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.     

A Functional Homolog of Escherichia coli NhaR in Vibrio cholerae

Escherichia coli NhaR controls expression of a sodium/proton (Na⁺/H⁺) antiporter, NhaA. The Vibrio cholerae NhaR protein shows over 60% identity to those of Escherichia coli and Salmonella enteritidis. V. cholerae NhaR complements an E. coli nhaR mutant for growth in 100 mM LiCl–33 mM NaCl, pH 7.6, and enhances the Na⁺-dependent induction of an E. coli chromosomal nhaA::lacZ fusion. These findings indicate functional homology to E. coli NhaR. Two V. cholerae nhaR mutants were constructed by using kanamycin resistance cartridge insertion at different sites to disrupt the gene. Both mutants showed sensitivity to growth in 120 mM LiCl, pH 9.2, compared with the wild-type strain and could be complemented by the introduction of V. cholerae nhaR on a low-copy-number plasmid. An nhaR mutation had no detectable effect on the virulence of the V. cholerae strain in the infant mouse model, suggesting that the antiporter system involved is not required in vivo, at least in this animal model.     

Nucleotide sequence of ompV, the gene for a major Vibrio cholerae outer membrane protein

Summary The nucleotide sequence of the ompV gene of Vibrio cholerae was determined. The product of the gene is a 28,000 dalton protein which, after the removal of a 19 amino acid signal sequence, produces a mature outer membrane protein of 26,000 daltons. The cleavage site was determined by amino-terminal amino acid sequencing of the purified mature protein. The DNA upstream of the gene shows the presence of a typical promoter region as judged from the Escherichia coli consensus information; however, the Shine-Dalgarno sequence is associated with a region capable of forming a secondary structure in the mRNA. The formation of this structure would inhibit binding of the mRNA to the ribosome and reduce translation. It is proposed that this structure is recognized by a positive activator in V. cholerae and because of its absence in E. coli ompV is poorly expressed. The distribution of rare codons within ompV suggests that they may serve to slow down the translation of particular domains such that the nascent polypeptide has an opportunity to take up its conformation without interference from the later formed regions. Such a mechanism could aid localization of the protein if export were by a cotranslational secretion system.     

Hsp33 confers bleach resistance by protecting elongation factor Tu against oxidative degradation in Vibrio cholerae

The redox‐regulated chaperone Hsp33 protects bacteria specifically against stress conditions that cause oxidative protein unfolding, such as treatment with bleach or exposure to peroxide at elevated temperatures. To gain insight into the mechanism by which expression of Hsp33 confers resistance to oxidative protein unfolding conditions, we made use of Vibrio cholerae strain O395 lacking the Hsp33 gene hslO. We found that this strain, which is exquisitely bleach‐sensitive, displays a temperature‐sensitive (ts) phenotype during aerobic growth, implying that V. cholerae suffers from oxidative heat stress when cultivated at 43°C. We utilized this phenotype to select for Escherichia coli genes that rescue the ts phenotype of V. cholerae ΔhslO when overexpressed. We discovered that expression of a single protein, the elongation factor EF‐Tu, was sufficient to rescue both the ts and bleach‐sensitive phenotypes of V. cholerae ΔhslO. In vivo studies revealed that V. cholerae EF‐Tu is highly sensitive to oxidative protein degradation in the absence of Hsp33, indicating that EF‐Tu is a vital chaperone substrate of Hsp33 in V. cholerae. These results suggest an ‘essential client protein’ model for Hsp33's chaperone action in Vibrio in which stabilization of a single oxidative stress‐sensitive protein is sufficient to enhance the oxidative stress resistance of the whole organism.     

The rpoH gene encoding σ32 homolog of Vibrio cholerae

The Vibrio cholerae rpoH gene coding for the heat-shock sigma factor, σ³², has been cloned and shown to functionally complement Escherichia coli rpoH mutants. The nt sequence of the gene has been determined and the deduced aa sequence is more than 80% homologous to the E. coli rpoH gene product. Downstream of the V. cholerae rpoH gene, an unidentified dehydrogenase gene (udhA) is present on the opposite strand facing rpoH. The predicted secondary structure of the 5′-proximal region of V. cholerae rpoH mRNA is apparently different from the conserved secondary structures of the rpoH mRNA reported for several bacterial species. The `RpoH box', a stretch of 9 aa (QRKLFFNLR) unique to σ<sup>32</sup> factors, and the `downstream box' sequence complementary to a part of the 16S rRNA, have been detected.     

