Characterization of VPI pathogenicity island and CTXphi prophage in environmental strains of Vibrio cholerae

Environmental isolates of Vibrio cholerae of eight randomly amplified polymorphic DNA (RAPD) fingerprint types from Calcutta, India, that were unusual in containing toxin-coregulated pilus or cholera toxin genes but not O1 or O139 antigens of epidemic strains were studied by PCR and sequencing to gain insights into V. cholerae evolution. We found that each isolate contained a variant form of the VPI pathogenicity island. Distinguishing features included (i) four new alleles of tcpF (which encodes secreted virulence protein; its exact function is unknown), 20 to 70% divergent (at the protein level) from each other and canonical tcpF; (ii) a new allele of toxT (virulence regulatory gene), 36% divergent (at the protein level) in its 5' half and nearly identical in its 3' half to canonical toxT; (iii) a new tcpA (pilin) gene; and (iv) four variant forms of a regulatory sequence upstream of toxT. Also found were transpositions of an IS903-related element and function-unknown genes to sites in VPI. Cholera toxin (ctx) genes were found in isolates of two RAPD types, in each case embedded in CTXphi-like prophages. Fragments that are inferred to contain only putative repressor, replication, and integration genes were present in two other RAPD types. New possible prophage repressor and replication genes were also identified. Our results show marked genetic diversity in the virulence-associated gene clusters found in some nonepidemic V. cholerae strains, suggest that some of these genes contribute to fitness in nature, and emphasize the potential importance of interstrain gene exchange in the evolution of this species.     

CTXphi and Vibrio cholerae: exploring a newly recognized type of phage-host cell relationship

The genes encoding cholera toxin, one of the principal virulence factors of the diarrhoeal pathogen Vibrio cholerae, are part of the genome of CTXphi, a filamentous bacteriophage. Thus, CTXphi has played a critical role in the evolution of the pathogenicity of V. cholerae. Unlike the well-studied F pilus-specific filamentous coliphages, CTXphi integrates site-specifically into its host chromosome and forms stable lysogens. Here we focus on the CTXphi life cycle and, in particular, on recent studies of the mechanism of CTXphi integration and the factors that govern lysogeny. These and other processes illustrate the remarkable dependence of CTXphi on host-encoded factors.     

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.     

Prophage CTXphi genome variability and its role in alteration of Vibrio cholerae El Tor virulence characteristics

Comparative analysis of CTXphi prophage genome of 366 V. cholerae El Tor strains isolated from infected people and water was carried out using the polymerase chain reaction. Four groups of vibrios, which carry different combinations of ctxA, zot, and ace genes from core region of CTXphi prophage coding key (cholera enterotoxin) and accessory (Zot and Ace toxins) pathogenicity factors, were determined: ctxA(+) zot(-) ace(+), ctxA(-) zot(+) ace(+), ctxA(-) zot(+) ace(-), ctxA(-) zot(-) ace(+). Vibrios that had lost all tested genes were also revealed. Genomic rearrangements occurring in water environment in virulent V. cholerae strains, which acquired foreign pathogenicity genes necessary for their existence in human organism, were proposed as one of the mechanisms of formation of clones with an incomplete or no prophage. Infection process in model animals challenged with wild and isogenic strains of V. cholerae differing in the set of the phage genes (ctxA, zot, and ace) was comparatively analyzed. It was shown that variability of CTXphi prophage genome was an important factor of modification of cholera vibrios virulent characteristics. Obtained data point to usefulness of ctxA, zot, and ace phage genes detection in wild V. cholerae isolates as it could permit evaluation of their virulent potential determining the severity of the infection.     

The Vibrio cholerae O139 Calcutta bacteriophage CTXphi is infectious and encodes a novel repressor.

