Testing the biological activity of Vibrio cholerae on cell subcultures

Testing the supernatants of ctx(+) strains of V. cholerae eltor and V. cholerae O139 on cell subcultures confirmed the possibility of the synthesis of hemolysin by V. cholerae under the condition of growing them in tripton medium lacking FeCl3. At the same time ctx(+) strains of V. cholerae of both serogroups retained, simultaneously with hemolysin production, their capacity for the synthesis of cholera toxin.     

Vibrio cholerae temperate phage O139: characteristics and role in changing expression of chromosomal virulence genes

Restriction analysis of temperate cholera phage 139 isolated from Vibrio cholerae P16064, serogroup 0139, showed its DNA to be double-stranded linear with cohesive terminals. DNA-DNA hybridization on nylon membranes revealed that many V. cholerae strains of serogroup 0139 isolated in different regions contained a temperate cholera phage 139 in their genomes. Southern blot hybridization of chromosomal DNA PST-fragments with phage probe showed that the temperate phage 139 was identical to the temperate phage of serogroup II V. eltor. The phage integrated in the chromosome near genes encoding motility (mot) and production of the capsule (cap) and purine (pur). Phage genome is apparently responsible for instability of cap, pur, and mot genes whose products are important for the development of an infectious process in cholera.     

Construction of a genetic map of the chromosome of Vibrio cholerae based on conjugational crossings

The results of cholera vibrio chromosomal mapping using Vibrio cholerae classica and V. cholerae eltor donor strains obtained with the help of various R. plasmids, are summarized in the paper. A genetic map of V. cholerae chromosome was established showing the order of 35 gene markers. The relationship between the genetic structures of cholera eltor and classical vibrio biotypes is discussed.     

Role of moderate bacteriophage 139 in change in production of cholera toxin in a classic strain of Vibrio cholerae

New data were obtained concerning cell sensitivity of pathogenic strains of cholera vibrions, which belong to the serogroup O1 of classical biovar, to the temperate bacteriophage K139, the native host of which is Vibrio cholerae O139. Molecular-genetic and biochemical studies showed that phage 139 integrated into the chromosome of strains V. cholerae O1 can change their toxigenic properties. A change in the production of cholera toxin (CT) in lysogens is associated both with an increase in the activity of the toxR regulatory gene and with a distortion of the structure of a chromosomal DNA region that contains a copy of the operon ctxAB encoding CT biosynthesis.     

Inheritance and expression of cholera toxin genes introduced into Vibrio cholerae el tor cells in a hybrid plasmid

Two replicons, pOX38 (in F-factor derivative lacking all IS elements) and pCT105 (containing cholera toxin operon cloned in pBR322) have been fused to produce recombinant plasmid, pCO109, which was then introduced into Vibrio cholerae eltor by conjugation. Restriction analysis showed pCO109 to dissociate in V. cholerae cells at a higher frequency than in Escherichia coli strains, its pOX38 component being lost, while the pCT105 component demonstrated relative stability. V. cholerae eltor RV79 (pCT105) produced 4-5 micrograms/ml of cholera toxin. Occasional insertion of cloned vctA, B operon into RV79 chromosome was also observed.     

Potential use of serological methods in detecting cholera toxin

In the study of 50 Vibrio cholerae museum strains, 45 of them producing cholerigenic effect in suckling rabbits, cholera toxin, determined by means of the passive immune hemolysis (PIH) test, has been detected in the supernatant of the culture fluid of only two strains: V. cholerae 569 B, a well-known producer of cholera toxin, and V. cholerae (eltor) 1310, from whose population a toxigenic variant has been obtained by selection. To study the capacity of V. cholerae for producing toxin in vitro, in six cholerigenic strains, besides the supernatant of their culture fluids, also protein fractions, cell lysates and membrane fractions have been studied in the PIH test. In all these strains cholera toxin has been detected only in membrane fractions, which should be taken into consideration in the serological evaluation of the toxigenicity of V. cholerae.     

