[Bacteriophage phi297--the new species of temperate phages Pseudomonas aeruginosa with a mosaic genome: potential use in phagotherapy].

The genome of halo-forming temperate Pseudomonas aeruginosa phage phi297 and lytic activity of its virulent mutant were studied. A mosaic structure was revealed for phi297 genome by its complete sequencing. The phi97 genome was partly homologous to the genomes of phages D3 and F116. High lytic activity was assumed for temperate P. aeruginosa bacteriophage phi297 on the basis of morphological features of negative colonies. Virulent mutant phi297vir, which was capable oflysing bacteria, while the wild-type phage induced lysogeny, was isolated. Lytic activity was compared for phi297 and the phages from commercial mixtures of two manufacturers (facilities of Nizhnii Novgorod and Perm'). Phage phi297 caused lysis of the mutant PAO1 bacteria that were resistant to the phages from commercial preparations, but the lystic activity spectrum of phi297 was narrower that the spectra of the commercial phages. The use of nonreverting virulent mutants of certain temperate bacteriophages was proposed for the treatment of P. aeruginosa infections.

[Genome instability of Pseudomonas aeruginosa phages of the EL species: examination of virulent mutants].

The article continues a study of pseudolysogeny in Pseudominas aeruginosa infected with phiKZ-like phages of the EL species. Analysis was performed for several newly isolated virulent mutants of EL phages (EL and RU) that were virulent (capable of causing lysis of bacteria infected with the wild-type phage) and a lower extent of opalescence of negative colonies (NCs). Wile-type recombinants were detected in crosses of virulent mutants of phages EL and RU to confirm the polygenic control of virulence. Since a deletion mutation was found in one of the virulent EL mutants and high genetic instability was characteristic of another mutant, a mobile genetic element was assumed to play a role in mutagenesis. Pseudolysogeny of bacteria provides for horizontal gene transfer between different bacterial strains. Hence, sequencing of the phage genome and demonstration of the lack of toxic gene products are insufficient for the phage to be included into a therapeutic mixture. To use live phages, it is essential to study in detail the possible consequences of their interaction with host bacteria.

[Interspecific migration and evolution of bacteriophages of the genus phiKZ: the purpose and criteria of the search for new phiKZ-like bacteriophages].

Some properties of bacteriophages with large (200 kb and more) sequenced genomes have been compared. In contrast to other large bacteriophages from different families, bacteriophages active on pseudomonads of various species (phiKZ-like bacteriophages) have some common features, which suggests their phylogenetic relationship and independence of their evolution as a result of migration among bacteria of this family. Among such common features are the absence in the genomes of these phages of sites sensitive to endonuclease PstI, the absence of genes encoding DNA polymerases that are similar to the known enzymes of this type, possible dependence of replication of the phage genome on bacterial DNA polymerase, and a considerably larger average gene size as compared to that for other phages. Criteria are suggested for searching for novel phiKZ-like bacteriophages: the size of a phage particle, production by bacteria infected with such phages of a large amount of highly viscous mucus. Taking into account the use of these bacteriophages in therapeutic preparations (due to a broad spectrum of lytic activity) and a poor knowledge of a majority of their gene products, it seems necessary to perform a more comprehensive genetic analysis of phages of this genus or their mutants for selecting those adequate for phage therapy.

[Ambivalent bacteriophages of different species active on Escherichia coli K12 and Salmonella sps. strains].

A study was made of several bacteriophages (including phages U2 and LB related to T-even phages of Escherichia coli) that grow both on E. coli K12 and on some Salmonella strains. Such phages were termed ambivalent. T-even ambivalent phages (U2 and LB) are rare and have a limited number of hosts among Salmonella strains. U2 and LB are similar to canonical E. coli-specific T-even phages in morphological type and size of the phage particle and in reaction with specific anti-T4 serum. Phages U2 and LB have identical sets of structural proteins, some of which are similar in size to structural proteins of phages T2 and T4. DNA restriction patterns of phages U2 and LB differ from each other and from those of T2 and T4. Still, DNAs of all four phages have considerable homology. Unexpectedly, phages U2 and LB grown on Salmonella bungori were unstable during centrifugation in a CsCl gradient. Ambivalent bacteriophages were found in species other than T-even phages and were similar in morphotype to lambdoid and other E. coli phages. One of the ambivalent phages was highly similar to well-known Felix01, which is specific for Salmonella. Ambivalent phages can be used to develop a new set for phage typing in Salmonella. An obvious advantage is that ambivalent phages can be reproduced in the E. coli K12 laboratory strain, which does not produce active temperate phages. Consequently, the resulting typing phage preparation is devoid of an admixture of temperate phages, which are common in Salmonella. The presence of temperate phages in phage-typing preparations may cause false-positive results in identifying specific Salmonella strains isolated from the environment or salmonellosis patients. Ambivalent phages are potentially useful for phage therapy and prevention of salmonellosis in humans and animals.

[Comparison of the genome for phylogenetically related bacteriophages phiKZ and EL of Pseudomonas aeruginosa: evolutionary aspects and minimal genome size].

Bacteriophages of the family Myoviridae represent one of the most widespread domains of the biosphere substantially affecting the ecological balance of microorganisms. Interestingly, sequence analysis of genomic DNAs of large bacteriophages revealed many genes coding for proteins with unknown functions. A new approach is proposed to improve the functional identification of genes. This approach is based on comparing the genome sequence for phylogenetically and morphologically related phages showing no considerable homology at the level of genomic DNA. It is assumed that gene functions essential for the development of phages of a given family are conserved and that the corresponding genes code for similar orthologous proteins even when lacking sequence homology. The genome was sequenced and compared for two Pseudomonas aeruginosa giant bacteriophages, phiKZ and EL, which belong to a group of (phiKZ-related phages. A substantial difference in genome organization was observed, suggesting specific features of phage evolution. In addition, the problem of the minimal genome of the superfamily is discussed on the basis of the difference in size and structure between the phiKZ and EL genomes.

[Design of an algorithm for the numerical classification of viruses]. / Postroenie algoritma chislovoi klassifikatsii virusov.

The data are presented dealing with the construction of algorithm of numerical classification of RNA- and DNA-containing viruses of vertebrates. The possibility of using of a limited number of parameters with certain coefficients was demonstrated. Suitable parameters for this purpose were elucidated and coefficients (weights) for them determined.