CTXphi is a lysogenic, filamentous bacteriophage. Its genome includes the genes encoding cholera toxin (ctxAB), one of the principal virulence factors of Vibrio cholerae; consequently, nonpathogenic strains of V. cholerae can be converted into toxigenic strains by CTXphi infection. O139 Calcutta strains of V. cholerae, which were linked to cholera outbreaks in Calcutta, India, in 1996, are novel pathogenic strains that carry two distinct CTX prophages integrated in tandem: CTX(ET), the prophage previously characterized within El Tor strains, and a new CTX Calcutta prophage (CTX(calc)). We found that the CTX(calc) prophage gives rise to infectious virions; thus, CTX(ET)phi is no longer the only known vector for transmission of ctxAB. The most functionally significant differences between the nucleotide sequences of CTX(calc)phi and CTX(ET)phi are located within the phages' repressor genes (rstR(calc) and rstR(ET), respectively) and their RstR operators. RstR(calc) is a novel, allele-specific repressor that regulates replication of CTX(calc)phi by inhibiting the activity of the rstA(calc) promoter. RstR(calc) has no inhibitory effect upon the classical and El Tor rstA promoters, which are instead regulated by their cognate RstRs. Consequently, production of RstR(calc) renders a CTX(calc) lysogen immune to superinfection by CTX(calc)phi but susceptible (heteroimmune) to infection by CTX(ET)phi. Analysis of the prophage arrays generated by sequentially integrated CTX phages revealed that pathogenic V. cholerae O139 Calcutta probably arose via infection of an O139 CTX(ET)phi lysogen by CTX(calc)phi.     

The tcp gene cluster of Vibrio cholerae

The toxin co-regulated pilus (TCP) has been identified as a critical colonization factor in both animal models and humans for Vibrio cholerae O1. The major pilin subunit, TcpA (and also TcpB), is similar to type-4 pilins but TCP probably more appropriately belongs to a sub-class which includes the bundle-forming pilus of enteropathogenic Escherichia coli. The genes for TCP biosynthesis and assembly are clustered with the exception of housekeeping functions such as TcpG (=DsbA, a periplasmic disulfide bond epimerase). The nt sequences from El Tor and classical strains show only minor differences corresponding to the major regulatory regions and in TcpA itself. These differences are thought to account for the alternate conditions required for expression of TCP by the two biotypes and the antigenic variation and lack of cross-protection. Aside from the TcpA only a few of the proteins have had their roles in TCP biogenesis defined. Regulation of TCP is controlled by the ToxR regulon via ToxT with a possible involvement of TcpP and the cAMP-CRP system. Experiments using the infant mouse cholera model have now shown that TCP is a colonization factor and protective antigen for both classical and El Tor O1 strains and in the O139 Bengal serotype and that the mannose-sensitive haemagglutinin pilus does not appear to play a comparable role.     

Variation in the genome of CTXphi prophage of Vibrio cholerae biovar El Tor caused by Tn5-Mob transposon

A key pathogenicity factor of the cholera etiologic agent is cholera toxin (CT) whose synthesis is encoded by the ctxAB operon forming apart of the CTXphi ptophage. Alterations in the virulent properties of the cholera vibrios are based on the variability of the CTXphi prophage containing the genes for ctxAB, zot, ace, cep, orfU, and psh in its core region. At the same time, the mechanism of the porophage genome reorganization needs further and more profound analysis. The goal of this work was to demonstrate that transposon Tn5-Mob (Kmr), when introduced into the chromosome of the V. cholera model strain MAK757 El Tor biovar containing two copies of the CTXphi prophage provoked a reorganization in the CTXphi prophage consisting in the deletion of zot, ace, cep, orfU genes. The level of the CT biosynthesis in the insertion mutants MAK757 chr::Tn5-Mob still retaining only the ctxAB operon, increased more than 2000 times as compared to that of the original strain. The enhanced CT production was shown to be associated with the altered structure of the chromosomal DNA region containing one copy of the ctxAB operon encoding this protein biosynthesis. The mutation in the CTXphi genome induced by Tn5-Mob was unstable. Among 600 isolated colonies obtained after dissemination of the MAK757 chr::Tn5-Mob transposant capable of CT overproduction in the full medium with no antibiotics, 5.8% gave clones that in parallel to the loss of Kmr marker, appeared to be deprived of the ctxAB operon thus becoming non-toxinogenic. The observed formation of the V. cholerae insertion mutants both capable of CT overproduction and non-toxinogenic ones, may be indicative of an important role played in the evolution of the cholera pathogen by the CTXphi genome variability induced by Tn elements. The plasmidless V. cholerae El Tor strain characterized by type II CT hyperproduction thus obtained in our experiments could be used for the production of this protein routinely applied to construct efficient cholera diagnostic and prophylactic preparations.     

