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.     

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.     

Transducing activity of the temperate SM bacteriophage of Pseudomonas aeruginosa

The temperate bacteriophage SM is not serologically related to the known transducing phages F116, G101, B3 of Pseudomonas aeruginosa. The strains with auxotrophic mutations within the wide ranges of the genetic map of P. aeruginosa strain PAO1 were used for studying the transducing activity of the SM phage. All of the 7 bacterial markers tested are transduced with SM phage grown on a prototrophic donor strain. The frequency of transduction of separate bacterial markers using the wild type SM phage is 2.3 to 4.6 X 10(-8). Linked ilv202+ - met28+ markers are cotransduced with SM phage at a frequency of about 1.5%.     

Interactions of Tn7 and temperate phage F116L of Pseudomonas aeruginosa

Summary Tn7 insertions into the genome of F116L, a Pseudomonas aeruginosa generalized transducing phage, were isolated by repeated cycles of transducing phage, were of strains lysogenic for F116cts mutants with selection for trimethoprim resistance (Tp¹). Two non-defective F116Lcts:Tn7 phage were characterized. They have reduced plaquing ability, produced non-lysogenic Tp^r transductants, and have yielded a deletion mutant of the phage genome upon selection for plaque formation in single infection. F116L DNA is circularly permuted and terminally redundant. A circular restriction map of 61.7 kb has been defined, and a cleavage site common to many enzymes has been identified at coordinate 23.3 kb on the map. It is presumed that this site represents the sequence for the initiation of DNA encapsidation by a headful packaging mode. The Tn7 insertion targets and a 13.4 kb deletion define regions of the F116L genome non-essential for either vegetative growth or lysogenization. The restriction map of Tn7 has been determined for five enzymes. Non-lysogenic Tp^r transuctants reveal a Tn7 insertion hot-spot in the P. aeruginosa genome.     

Mapping of a gene controlling the production of phospholipase C and alkaline phosphatase in Pseudomonas aeruginosa

Summary Using plasmid R68.45 mediated conjugation and transduction with bacteriophage F116L, a genetic locus controlling at least two orthophosphate repressible proteins in Pseudomonas aeruginosa has been mapped at about 22–23 min on the PAO chromosome.     

Characterization of Pseudomonas aeruginosa phage KPP21 belonging to family Podoviridae genus N4‐like viruses isolated in Japan

Bacteriophages (phages) belonging to the family Podoviridae genus N4‐like viruses have been used as therapeutic agent in phage therapy against Pseudomonas aeruginosa infections. P. aeruginosa phage KPP21 was isolated in Japan, and phylogenetically investigated the phages belonging to this viral genus. Morphological and genetic analyses confirmed that phage KPP21 belongs to the family Podoviridae genus N4‐like viruses. Moreover, phylogenetic analyses based on putative DNA polymerase and major virion protein showed that P. aeruginosa phages belonging to the genus N4‐like viruses are separated into two lineages and that phage KPP21 is in the same clade as phage LUZ7.     

Insights into Mechanisms and Proteomic Characterisation of Pseudomonas aeruginosa Adaptation to a Novel Antimicrobial Substance

Antibiotic resistance has been reported since the introduction of synthetic antibiotics. Bacteria, such as one of the most common nosocomial pathogens P. aeruginosa, adapt quickly to changing environmental conditions, due to their short generation time. Thus microevolutional changes can be monitored in situ. In this study, the microevolutional process of Pseudomonas aeruginosa PAO1 resistance against a recently developed novel antibacterial zinc Schiff-base (ZSB) was investigated at the proteome level. After extended exposure to ZSB the passaged strain differed in tolerance against ZSB, with the adapted P. aeruginosa PAO1 exhibiting 1.6 times higher minimal inhibitory concentration. Using Two-dimensional Difference Gel Electrophoresis, the changes in the proteome of ZSB adapted P. aeruginosa PAO1 were examined by comparison with the non-adapted P. aeruginosa PAO1. The proteome of the adapted P. aeruginosa PAO1 strain differed significantly from the non-adapted in the abundance of two proteins when both strains were grown under stressing conditions. One protein could be identified as the outer membrane protein D that plays a role in uptake of basic amino acids as well as in carbapeneme resistance. The second protein has been identified as alkyl peroxide reductase subunit F. Our data indicated a slight increase in abundance of alkyl peroxide reductase F (AhpF) in the case of ZSB passaged P. aeruginosa PAO1. Higher abundance of Ahp has been discussed in the literature as a promoter of accelerated detoxification of benzene derivatives. The observed up-regulated AhpF thus appears to be connected to an increased tolerance against ZSB. Changes in the abundance of proteins connected to oxidative stress were also found after short-time exposure of P. aeruginosa PAO1 to the ZSB. Furthermore, adapted P. aeruginosa PAO1 showed increased tolerance against hydrogen peroxide and, in addition, showed accelerated degradation of ZSB, as determined by HPLC measurements.     

