Temperate SM phage from Pseudomonas aeruginosa as a vector for cloning genetic information]

The recombinant bacteriophages with the genomes containing the DNA fragments of bacteria Erwinia chrysanthemi, including the pectatelyase gene, were constructed on the base of Pseudomonas aeruginosa temperate bacteriophage SM. The gene transferred into Pseudomonas aeruginosa PAO1 cells by transfection is expressed in the new bacterial host. The restriction maps of the recombinant bacteriophages are constructed and the position of an insert is defined. Bacteriophage SM was found to be capable of reproducing in Pseudomonas aeruginosa PAO1 cells when its DNA was shortened to 88% or increased to 111% of the normal genome length. Except for bacteriophage SM, the recombinant bacteriophage SM-2 with an unique restriction endonuclease site for XbaI can also be used as a vector for cloning. Bacteriophage SM capacity in cloning of heterological DNA at HindIII sites is not less than 8 Md, capacity of bacteriophage SM-2 is not less than 5 and 8 Md at XbaI and HindIII sites respectively.     

Localization of prophage SM of Pseudomonas aeruginosa in the chromosome of host cells

Pseudomonas aeruginosa PAO SM-prophage was localized on the chromosome between thr-9001 and pur-66 locuses on 42-43 min of chromosomal genetic map. The location of prophage was identified on the basis of prophage linkage with the above-mentioned markers and confirmed by the purine, hypoxanthine and threonine deletions in course of thermoinduction of SM cts6 prophage from lysogens. The decrease for two orders in lysogenization frequency of thr mutants by SM bacteriophage suggests the integration of SM prophage in these cells into some other region of chromosome.     

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%.     

Transfecting activity of Pseudomonas aeruginosa bacteriophage SM

Factors affecting the efficiency of transfection of Ps. aeruginosa PAO1 cells by the temperate SM bacteriophage DNA have been determined. The efficiency of transfection by DNA preparations isolated from the wild type bacteriophage SMc+ or its thermoinducible mutant SM cts6 is practically the same. The frequency of transfection is (7-9) X 10(4) of infectious centers per mkg of transfecting DNA. Variability in the frequencies of transfection has been registered depending of the infection conditions or on the transfer of the Ps. aeruginosa PAO1 recipient strain population into the competence phase. The efficiency of transfection is increased by the addition of Ca2+ or Mg2+ ions affecting the adsorption and absorbtion of phage DNA by the recipient cells. Optimal concentrations of the bivalent metal ions are 0.15M CaCl2 and 0.2M MgCl2. The results obtained have been used for optimizing the conditions of Ps. aeruginosa PAO1 transfection by SM bacteriophage DNA.     

Phenotypic mixing of pyocin R2 and bacteriophage PS17 in Pseudomonas aeruginosa PAO.

Previous results indicate that a group of bacteriocins in Pseudomonas aeruginosa, named R-type pyocins, have a structure resembling bacteriophage tails and share some serological homology with certain bacteriophages. This paper presents genetic evidence which strongly suggests that components of pyocin R2, an R-type pyocin of P. aeruginosa PAO, and tail components of bacteriophage PS17 are interchangeable. Complementation tests with pyocin R2-deficient mutants of PAO and ts mutants of PS17 revealed that various phenotypic interactions occur between the pyocin and bacteriophage in PAO cells lysogenized or infected with PS17. (i) Certain pyocin R2-deficient mutations were phenotypically suppressed in cells carrying PS17 prophage. (ii) A temperature-sensitive mutant of PS17, tsQ31, was phenotypically suppressed in PAO cells treated with mitomycin C. (iii) Phenotypically mixed phages with receptor and serological specificities of pyocin R2 were formed in PS17 lysogens of certain pyocin R2-deficient mutants.     

Isolation and characterization of a generalized transducing phage for Pseudomonas aeruginosa strains PAO1 and PA14

A temperate, type IV pilus-dependent, double-stranded DNA bacteriophage named DMS3 was isolated from a clinical strain of Pseudomonas aeruginosa. A clear-plaque variant of this bacteriophage was isolated. DMS3 is capable of mediating generalized transduction within and between P. aeruginosa strains PA14 and PAO1, thus providing a useful tool for the genetic analysis of P. aeruginosa.     

The adsorption of Pseudomonas aeruginosa bacteriophage φKMV is dependent on expression regulation of type IV pili genes

Pseudomonas aeruginosa bacteriophage φKMV requires type IV pili for infection, as observed from the phenotypic characterization and phage adsorption assays on a phage infection-resistant host strain mutant. A cosmid clone library of the host ( P. aeruginosa PAO1) genomic DNA was generated and used to select for a clone that was able to restore φKMV infection in the resistant mutant. This complementing cosmid also re-established type IV pili-dependent twitching motility. The correlation between bacteriophage φKMV infectivity and type IV pili, along with its associated twitching motility, was confirmed by the resistance of a P. aeruginosa PAO1Δ pilA mutant to the phage. Subcloning of the complementing cosmid and further phage infection analysis and motility assays suggests that a common regulatory mechanism and/or interaction between the ponA and pilMNOPQ gene products are essential for bacteriophage φKMV infectivity.     