Isolation and characterization of the Vibrio cholerae recA gene

A 3.6-kilobase PstI fragment was isolated from a Vibrio cholerae chromosomal DNA library and shown to encode RecA-like activity in complementation studies with Escherichia coli recA mutants. Although DNA hybridization experiments failed to detect any homology between the E. coli and V. cholerae recA genes, hyperimmune antiserum produced against purified E. coli RecA protein recognized epitopes shared by the V. cholerae protein. The V. cholerae chromosomal fragments, when cloned and transferred to E. coli, provided the missing recA functions, including resistance to the alkylating agent methyl methanesulfonate, resistance to UV irradiation, and promotion of homologous recombination in Hfr mating experiments.     

霍乱弧菌检测方法的研究进展

烈性肠道传染病霍乱能引起大范围乃至世界性大流行,在我国被列为甲类传染病.霍乱弧菌是导致感染者严重腹泻、引起霍乱的病原菌.霍乱弧菌的快速、准确检测是霍乱预防、控制的重要依据.目前,国内、外针对霍乱弧菌建立了许多有效的检测方法,尤其是分子生物学相关技术的应用,为霍乱弧菌的检测提供了新的手段.本文综述了近年来霍乱弧菌检测方法...     

pIIICTX,a predicted CTXphi minor coat protein,can expand the host range of coliphage fd to include Vibrio cholerae

CTXphi is a filamentous bacteriophage that encodes cholera toxin. CTXphi infection of its host bacterium, Vibrio cholerae, requires the toxin-coregulated pilus (TCP) and the products of the V. cholerae tolQRA genes. Here, we have explored the role of OrfU, a predicted CTXphi minor coat protein, in CTXphi infection. Prior to the discovery that it was part of a prophage, orfU was initially described as an open reading frame of unknown function that lacked similarity to known protein sequences. Based on its size and position in the CTXphi genome, we hypothesized that OrfU may function in a manner similar to that of the coliphage fd protein pIII and mediate CTXphi infection as well as playing a role in CTXphi assembly and release. Deletion of orfU from CTXphi dramatically reduced the number of CTXphi virions detected in supernatants from CTXphi-bearing cells. This defect was complemented by expression of orfU in trans, thereby confirming a role for this gene in CTXphi assembly and/or release. To evaluate the requirement for OrfU in CTXphi infection, we introduced fragments of orfU into gIII in an fd derivative to create OrfU-pIII fusions. While fd is ordinarily unable to infect V. cholerae, an fd phage displaying the N-terminal 274 amino acids of OrfU could infect V. cholerae in a TCP- and TolA-dependent fashion. Since our findings indicate that OrfU functions as the CTXphi pIII, we propose to rename OrfU as pIII(CTX). Our data also provide new evidence for a conserved pathway for filamentous phage infection.     

TolC affects virulence gene expression in Vibrio cholerae

A Vibrio cholerae tolC mutant showed increased toxT expression in M9 medium, but not in the presence of four amino acids that induce cholera toxin production, and in LB with high osmolarity but not high pH or temperature. TolC did not affect expression of other regulatory genes in the ToxR regulon.     

Vibrio cholerae infection of Drosophila melanogaster mimics the human disease cholera

Cholera, the pandemic diarrheal disease caused by the gram-negative bacterium Vibrio cholerae, continues to be a major public health challenge in the developing world. Cholera toxin, which is responsible for the voluminous stools of cholera, causes constitutive activation of adenylyl cyclase, resulting in the export of ions into the intestinal lumen. Environmental studies have demonstrated a close association between V. cholerae and many species of arthropods including insects. Here we report the susceptibility of the fruit fly, Drosophila melanogaster, to oral V. cholerae infection through a process that exhibits many of the hallmarks of human disease: (i) death of the fly is dependent on the presence of cholera toxin and is preceded by rapid weight loss; (ii) flies harboring mutant alleles of either adenylyl cyclase, Gsalpha, or the Gardos K channel homolog SK are resistant to V. cholerae infection; and (iii) ingestion of a K channel blocker along with V. cholerae protects wild-type flies against death. In mammals, ingestion of as little as 25 mug of cholera toxin results in massive diarrhea. In contrast, we found that ingestion of cholera toxin was not lethal to the fly. However, when cholera toxin was co-administered with a pathogenic strain of V. cholerae carrying a chromosomal deletion of the genes encoding cholera toxin, death of the fly ensued. These findings suggest that additional virulence factors are required for intoxication of the fly that may not be essential for intoxication of mammals. Furthermore, we demonstrate for the first time the mechanism of action of cholera toxin in a whole organism and the utility of D. melanogaster as an accurate, inexpensive model for elucidation of host susceptibility to cholera.     

