Complete genome sequences of two Pseudomonas aeruginosa temperate phages, MP29 and MP42, which lack the phage-host CRISPR interaction

We report the complete genome sequence of two Pseudomonas aeruginosa phages MP29 and MP42. Their genomes are similar to those of P. aeruginosa temperate phages DMS3 and MP22, whose lysogens are impaired in swarming motilities, involving the host CRISPR loci. Both MP29 and MP42 lysogens, however, were proficient in swarming, suggesting the absence of the phage-host CRISPR interaction.     

Complete genome sequence of Pseudomonas aeruginosa lytic bacteriophage PA1O which resembles temperate bacteriophage D3112

A novel Pseudomonas aeruginosa lytic bacteriophage (phage), PA1Ø, was isolated, and its genome was sequenced completely. This phage is able to lyse not only P. aeruginosa but also Staphylococcus aureus. Genome analysis of PA1Ø showed that it is similar to a P. aeruginosa temperate phage, D3112, with the exception of the absence of a c repressor-encoding gene, which is known to play a critical role in the maintenance of the lysogenic state of D3112 in P. aeruginosa.     

The CRISPR/Cas Adaptive Immune System of Pseudomonas aeruginosa Mediates Resistance to Naturally Occurring and Engineered Phages

Here we report the isolation of 6 temperate bacteriophages (phages) that are prevented from replicating within the laboratory strain Pseudomonas aeruginosa PA14 by the endogenous CRISPR/Cas system of this microbe. These phages are only the second identified group of naturally occurring phages demonstrated to be blocked for replication by a nonengineered CRISPR/Cas system, and our results provide the first evidence that the P. aeruginosa type I-F CRISPR/Cas system can function in phage resistance. Previous studies have highlighted the importance of the protospacer adjacent motif (PAM) and a proximal 8-nucleotide seed sequence in mediating CRISPR/Cas-based immunity. Through engineering of a protospacer region of phage DMS3 to make it a target of resistance by the CRISPR/Cas system and screening for mutants that escape CRISPR/Cas-mediated resistance, we show that nucleotides within the PAM and seed sequence and across the non-seed-sequence regions are critical for the functioning of this CRISPR/Cas system. We also demonstrate that P. aeruginosa can acquire spacer content in response to lytic phage challenge, illustrating the adaptive nature of this CRISPR/Cas system. Finally, we demonstrate that the P. aeruginosa CRISPR/Cas system mediates a gradient of resistance to a phage based on the level of complementarity between CRISPR spacer RNA and phage protospacer target. This work introduces a new in vivo system to study CRISPR/Cas-mediated resistance and an additional set of tools for the elucidation of CRISPR/Cas function.     

Compatibility of transposable phages of Escherichia coli and Pseudomonas aeruginosa. I. Co-development of phages Mu and D3112 and integration of phage D3112 into RP4::Mu plasmid in Pseudomonas aeruginosa cells

The possibility of using a model system (which included RP4::Mu plasmid and D3112 phage in Pseudomonas aeruginosa cells) for analysis of compatibility of transposable Escherichia coli phage Mu and P. aeruginosa phage D3112, as phages and transposons, was studied. No interaction was observed during the vegetative growth of phages. The majority of the hybrid RP4::Mu plasmids lost the Mu DNA after insertion of D3112 into RP4::Mu. The phenomenon was not a result of transposition immunity. We consider the loss of the Mu DNA as a consequence either of plasmid RP4::Mu instability in P. aeruginosa cells, because of the lack of functional Mu repressor, or of some D3112-encoded activity involved in its transposition. For the inambiguous conclusion on compatibility of two phages as transposons, it is necessary to modify the model system, eliminating the possibility of Mu phage replication--transposition.     

