A study of the prevalence of regulatory genes controlling virulence gene expression among Vibrio choleraeeltor biovariant strains varying in their pandemic potential

The evolution of the genome of the pathogenic agent of the seventh cholera pandemia Vibrio cholerae eltor biovariant was thought to occur by acquiring not only structural genes of virulence but also regulatory systems as a result of horizontal transfer events. The polymerase chain reaction revealed the presence of the following regulatory genes that control the virulence gene expression in the chromosome of pre-pandemic and pandemic strains of cholera vibrios eltor: toxR, toxT, tcpP, tcpH, luxS, luxO, crp, vicH, pepA. The avirulent V. cholerae strain ATCC14033 isolated in 1910 (hypothetical predecessor of the cholera eltor agent) was shown to be lacking the regulatory genes toxT, tcpP, tcpHlocalized in the pathogenicity island VPI-1, and to be capable of realizing positive control over the expression of the virulence genes involved in the ToxR regulon. The virulent strains isolated from cholera patients during the local cholera outbreak in Indonesia in 1937 did not differ from the strains that caused cholera eltor pandemic in 1961. The strains had identical content of the regulatory genes tested. Only one strain of the four isolates studied contained no tcpPgene. Two key regulatory genes, toxR and toxT, were sequenced in all the isolates. The toxR nucleotide sequence of three pre-pandemic strains was shown to be indistinguishable from that of the pandemic isolates. On the other hand, the clinical strain MAK757 isolated prior to the emergence of the epidemic demonstrated an altered nucleotide sequence in its toxR gene. Experiments with the intra-intestinal challenge of suckling rabbits were indicative of similar virulence levels for the pre-pandemic and pandemic clinical strains. These results may serve as the evidence of the in vivo activity of the pre-pandemic strains of the toxT, tcpH, and tcpP positive regulatory genes that acquired in V. cholerae during the evolutionary process.     

Comparative genomic analysis of vibrio cholerae El Tor preseventh and seventh pandemic strains isolated in various periods

Genetic organization of 52 Vibrio cholerae El Tor biotype preseventh and seventh pandemic strains isolated in various periods was studied by PCR assay and DNA-DNA hybridization. It was established that the genome of most ancient of analyzed strains isolated from a diarrhea patient in 1910 was devoid of CTX and RS1 prophages, vibrio pathogenicity islands (VPI and VPI-2), and pandemic islands (VSP-1 and VSP-2) that contain key virulence genes. The appearance of pathogenic properties in cholera vibrios for the first time causing a local outbreak of cholera in 1937 is connected with the acquisition of VPI and CTX that carried genes tcpA and ctx-AB, respectively, which are responsible for the colonization of small intestine and encode the production of cholera toxin. The appearance of seventh pandemic agent for cholera was shown to correlate with the acquisition by its precursor of two additional blocks of genes VSP-1 and VSP-2. This finding strongly supports the involvement of these genes in formation of the pandemic potential in strains. Molecular typing methods allowed elucidation of differences in the genetic organization between prepandemic and pandemic strains. The detected variability of the genome of contemporary virulent strains may be a reason for the occurrence of etiological agent for cholera with new properties.     

Hemolytic Vibrio cholerae O1 that is sensitive to Mukerjee's cholera phage IV and the phage produced by the hemolytic vibrio lysogenized with the infection of Mukerjee's cholera phage IV

Strains of hemolytic Vibrio cholerae O1 (El Tor vibrio) which are sensitive to Mukerjee's cholera phage group IV were isolated from cholera patients in North-East Thailand in 1986. Plaques of the phage on these hemolytic V. cholerae O1 were usually translucent but almost transparent on some strains, just like the plaques on non-hemolytic V. cholerae O1 (classical vibrio). These hemolytic V. cholerae O1 were lysogenized with the infection of cholera phage IV, and the lysogenized strains produced phage different from cholera phage IV. These hemolytic strains were classified into Cured type in prophage typing of V. cholerae O1, El Tor, because they were also lysogenized with Kappa phage and were hemolytic. When Cured-type V. cholerae O1, El Tor previously isolated in various countries were examined for the sensitivity to cholera phage IV, some of the isolates were sensitive.     

