[Microevolution of cholera agent in the modern period].

AIM: To carry out comparative molecular genetic analysis of highly pathogenic atypical Vibrio cholerae strains biovar El Tor, isolated in the territory of RF, in order to determine micro-evolutionary alterations of cholera agent in the modern period. MATERIALS AND METHODS: 38 clinical strains have been examined by means of polymerase chain reaction, sequencing and MLVA-analysis. The selected strains were isolated at different periods of time during cholera epidemic complications and differed between each other in virulence. RESULTS: It is demonstrated that new variants have emerged in the course of short-term microevolution. Their genome structure and function differ from those of all previously known strains. The genome alterations have been caused by point mutations in ctxB u tcpA genes associated with virulence and located in CTXΦ prophage and pathogenicity island VPI-1 respectively, as well as by the extended deletion in pandemicity island VSP-II. Presented is the dynamics of genome structure and function alterations in modern strains. CONCLUSION: The discovered genomic alterations in the new variants of the agent evolved in the process of microevolution are indicative of their epidemic potential enhancement and probability of virulence potentiation.

[Genetic characterization of toxigenic Vibrio cholerae non-O1/non-O139 strains, isolated in the Middle Asia].

Here, we report the characterization of 22 clinical toxigenic V. cholerae non-O1/non-O139 strains isolated in the Middle Asia (Uzbekistan) in 1971-1990. PCR analysis has revealed that these strains contain the main virulence genes such as ctxA, zot, ace (CTXφ); rstC (RS1φ); tcpA, toxT, aldA (pathogenicity island VPI), but they lack both pandemic islands VSP-I and VSP-II specific to epidemic strains of O1 serogroup of El Tor biotype and O139 serogroup. Only two of the twenty two toxigenic strains have tcpA gene of El Tor type, one strain has tcpA gene of classical type, while nineteen other strains carry a new variant of this gene, designated as tcpA(uzb).. Nucleotide sequences analysis of virulence genes in toxigenic V. cholerae non-O1/non-O139 strains from Uzbekistan showed that they differ significantly from the sequences of these genes in epidemic O1 and O139 strain indicating that they belong to a separate line of evolution of virulent V. cholerae strains. For the first time it is shown that V. cholerae non-O1/non-O139 toxigenic strains of different serogroups may belong to the same clone.

[Standard algorithm of molecular typing of Yersinia pestis strains].

AIM: Development of the standard algorithm of molecular typing of Yersinia pestis that ensures establishing of subspecies, biovar and focus membership of the studied isolate. Determination of the characteristic strain genotypes of plague infectious agent of main and nonmain subspecies from various natural foci of plague of the Russian Federation and the near abroad. MATERIALS AND METHODS: Genotyping of 192 natural Y. pestis strains of main and nonmain subspecies was performed by using PCR methods, multilocus sequencing and multilocus analysis of variable tandem repeat number. RESULTS: A standard algorithm of molecular typing of plague infectious agent including several stages of Yersinia pestis differentiation by membership: in main and nonmain subspecies, various biovars of the main subspecies, specific subspecies; natural foci and geographic territories was developed. The algorithm is based on 3 typing methods--PCR, multilocus sequence typing and multilocus analysis of variable tandem repeat number using standard DNA targets--life support genes (terC, ilvN, inv, glpD, napA, rhaS and araC) and 7 loci of variable tandem repeats (ms01, ms04, ms06, ms07, ms46, ms62, ms70). The effectiveness of the developed algorithm is shown on the large number of natural Y. pestis strains. Characteristic sequence types of Y. pestis strains of various subspecies and biovars as well as MLVA7 genotypes of strains from natural foci of plague of the Russian Federation and the near abroad were established. CONCLUSION: The application of the developed algorithm will increase the effectiveness of epidemiologic monitoring of plague infectious agent, and analysis of epidemics and outbreaks of plague with establishing the source of origin of the strain and routes of introduction of the infection.

[Determination of genetic bases of auxotrophy in Yersinia pestis ssp. caucasica strains].

Based on the results of computer analysis of nucleotide sequences in strains Yersinia pestis and Y. pseudotuberculosis recorded in the files of NCBI GenBank database, differences between genes argA, aroG, aroF, thiH, and thiG of strain Pestoides F (subspecies caucasica) were found, compared to other strains of plaque agent and pseudotuberculosis microbe. Using PCR with calculated primers and the method of sequence analysis, the structure of variable regions of these genes was studied in 96 natural Y. pestis and Y. pseudotuberculosis strains. It was shown that all examined strains of subspecies caucasica, unlike strains of plague-causing agent of other subspecies and pseudotubercolosis microbe, had identical mutations in genes argA (integration of the insertion sequence IS100), aroG (insertion of ten nucleotides), aroF (inserion of IS100), thiH (insertion of nucleotide T), and thiG (deletion of 13 nucleotides). These mutations are the reason for the absence in strains belonging to this subspecies of the ability to synthesize arginine, phenylalanine, tyrosine, and vitamin B1 (thiamine), and cause their auxotrophy for these growth factors.

[Genetic characterization of Vibrio cholerae strains emerging in Russian Federation during 7th cholera pandemic].