Rapid detection and identification of odontoglossum ringspot virus by polymerase chain reaction amplification

Abstract A hemolysis gene ( hlx ) which lyses sheep erythrocytes on blood agar plates when expressed in Escherichia coli was cloned from Vibrio cholerae . The cloned gene is predicted to encode a polypeptide of 92 amino acid residues with a deduced molecular mass of 10451. E. coli transformed with this gene lysed sheep, goose, horse and chicken erythrocytes but not those of guinea pig and human. The hlx gene was observed in classical- and El Tor-biotype V. cholerae O1, V. cholerae non-O1, and V. mimicus , but not in V. parahaemolyticus .     

A Potential Epidemic Factor from the Bacteria, <Emphasis Type="Italic">Vibrio cholerae WO7</Emphasis>

Certain species of Vibrio cholerae have evolved mechanisms to become pathogenic to humans, with the potential to cause a severe life-threatening diarrheal disease, cholera. Cholera can emerge as explosive outbreaks in the human population. V. cholerae illness is produced primarily through the expression of a potent toxin (cholera toxin) within the human intestine. The present study has been carried out on a novel toxin purified from V. cholerae W07, an epidemic cholera strain devoid of cholera toxin gene (ctx). A modified method of purification improved purification fold as well as yield of this toxin. Heating was found to be the essential and sufficient condition for dissociation of the two subunits (58 kDa and 40 kDa) of this toxin (pI 5.2). The 40-kDa subunit of the purified toxin was identified as the carbohydrate binding subunit. This toxin was found to induce apoptosis in HEp-2 cells. Thus, the WO7 toxin seems to have potential importance in the pathogenesis of disease associated with Vibrio cholerae WO7.     

Biological Activities of Lipopolysaccharide Isolated from Vibrio cholerae O139, a New Epidemic Strain for Recent Cholera in Indian Subcontinent

Biological activities of lipopolysaccharide (LPS) isolated from Vibrio cholerae O139, a new causative agent for recent cholera epidemic in Indian subcontinent, were investigated in comparison with those of LPS from O1 V. cholerae. V. cholerae O139 LPS exerted mitogenic activity, lethal toxicity and Shwartzman reaction to the same extent as those observed for O1 V. cholerae LPS, although these activities except for lethal toxicity were obviously lower than those of Salmonella typhimurium LT-2 LPS used as a reference. It was, therefore, suggested that O139 LPS does not contribute to the high infective and pathogenic potentials of the V. cholerae O139 strain as in the case of O1 V. cholerae.     

Thiol‐based switch mechanism of virulence regulator AphB modulates oxidative stress response in Vibrio cholerae

Bacterial pathogens display versatile gene expression to adapt to changing surroundings. For example, Vibrio cholerae, the causative agent of cholera, utilizes distinct genetic programs to combat reactive oxygen species (ROS) in aquatic environments or during host infection. We previously reported that the virulence activator AphB in V. cholerae is involved in ROS resistance. Here by performing a genetic screen, we show that AphB represses ROS resistance gene ohrA, which is also repressed by another regulator, OhrR. Reduced forms of both AphB and OhrR directly bind to the ohrA promoter and repress its expression, whereas organic hydroperoxides such as cumene hydroperoxide (CHP) deactivate AphB and OhrR. OhrA is critical for V. cholerae adult mouse colonization but is dispensable when the mice are treated with antioxidants. Furthermore, similar to our previous finding that AphB and OhrR exhibit different reduction rates during the shift from oxic to anoxic environments, we found that AphB is also oxidized more slowly than OhrR under peroxide stress or exposure to oxygen. This differential regulation optimizes the expression of ohrA and contributes to V. cholerae's ability to survive in a variety of environmental niches that contain different levels of ROS.     