Vibrio cholerae laboratory infection of the adult house fly Musca domestica

The present study was designed to test the hypothesis that house flies may be capable of specifically harbouring ingested Vibrio cholerae in their digestive tracts. Flies were continuously fed green fluorescent protein (GFP)‐labelled, non‐O1/non‐O139 environmental strains of V. cholerae. Bacterial burdens were quantitatively measured using plate counts and localization was directly observed using confocal microscopy. Vibrio cholerae were present in the fly alimentary canal after just 4 h, and reached a plateau of ～10⁷ colony‐forming units (CFU)/fly after 5 days in those flies most tolerant of the pathogen. However, individual flies were resistant to the pathogen: one or more flies were found to carry < 180 V. cholerae CFU at each time‐point examined. In flies carrying V. cholerae, the pathogen was predominantly localized to the midgut rather than the rectal space or crop. The proportion of house flies carrying V. cholerae in the midgut was dose‐dependent: the continuous ingestion of a concentrated, freshly prepared dose of V. cholerae increased the likelihood that fluorescent cells would be observed. However, V. cholerae may be a transient inhabitant of the house fly. This work represents the first demonstration that V. cholerae can inhabit the house fly midgut, and provides a platform for future studies of host, pathogen and environmental mediators of the successful colonization of this disease vector.     

Lack of umuDC gene functions in Vibrio cholerae cells

Attempts to identify an umuDC analog, using interspecific complementation of Escherichia coli mutants with plasmids containing a gene bank of Vibrio cholerae, were not successful. The DNA from none of the vibrio species examined including marine vibrios hybridized to E. coli umuC and umuD gene sequences. These cells are not mutable by ultraviolet (UV) light and cannot Weigle-reactivate UV-irradiated choleraphages, suggesting that vibrios are deficient in the umuDC operon. This possibility is supported by the fact that when the plasmid pKM101 carrying the mucAB genes is introduced into V. cholerae cells, they acquire the UV-mutable phenotype and UV-irradiated choleraphages can be Weigle-reactivated.     

Functional analysis of the essential GTP-binding-protein-coding gene cgtA of Vibrio cholerae

The cgtA gene, coding for the conserved G protein CgtA, is essential in bacteria. In contrast to a previous report, here we show by using genetic analysis that cgtA is essential in Vibrio cholerae even in a Delta relA background. Depletion of CgtA affected the growth of V. cholerae and rendered the cells highly sensitive to the replication inhibitor hydroxyurea. Overexpression of V. cholerae CgtA caused distinct elongation of Escherichia coli cells. Deletion analysis indicated that the C-terminal end of CgtA plays a critical role in its proper function.     

Pore formation by Vibrio cholerae cytolysin requires cholesterol in both monolayers of the target membrane

Vibrio cholerae cytolysin (VCC) forms oligomeric transmembrane pores in cholesterol-rich membranes. To better understand this process, we used planar bilayer membranes. In symmetric membranes, the rate of the channel formation by VCC has a superlinear dependency on the cholesterol membrane fraction. Thus, more than one cholesterol molecule can facilitate VCC-pore formation. In asymmetric membranes, the rate of pore formation is limited by the leaflet with the lower cholesterol content. Methyl-beta-cyclodextrin, which removes cholesterol from membranes, rapidly inhibits VCC pore formation, even when it is added to the side opposite that of VCC addition. The results suggest that cholesterol in both membrane leaflets aid VCC-pore formation and that either leaflet can function as a kinetic bottleneck with respect to the rate of pore-formation.     

Going against the grain: chemotaxis and infection in Vibrio cholerae

Chemotaxis is the process by which motile cells move in a biased manner both towards favourable and away from unfavourable environments. The requirement of this process for infection has been examined in several bacterial pathogens, including Vibrio cholerae. The single polar flagellum of Vibrio species is powered by a sodium-motive force across the inner membrane, and can rotate to produce speeds of up to 60 cell-body lengths (approximately 60microm) per second. Investigating the role of the chemotactic control of rapid flagellar motility during V. cholerae infection has revealed some unexpected and intriguing results.