AIM: Comparative molecular-genetic analysis of clinical Vibrio cholerae eltor biovariant strains isolated in Russia during various years. MATERIALS AND METHODS: Microbiological and biochemical methods were used for studies of 25 clinical strains of classic and eltor biovariant cholera, PCR testing and sequencing of various genes was also performed. RESULTS: Phenotypic and genetic analysis of clinical V. cholerae strains isolated in Russia during 7th cholera pandemic has confirmed that they belong to biovariant eltor. PCR testing of 21 isolates obtained from patients in 1970 - 2010 has shown that epidemic complications in Russia from 1993 were caused by altered V. cholerae biovariant eltor. Presence of classic cholera biovariant ctxB coding gene in cholera toxin coding CTX prophage is the genetic alteration of these variants, ctxB sequencing in altered variants has confirmed PCR data and shown 2 ctxB gene alleles (ctxB1 and ctxB7). Altered variants produced significantly more cholera toxin than typical strains. CONCLUSION: In 1970 - 2010 67.6% of clinical isolates were altered V. cholera biovariant eltor variants. These new variants were genetically diverse. Alteration of cholera eltor biovariant genome caused toxigenicity increase.

[Genetic bases of methionine dependence in Yersinia pestis strains of major and non-major subspecies].

Structural and functional organization of genes responsible for biosynthesis of amino acid methionine, which plays a leading role in cellular metabolism of bacteria, was studied in 24 natural Yersinia pestis strains of the major and minor subspecies from various natural plague foci located in the territory of Russian Federation and neighbouring foreign countries, and also in Y. pestis and Y. pseudotuberculosis strains recorded in the files of NCBI GenBank database. Conservatism of genes metA, metB, metC, metE, and metH as well as regulatory genes metR and metJ involved in biosynthesis of this amino acid was established. Sequencing of the variable locus of gene metB in natural Y. pestis strains of major and minor subspecies revealed that the reason for the methionine dependence of strains belonging to the major subspecies is a deletion of a single nucleotide (-G) in the 988 position from the beginning of the gene, whereas this dependence in strains belonging to subspecies hissarica results from the appearance of a single nucleotide (+G) insertion in the 989 position of gene metB. These mutations are absent in strains of the caucasica, altaica, and ulegeica subspecies of the plague agent and in strains of pseudotuberculosis microbe, which correlates with their capacity for methionine biosynthesis.

[Analysis of insect toxin complex gene variability of Yersinia pestis and Yersinia pseudotuberculosis strains].

The nucleotide sequences of the Tc's insect toxin complex genes have been analyzed in 18 natural strains of the main and non-main subspecies of Yersinia pestis isolated in different natural foci in the Russian Federation, as well as neighboring and more remote countries, as compared to the data on Y. pestis and Y. pseudotuberculosis strains stored in the NCBI GenBank database. The nucleotide sequences of these genes in plague agent strains have been found to be highly conserved, in contrast to those of the pseudotuberculosis agent. The sequences of two genes, tcaC and tccC2, have been found to be almost identical in Y. pestis strains, whereas other three genes (tcaA, tcaB, and tccC1) contain a few mutations, which, however, are not common for all strains of the plague agent. Exceptions are only strains of the Y. pestis biovar orientalis, whose tcaB gene is in a nonfunctional state due to a nucleotide deletion. The results suggest that the formation of the species Y. pestis as an agent of a natural focal infection with a transmissive mechanism has not resulted in degradation of the Tc's complex genes. Instead, these genes are likely to have been altered as the plague agent have been adapting to the new environment.

[Sequence analysis of the yadA, inv, and ail genes and their expression in the main and nonmain Yersinia pestis subspecies and Yersinia pseudotuberculosis].

The nucleotide sequences of the inv, yadA, and ail adhesin-invasin genes were analyzed in 24 strains of the main and nonmain Yersinia pestis subspecies, which were isolated from natural plague foci in Russia and neighbor countries, and ten Y. pseudotuberculosis strains. All of the five plague agent subspecies (main, caucasica, altaica, ulegeica, and hissarica) had the inv and yadA genes altered by insertion of the IS element and a single nucleotide deletion, respectively, as was earlier observed for the Y. pestis strains KIM and CO92. Consequently, the strains lacked functional activity of the Inv and YadA proteins. The ail gene of the main and ulegeica subspecies had a missense mutation, which replaced Val138 with Phe in the Ail protein. The strains of the caucasica subspecies had an AGT insertion in the ail gene, resulting in Ser148 insertion in the polypeptide chain. The changes in the ail sequence probably exerted no effect on ail expression, since the strains of all subspecies were resistant to blood serum complement.

[Structural and functional analysis of araN gene in the Yersinia pestis strains of various origin].

Structural and functional analysis of the araN gene involved in regulation of expression of diagnostically significant symptom (arabinose fermentation) was performed in the Yersinia pestis microorganism. Lack of arabinose fermentation in the Altai substrain, Hissar substrain, and Talas strains was shown to be due to solitary nucleotide insert into the araN gene. The insert is in the position 763 bp. The strains of the main, Caucasian, and Ulege substrains do not contain this mutation of the araN gene. The absence of the mutation correlates with ability to ferment arabinose.

[A study of the nucleotide sequence variability of rha locus genes of Yersinia pestis main and non-main subspecies].

A study of the structural and regulatory genes, determining rhamnose fermentation, that are located in the rha locus of the chromosome of Yersinia pestis main and non-main subspecies and of Yersinia pseudotuberculosis of serogroups I-III was performed. The nucleotide sequence of Y. pestis main subspecies differs substantially from those of non-main subspecies and Y. pseudotuberculosis by the presence of a nucleotide substitution in 671 bp location of rhaS gene resulting presumably in the Y. pestis non-main subsp inability to utilize rhamnose. This results in incapability of Y. pestis non-main subspecies to utilize rhamnose. Other nucleotide substitutions found in Y. pestis non-main subspecies strains influence only upon expression efficiency of this diagnostic criterion.

[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.