Characteristics of phages-transposons of Pseudomonas aeruginosa belonging to 2 groups distinguished by DNA-DNA homology

14 new transposable phages (TP) were isolated from approx. 200 clinical isolates of Pseudomonas aeruginosa. The frequent occurrence of TP of P. aeruginosa has been confirmed. There are at least two different groups of TP, namely, the group of D3112 and that of B3. The distinctive features of phages belonging to the groups are as follows: 1) low level of DNA-DNA homology (less than 10%), the whole region of homology in phage genomes of different groups being located on right genome end (29-38 kb); only one of phages of the B3 group shows an additional homology with D3112 DNA outside the above mentioned region; 2) a variable DNA is observed on the left end of the B3 group phage genomes and no such DNA is revealed on the left end of genomes of the D3112 group phages; 3) all phages of the B3 group have specific type of interaction with RPL11 plasmid, which distinguish them from phages of the D3112 group; 4) phages belonging to the two groups differ greatly in their growth in cells harbouring pMG7 plasmid which mediates production of PaeR7 endonuclease and in the number of DNA sites sensitive to SalGI, PstI, BglII endonucleases. Since some of the B3 group phage genomes possess BamH1 sites, resistance to this enzyme cannot be regarded as a general characteristics for all TP of P. aeruginosa, as it was earlier proposed. Some aspects of modular hypothesis of bacteriophage evolution concerning, in particular, the ways of module formation are discussed.     

Expression of the genome of Mu-like phage D3112 specific for Pseudomonas aeruginosa in Escherichia coli and Pseudomonas putida cells

The behavior of Escherichia coli cells carrying RP4 plasmid which contains the genome of a Mu-like D3112 phage specific for Pseudomonas aeruginosa was studied. Two different types of D3112 genome expression were revealed in E. coli. The first is BP4-dependent expression. In this case, expression of certain D3112 genes designated as "kil" only takes place when RP4 is present. As a result, cell division stops at 30 degrees C and cells form filaments. Cell division is not blocked at 42 degrees C. The second type of D3112 genome expression is RP4-independent. A small number of phage is produced independently of RP4 plasmid but this does not take place at 42 degrees C. No detectable quantity of the functionally active repressor of the phage was determined in E. coli (D3112). It is possible that the only cause for cell stability of E. coli (D3112) or E. coli (RP4::D3112) at 42 degrees C in the absence of the repressor is the fact of an extremely poor expression of D3112. In another heterologous system, P. putida both ways of phage development (lytic and lysogenic) are observed. This special state of D3112 genome in E. coli cells is proposed to be named "conditionally expressible prophage" or, in short, "conex-phage", to distinguish it from a classical lysogenic state when stability is determined by repressor activity. Specific blockade of cell division, due to D3112 expression, was also found in P. putida cells. It is evident that the kil function of D3112 is not specific to recognize the difference between division machinery of bacteria belonging to distinct species or genera. Protein synthesis is needed to stop cell division and during a short time period this process could be reversible. Isolation of E. coli (D3112) which lost RP4 plasmid may be regarded as an evidence for D3112 transposition in E. coli. Some possibilities for using the system to look for E. coli mutants with modified expression of foreign genes are considered.     

Use of deletion mutants of plasmid RP4::D3112 for the genetic analysis of Pseudomonas aeruginosa bacteriophage D3112

The hybrid plasmid RP4::D3112 becomes unstable in Escherichia coli K-12 cells under certain growth conditions. The deletion mutants of this plasmid are formed at a high frequency. All the deletions selected have a specific feature: they start in the left end, at the point of joining of plasmid and phage DNA, and remove different portions of the phage genome. The deletion mutants have been used for genetic mapping of D3112. We have localized the repressor gene cI (0-1.3 kb), 3 early genes (1.3-14.2 kb) and two groups of late genes (14.2-29.9 and 29.9-38 kb). Electron microscope studies of RP4::D3112 DNA and its deletion derivatives have shown that integration of D3112 genome in RP4 occurs through the ends of the genome, without permutations. It appears that bacterial nucleotide sequences joined to DNA from mature D3112 particles, to the right end of D3112 genome, are lost. Thus, transposable phages D3112 of Pseudomonas aeruginosa and E. coli Mu phage have some similarities in the genome organization and in the way of their integration into the host DNA.     

