) mutant were investigated for the ability to colonize the mouse small intestine. The galU and R-LPS mutants, but not the galE mutant, were defective in colonization, a phenotype also associated with O-antigen-negative mutants. By investigating several parameters in vitro, we could show that galU and R-LPS mutants were more sensitive to short-chain organic acids, cationic antimicrobial peptides, the complement system, and bile salts as well as other hydrophobic agents, indicating that their outer membrane no longer provides an effective barrier function. O-antigen-negative strains were found to be sensitive to complement and cationic peptides, but they displayed significant resistance to bile salts and short-chain organic acids. Furthermore, we found that galU and galE are essential for the formation of a biofilm in a spontaneous phage-resistant rugose variant, suggesting that the synthesis of UDP-galactose via UDP-glucose is necessary for biosynthesis of the exopolysaccharide. In addition, we provide evidence that the production of exopolysaccharide limits the access of phage K139 to its receptor, the O antigen. In conclusion, our results indicate involvement of galU in V. cholerae virulence, correlated with the observed change in LPS structure, and a role for galU and galE in environmental survival of V. cholerae.

The phosphorylated form of the enhancer-binding protein NTRC has an ATPase activity that is essential for activation of transcription.

The NTRC protein of enteric bacteria is an enhancer-binding protein that activates transcription in response to limitation of combined nitrogen. NTRC activates transcription by catalyzing formation of open complexes by RNA polymerase (sigma 54 holoenzyme form) in an ATP-dependent reaction. To catalyze open complex formation, NTRC must be phosphorylated. We show that phosphorylated NTRC has an ATPase activity, and we present biochemical and genetic evidence that NTRC must hydrolyze ATP to catalyze open complex formation. It is likely that all activators of sigma 54 holoenzyme have an ATPase activity.

The virulence regulatory protein ToxR mediates enhanced bile resistance in Vibrio cholerae and other pathogenic Vibrio species.

The transmembrane regulatory protein ToxR is required for expression of virulence factors in the human diarrheal pathogen Vibrio cholerae, including cholera toxin (CT) and the toxin coregulated pilus (TCP). ToxR is necessary for transcription of the gene encoding a second regulatory protein, ToxT, which is the direct transcriptional activator of CT and TCP genes. However, ToxR, independent of ToxT, directly activates and represses transcription of the outer membrane porins OmpU and OmpT, respectively. The genes encoding TCP and CT (and including ToxT) lie on horizontally acquired genetic elements, while the toxR, ompU, and ompT genes are apparently in the ancestral Vibrio chromosome. The contribution of ToxR-dependent modulation of outer membrane porins to cholera pathogenesis has remained unknown. We demonstrate that ToxR mediates enhanced bile resistance in a ToxT-independent manner. In both classical and El Tor biotypes of V. cholerae, a toxR mutant strain has a reduced minimum bactericidal concentration (MBC) of bile, the bile component deoxycholate (DC), and the anionic detergent sodium dodecyl sulfate (SDS) compared to both wild-type and toxT mutant strains. Classical and El Tor toxR mutant strains also exhibit reduced growth rates at subinhibitory concentrations of DC and SDS. Growth of either V. cholerae biotype in subinhibitory concentrations of bile or DC induces increased ToxR-dependent production of a major 38-kDa outer membrane protein, which was confirmed to be OmpU by Western blot. Measurement of transcription of a ompUp-lacZ fusion in both biotypes reveals stimulation (about two- to threefold) of ToxR-dependent ompU transcription by the presence of bile or DC, suggesting that ToxR may respond to the presence of bile. The toxR mutant strains of three additional human intestinal pathogenic Vibrio species, V. mimicus, V. fluvialis, and V. parahaemolyticus, display lower MBCs of bile, DC, and SDS and have altered outer membrane protein profiles compared to the parental wild-type strains. Our results demonstrate a conserved role for ToxR in the modulation of outer membrane proteins and bile resistance of pathogenic Vibrio species and suggest that these ToxR-dependent outer membrane proteins may mediate enhanced resistance to bile. We speculate that ToxR-mediated bile resistance was an early step in the evolution of V. cholerae as an intestinal pathogen.

Phosphorylation of the flagellar regulatory protein FlrC is necessary for Vibrio cholerae motility and enhanced colonization.

The human pathogen Vibrio cholerae specifically expresses virulence factors within the host, including cholera toxin (CT) and the toxin co-regulated pilus (TCP), which allow it to colonize the intestine and cause disease. V. cholerae is a highly motile organism by virtue of a polar flagellum, and motility has been inferred to be an important aspect of virulence, yet the exact role of motility in pathogenesis has remained undefined. The two-component regulatory system FlrB/FlrC is required for polar flagellar synthesis; FlrC is a sigma54-dependent transcriptional activator. We demonstrate that the transcriptional activity of FlrC affects both motility and colonization of V. cholerae. In a purified in vitro reaction, FlrB transfers phosphate to the wild-type FlrC protein, but not to a mutant form in which the aspartate residue at amino acid position 54 has been changed to alanine (D54A), consistent with this being the site of phosphorylation of FlrC. The wild-type FlrC protein, but not the D54A protein, activates sigma54-dependent transcription in a heterologous system, demonstrating that phospho-FlrC is the transcriptionally active form. A V. cholerae strain containing a chromosomal flrCD54A allele did not synthesize a flagellum and had no detectable levels of transcription of the critical sigma54-dependent flagellin gene flaA. The V. cholerae flrCD54A mutant strain was also defective in its ability to colonize the infant mouse small intestine, approximately 50-fold worse than an isogenic wild-type strain. Another mutation of FlrC (methionine 114 to isoleucine; M114I) confers constitutive transcriptional activity in the absence of phosphorylation, but a V. cholerae flrCM114I mutant strain, although flagellated and motile, was also defective in its ability to colonize. The strains carrying D54A or M114I mutant FlrC proteins expressed normal levels of CT and TCP under in vitro inducing conditions. Our results show that FlrC 'locked' into either an inactive (D54A) or an active (M114I) state results in colonization defects, thereby demonstrating a requirement for modulation of FlrC activity during V. cholerae pathogenesis. Thus, the sigma54-dependent transcriptional activity of the flagellar regulatory protein FlrC contributes not only to motility, but also to colonization of V. cholerae.

The absence of a flagellum leads to altered colony morphology, biofilm development and virulence in Vibrio cholerae O139.

Throughout most of history, epidemic and pandemic cholera was caused by Vibrio cholerae of the serogroup O1. In 1992, however, a V. cholerae strain of the serogroup O139 emerged as a new agent of epidemic cholera. Interestingly, V. cholerae O139 forms biofilms on abiotic surfaces more rapidly than V. cholerae O1 biotype El Tor, perhaps because regulation of exopolysaccharide synthesis in V. cholerae O139 differs from that in O1 El Tor. Here, we show that all flagellar mutants of V. cholerae O139 have a rugose colony morphology that is dependent on the vps genes. This suggests that the absence of the flagellar structure constitutes a signal to increase exopolysaccharide synthesis. Furthermore, although exopolysaccharide production is required for the development of a three-dimensional biofilm, inappropriate exopolysaccharide production leads to inefficient colonization of the infant mouse intestinal epithelium by flagellar mutants. Thus, precise regulation of exopolysaccharide synthesis is an important factor in the survival of V. cholerae O139 in both aquatic environments and the mammalian intestine.