Complete Genome Sequence of IME15, the First T7-Like Bacteriophage Lytic to Pan-Antibiotic-Resistant Stenotrophomonas maltophilia

T7-like bacteriophages are a class of virulent bacteriophages which have a clearer genetic background and smaller genomes than other phages. In addition, it grows faster and is easier to culture than other phages. At present, the numbers of available T7-like bacteriophage genomes and Stenotrophomonas maltophilia genomes are small, and IME15 is the first T7-like virulent Stenotrophomonas phage whose sequence has been reported. It shows effective lysis of S. maltophilia. Here we announce its complete genome, and major findings from its annotation are described.     

Prophage Tracer: precisely tracing prophages in prokaryotic genomes using overlapping split-read alignment

The life cycle of temperate phages includes a lysogenic cycle stage when the phage integrates into the host genome and becomes a prophage. However, the identification of prophages that are highly divergent from known phages remains challenging. In this study, by taking advantage of the lysis-lysogeny switch of temperate phages, we designed Prophage Tracer, a tool for recognizing active prophages in prokaryotic genomes using short-read sequencing data, independent of phage gene similarity searching. Prophage Tracer uses the criterion of overlapping split-read alignment to recognize discriminative reads that contain bacterial (attB) and phage (attP) att sites representing prophage excision signals. Performance testing showed that Prophage Tracer could predict known prophages with precise boundaries, as well as novel prophages. Two novel prophages, dsDNA and ssDNA, encoding highly divergent major capsid proteins, were identified in coral-associated bacteria. Prophage Tracer is a reliable data mining tool for the identification of novel temperate phages and mobile genetic elements. The code for the Prophage Tracer is publicly available at https://github.com/WangLab-SCSIO/Prophage_Tracer.     

Lactococcal phage genes involved in sensitivity to AbiK and their relation to single-strand annealing proteins

Lactococcal phage mutants insensitive to the antiviral abortive infection mechanism AbiK are divided into two classes. One comprises virulent phages that result from DNA exchanges between a virulent phage and the host chromosome. Here, we report the analysis of the second class of phage mutants, which are insensitive to AbiK as a result of a single nucleotide change causing an amino acid substitution. The mutated genes occupy the same position in the various lactococcal phage genomes, but the deduced proteins do not share amino acid sequence similarity. Four nonsimilar proteins involved in the sensitivity to AbiK (Sak) were identified. Two of these Sak proteins are related to Erf and RAD52, single-strand annealing proteins involved in homologous recombination.     

Properties of the new D3-like Pseudomonas aeruginosa bacteriophage phiPMG1: Genome structure and prospects for the use in phage therapy

Results of studying the novel virulent phage phiPMG1 active on Pseudomonas aeruginosa are presented. It is shown that phiPMG1 exhibits significant homology and the similarity in the overall structure with the genome of a temperate phage converts D3. Phage phiPMG1 differs from D3 in that it fails to stably lysogenize bacteria and can grow on strains carrying plasmids that cause growth inhibition of phage D3 and some other phages. This significantly diminishes the probability of horizontal gene transfer with phage phiPMG1 and suggests the possible employment of this phage in phage therapy. A comparison of phages phiPMG1 and D3 structures of genomes in demonstrated not only high homology of 65 genes, but also the presence of 16 genes in the phiPMG1 genome that were not included in the in NCBI database. Apparently, the evolution of genomes in phages of this species is mostly associated with migrations into other species of bacteria, and recombinations with phages of other species (for example, F116). A detailed analysis of structure of one region genomes, which significant nonhomology for the three D3-like phages (D3, phiPMG1 and PAJU2), revealed that the phiPMG1 genome possible closest to a hypothetical genome of ancestral phage of this species.     