Antirepression System Associated with the Life Cycle Switch in the Temperate Podoviridae Phage SPC32H

Prophages switch from lysogenic to lytic mode in response to the host SOS response. The primary factor that governs this switch is a phage repressor, which is typically a host RecA-dependent autocleavable protein. Here, in an effort to reveal the mechanism underlying the phenotypic differences between the Salmonella temperate phages SPC32H and SPC32N, whose genome sequences differ by only two nucleotides, we identified a new class of Podoviridae phage lytic switch antirepressor that is structurally distinct from the previously reported Sipho- and Myoviridae phage antirepressors. The SPC32H repressor (Rep) is not cleaved by the SOS response but instead is inactivated by a small antirepressor (Ant), the expression of which is negatively controlled by host LexA. A single nucleotide mutation in the consensus sequence of the LexA-binding site, which overlaps with the ant promoter, results in constitutive Ant synthesis and consequently induces SPC32N to enter the lytic cycle. Numerous potential Ant homologues were identified in a variety of putative prophages and temperate Podoviridae phages, indicating that antirepressors may be widespread among temperate phages in the order Caudovirales to mediate a prudent prophage induction.     

Insights into the diversity of φRSM phages infecting strains of the phytopathogen Ralstonia solanacearum complex: regulation and evolution

The filamentous φRSM phages (φRSM1 and φRSM3) have integration/excision capabilities in the phytopathogenic bacterium Ralstonia solanacearum. In the present study, we further investigated φRSM-like sequences present in the genomes of R. solanacearum strains belonging to the four major evolutionary lineages (phylotypes I–IV). Based on bioinformatics and comparative genomic analyses, we found that φRSM homologs are highly diverse in R. solanacearum complex strains. We detected an open reading frame (ORF)15 located upstream of the gene for φRSM integrase, which exhibited amino acid sequence similarity to phage repressor proteins. ORF15-encoded protein (a putative repressor) was found to encode a 104-residue polypeptide containing a DNA-binding (helix-turn-helix) domain and was expressed in R. solanacearum lysogenic strains. This suggested that φRSM3-ORF15 might be involved in the establishment and maintenance of a lysogenic state, as well as in phage immunity. Comparison of the putative repressor proteins and their binding sites within φRSM-related prophages provides insights into how these regulatory systems of filamentous phages have evolved and diverged in the R. solanacearum complex. In conclusion, φRSM phages represent a unique group of filamentous phages that are equipped with innate integration/excision (ORF14) and regulatory systems (ORF15).     

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.     

Pseudomonas aeruginosa bacteriophages with DNA structure similar to the DNA structure of Mu1 phage. II. Evidence for similarity between D3112, B3, and B39 bacteriophages: analysis of DNA splits by restriction endonucleases, isolation of D3112 and B3 recombinant phages

It is found that bacteriophages B3 and B39 specific for Pseudomonas aeruginosa have the same genome structure as previously described phage D3112. On the right (S) end of their genomes a variable non-phage DNA is located (approximately 0.9-2.5 kilobases for different phages). It is probable that this variable DNa has its origin from different regions of bacterial chromosome. In genome of one of the phages, B3 phage, such variable DNA (not more than 150 base pairs) was found on the left end of DNA molecule. Isolation of a viable B3XD3112 recombinant phage and analysis of its genome with restriction technique and with studies of homo- and heteroduplex molecules had confirmed genetical relationship of B3 and D3112. Some essential non-homology of B3 and D3112 DNAs have been found on the right ends of genomes of the phages.     