Linkage map of Pseudomonas aeruginosa PAT.

The locations of new markers relative to markers previously mapped on the chromosome of Pseudomonas aeruginosa strain PAT were defined by generalized transduction with phage F116L and F1083. Although the marker orders of the various marker groups were deduced mainly from the results of two-factor crosses, the locations of a number of markers were confirmed by three-factor crosses. A linkage map of the chromosome of P. aeruginosa PAT was constructed which shows the relative locations of 50 genes. From the available data, the linkage maps of P. aeruginosa strains PAO and PAT appear to be similar.     

Antibacterial efficacy of lytic <Emphasis Type="Italic">Pseudomonas</Emphasis> bacteriophage in normal and neutropenic mice models

Recently, lytic bacteriophages (phages) have been focused on treating bacterial infectious diseases. We investigated the protective efficacy of a novel Pseudomonas aeruginosa phage, PA1Ø, in normal and neutropenic mice. A lethal dose of P. aeruginosa PAO1 was administered via the intraperitoneal route and a single dose of PA1Ø with different multiplicities of infection (MOI) was treated into infected mice. Immunocompetent mice infected with P. aeruginosa PAO1 were successfully protected by PA1Ø of 1 MOI, 10 MOI or 100 MOI with 80% to 100% survival rate. No viable bacteria were found in organ samples after 48 h of the phage treatment. Phage clearing patterns were different in the presence or absence of host bacteria but PA1Ø disappeared from all organs after 72 h except spleen in the presence of host bacteria. On the contrary, PA1Ø treatment could not protect neutropenic mice infected with P. aeruginosa PAO1 even though could extend their lives for a short time. In in vitro phage-neutrophil bactericidal test, a stronger bactericidal effect was observed in phage-neutrophil co-treatment than in phage single treatment without neutrophils, suggesting phage-neutrophil co-work is essential for the efficient killing of bacteria in the mouse model. In conclusion, PA1Ø can be possibly utilized in future phage therapy endeavors since it exhibited strong protective effects against virulent P. aeruginosa infection.     

Pseudomonas aeruginosa outer membrane protein F produced inEscherichia coli retains vaccine efficacy

Pseudomonas aeruginosa outer membrane protein F was purified by extraction from polyacrylamide gels of cell envelope proteins of anEscherichia coli strain expressing the cloned gene for protein F. Antisera directed against protein F purified fromP. aeruginosa PAO1 reacted with thisE. coli strain by immunofluorescence assay and immunoblotting, whereas these antisera were nonreactive withE. coli strains lacking thePseudomonas protein F gene. The protein F purified from thisE. coli strain was used to immunize mice by intramuscular injection of 10 µg of protein F preparation on days 1 and 14, followed by burn and challenge of the mice on day 28. As compared with control mice immunized withE. coli K-12 lipopolysaccharide, immunization with theE. coli-derived protein F afforded significant protection against subsequent challenge with heterologous Fisher-Devlin immunotype 5 and 6 strains ofP. aeruginosa. Antisera from mice immunized with theE. coli-derived protein F reacted at bands corresponding to protein F and 2-mercaptoethanol-modified protein F upon immunoblotting against cell envelope proteins of the PAO1, immunotype 5, and immunotype 6 strains ofP. aeruginosa and theE. coli strain containing the cloned F gene, but failed to react at these sites in anE. coli strain lacking the F gene. These data demonstrate thatP. aeruginosa protein F produced inE. coli through genetic engineering techniques retains its vaccine efficacy in the complete absence of anyP. aeruginosa lipopolysaccharide.     

Genetic determinant of pyocin R2 in Pseudomonas aeruginosa PAO. I. Localization of the pyocin R2 gene cluster between the trpCD and trpE genes

Thirty-seven mutants defective in pyocin R2 production in the P. aeruginosa PAO strain were subjected to fine mapping of pyocin R2 genes by transduction with phage F116L. Sixteen complementation groups (designated prtA through prtP) involved in pyocin R2 production were tentatively identified by complementation tests using phage F116L. Their linkages to trpC and trpE markers and fine mapping by three point crosses demonstrated that most of the mutations (prtA through prtN) were located in between trpC and trpE, and that the prtP mutation was localized outside this major prt cluster but in the proximity of the rifA and strA region.     