Molecular-epidemiological characteristic and possible origin of Vibrio cholerae non O1/non O139 with complete and limited set of virulence genes

Study of molecular-epidemiological characteristics of Vibrio cholerae non O1/non O139 serogroup with complete and limited set of virulence genes was performed. Differences of their genes composition as compared to these of O1 serogroup (classic and El Tor biovars) were revealed, which points to their origin from avirulent environmental cholera vibrios.     

A method for studies of an El Tor-associated antigen of Vibrio cholerae O1

A method for studying the biotype El Tor associated mannose-sensitive haemagglutinin (MSHA) of V. cholerae O1 has been developed. By using crude MSHA adsorbed to chicken erythrocytes as solid phase antigen in an enzyme-linked immunosorbent assay (ELISA), antisera against V. cholerae of the El Tor biotype reacted in high titre with the MSHA-coated cells, whereas antisera against vibrios of the classical biotype did not bind significantly, i.e. in higher titre than pre-immune sera. The binding of anti-MSHA serum, or a monoclonal antibody against MSHA, to the MSHA-coated erythrocytes could be efficiently inhibited by crude MSHA as well as by El Tor vibrios whereas neither V. cholerae lipopolysaccharide nor different strains of classical vibrios had any inhibitory effect. These results support the existence of an El Tor-associated immunogen. They also suggest a possibility of determining antibodies against different haemagglutinins in ELISA without having access to purified antigens.     

Vibrio cholerae O1 strains are facultative intracellular bacteria, able to survive and multiply symbiotically inside the aquatic free-living amoeba Acanthamoeba castellanii

Vibrio cholerae species are extracellular, waterborne, gram-negative bacteria that are overwhelmed by predators in aquatic environments. The unencapsulated serogroup V. cholerae O1 and encapsulated V. cholerae O139 cause epidemic and pandemic outbreaks of cholera. It has recently been shown that the aquatic and free-living amoeba Acanthamoeba castellanii is not a predator to V. cholerae O139; rather, V. cholerae O139 has shown an intracellular compatibility with this host. The aim of this study was to examine the ability of V. cholerae O1 classical and El Tor strains to grow and survive in A. castellanii. The interaction between A. castellanii and V. cholerae O1 strains was studied by means of amoeba cell counts and viable counts of the bacteria in the absence or presence of amoebae. The viable count of intracellularly growing bacteria was estimated by utilizing gentamicin assay. Confocal microscopy and electron microscopy were used to determine the intracellular localization of V. cholerae in A. castellanii. The results showed that V. cholerae O1 classical and El Tor strains grew and survived intracellularly in the cytoplasm of trophozoites, and that the bacteria were also found in the cysts of A. castellanii. The interaction showed a facultative intracellular behaviour of V. cholerae O1 classical and El Tor strains and a possible role of A. castellanii as an environmental host of V. cholerae species.     

Role of neuraminidase from cholera vibrions in the pathogenesis of experimental cholera]

A study was made of a possible effect of neuraminidase of cholera vibrios on cholera pathogenesis. It was shown that in intraintestinal injection of cholera vibrios of the El Tor biotype to nursling rabbits neuraminidase could be revealed in their intestine 5 to 8 hours after the infection. Addition of neuraminidase to the weakly cholerogenic strain cholera vibrios intensified its cholerogenic action in infection of the animals. The antineuraminidase serum administered to the infected rabbits prevented clinical manifestations of experimental cholera, although it failed to always eliminate the cholerogenic syndrome (revealed during autopsy). At the same time neuraminidase did not influence the capacity of cholerogen to produce the cholerogenic syndrome. The authors consider that the action of the enzyme should occur at the early stages of the pathogenic process, and could be associated with creation of conditions for the attachement of cholera causative agent to the intestinal wall or for the action of their exotoxin.     

A glimpse into the expanded genome content of Vibrio cholerae through identification of genes present in environmental strains