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.     

TL, the new bacteriophage of Pseudomonas aeruginosa and its application for the search of halo-producing bacteriophages

The properties of new virulent bacteriophage TL of Pseudomonas aeruginosa belonging to the family Podoviridae (genome size of 46 kb) were investigated. This bacteriophage is capable of lysogenizing the bacterial lawn in halo zones around negative colonies (NC) of other bacteriophages. TL forms large NC, that are hardly distinguishable on the lawn of P. aeruginisa PAO1. At the same time, on the lawns of some phage-resistant PAO1 mutants, as well as on those produced by a number of clinical isolates, TL forms more transparent NC. It is suggested that more effective growth of the bacteriophage TL NC is associated with the differences in outer lipopolysaccharide (LPS) layer of the cell walls of different bacterial strains, as well as of the bacteria inside and outside of the halos. This TL property was used to optimize selection of bacteriophages producing halos around NC on the lawn of P. aeruginosa PAO1. As a result, a group of bacteriophages differing in the patterns of interaction between their halos and TL bacteriophage, as well as in some characters was identified. Taking into consideration the importance of cell-surfaced structures of P. aeruginosa in manifestation of virulence and pathogenicity, possible utilization of specific phage enzymes, polysacchadide depolymerases, for more effective treatment of P. aeruginosa infections is discussed.     

Effect of ozone on bacteriophages in the phage--host-cell system

The antiviral action of ozone was studied using Escherichia coli K-12 AB1157 virulent phage T4 and Pseudomonas aeruginosa PAO1 temperate phage SM as models depending on the phage state during the action: a free phage, a phage in the presence of sensitive host cells, or a vegetative phage. Bacteriophages T4 and SM were found to be much more sensitive to ozone as compared to the bacterial strains AB1157 and PAO1. The latter protected phage particles against the activation by ozone at a concentration which effectively inactivated these phages in the absence of the bacteria. Ozone also exerted an inhibiting effect on vegetative phage SM, and the degree of inhibition decreased with the termination of intracellular growth stages.     

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.     

Basic characterization of a Pseudomonas aeruginosa PAO1 bacteriophage

A bacteriophage of Pseudomonas aeruginosa PAO1 was characterized. Bacteriophage PIK was found to adsorb on the cell wall of the host organism. Electron microscopy of the phage PIK revealed that it had a bipyramidal hexagonal prismatic head of 110 nm in diameter, a tail which was 158 nm long and a tail plate of 47 nm width. This paper describes its basic characters, and a quantitative study was made of its adsorption to exponential phase cells of two different strains of P. aeruginosa. PIK was found to contain double stranded DNA and it appears to be virulent towards its host, P. aeruginosa PAO1. It was classified into the group of phages possessing a contractile tail.     

IncP-1 R plasmids decrease the serum resistance and the virulence of Pseudomonas aeruginosa

Pseudomonas aeruginosa strain PAO1 was compared to PAO1 strains containing an IncP-1 R plasmid (RP1, R68, or R68.45) in an experimental mouse burn infection model. All R plasmids tested caused a 10- to 400-fold increase in mean lethal dose (LD50). The decrease in virulence produced by plasmids R68 and R68.45 was significantly greater than the decrease caused by the closely related plasmid RP1. All plasmids also led to an increased sensitivity of strain PAO1 to human serum bactericidal activity. Virulence and serum resistance of strain PAO1 were restored by curing of the entire plasmid R68.45 but not by deletions in the plasmid's transfer gene regions.     

IS222, a new insertion element associated with the genome of Pseudomonas aeruginosa.

A new insertion element, IS222, was identified to be associated with the DNA of a mutant strain of the converting Pseudomonas aeruginosa bacteriophage D3. The insertion sequence was 1,350 base pairs in size and possessed terminal inverted repeats. The nucleotide sequence contained single cleavage sites for EcoRI and PvuI but none for BamHI, PstI, HindIII, SmaI, or SalI. By Southern hybridization analysis, no homology was found with genomic DNA from P. aeruginosa PAT or Escherichia coli. Genomic DNA from the phage host, P. aeruginosa PAO, contained two sequences homologous to IS222.     

Transfer of chromosomal genes mediated by plasmid r68.45 in Rhodopseudomonas sphaeroides.

Plasmid R68.45 was transferred from Pseudomonas aeruginosa PAO25 to the photosynthetic species Rhodopseudomonas gelatinosa and Rhodopseudomonas sphaeroides by selection for resistance to antibiotics. R. sphaeroides strains carrying the plasmid could transfer the plasmid and also chromosomal genes to other strains of R. sphaeroides.     