Transducing phages of Pseudomonas aeruginosa related to phage F116L

New phages K104 and B26, which are relative to F116L by a number of biological characters, appeared to show general transducing activity. Phage K104 transduces all tested markers with higher frequency than the phage B26. Linkage of the bacterial markers pair ilv202--met28 durspectively. When recipient bacteria lysogenic for phages K104 and B26 are used, frequencies of transduction by phage F116L are decreased. In the presence of F116L prophage the frequency of transduction by phage B26 is 10-fold increased. Phages B26 and F116L do not grow on bacteria lysogenic for these phages. Phage F116L does not grow on the lawn of bacteria, lysogenic for phage K104, while phage B26 grows on the same lawn with the efficiency of plating about 10(-2).     

Susceptibility of Pseudomonas aeruginosa veterinary isolates to Pbunavirus PB1-like phages

In recent years, antimicrobial-resistant Pseudomonas aeruginosa strains have increased in the veterinary field. Therefore, phage therapy has received significant attention as an approach for overcoming antimicrobial resistance. In this context, we isolated and characterized four Pseudomonas bacteriophages. Phylogenetic analysis showed that the isolated phages are novel Myoviridae Pbunavirus PB1-like phages with ØR12 belonging to a different clade compared with the other three. These phages had distinct lytic activity against 22 P. aeruginosa veterinary isolates. The phage cocktail composed from the PB1-like phages clearly inhibited the occurrence of the phage-resistant variant, suggesting that these phages could be useful in phage therapy.     

Isolation of <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> Specific Phages with Broad Activity Spectra

The aim of the study was to screen various kinds of samples for Pseudomonas aeruginosa specific phages and to isolate and partially characterize those with broad activity spectra. The Pseudomonas specific phages were isolated using an enrichment procedure with single strains or the cocktail of P. aeruginosa strains as hosts. Using the described procedure, phages were successfully isolated only from water samples, while in soil and feces no Pseudomonas specific phages were detected. The lytic spectra of isolated phages were determined by spot method on lawns of 33 P. aeruginosa strains and five species belonging to family Enterobacteriaceae. The results showed that among isolated phages, 001A, δ, and I possessed the broad activity spectra, as were able to plaque on more than 50% of tested P. aeruginosa strains, while none of the phages were able to lyse the other tested species. Significant differences in phage activity spectra were not observed when P. aeruginosa cocktail was applied for sample enrichment. The most of the phages examined by electron microscopy belonged to family Siphoviridae, while the broad activity spectra isolates, except for 001A, possessed morphological characteristics of family Podoviridae. Digested DNA of the phages δ and I showed similar patterns, indicating the prevalence and success of this phage type in the environment.     

Characterization of the Newly Isolated Lytic Bacteriophages KTN6 and KT28 and Their Efficacy against Pseudomonas aeruginosa Biofilm

We here describe two novel lytic phages, KT28 and KTN6, infecting Pseudomonas aeruginosa, isolated from a sewage sample from an irrigated field near Wroclaw, in Poland. Both viruses show characteristic features of Pbunalikevirus genus within the Myoviridae family with respect to shape and size of head/tail, as well as LPS host receptor recognition. Genome analysis confirmed the similarity to other PB1-related phages, ranging between 48 and 96%. Pseudomonas phage KT28 has a genome size of 66,381 bp and KTN6 of 65,994 bp. The latent period, burst size, stability and host range was determined for both viruses under standard laboratory conditions. Biofilm eradication efficacy was tested on peg-lid plate assay and PET membrane surface. Significant reduction of colony forming units was observed (70-90%) in 24 h to 72 h old Pseudomonas aeruginosa PAO1 biofilm cultures for both phages. Furthermore, a pyocyanin and pyoverdin reduction tests reveal that tested phages lowers the amount of both secreted dyes in 48-72 h old biofilms. Diffusion and goniometry experiments revealed the increase of diffusion rate through the biofilm matrix after phage application. These characteristics indicate these phages could be used to prevent Pseudomonas aeruginosa infections and biofilm formation. It was also shown, that PB1-related phage treatment of biofilm caused the emergence of stable phage-resistant mutants growing as small colony variants.     

Influence of <Emphasis Type="Italic">Pseudomonas aeruginosa pvdQ</Emphasis> Gene on Altering Antibiotic Susceptibility Under Swarming Conditions