Morphological and genetic analysis of three bacteriophages of Serratia marcescens isolated from environmental water

Increases in multidrug-resistant strains of Serratia marcescens are of great concern in pediatrics, especially in neonatal intensive care units. In the search for bacteriophages to control infectious diseases caused by multidrug-resistant S. marcescens , three phages (KSP20, KSP90, and KSP100) were isolated from environmental water and were characterized morphologically and genetically. KSP20 and KSP90 belonged to morphotype A1 of the family Myoviridae , and KSP100 belonged to morphotype C3 of the family Podoviridae . Analysis of the DNA region coding virion proteins, together with their morphological features, indicated that KSP20, KSP90, and KSP100 were related to the P2-like phage (temperate), T4-type phage (virulent), and phiEco32 phage (virulent), respectively. Based on amino acid sequences of the major capsid protein, KSP90 formed a new branch with a Stenotrophomonas maltophilia phage, Smp14, in the T4-type phage phylogeny. Both Smp14 and phiEco32 have been reported as potential therapeutic phages. These results suggest that KSP90 and KSP100 may be candidate therapeutic phages to control S. marcescens infection.     

Erratum: Causes and Consequences of Bacteriophage Diversification via Genetic Exchanges across Lifestyles and Bacterial Taxa

Bacteriophages (phages) evolve rapidly by acquiring genes from other phages. This results in mosaic genomes. Here, we identify numerous genetic transfers between distantly related phages and aim at understanding their frequency, consequences, and the conditions favoring them. Gene flow tends to occur between phages that are enriched for recombinases, transposases, and nonhomologous end joining, suggesting that both homologous and illegitimate recombination contribute to gene flow. Phage family and host phyla are strong barriers to gene exchange, but phage lifestyle is not. Even if we observe four times more recent transfers between temperate phages than between other pairs, there is extensive gene flow between temperate and virulent phages, and between the latter. These predominantly involve virulent phages with large genomes previously classed as low gene flux, and lead to the preferential transfer of genes encoding functions involved in cell energetics, nucleotide metabolism, DNA packaging and injection, and virion assembly. Such exchanges may contribute to the observed twice larger genomes of virulent phages. We used genetic transfers, which occur upon coinfection of a host, to compare phage host range. We found that virulent phages have broader host ranges and can mediate genetic exchanges between narrow host range temperate phages infecting distant bacterial hosts, thus contributing to gene flow between virulent phages, as well as between temperate phages. This gene flow drastically expands the gene repertoires available for phage and bacterial evolution, including the transfer of functional innovations across taxa.     

DSIR: Assessing the Design of Highly Potent siRNA by Testing a Set of Cancer-Relevant Target Genes

Chemically synthesized small interfering RNA (siRNA) is a widespread molecular tool used to knock down genes in mammalian cells. However, designing potent siRNA remains challenging. Among tools predicting siRNA efficacy, very few have been validated on endogenous targets in realistic experimental conditions. We previously described a tool to assist efficient siRNA design (DSIR, Designer of siRNA), which focuses on intrinsic features of the siRNA sequence. Here, we evaluated DSIR’s performance by systematically investigating the potency of the siRNA it designs to target ten cancer-related genes. mRNA knockdown was measured by quantitative RT-PCR in cell-based assays, revealing that over 60% of siRNA sequences designed by DSIR silenced their target genes by at least 70%. Silencing efficacy was sustained even when low siRNA concentrations were used. This systematic analysis revealed in particular that, for a subset of genes, the efficiency of siRNA constructs significantly increases when the sequence is located closer to the 5′-end of the target gene coding sequence, suggesting the distance to the 5′-end as a new feature for siRNA potency prediction. A new version of DSIR incorporating these new findings, as well as the list of validated siRNA against the tested cancer genes, has been made available on the web (http://biodev.extra.cea.fr/DSIR).     

Phylogenetic and complementation analysis of a single-stranded DNA binding protein family from lactococcal phages indicates a non-bacterial origin

Background

The single-stranded-nucleic acid binding (SSB) protein superfamily includes proteins encoded by different organisms from Bacteria and their phages to Eukaryotes. SSB proteins share common structural characteristics and have been suggested to descend from an ancestor polypeptide. However, as other proteins involved in DNA replication, bacterial SSB proteins are clearly different from those found in Archaea and Eukaryotes. It was proposed that the corresponding genes in the phage genomes were transferred from the bacterial hosts. Recently new SSB proteins encoded by the virulent lactococcal bacteriophages (Orf14_bIL67-like proteins) have been identified and characterized structurally and biochemically.