Cloning and characterization of the Vibrio cholerae genes encoding the utilization of iron from haemin and haemoglobin

Vibrio cholerae can utilize haemin or haemoglobin as its sole source of iron. Four haem utilization mutants of a classical strain of V. cholerae were isolated. These mutations were complemented with pHUT1, a cosmid clone isolated from a library of wild-type CA401 DNA. Two independent Tn5 insertions into the cloned sequence disrupted function in all of the complemented mutants. Escherichia coli 1017 transformed with pHUT1 failed to utilize haemin as an iron source; a second plasmid containing a different cloned fragment of V. cholerae DNA (pHUT3) was required in addition to pHUT1 to reconstitute the system in E. coli. Minicell analysis and SDS-PAGE of protein fractions indicate that pHUT10 (a subclone of p>HUT1) encodes a 26 kDa inner membrane protein, and pHUT3 encodes a 77 kDa outer membrane protein. Loss of either protein by Tn5 mutagenesis abolishes haem utilization in E. coli. An E. coli hemA mutant that cannot synthesize porphyrins was transformed with the recombinant plasmids to determine whether the plasmids encoded the ability to transport the porphyrin as well as the iron. The transformants grew aerobically in media containing haemin, whereas the parental strain was unable to grow under these conditions. This indicates that V. cholerae haem-iron utilization genes allow transport of the entire haem moiety into the cell.     

Arctic Actinomycetes as Potential Inhibitors of <Emphasis Type="Italic">Vibrio cholerae</Emphasis> Biofilm

The aim of this study was to identify novel biofilm inhibitors from actinomycetes isolated from the Arctic against Vibrio cholerae, the causative agent of cholera. The biofilm inhibitory activity of actinomycetes was assessed using biofilm assay and was confirmed using air–liquid interphase coverslip assay. The potential isolates were identified using 16S rRNA gene sequencing. Of all, three isolates showed significant biofilm inhibition against V. cholerae. The results showed that 20% of the actinomycetes culture supernatant could inhibit up to 80% of the biofilm formation. When different extracted fractions were assessed, significant biofilm inhibition activity was only seen in the diethyl ether fraction of A745. At 200 μg ml⁻¹ of diethyl ether fraction, 60% inhibition of V. cholerae biofilm was observed. The two potential isolates were found to be Streptomyces sp. and one isolate belonged to Nocardiopsis sp. This is the first report showing a Streptomyces sp. and Nocardiopsis sp. isolated from the Arctic having a biofilm inhibitory activity against V. cholerae. The spread of drug resistant V. cholerae strains is a major clinical problem and the ineffectiveness in antibiotic treatment necessitates finding new modes of prevention and containment of the disease, cholera. The formation of biofilms during the proliferation of V. cholerae is linked to its pathogenesis. Hence, the bioactive compound from the culture supernatant of the isolates identified in this study may be a promising source for the development of a potential quorum sensing inhibitors against V. cholerae.     

TcpA pilin sequences and colonization requirements for O1 and O139 Vibrio cholerae

The distribution, characterization and function of the tcpA gene was investigated in Vibrio cholerae O1 strains of the El Tor biotype and in a newly emergent non-O1 strain classified as serogroup O139. The V. cholerae tcpA gene from the classical biotype strain O395 was used as a probe to identify a clone carrying the tcpA gene from the El Tor biotype strain E7946. The sequence of the E7946 tcpA gene revealed that the mature El Tor TcpA pilin has the same number of residues as, and is 82% identical to, TcpA of classical biotype strain O395. The majority of differences in primary structure are either conservative or clustered in a manner such that compensatory changes retain regional amino acid size, polarity and charge. In a functional analysis, the cloned gene was used to construct an El Tor mutant strain containing an insertion in tcpA. This strain exhibited a colonization defect in the infant mouse cholera model similar in magnitude to that previously described for classical biotype tcpA mutants, thus establishing an equivalent role for TCP in intestinal colonization by El Tor biotype strains. The tcpA analysis was further extended to both a prototype El Tor strain from the Peru epidemic and to the first non-O1 strain known to cause epidemic cholera, an O139 V. cholerae isolate from the current widespread Asian epidemic. These strains were shown to carry tcpA with a sequence identical to E7946. These results provide further evidence that the newly emergent non-O1 serogroup O139 strain represents a derivative of an El Tor biotype strain and, despite its different LPS structure, shares common TCP-associated antigens. Therefore, there appear to be only two related sequences associated with TCP pilin required for colonization by all strains responsible for epidemic cholera, one primary sequence associated with classical strains and one for El Tor strains and the recent O139 derivative. A diagnostic correlation between the presence of tcpA and the V. cholerae to colonize and cause clinical is now extended to strains of both O1 and non-O1 serotypes.