Transformation by extracellular DNA produced by Pseudomonas aeruginosa

Most Pseudomonas aeruginosa strains are capable of producing extracellular DNA. Very closely linked chromosomal markers (leu+ and trp+) were co-transferred to P. aeruginosa PAO1819 (leu9001, trp9008) by the extracellular DNA produced by P. aeruginosa strains IFO3445 and PAO1 at a frequency of 10(-7) to 10(-8). Treatment of the extracellular DNA with DNase, heating at 95 C or sonication completely destroyed its transforming ability. The R plasmid in the extracellular DNA produced by P. aeruginosa IFO3445 (RP4) or PAO2142 (RLb679) could be transferred to Escherichia coli ML4901 or P. aeruginosa PAO1819. The resultant transformants showed identical resistance patterns in the respective donors, and the sizes of the DNAs of RLb679 and RP4 isolated from the transformants were the same as those in the respective donors. These results demonstrate that the extracellular DNA contains both chromosomal DNA and plasmid DNA, and that it exhibits transforming ability. This implies that transformation by the extracellular DNA produced by P. aeruginosa may occur in nature and this seems to be of clinical importance in view of the spread of R plasmids among pathogens.     

Specialized transduction of Pseudomonas aeruginosa PAO by bacteriophage D3.

D3, a temperate bacteriophage of Pseudomonas aeruginosa PAO, was found to specifically transduce the alleles met-49 and met-117. Induction of established lysogens with UV light was necessary for the production of transducing lysates. Transduced cells were immune to superinfection by phage D3 and could give rise to high-frequency transducing lysates. Cotransduction of these two alleles could not be demonstrated. met-117 was mapped to 26 min on the PAO genetic map. Complementation studies using the generalized transducing phage F116L indicated that met-49 is an allele of met-9011 which maps at 55 min. The integrated D3 prophage was shown to be coinherited with met-117 and with met-49.     

Inducible UV repair potential of Pseudomonas aeruginosa PAO

Pseudomonas aeruginosa PAO lacks UV-inducible Weigle reactivation and Weigle mutagenesis of UV-damaged bacteriophages. This lack of UV-inducible, error-prone DNA repair appears to be due to the absence of efficiently expressed umuDC-like genes in this species. When the P. aeruginosa recA gene is introduced into a recA(Def) mutant of Escherichia coli K12, the P. aeruginosa recA gene product is capable of mediating UV-induced mutagenesis, indicating that it could participate in a recA-lexA-like regulatory network and function in inducible DNA repair pathways if such existed in P. aeruginosa. The presence of the IncP9, UV-resistance plasmid R2 in RecA+ strains of P. aeruginosa PAO allows UV-inducible, mutagenic DNA repair of UV-irradiated bacteriophages. R2 also greatly stimulates the ability of UV radiation to induce mutagenesis of the bacterial chromosome. When R2 is introduced into P. aeruginosa strains containing either the recA908 or recA102 mutation, plasmid-mediated UV resistance and Weigle reactivation are not observed. These observations suggest that the increased protection afforded to P. aeruginosa by R2 is derived from a RecA-mediated, DNA-damage-inducible, error-prone DNA repair system which complements the lack of a chromosomally encoded umuDC-like operon.     

Analysis of flagellar genes in Pseudomonas aeruginosa by use of Rfla plasmids and conjugations.

Over 300 flagellar mutants were isolated in Pseudomonas aeruginosa PAO. R-prime plasmids carrying segments of bacterial chromosome which can complement the mutant phenotypes were isolated by means of plasmid R68.45. Among the R-prime plasmids, pMT6 complemented 167 out of 307 mutants examined, and pMT19 complemented the remaining 140 mutants. We found no mutant which was complemented by both of these plasmids. Hence, the flagellar genes were divided into two clusters by these two plasmids, namely, region I on pMT19 and region II on pMT6. By FP5- and R68.45-mediated conjugation, these two regions were located on the P. aeruginosa PAO chromosome with an order of puuF--region I--region II--oru-325.     

Anaerobic activation of the entire denitrification pathway in Pseudomonas aeruginosa requires Anr, an analog of Fnr.

The Pseudomonas aeruginosa gene anr, which encodes a structural and functional analog of the anaerobic regulator Fnr in Escherichia coli, was mapped to the SpeI fragment R, which is at about 59 min on the genomic map of P. aeruginosa PAO1. Wild-type P. aeruginosa PAO1 grew under anaerobic conditions with nitrate, nitrite, and nitrous oxide as alternative electron acceptors. An anr deletion mutant, PAO6261, was constructed. It was unable to grow with these alternative electron acceptors; however, its ability to denitrify was restored upon the introduction of the wild-type anr gene. In addition, the activities of two enzymes in the denitrification pathway, nitrite reductase and nitric oxide reductase, were not detectable under oxygen-limiting conditions in strain PAO6261 but were restored when complemented with the anr+ gene. These results indicate that the anr gene product plays a key role in anaerobically activating the entire denitrification pathway.