Methodology/Principal Findings

This study focused on the determination of phylogenetic relationships between Orf14_bIL67-like proteins and other SSBs. We have performed a large scale phylogenetic analysis and pairwise sequence comparisons of SSB proteins from different phyla. The results show that, in remarkable contrast to other phage SSBs, the Orf14_bIL67–like proteins form a distinct, self-contained and well supported phylogenetic group connected to the archaeal SSBs. Functional studies demonstrated that, despite the structural and amino acid sequence differences from bacterial SSBs, Orf14_bIL67 protein complements the conditional lethal ssb-1 mutation of Escherichia coli.

Conclusions/Significance

Here we identified for the first time a group of phages encoded SSBs which are clearly distinct from their bacterial counterparts. All methods supported the recognition of these phage proteins as a new family within the SSB superfamily. Our findings suggest that unlike other phages, the virulent lactococcal phages carry ssb genes that were not acquired from their hosts, but transferred from an archaeal genome. This represents a unique example of a horizontal gene transfer between Archaea and bacterial phages.     

Molecular characterization and comparison of 38 virulent and temperate bacteriophages of Streptococcus lactis

Thirty-three virulent and five temperate phages of Streptococcus lactis and Streptococcus cremoris were differentiated into three groups by DNA homology. A complete lack of DNA homology was demonstrated between the phage groups. Within each group, large parts of the phage genomes were homologous except for a few phages. One group consisted of five temperate and two virulent phages suggesting that virulent phages isolated during abnormal fermentations and temperate phages isolated after induction from lactic streptococcal starter cultures may be related to one another. We observed a good correlation between the grouping of phages by DNA homology and by their protein composition since within the same DNA homology group, the protein composition of a phage exhibited some similarities with that of the other phages of the group. Therefore, the DNA homologies seemed to be located, at least, in the region coding for the structural proteins. By immunoblotting, we confirmed the relatedness between the proteins of the phages belonging to the same DNA homology group. The important host range factor in bacterium-phage interactions appeared to be an unreliable criterion in determining phage taxonomy.     

The Role of Horizontal Gene Transfer by Bacteriophages in the Origin of Pathogenic Bacteria

The review considers the involvement of bacteriophages in transferring genes, which determine bacterial pathogenicity, and the increasing role of comparative genomics and genetics of bacteria and bacteriophages in detecting new cases of horizontal gene transfer. Examples of phage participation in this process proved to a different extent are described. Emphasis is placed on the original work carried out in Russia and focused on bacteriophages (temperate transposable phages and giant virulent KZ-like phages) of conditional pathogen Pseudomonas aeruginosa.Consideration is given to the possible lines of further research of the role of bacteriophages in the infection process and, in particular, the role of virulent phages, whose products are similar to those of pathogenic bacteria, in modification of clinical signs of infectious diseases and in evolution. An attempt is made to predict the possible direction of pathogen evolution associated with development of new treatment strategies and generation of new specific niches.     

Comparative Genomic Analysis of Ten Streptococcus pneumoniae Temperate Bacteriophages

