Study of the diversity in a group of phages of Pseudomonas aeruginosa species PB1 (Myoviridae) and their behavior in adsorbtion-resistant bacterial mutants

A group of 12 Pseudomonas aeruginosa virulent bacteriophages of different origin scored with regard to the plaque phenotype are assigned to PB1-like species based on the similarity in respect to morphology of particles and high DNA homology. Phages differ in restriction profile and the set of capsid major proteins. For the purpose of studying adsorption properties of these phages, 20 random spontaneous mutants of P. aeruginosa PAO1 with the disturbed adsorption placed in two groups were isolated. Mutants of the first group completely lost the ability to adsorb all phages of this species. It is assumed that their adsorption receptors are functionally inactive or lost at all, because the attempt to isolate phage mutants or detect natural phages of PB1 species capable of overcoming resistance of these bacteria failed. The second group includes five bacterial mutants resistant to the majority of phages belonging to species PB1, These mutants maintain the vigorous growth of phage SN and poor growth of phage 9/3, which forms turbid plaques with low efficiency of plating. In the background of weak growth, phage 9/3 yields plaques that grew well. The examination of the progeny of phage 9/3, which can grow on these bacteria, showed that its DNA differed from DNA of the original phage 9/3 by restriction profile and is identical to DNA of phage PB1 with regard to this trait. Data supported a suggestion that this phage variant resulted from recombination of phage 9/3 DNA with the locus of P. aeruginosa PAO1 genome encoding the bacteriocinogenic factor R. However, this variant of phage 9/3 did not manifest the ability to grow on phage-resistant mutants of the first group. Possible reasons for the difference between phages 9/3 or SN and the remaining phages of PB1 species are discussed. A preliminary formal scheme of the modular structure for adsorption receptors on the surface of P. aeruginosa PAO1 bacteria was constructed based on the analysis of growth of some other phage species on adsorption mutants of the first type.     

Pseudomonas aeruginosa transposable bacteriophages D3112 and B3 require pili and surface growth for adsorption.

Pseudomonas aeruginosa transposable bacteriophages D3112 and B3 were found to require pili for infection. Seventy mutants of P. aeruginosa PAO selected by resistance to D3112 or B3 were also resistant to the phage not used in the selection and suggested that the receptors of these two phages are identical. Of five resistant mutants examined, all were defective in the production of pili and did not adsorb either phage. P. aeruginosa PAK strains altered in pilus expression, such as hyperpiliated or nonpiliated mutants, adsorbed the phage but were not productively infected, implying that an additional host function was required for infection. The cell-associated lipopolysaccharide was not required for D3112 or B3 infection, since mutants deficient in O side-chain and core biosynthesis were still capable of adsorption and productive infection. This is in contrast to Escherichia coli mutator phages Mu and D108, which are dependent on lipopolysaccharide for adsorption. The P. aeruginosa phages adsorbed only to cells grown on solid media or in liquid media supplemented with agents that increase the macroviscosity, such as polyvinylpyrrolidone. Adsorption time course studies of D3112 and B3 using cells grown in solid media revealed similar but not identical adsorption patterns. These studies suggested that expression of the D3112 and B3 cell receptor is induced by growth on solid media.     

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.     

Isolation and analysis of Pseudomonas aeruginosa PAO mutants resistant to nonlysogenic bacteriophages

Nonlysogenizing Pseudomonas aeruginosa PAO bacteriophages were studied. According to morphology of the plaques, they were distributed into three groups: phi k, phi m and phi mn. The mutants of P. aeruginosa PAO resistant to these bacteriophages were selected. On the basis of cris-cross resistance analysis of the mutants, a formal scheme of the receptor sites on the P. aeruginosa PAO bacterial cell surface is drawn. It is shown that bacteriophages phi k and phi m use different receptors for their adsorption. The receptors of phi m and phi mn phages are specifically interconnected. Thus, the receptor for phi k phages is connected with the receptor for phage phi 11. It appears that the receptor for bacteriophage E79 is identical to those of phi m phages. The phi m receptor is of a composite structure: it includes two different receptors used by phi mn phages.     