<Emphasis Type="Italic">Pseudomonas Aeruginosa</Emphasis> bacteriophage SN: 3D-reconstruction of the capsid and identification of surface proteins by electron microscopy

The virulent Pseudomonas aeruginosa bacteriophage SN belongs to the PB1-like species of the Myoviridae family. The comparatively small (66,391 bp) DNA genome of this phage encodes 89 predicted open reading frames and the proteome involves more than 20 structural proteins. A 3D model of the phage capsid to approximately 18 Å resolution reveals certain peculiarities of capsomer structure typical of only this bacteriophage species. In the present work recombinant structural proteins SN gp22 and gp29 were expressed and purified; and specific polyclonal antibodies were obtained. Immuno-electron microscopy of purified phage SN using secondary gold-conjugated antibodies has revealed that gp29 forms a phage sheath, and gp22 decorates the capsid. Precise identification of multicopy major capsid proteins is essential for subsequent construction of gene-engineered phages bearing non-native peptides on their surfaces (phage display).     

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.     

Properties of natural interspecific hybrids of transposable phages of Pseudomonas aeruginosa: specific characteristics of phage PL24 transposition

Properties of natural hybrid transposable phages (TP) of Pseudomonas aeruginosa, including phage PL24 and lysogens for this phage, were studied. PL24 possesses the properties of TP from two previously described groups, B3 and D3112. Its genome, unlike the genome of D3112, contains many sites susceptible to the SalGI restriction endonuclease and possesses no more than 100 nucleotides of bacterial origin located at the left genome end. However, unlike B3, phage PL24 failed to induce auxotrophic mutants upon integration in the bacterial genome. This phage differed from both B3 and D3112 in sensitivity to chloroform treatment. A more detailed examination of a group containing 25 randomly isolated lysogens for phage PL24 revealed previously unknown processes occurring at early stages of bacterial lysogenization. There are at least two different modes of cell lysogenization with phage PL24. In the first case, the emerging lysogens contained a single prophage genome located (in each lysogen) at individual sites. In the second case, polylysogenic bacteria appeared, and, after primary integration of a phage genome, replicative transposition occurred at new sites (often accompanied by the appearance of prophage clusters at these sites). The choice of the mode of lysogenization can be determined both by differences in the physiological state of bacteria and by specific features of phage PL24, which possibly affect the time of repressor accumulation to the concentration sufficient for blocking phage growth or the stability of the lysogenic state.     

Introduction of the hybrid plasmid RP4::D3112 into Pseudomonas putida cells requires the presence of specific mutation in the phage genome

The wild type of D3112, a transposable phage of Pseudomonas aeruginosa can not be introduced as a portion of the hybrid plasmid RP4::D3112 into Pseudomonas putida cells. It is only possible when phage D3112 carries mutations designated lpc (lethal for P. putida and Escherichia coli). Analysis of heteroduplex molecules between DNAs of phages D3112w+ and D3112lpc demonstrated the absence of nonhomology regions, which suggests that lpc is a point mutation. The lpc2 mutation was located within the interval 20-29.9 kb of the phage genome.     

Morphological and genetic diversity of temperate phages in Clostridium difficile

Eight temperate phages were characterized after mitomycin C induction of six Clostridium difficile isolates corresponding to six distinct PCR ribotypes. The hypervirulent C. difficile strain responsible for a multi-institutional outbreak (NAP1/027 or QCD-32g58) was among these prophage-containing strains. Observation of the crude lysates by transmission electron microscopy (TEM) revealed the presence of three phages with isometric capsids and long contractile tails (Myoviridae family), as well as five phages with long noncontractile tails (Siphoviridae family). TEM analyses also revealed the presence of a significant number of phage tail-like particles in all the lysates. Southern hybridization experiments with restricted prophage DNA showed that C. difficile phages belonging to the family Myoviridae are highly similar and most likely related to previously described prophages phiC2, phiC5, and phiCD119. On the other hand, members of the Siphoviridae phage family are more genetically divergent, suggesting that they originated from distantly related ancestors. Our data thus suggest that there are at least three genetically distinct groups of temperate phages in C. difficile; one group is composed of highly related myophages, and the other two groups are composed of more genetically heterogeneous siphophages. Finally, no gene homologous to genes encoding C. difficile toxins or toxin regulators could be identified in the genomes of these phages using DNA hybridization. Interestingly, each unique phage restriction profile correlated with a specific C. difficile PCR ribotype.     