Streptococcus pneumoniae is an important human pathogen that often carries temperate bacteriophages. As part of a program to characterize the genetic makeup of prophages associated with clinical strains and to assess the potential roles that they play in the biology and pathogenesis in their host, we performed comparative genomic analysis of 10 temperate pneumococcal phages. All of the genomes are organized into five major gene clusters: lysogeny, replication, packaging, morphogenesis, and lysis clusters. All of the phage particles observed showed a Siphoviridae morphology. The only genes that are well conserved in all the genomes studied are those involved in the integration and the lysis of the host in addition to two genes, of unknown function, within the replication module. We observed that a high percentage of the open reading frames contained no similarities to any sequences catalogued in public databases; however, genes that were homologous to known phage virulence genes, including the pblB gene of Streptococcus mitis and the vapE gene of Dichelobacter nodosus, were also identified. Interestingly, bioinformatic tools showed the presence of a toxin-antitoxin system in the phage φSpn_6, and this represents the first time that an addition system in a pneumophage has been identified. Collectively, the temperate pneumophages contain a diverse set of genes with various levels of similarity among them.Streptococcus pneumoniae (the pneumococcus) is an important human pathogen and a major etiological agent of pneumonia, bacteremia, and meningitis in adults and of otitis media in children. The casualties due to the pneumococcus are estimated to be over 1.6 million deaths per year, and most of these deaths are of young children in developing countries (40). S. pneumoniae is also a human commensal that resides in the upper respiratory tract, and it is asymptomatically carried in the nasopharynx of up to 60% of the normal population (48).Bacteriophages of S. pneumoniae (pneumophages) were first identified in 1975 from samples isolated from throat swabs of healthy children by two independent groups (46, 65). Since then, pneumophages have been identified from different sources and a variety of locations (44). The abundance of temperate bacteriophages in S. pneumoniae has been reported in different studies in the past (6, 54). Up to 76% of clinical isolates have been showed to contain prophages (or prophage remnants) when studied with a DNA probe specific for the major autolysin gene, lytA, which hybridizes with many of the endolysin genes of temperate pneumococcal phages (54). Hybridization analyses have identified highly similar prophages among pneumococcal clinical isolates even of different capsular serotypes, a result which indicates the widespread distribution of these mobile genetic elements among virulent strains (26).Only three S. pneumoniae bacteriophage genomes have been characterized in detail, and their sequences have been determined. Dp-1 and Cp-1 are lytic bacteriophages, whereas MM1 is a temperate pneumophage (45, 50, 52). Genes coding for virulence factors such as toxins or secreted enzymes have been associated with the presence of prophages in both gram-negative (67) and gram-positive bacteria, such as Streptococcus pyogenes (7) and Staphylococcus aureus (23). Because a considerable number of toxin genes are located in prophages, phage dynamics are of apparent importance for bacterial pathogenesis. Unfortunately, the role of temperate bacteriophages in the virulence of S. pneumoniae remains mostly unknown.Recently, the availability of relatively inexpensive next-generation sequencing technologies has permitted the complete genomic analysis of dozens of genomes of pneumococcal clinical isolates. In this report, we present a comparative genomic analysis of 10 pneumophages identified in the genomes of newly sequenced S. pneumoniae strains. The proteome of these phages has been predicted and annotated by comparative sequence analyses by using the available databases at the National Center for Biotechnological Information website (http://www.ncbi.nlm.nih.gov/). This systematic characterization of pneumophage genomes provides for a substantial increase in our knowledge of the global proteome and the overall genetic diversity of this important human pathogen. The comparative analysis of multiple temperate bacteriophages from a single species offers a unique opportunity to study one of the mechanisms of lateral gene transfer that drive prokaryotic genetic diversity.     

Reticulate representation of evolutionary and functional relationships between phage genomes

Bacteriophage genomes show pervasive mosaicism, indicating the importance of horizontal gene exchange in their evolution. Phage genomes represent unique combinations of modules, each of them with a different phylogenetic history. The traditional classification, based on a variety of criteria such as nucleic acid type (single/double-stranded DNA/RNA), morphology, and host range, appeared inconsistent with sequence analyses. With the genomic era, an ever increasing number of sequenced phages cannot be classified, in part due to a lack of morphological information and in part to the intrinsic incapability of tree-based methods to efficiently deal with mosaicism. This problem led some virologists to call for a moratorium on the creation of additional taxa in the order Caudovirales, in order to let virologists discuss classification schemes that might better suit phage evolution. In this context, we propose a framework for a reticulate classification of phages based on gene content. Starting from gene families, we built a weighted graph, where nodes represent phages and edges represent phage-phage similarities in terms of shared genes. We then apply various measures of graph topology to analyze the resulting graph. Most double-stranded DNA phages are found in a single component. The values of the clustering coefficient and closeness distinguish temperate from virulent phages, whereas chimeric phages are characterized by a high betweenness coefficient. We apply a 2-step clustering method to this graph to generate a reticulate classification of phages: Each phage is associated with a membership vector, which quantitatively characterizes its membership to the set of clusters. Furthermore, we cluster genes based on their "phylogenetic profiles" to define "evolutionary cohesive modules." In virulent phages, evolutionary modules span several functional categories, whereas in temperate phages they correspond better to functional modules. Moreover, despite the fact that modules only cover a fraction of all phage genes, phage groups can be distinguished by their different combination of modules, serving the bases for a higher level reticulate classification. These 2 classification schemes provide an automatic and dynamic way of representing the relationships within the phage population and can be extended to include newly sequenced phage genomes, as well as other types of genetic elements.     