In Pseudomonas aeruginosa PAO1, the pvdQ gene has been shown to have at least two functions. It encodes the acylase enzyme and hydrolyzes 3-oxo-C12-HSL, the key signaling molecule of quorum sensing system. In addition, pvdQ is involved in swarming motility. It is required for up-regulated during swarming motility, which is triggered by high cell densities. As high-density bacterial populations also display elevated antibiotic resistance, studies have demonstrated that swarm-cell differentiation in P. aeruginosa promotes increased resistance to various antibiotics. PvdQ acts as a signal during swarm-cell differentiation, and thus may play a role in P. aeruginosa antibiotic resistance. The aim of this study is to examine whether pvdQ was involved in modifying antibiotic susceptibility during swarming conditions, and to investigate the mechanism by which this occurred. We constructed the PAO1pMEpvdQ strain, which overproduced PvdQ. PAO1pMEpvdQ promotes swarming motility, while PAO1ΔpvdQ abolishes swarming motility. In addition, both PAO1 and PAO1pMEpvdQ acquired resistance to ceftazidime, ciprofloxacin, meropenem, polymyxin B, and gentamicin, though PAO1pMEpvdQ exhibited a two to eightfold increase in antibiotic resistance compared to PAO1. These results indicate that pvdQ plays an important role in elevating antibiotic resistance via swarm-cell differentiation and possibly other mechanisms as well. We analyzed outer membrane permeability. Our data also suggest that pvdQ decreases P. aeruginosa outer membrane permeability, thereby elevating antibiotic resistance under swarming conditions. Our results suggest new approaches for reducing P. aeruginosa resistance.     

The pilE gene product of Pseudomonas aeruginosa, required for pilus biogenesis, shares amino acid sequence identity with the N-termini of type 4 prepilin proteins

A new locus required for type 4 pilus biogenesis by Pseudomonas aeruginosa has been identified. A pilE mutant, designated MJ-6, was broadly resistant to pili-specific phages and unable to translocate across solid surfaces by the pilus-dependent mechanism of twitching motility (Twt⁻). Immunoblot analysis demonstrated that MJ-6 was devoid of pili (Pil⁻) but was unaffected in the production of unassembled pilin pools. Genetic studies aimed at localizing the pilE mutation on the P. aeruginosa PAO chromosome demonstrated a strong co-linkage between MJ-6 phage resistance and the proB marker located at 71 min. Cloning of the pilE gene was facilitated by the isolation and identification of a proB⁺-containing plasmid from a PAO1 cosmid library. Upon introduction of the PA01 proB⁺ cosmid clone into MJ-6, sensitivity to pili-specific phage, twitching motility and pilus production were restored. The nucleotide sequence of a 1 kb Eco RV-Clal fragment containing the pilE region revealed a single complete open reading frame with characteristic P. aeruginosa codon bias. PilE, a protein with a molecular weight of 15278, showed significant sequence identity to the pilin precursors of P. aeruginosa and to other type 4 prepilin proteins. The region of highest homology was localized to the N-terminal 40 amino acid residues. The putative PilE N-terminus contained a seven-residue basic leader sequence followed by a consensus cleavage site for prepilin pep-tidase and a largely hydrophobic region which contained tyrosine residues (Tyr-24 and Tyr-27) previously implicated in maintaining pilin subunit-subunit interactions. The requirement of PilE in pilus biogenesis was confirmed by demonstrating that chromosomal pilE insertion mutants were pilus- and twitching-motility deficient.     

Characterization of JG024, a pseudomonas aeruginosa PB1-like broad host range phage under simulated infection conditions

Background  

Pseudomonas aeruginosa causes lung infections in patients suffering from the genetic disorder Cystic Fibrosis (CF). Once a chronic lung infection is established, P. aeruginosa cannot be eradicated by antibiotic treatment. Phage therapy is an alternative to treat these chronic P. aeruginosa infections. However, little is known about the factors which influence phage infection of P. aeruginosa under infection conditions and suitable broad host range phages.     

Molecular characterization of new group A streptococcal bacteriophages containing the gene for streptococcal erythrogenic toxin A (speA)

Summary Bacteriophage T12 is the prototype phage carrying the streptococcal erythrogenic toxin A (speA) gene. To examine more closely the phages involved in lysogenic conversion, we examined 300 group A streptococcal strains, and identified and isolated two new phages that carry the speA gene. The molecular sizes of these phage genomes were between 32 and 40 kb, similar to that of phage T12 (35 kb). However, as ascertained by restriction analysis, the physical maps of the new phage genomes were different from phage T12 and from each other. Hybridization analysis also showed that all of these phages were only partially related to one another and the speA gene was always located close to the phage attachment site. Additionally, colony hybridization showed that whereas phage T12 or one of its close relatives is the most common phage associated with the group A streptococci, phage 49 has a much stronger association with the speA gene. A defective phage was also found following pulsed field gel electrophoresis of total phage DNA. This phage appears to be a resident of strain T25₃c and is found only following induction of a T25₃c lysogen. Restriction enzyme analysis of the isolated defective phage DNA suggests that it is the source of the submolar amounts of DNA previously found in association with phage T12 digestion patterns. Additionally, the defective phage may serve as the site of integration of the speA gene-carrying phages described above.