Vibrio cholerae has multiple survival strategies which are reflected both in its broad distribution in many aquatic environments and its high genotypic diversity. To obtain additional information regarding the content of the V. cholerae genome, suppression subtractive hybridization (SSH) was used to prepare libraries of DNA sequences from two southern California coastal isolates which are divergent or absent in the clinical strain V. cholerae O1 El Tor N16961. More than 1,400 subtracted clones were sequenced. This revealed the presence of novel sequences encoding functions related to cell surface structures, transport, metabolism, signal transduction, luminescence, mobile elements, stress resistance, and virulence. Flanking sequence information was determined for loci of interest, and the distribution of these sequences was assessed for a collection of V. cholerae strains obtained from southern California and Mexican environments. This led to the surprising observation that sequences related to the toxin genes toxA, cnf1, and exoY are widespread and more common in these strains than those of the cholera toxin genes which are a hallmark of the pandemic strains of V. cholerae. Gene transfer among these strains could be facilitated by a 4.9-kbp plasmid discovered in one isolate, which possesses similarity to plasmids from other environmental vibrios. By investigating some of the nucleotide sequence basis for V. cholerae genotypic diversity, DNA fragments have been uncovered which could promote survival in coastal environments. Furthermore, a set of genes has been described which could be involved in as yet undiscovered interactions between V. cholerae and eukaryotic organisms.     

Long-term survival of E1 Tor cholera vibrios in naturally contaminated sewage]

El Tor cholera vibrios of Ogava serological type were revealed in the sewage of the locomotive shed for 15 months. In experiment with an oil catcher in naturally infected sewage El Tor vibrios survived 36 days, in storage of this sewage at the laboratory--39 days, in the artificially infected sewage of a settlement and of a milk plant--2 and 11 days, respectively, in the oil and disel fuel--14 months. Consequently, El Tor vibrio can survive in the sewage with a high oil product content for a long time.     

CTX prophages in classical biotype Vibrio cholerae: functional phage genes but dysfunctional phage genomes

CTXphi is a filamentous, lysogenic bacteriophage whose genome encodes cholera toxin, the primary virulence factor produced by Vibrio cholerae. CTX prophages in O1 El Tor and O139 strains of V. cholerae are found within arrays of genetically related elements integrated at a single locus within the V. cholerae large chromosome. The prophages of O1 El Tor and O139 strains generally yield infectious CTXphi. In contrast, O1 classical strains of V. cholerae do not produce CTXphi, although they produce cholera toxin and they contain CTX prophages integrated at two sites. We have identified the second site of CTX prophage integration in O1 classical strains and characterized the classical prophage arrays genetically and functionally. The genes of classical prophages encode functional forms of all of the proteins needed for production of CTXphi. Classical CTX prophages are present either as solitary prophages or as arrays of two truncated, fused prophages. RS1, a genetic element that is closely related to CTXphi and is often interspersed with CTX prophages in El Tor strains, was not detected in classical V. cholerae. Our model for CTXphi production predicts that the CTX prophage arrangements in classical strains will not yield extrachromosomal CTX DNA and thus will not yield virions, and our experimental results confirm this prediction. Thus, failure of O1 classical strains of V. cholerae to produce CTXphi is due to overall deficiencies in the structures of the arrays of classical prophages, rather than to mutations affecting individual CTX prophage genes.     

Genetic diversity of toxigenic and nontoxigenic Vibrio cholerae serogroups O1 and O139 revealed by array-based comparative genomic hybridization

Toxigenic serogroups O1 and O139 of Vibrio cholerae may cause cholera epidemics or pandemics. Nontoxigenic strains within these serogroups also exist in the environment, and also some may cause sporadic cases of disease. Herein, we investigate the genomic diversity among toxigenic and nontoxigenic O1 and O139 strains by comparative genomic microarray hybridization with the genome of El Tor strain N16961 as a base. Conservation of the toxigenic O1 El Tor and O139 strains is found as previously reported, whereas accumulation of genome changes was documented in toxigenic El Tor strains isolated within the 40 years of the seventh pandemic. High phylogenetic diversity in nontoxigenic O1 and O139 strains is observed, and most of the genes absent from nontoxigenic strains are clustered together in the N16961 genome. By comparing these toxigenic and nontoxigenic strains, we observed that the small chromosome of V. cholerae is quite conservative and stable, outside of the superintegron region. In contrast to the general stability of the genome, the superintegron demonstrates pronounced divergence among toxigenic and nontoxigenic strains. Additionally, sequence variation in virulence-related genes is found in nontoxigenic El Tor strains, and we speculate that these intermediate strains may have pathogenic potential should they acquire CTX prophage alleles and other gene clusters. This genome-wide comparison of toxigenic and nontoxigenic V. cholerae strains may promote understanding of clonal differentiation of V. cholerae and contribute to an understanding of the origins and clonal selection of epidemic strains.     

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.