The dilemma of phage taxonomy illustrated by comparative genomics of Sfi21-like Siphoviridae in lactic acid bacteria

The complete genome sequences of two dairy phages, Streptococcus thermophilus phage 7201 and Lactobacillus casei phage A2, are reported. Comparative genomics reveals that both phages are members of the recently proposed Sfi21-like genus of Siphoviridae, a widely distributed phage type in low-GC-content gram-positive bacteria. Graded relatedness, the hallmark of evolving biological systems, was observed when different Sfi21-like phages were compared. Across the structural module, the graded relatedness was represented by a high level of DNA sequence similarity or protein sequence similarity, or a shared gene map in the absence of sequence relatedness. This varying range of relatedness was found within Sfi21-like phages from a single species as demonstrated by the different prophages harbored by Lactococcus lactis strain IL1403. A systematic dot plot analysis with 11 complete L. lactis phage genome sequences revealed a clear separation of all temperate phages from two classes of virulent phages. The temperate lactococcal phages share DNA sequence homology in a patchwise fashion over the nonstructural gene cluster. With respect to structural genes, four DNA homology groups could be defined within temperate L. lactis phages. Closely related structural modules for all four DNA homology groups were detected in phages from Streptococcus or Listeria, suggesting that they represent distinct evolutionary lineages that have not uniquely evolved in L. lactis. It seems reasonable to base phage taxonomy on data from comparative genomics. However, the peculiar modular nature of phage evolution creates ambiguities in the definition of phage taxa by comparative genomics. For example, depending on the module on which the classification is based, temperate lactococcal phages can be classified as a single phage species, as four distinct phage species, or as two if not three different phage genera. We propose to base phage taxonomy on comparative genomics of a single structural gene module (head or tail genes). This partially phylogeny-based taxonomical system still mirrors some aspects of the current International Committee on Taxonomy in Virology classification system. In this system the currently sequenced lactococcal phages would be grouped into five genera: c2-, sk1, Sfi11-, r1t-, and Sfi21-like phages.     

Functional and structural basis for a bacteriophage homolog of human RAD52

In eukaryotes, homologous recombination proteins such as RAD51 and RAD52 play crucial roles in DNA repair and genome stability. Human RAD52 is a member of a large single-strand annealing protein (SSAP) family [1] and stimulates Rad51-dependent recombination [2, 3]. In prokaryotes and phages, it has been difficult to establish the presence of RAD52 homologs with conserved sequences. Putative SSAPs were recently found in several phages that infect strains of Lactococcus lactis[4]. One of these SSAPs was identified as Sak and was found in the virulent L. lactis phage ul36, which belongs to the Siphoviridae family [4, 5]. In this study, we show that Sak is homologous to the N terminus of human RAD52. Purified Sak binds single-stranded DNA (ssDNA) preferentially over double-stranded DNA (dsDNA) and promotes the renaturation of long complementary ssDNAs. Sak also binds RecA and stimulates homologous recombination reactions. Mutations shown to modulate RAD52 DNA binding [6] affect Sak similarly. Remarkably, electron-microscopic reconstruction of Sak reveals an undecameric (11) subunit ring, similar to the crystal structure of the N-terminal fragment of human RAD52 [7, 8]. For the first time, we propose a viral homolog of RAD52 at the amino acid, phylogenic, functional, and structural levels.     

Automated classification of tailed bacteriophages according to their neck organization

Background

The genetic diversity observed among bacteriophages remains a major obstacle for the identification of homologs and the comparison of their functional modules. In the structural module, although several classes of homologous proteins contributing to the head and tail structure can be detected, proteins of the head-to-tail connection (or neck) are generally more divergent. Yet, molecular analyses of a few tailed phages belonging to different morphological classes suggested that only a limited number of structural solutions are used in order to produce a functional virion. To challenge this hypothesis and analyze proteins diversity at the virion neck, we developed a specific computational strategy to cope with sequence divergence in phage proteins. We searched for homologs of a set of proteins encoded in the structural module using a phage learning database.