Core and accessory genome architecture in a group of Pseudomonas aeruginosa Mu-like phages

Background

Bacteriophages that infect the opportunistic pathogen Pseudomonas aeruginosa have been classified into several groups. One of them, which includes temperate phage particles with icosahedral heads and long flexible tails, bears genomes whose architecture and replication mechanism, but not their nucleotide sequences, are like those of coliphage Mu. By comparing the genomic sequences of this group of P. aeruginosa phages one could draw conclusions about their ontogeny and evolution.

Results

Two newly isolated Mu-like phages of P. aeruginosa are described and their genomes sequenced and compared with those available in the public data banks. The genome sequences of the two phages are similar to each other and to those of a group of P. aeruginosa transposable phages. Comparing twelve of these genomes revealed a common genomic architecture in the group. Each phage genome had numerous genes with homologues in all the other genomes and a set of variable genes specific for each genome. The first group, which comprised most of the genes with assigned functions, was named “core genome”, and the second group, containing mostly short ORFs without assigned functions was called “accessory genome”. Like in other phage groups, variable genes are confined to specific regions in the genome.

Conclusion

Based on the known and inferred functions for some of the variable genes of the phages analyzed here, they appear to confer selective advantages for the phage survival under particular host conditions. We speculate that phages have developed a mechanism for horizontally acquiring genes to incorporate them at specific loci in the genome that help phage adaptation to the selective pressures imposed by the host.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-1146) contains supplementary material, which is available to authorized users.     

Analysis of six prophages in Lactococcus lactis IL1403: different genetic structure of temperate and virulent phage populations

We report the genetic organisation of six prophages present in the genome of Lactococcus lactis IL1403. The three larger prophages (36–42 kb), belong to the already described P335 group of temperate phages, whereas the three smaller ones (13–15 kb) are most probably satellites relying on helper phage(s) for multiplication. These data give a new insight into the genetic structure of lactococcal phage populations. P335 temperate phages have variable genomes, sharing homology over only 10–33% of their length. In contrast, virulent phages have highly similar genomes sharing homology over >90% of their length. Further analysis of genetic structure in all known groups of phages active on other bacterial hosts such as Escherichia coli, Bacillus subtilis, Mycobacterium and Streptococcus thermophilus confirmed the existence of two types of genetic structure related to the phage way of life. This might reflect different intensities of horizontal DNA exchange: low among purely virulent phages and high among temperate phages and their lytic homologues. We suggest that the constraints on genetic exchange among purely virulent phages reflect their optimal genetic organisation, adapted to a more specialised and extreme form of parasitism than temperate/lytic phages.     

Thirteen Virulent and Temperate Bacteriophages of Lactobacillus bulgaricus and Lactobacillus lactis Belong to a Single DNA Homology Group

Thirteen virulent phages and two temperate phages of two closely related bacterial species (Lactobacillus lactis and L. bulgaricus) were compared for their protein composition, their antigenic properties, their restriction endonuclease patterns, and their DNA homology. The immunoblotting studies and the DNA-DNA hybridizations showed that the phages could be differentiated into two groups. One group contained 2 temperate phages of L. bulgaricus and 11 virulent phages of L. lactis. Inside each group, at least two common proteins of identical sizes could be detected for each phage. These proteins were able to cross-react in immunoblotting experiments with an antiserum raised against one phage of the same group. Temperate phage DNAs showed partial homology with DNAs from some virulent phages. These homologies seem to be located on the region coding for the structural proteins since recombinant plasmids coding for one of the major phage proteins of one phage were able to hybridize with the DNAs from phages of the same group. These results suggest that temperate and virulent phages may be related to one another.