Two loci in the genome of the transposable phage B39 of Pseudomonas aeruginosa affecting the process of integration. I. Study of the properties of phages with the Pde- phenotype and mapping of the rms site

Mutants and recombinants of transposable Pseudomonas aeruginosa bacteriophage B39 with a specific phenotype Pde- (pleiotropic developmental effect) were studied. Pde- phages produce clear minute plaques on lawns of P. aeruginosa PAO1 and fail to grow in cells of PAO1 harbouring Rms 163 (Inc P5) plasmid. Pde+ character is under control of the two loci in phage genome which were designated pdeX and pdeY. In hybrid phages the pdeX and pdeY loci originating from different transposable phages (pdeX from B39 and pdeY from PH132) do not accomplish their function and, as a result, the hybrid phages have the Pde- phenotype. The frequency of integration (f.o.i.) of Pde- phages into bacterial chromosome is lower than f.o.i. for Pde+ phages, as well as the frequency of stable lysogenization of infected bacteria; lytic development of the Pde- phages is also limited. The great difference among the transposable phages in their reaction to the presence of Rms163 plasmid is caused by some differences in the specific rms site in the phage genome. The site is located inside the interval 1.1-3.9 kb of the physical genome map, being closely linked to cI gene of phage B39. The growth of Pde- phages in cells with Rms163 can be restored, due to additional mutations in phage genes affecting lysogenization.     

Expression of Pseudomonas aeruginosa phage transposons in Pseudomonas putida PpG1 cells. II. Zygotic induction--a necessary condition for the formation of defective lysogens

The transfer of hybrid plasmid RP4::PT (where PT is the genome of a transposable phage specific for Pseudomonas aeruginosa) into recipient cells of P. putida strain PpG1 occurs with the same frequency as into P. aeruginosa, the homologous host for PT. Approximately 1/3 of all PpG1 exconjugants carrying RP4 markers lost the capability to produce viable PT phage. In contrast, in a cross with homologous recipient P. aeruginosa all exconjugant clones contained nondefective prophages in the hybrid plasmids. Zygotic induction is an obligatory condition for detection of PpG1 exconjugants with defective phages. The defective prophages in RP4::PT hybrid plasmids have deletions of different size; the other carry mutations indistinguishable from point mutations in an essential phage gene. Some of deletions also cover plasmid genes. At least some of the defective prophages, including deleted ones, have arisen in the recipient cells of P. putida after transfer of the hybrid plasmid.     

Mode of the rational use of Pseudomonas aeruginosa bacteriophages in therapeutic and epidemic control practice

Ecological aspects of the circulation of P. aeruginosa and P. aeruginosa bacteriophages under hospital conditions were under study. The statement concerning the formation of triple parasitic systems was put forward. The influence of these systems on the formation of phage and antibiotic resistance in P. aeruginosa hospital strains was studied. Spontaneous circulation of faintly virulent phages taking part in the formation of triple parasitic systems was shown not to ensure the elimination of P. aeruginosa hospital strains in clinics. Construction of highly virulent phages adapted to local P. aeruginosa strains was the only way of ensuring the protection of patients. Theoretical and practical approaches to the use of highly active bacteriophages for controlling P. aeruginosa infection were substantiated. The realization of these approaches resulted in achieving not only a clinical, but also essential epidemic control effect in cases of purulent septic infections caused by P. aeruginosa (a decreased frequentcy of hospital infections from 40.8% to 8.93%).     

Study of the diversity in a group of phages of <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> species PB1 (Myoviridae) and their behavior in adsorbtion-resistant bacterial mutants