Results

We show that using a combination of iterative profile-profile comparison and gene context analyses, we can identify a set of head, neck and tail proteins in most tailed bacteriophages of our database. Classification of phages based on neck protein sequences delineates 4 Types corresponding to known morphological subfamilies. Further analysis of the most abundant Type 1 yields 10 Clusters characterized by consistent sets of head, neck and tail proteins. We developed Virfam, a webserver that automatically identifies proteins of the phage head-neck-tail module and assign phages to the most closely related cluster of phages. This server was tested against 624 new phages from the NCBI database. 93% of the tailed and unclassified phages could be assigned to our head-neck-tail based categories, thus highlighting the large representativeness of the identified virion architectures. Types and Clusters delineate consistent subgroups of Caudovirales, which correlate with several virion properties.

Conclusions

Our method and webserver have the capacity to automatically classify most tailed phages, detect their structural module, assign a function to a set of their head, neck and tail genes, provide their morphologic subtype and localize these phages within a “head-neck-tail” based classification. It should enable analysis of large sets of phage genomes. In particular, it should contribute to the classification of the abundant unknown viruses found on assembled contigs of metagenomic samples.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-1027) contains supplementary material, which is available to authorized users.     

Isolation and characterization of bacteriophages for avian pathogenic E. coli strains

Aims:  To isolate and characterize bacteriophages, and to evaluate its lytic performance against avian pathogenic Escherichia coli (APEC) strains with high patterns of antibiotic resistance, in order to select phages for a therapeutic product to treat colibacillosis in chickens.
Methods and Results:  Bacteriophages were isolated from poultry sewage and tested against 148 O-serotyped APEC strains. The morphological characterization of the bacteriophages was made by transmission electronic microscopy (TEM) observations and the genetic comparison between bacteriophages DNA was performed by restriction fragment length polymorphism (RFLP) patterns. Results showed that 70·5% of the tested E. coli strains were sensitive to a combination of three of the five isolated phages, that seemed to be virulent and taxonomically belong to the Caudovirales order. Two of them look like 16–19, T4-like phages ( Myoviridae ) and the third is a T1-like phage and belongs to Syphoviridae family. All of them are genetically different.
Conclusions:  It was possible to obtain a combination of three different lytic bacteriophages with broad lytic spectra against the most prevalent O-serotypes of APEC.
Significance and Impact of the Study:  Data reported in this study, presents an in vitro well studied phage product to be used as antimicrobial agent to treat colibacillosis in poultry industry.     

Manipulating or Superseding Host Recombination Functions: A Dilemma That Shapes Phage Evolvability

Phages, like many parasites, tend to have small genomes and may encode autonomous functions or manipulate those of their hosts''. Recombination functions are essential for phage replication and diversification. They are also nearly ubiquitous in bacteria. The E. coli genome encodes many copies of an octamer (Chi) motif that upon recognition by RecBCD favors repair of double strand breaks by homologous recombination. This might allow self from non-self discrimination because RecBCD degrades DNA lacking Chi. Bacteriophage Lambda, an E. coli parasite, lacks Chi motifs, but escapes degradation by inhibiting RecBCD and encoding its own autonomous recombination machinery. We found that only half of 275 lambdoid genomes encode recombinases, the remaining relying on the host''s machinery. Unexpectedly, we found that some lambdoid phages contain extremely high numbers of Chi motifs concentrated between the phage origin of replication and the packaging site. This suggests a tight association between replication, packaging and RecBCD-mediated recombination in these phages. Indeed, phages lacking recombinases strongly over-represent Chi motifs. Conversely, phages encoding recombinases and inhibiting host recombination machinery select for the absence of Chi motifs. Host and phage recombinases use different mechanisms and the latter are more tolerant to sequence divergence. Accordingly, we show that phages encoding their own recombination machinery have more mosaic genomes resulting from recent recombination events and have more diverse gene repertoires, i.e. larger pan genomes. We discuss the costs and benefits of superseding or manipulating host recombination functions and how this decision shapes phage genome structure and evolvability.     

Bacteriophage phi297, a new species of <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> temperate phages with a mosaic genome: Potential use in phage therapy

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 phi297 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 of lysing the wild-type phage bacteria, 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 lytic 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.