Characterization of Vibrio cholerae eltor in the city of Kazan in 2001

Information on V. cholerae eltor isolated in the focus of cholera in Kazan in 2001 at different periods of the outbreak is presented. The identity of strains isolated from patients, vibriocarriers and environmental objects, including their antibioticograms (sensitivity to cyprofloxacin and resistance to trimethoprim--sulfamethoxazole, streptomycin, furazolidone and nalidixic acid, which may be regarded as markers), is shown. Variable tandem repetitions in the DNA of 30 isolates strains of different origin have been determined. The results of this determination make it possible to classify all these strains as one genotype, which confirms the suggestion on the circulation of one subclone of the infective agent of cholera in the focus. As revealed in this investigation, the isolated strains are labile with respect to diagnostic phage eltor, while ctx+ strains are resistant to phage eltor ctx+.     

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.     

Determination of Vibrio cholerae enterotoxin by the passive immune hemolysis technic

To determine the antigenic determinants of cholera toxin, the passive immune hemolysis test was used. This test, proved to be highly sensitive (100-200 pg/ml) and specific, yielded results quicker than all other immunological methods for the determination of cholera toxin. The study of 36 cholera and NAG-vibrio strains revealed that V. cholerae synthesized the greatest amount of the toxin, whereas V. eltor formed a heterogenous group, comprising strains capable of synthesizing the toxin in considerable amounts, as well as strains synthetizing no toxin. Some strains of NAG-vibrio were found to produce insignificant amounts of the toxin.     

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.     

Comparative study of the diagnostic value of new cholera eltor bacteriophages ctx+, ctx-, and KhDF-3, 4, and 5

The comparative evaluation of the diagnostic value of new cholera eltor bacteriophages ctx+ and ctx-, as well as monophages X[symbol: see text]-3, 4, 5, demonstrated their high activity and specificity. Using of these bacteriophages epidemic potential of 95% Vibrio cholerae eltor strains ctx+ and 84.5% of V. cholerae eltor stains ctx- was determined. Commercial monophages X[symbol: see text]-3, 4, 5 were inferior to bacteriophages ctx+ and ctx- in their diagnostic value: only 55% of strains having gene ctxAB were found to be epidemically dangerous, i.e. 45% of strains capable of causing the disease were not detected. On the basis of the results obtained in this investigation cholera eltor bacteriophages ctx+ and ctx- were recommended for introduction into practical use, while further production of cholera diagnostic monophages X[symbol: see text]-3, 4, 5 was recommended to be stopped.     

The capacity to produce cholera exotoxin in natural strains of Vibrio cholerae

The study of 27 V. cholerae strains, isolated from cholera patients and found to be hemolytically inactive, with a view to establish their capacity for the production of cholera toxin has revealed that 4 strains (V. cholerae cholerae Dacca 35, V. cholerae cholerae Dacca 3, V. cholerae cholerae B1307, V. cholerae cholerae J89) produce this protein. The quantitative determination of enterotoxin has been made with the use of GM1 ELISA technique. Strain Dacca 35 has been found to be highly toxigenic and, as regards the amount of exotoxin it produces, no different from V. cholerae cholerae strain 569B, a well-known producer of cholera toxin. In strain Dacca 35 correlation between the capacity of the cells for toxin production and the morphology of colonies has been established. The study has revealed that the chromosome of strain Dacca 35 contains two copies of gene vctAB responsible for the synthesis of cholera toxin.     

Strains of Vibrio cholerae serogroups O1 and O139 that produce the basic protective antigens

To find out stable and effective producers of major protective antigens intended for use as components of cholera chemical vaccine against V. cholerae strains of serogroups O and O139, the comparative analysis of the production of cholera toxin, toxin-coregulated pili (TCP), antigens O1 and O139, polysaccharide capsule and outer membrane protein OmpU in different V. cholerae strains groups O1 and O139 has been made. V. cholerae strain KM68, serogroup O1, has been found capable of the production of antigen O1, serovar Ogawa, protein OmpU at a sufficiently high level and the hyperproduction of cholera toxin and TCP, and thus suitable for use in the manufacture of cholera bivalent vaccine as the source of these antigens. Specially selected alysogenic noncapsular strain KM137 of serogroup O139, characterized by a high and stable level of the biosynthesis of this somatic antigen when grown in both laboratory and production conditions, may serve as the produces of antigen O139.     