A group of 12 Pseudomonas aeruginosa virulent bacteriophages of different origin scored with regard to the plaque phenotype are assigned to PB1-like species based on the similarity in respect to morphology of particles and high DNA homology. Phages differ in restriction profile and the set of capsid major proteins. For the purpose of studying adsorption properties of these phages, 20 random spontaneous mutants of P. aeruginosa PAO1 with the disturbed adsorption placed in two groups were isolated. Mutants of the first group completely lost the ability to adsorb all phages of this species. It is assumed that their adsorption receptors are functionally inactive or lost at all, because the attempt to isolate phage mutants or detect natural phages of PB1 species capable of overcoming resistance of these bacteria failed. The second group includes five bacterial mutants resistant to the majority of phages belonging to species PB1. These mutants maintain the vigorous growth of phage SN and poor growth of phage 9/3, which forms turbid plaques with low efficiency of plating. In the background of weak growth, phage 9/3 yields plaques that grew well. The examination of the progeny of phage 9/3, which can grow on these bacteria, showed that its DNA differed from DNA of the original phage 9/3 by restriction profile and is identical to DNA of phage PB1 with regard to this trait. Data supported a suggestion that this phage variant resulted from recombination of phage 9/3 DNA with the locus of P. aeruginosa PAO1 genome encoding the bacteriocinogenic factor R. However, this variant of phage 9/3 did not manifest the ability to grow on phage-resistant mutants of the first group. Possible reasons for the difference between phages 9/3 or SN and the remaining phages of PB1 species are discussed. A preliminary formal scheme of the modular structure for adsorption receptors on the surface of P. aeruginosa PAO1 bacteria was constructed based on the analysis of growth of some other phage species on adsorption mutants of the first type.     

A conserved C-terminal region in Gp71 of the small isometric-head phage LL-H and ORF474 of the prolate-head phage JCL1032 is implicated in specificity of adsorption of phage to its host, Lactobacillus delbrueckii

Thirty-five phage-resistant mutants of Lactobacillus delbrueckii subsp. lactis ATCC 15808 were selected. Thirty-three of these mutants were assigned to the Bes group, while the remaining two were grouped under the Ads designation. Bes group mutants adsorbed phage LL-H but did not allow efficient phage development. Preliminary evidence suggests that these strains exhibit a mutation that changes the DNA specificity of a restriction-modification system. The Ads group mutants did not adsorb the small isometric-head phage LL-H. The results suggest that there are at least three different types of phage receptors in L. delbrueckii: two that are specific for small isometric-head phages and one that is specific for prolate-head phage JCL1032. Five LL-H host-range mutants which could overcome the adsorption block (a-type mutants) were selected and investigated by sequencing the genes g71 and g17, which encode minor and major tail proteins, respectively. Each of the a-type mutants carried a nucleotide change at the 3' end of gene g71. No mutations were observed in gene g17. Comparison of the gene product of g71 of phage LL-H with its homolog in JCL1032 (ORF474) showed that these proteins had very similar C-terminal regions. No similarities were found at the N-terminal part of the proteins. We conclude that the C-terminal portion of the protein encoded by g71 of phage LL-H and its homolog in phage JCL1032 determines the adsorption specificities of these phages on L. delbrueckii.     

Expression of Pseudomonas aeruginosa transposable phages in Pseudomonas putida cells. I. The establishment of a lysogenic state and the effectiveness of lytic development

Expression of transposable phages (TP) of Pseudomonas aeruginosa in the cells of P. putida was studied. The high efficiency of phage lytic development was shown both as a consequence of zygotic induction after transfer of the RP4::TPc+ plasmid into nonlysogenic recipients, and as a result of heat induction of lysogens PpG1 (D3112cts15). The high phage yield (20-25 particles of D3112cts phage per one cell of P. putida) is an evidence for a high level of transposition in the cells of this bacterial species. Plasmids RP4::TP are transferred into cells of PpG1 and PAO1 with similar frequency. However, the efficiency of establishment of the lysogenic state is lower in PpG1. Transposable phages of P. aeruginosa can integrate into the chromosome of PpG1 producing stable inducible lysogens. The presence of RP4 in the P. putida cells is not necessary for expression of transposable phages. The transposable phage D3112cts15 can be used in experiments of interspecies transduction of plasmids and chromosomal genes.     

Classification of 17 newly isolated virulent bacteriophages of Pseudomonas aeruginosa

Seventeen virulent bacteriophages specific to Pseudomonas aeruginosa strains were isolated by screening various environmental samples. These isolated bacteriophages were grouped based on results obtained from restriction fragment analysis of phage genomes, random amplification of polymorphic DNA (RAPD) typing, morphology observations under transmission electron microscope, and host range analysis. All 17 bacteriophages are double-stranded DNA viruses and can be divided into 5 groups based on DNA restriction profiles. A set of 10-mer primers was used in RAPD typing of phages, and similar conclusions were obtained as for restriction fragment analysis. One phage was randomly selected from each of the 5 groups for morphology observations. Four of them had an icosahedral head with a long contractile tail, belonging to the Myoviridae family, and one phage had an icosahedral head with a short tail, thereby belonging to the Podoviridae family. Host range experiments were conducted on 7 laboratory strains and 12 clinical strains of P.?aeruginosa. The results showed that 13 phages had the same infection profile, killing 8 out of 19 tested P.?aeruginosa strains, and the remaining 4 phages had different and unique infection profiles. This study highlights the diversity of bacteriophages specific to P.?aeruginosa in the environment.     

Genome instability of <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> 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 vir 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.     

The extraction and analysis of lipopolysaccharides from Pseudomonas aeruginosa strain PAO, and three rough mutants.

Three spontaneously arising rough mutants of Pseudomonas aeruginosa have been isolated by selection for resistance to virulent lipopolysaccharide (LPS) specific bacteriophages. In addition, the first phages specific for rough mutants of P. aeruginosa were isolated. Using these phage and autoagglutination patterns in 4% NaCl and acriflavine, these mutants could be clearly distinguished from the wild-type strain and each other. Chemical analysis of the LPS together with chromatographic resolution of the polysaccharide moieties showed alterations in both O-specific side chains and core regions.     

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.     

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.     

Dynamic interaction of virulent Pseudomonas aeruginosa bacteriophages with the host bacteria

The population interactions of Pseudomonas aeruginosa virulent bacteriophages phi kF77 and phi mnF82 with host bacterial cells were studied in dynamics under the conditions of continuous cultivation in the chemostat regime with glucose limitation. Two different types of maintaining the bacterium and its specific bacteriophages in the population were detected. When P. aeruginosa was cultivated with phage phi mnF82, such a maintenance was realized due to the successive appearance of bacterial mutants resistant to the phage and of phage mutants overcoming this resistance. When P. aeruginosa was cultivated with phage phi kF77, these were maintained owing to the ability of P. aeruginosa to form unstable phage-resistant variants with the segregation of phage-sensitive cells.     

Distribution of phage-resistant Pseudomonas aeruginosa strains

The sensitivity of a number of P. aeruginosa clinical strains to virulent bacteriophages has been studied. Phage-resistant strains have been found to constitute a considerable proportion among the tested P. aeruginosa strains. The strains under study fall into 19 groups differing in their sensitivity to the bacteriophages used in this investigation. The strains belonging to some groups are phenotypically identical to experimentally obtained P. aeruginosa phage-resistant mutants PAO. The use of bacteriophage mutants has made it possible to demonstrate that in most cases the resistance of P. aeruginosa natural strains to type phi k phages is due to disturbances in their adsorption, whereas their resistance to type phi m and phi mn phages is, seemingly, not linked with disturbances in their capacity for adsorption on the cell membranes of the bacteria.     

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.     

Susceptibility of Different Coliphage Genomes to Host-controlled Variation

Twenty-eight coliphages were studied for their susceptibility to four systems of host control variation in Escherichia coli. Both temperate and virulent phages were studied, including phages with ribonucleic acid, double- and single-stranded deoxyribonucleic acid (DNA) and glucosylated DNA. The systems examined were E. coli C-K, K-B, B-K, and K-K(P1). The C-K, K-B, and B-K systems affected temperate phages and nonlysogenizing mutants derived from temperate phages. In general, these systems did not restrict virulent phages. Phage 21e, a variant of phage 21, lost the ability to undergo restriction in the C-K and B-K systems, but retained susceptibility to the K-B and K-K(P1) systems. This suggests that the genetic site(s) on the phage, as well as in the host, determines susceptibility to host-controlled variation. Both temperate and dependent virulent phages were susceptible to the host control system resulting from the presence of prophage P1. The autonomous and small virulents were not susceptible. In a given system, the various susceptible phages differed widely in their efficiency of plating on the restricting host. If the few infections that occur arise in rare special cells, then different populations of special cells are available to different phage species. For most phage types, when a susceptible phage infected a nonrestricting host, the progeny showed the specificity appropriate to that host. Behavior of T3 was exceptional, however. When T3 obtained from E. coli K infected E. coli C or B, some of the progeny phages retained K host specificity, whereas others acquired the specificity of the new host.     

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 phi 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.