Filamentous phages linked to virulence of Vibrio cholerae

The pathogenicity of Vibrio cholerae depends upon its production of two key virulence factors: the toxin co-regulated pilus (TCP), a colonization factor, and cholera toxin, an exotoxin. Genes encoding both virulence factors were introduced into V. cholerae by horizontal gene transfer. The toxin genes are contained within the genome of CTXphi, an integrated filamentous phage identified in 1996. In the past few years, it has been shown that CTXphi relies on novel processes for phage DNA integration, replication and secretion. In addition, expression of CTXphi genes--including the toxin genes--and transmission of CTXphi were recently found to be promoted by the antirepressor RstC, which is encoded within RS1, a newly described satellite phage of CTXphi. The genetic island that encodes TCP has also been described as a filamentous phage; however, these sequences are unlike the genome of any previously characterized filamentous phage.     

El Tor型霍乱弧菌及其细胞壁缺陷型分子遗传学背景的研究

El Tor 型霍乱弧菌(以下简称 El Tor 弧菌)可以在人工培养条件下长期存活。当微环境改变时可形成细胞壁有不同程度缺陷的菌株如抗噬菌体突变株或 L 型菌株。我们以 DNA 酶切图谱和 El Tor 弧菌溶血素、神经氨酸酶基因探针杂交图谱为参数对 El Tor 弧菌的野生型及其细胞壁缺陷型变异株在遗传背景上进行了比较分析研究。结果提示细胞壁缺陷型菌株与其野生型在DNA 水平上高度同源。此外,文中还介绍了一种从 L 型菌株中制备 DNA 的方法。     

Vibrion variability under the action of antibiotics]

Tetracycline, streptomycin and monomycin resistant variants of the cholera and NAG-vibrios were obtained by means of repeated passages on nutrient media with increasing concentrations of the antibiotics (114 variants V. cholerae asiaticae, 1337 variants of V. cholerae eltor and 299 variants of NAG-vibrios of the 1st Heiberg group). The highest number of the antibiotic resistant variants was obtained under the effect of streptomycin and the resistance level to it was much higher (up to 8000 gamma/ml) than that to tetracycline or monomycin (160 or 320 gamma/ml respectively). The study of the differential-diagnostic properties of the above vibrios showed that 14.8 per cent of the strains of V. cholerae asiaticae and 4.6 per cent of the strains of V. cholerae eltor became non-typical with respect to the colony morphology and fermentative properties. Their agglutinability with the species or type specific cholera sera partially decreased. Nine per cent out of 299 antibiotic resistant NAG-vibrios had changes only in the colony structure. None of them changed their fermentative properties or acquired even minor capacity for agglutination with cholera sera or lysing with specific bacteriophages. The described changes in the properties of the antibiotic resistant cholera and NAG-vibrios were not stable and disappeared after 2- or 3-fold passages on media containing no antibiotics.     

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.     

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.     

Phenotypical analysis of heterogenic Vibrio cholerae strain Dacca 35 Ogawa

The comparative analysis of the production of the main pathogenicity factors by toxigenic and non-toxigenic clones of V. cholerae natural classical strain Dacca 35 Ogawa has been carried out. The data obtained in this analysis indicate that the appearance of turbid colonies, not synthesing cholera toxin, is linked with the production of an exopolysaccharide layer on the outer surface of the cells, which determines their morphology. The suggestion has been made that the regulatory gene toxR controls the expression of not only cholera toxin, protein OmpU, but also exopolysaccharide.     

Experimental resistance of Vibrio cholerae el tor to nalidixic acid and fluoroquinolones]

It was shown that sensitivity of Vibrio cholerae eltor P-5879 to tetracycline, levomycetin, furazolidone, trimethoprim/sulfamethoxazole, aminoglycosides, beta-lactams, rifampicin, quinolones in vitro correlated with drugs efficacy in the treatment of experimental cholera of albino mice. Mutants of V. cholerae eltor P-5879 Nalr resistant to nalidixic acid (MIC 160-200 mg/l) formed with frequency 10(-9)-110(-8) had no cross resistance to fluoroquinolones. But the efficacy of ofloxacin, lomefloxacin, norfloxacin against these mutants in vivo reduced, though it was not changed in vitro. Mutants of V. cholerae eltor P-5879 resistant to fluoroquinolones and selected after culturing in the presence of the drugs had cross resistance to all quinolones studied. Infection caused by Cpfr mutant could not be treated with nalidixic acid and fluoroquinolones, therapeutic efficacy of rifampicin and beta-lactams, also reduced though sensitivity in vitro was not changed. The results of investigation proves the necessity of quinolones use for cholerae treatment as it is recommended for other severe enteric infections.