Role of lysogenizing phages in the spread of drug-resistance plasmids in a staphylococcal population

The frequency of the transduction of plasmids rms5, rms7, pT127, pC194, pS194 and pUB101 by phages belonging to serological group B (80, 52, 52A, 53, 85, phi 11, S2) in two systems was compared. In system 1 phages for transduction were obtained from plasmid-containing lysogenic donors in the process of induction with mitomycin C; in system 2 phages for transduction were obtained by their multiplication in plasmid-containing nonlysogenic donors. In system 1 the transduction of plasmids rms5, rms7, pT127, pS194 by phage 52A was found to occur with a greater (by 3-5 orders) frequency than in system 2 (the frequency of transduction was 10(-2) to 10(-4), and 10(-6) to 10(-8) respectively). A similar situation was observed with plasmids rms5 and rms7 and phage 52; plasmid pT127 and phage 53; but not observed with plasmids rms5 and rms7 and phages 80, phi 11 and S2; plasmids pC194 and pS194 and phage 53; plasmid pUB101 and phages 52A, 80 and phi 11; plasmids pC194, pS194 and pT127 and phage 85.     

Bacteriophage selection against a plasmid-encoded sex apparatus leads to the loss of antibiotic-resistance plasmids

Antibiotic-resistance genes are often carried by conjugative plasmids, which spread within and between bacterial species. It has long been recognized that some viruses of bacteria (bacteriophage; phage) have evolved to infect and kill plasmid-harbouring cells. This raises a question: can phages cause the loss of plasmid-associated antibiotic resistance by selecting for plasmid-free bacteria, or can bacteria or plasmids evolve resistance to phages in other ways? Here, we show that multiple antibiotic-resistance genes containing plasmids are stably maintained in both Escherichia coli and Salmonella enterica in the absence of phages, while plasmid-dependent phage PRD1 causes a dramatic reduction in the frequency of antibiotic-resistant bacteria. The loss of antibiotic resistance in cells initially harbouring RP4 plasmid was shown to result from evolution of phage resistance where bacterial cells expelled their plasmid (and hence the suitable receptor for phages). Phages also selected for a low frequency of plasmid-containing, phage-resistant bacteria, presumably as a result of modification of the plasmid-encoded receptor. However, these double-resistant mutants had a growth cost compared with phage-resistant but antibiotic-susceptible mutants and were unable to conjugate. These results suggest that bacteriophages could play a significant role in restricting the spread of plasmid-encoded antibiotic resistance.     

Properties of R plasmid R772 and the corresponding pilus-specific phage PR772.

R plasmid R772 was isolated from a strain of Proteus mirabilis and is a self-transmissible P-1 incompatibility group plasmid having a molecular weight of about 27 x 10(6). It renders bacterial hosts resistant to kanamycin. Phage PR772 was isolated as a phage dependent on the presence of R772 in bacterial hosts. It is hexagonal-shaped with a diameter of 53 nm, has a thick inner membrane and no tail. Vaguely defined appendages are sometimes apparent at some vertices and the phage possesses double-stranded DNA. The DNA has a guanine plus cytosine molar content of 48%. The phage is sensitive to chloroform and has a buoyant density of 1.26 g cm(-3). These observations suggested that the inner membrane of the phage could contain lipid. Phage PR772 differs in morphology from the double-stranded DNA plasmid-specific phages PR4 and PRR1 which adsorb to tips and sides, respectively, of sex pili coded for by P-1 incompatibility group plasmids. Phage PR772 formed clear plaques which varied in diameter. Serologically, phages PR772 and PR4 are possibly related though very distantly, but the two phages have identical host ranges. Phage PR772 adsorbed by one of its apices to tips of sex pili coded for by plasmid R772 in Escherichia coli. It also formed plaques on Salmonella typhimurium Proteus morganii and Providence strains harbouring this plasmid as well as strains of E. coli carrying plasmids of incompatibility groups N or W. The phage produced areas of partial clearing on lawns of P. mirabilis PM5006 harbouring plasmid R772, the P-1 incompatibility group plasmid RP4, the W group plasmid RSa or the N group plasmid N3, and on lawns of Providence strain P29 carrying plasmid RP4.     

Inheritance of biodegradation plasmids in the cells of homo- and heterologous hosts

A systematic analysis of the inheritance of D plasmids of the IncP-9 group (alpha-, beta-, gamma-, delta-, epsilon-, zeta-, eta-, theta-subgroups), IncP-7, as well as of those of undefined systematic affiliation in the cells of homologous (Pseudomonas putida) and heterologous (Escherichia coli) hosts was performed for the first time. For this purpose, mini-Tn5 transposons determining resistance to kanamycin (or streptomycin) were introduced into all the D plasmids under study. It has been established that all IncP-9 plasmids can be transmitted to the cells of a heterologous host E. coli (with the exception of plasmid pSVS15 from theta-subgroup). IncP-7 plasmids and those of undefined systematic affiliation do not possess this property and can be transmitted and stably inherited only in P. putida. The distinctive feature of most IncP-9 plasmids (alpha-, beta-, gamma-, delta-, epsilon-, and zeta-subgroups) is strict dependence of their inheritance on the temperature factor. At 37 degrees C, the plasmids of delta-, zeta-, and theta-subgroups are unstable in P. putida cells, while in E. coli nearly all plasmids of this systematic group are unstable. The exceptions are the plasmids of eta- and gamma-subgroups. Inheritance of these plasmids does not depend on temperature. At 28 degrees C and 37 degrees C, the eta plasmid is not maintained stably (inheritance stability is 2%), while the gamma plasmid has almost 100% stability under the same conditions.     

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.     

Construction and characteristics of mini-Mu phages

The paper reports on the principles of construction, physical characterization and results of preliminary genetic investigation of hybrid plasmids containing Mu DNA sequences or deletion derivatives of phage Mu, the so-called mini-Mu phages. The mini-Mu were obtained by joining both phage ends within one plasmid in a regular orientation. A collection obtained by in vitro manipulations included 14 recombinant plasmids containing different DNA fragments of the Mu genome. Seven plasmids have both ends of phage Mu, three plasmids containing regularly oriented ends, i.e. mini-phages of different size: the mini-Mu5 (11 kb) within pRM8 plasmid, the mini-Mu4 Ap (18 kb) within pRM6 and the mini-mini-Mu (4.4 kb) within pRM5. The collection comprises mini-Mu phages with the gene kil inactivated after treatment with hydroxylamine. Biological properties of the hybrid plasmids have been preliminary studied.     

Genetic control of the formation of plasmid F'. I. Effect of recA- and seg-2 mutations in an Hfr donor strain on the character of plasmid F' formation]

Assuming the similarity of the processes of illegitimate recombination, such as deletion formation, with the process of F' plasmid formation, we have undertaken the study of the influence of recA- and seg- alleles of Hfr donor on the F' plasmid formation. The data obtained demonstrate the strong influence of donor genotype on the frequency of F' plasmid formation and on the nature of F' plasmids formed, thus demonstrating that the most of F' plasmids have been formed via recombination in Hfr donor cells. The recA- mutation decreased the total yield of F' plasmids selected using both proximal and distal Hfr markers and affected drastically the distribution of the F' plasmids inheriting different proximal unselected markers. The existence of recA-dependent and recA-independent modes of F' plasmid formation was demonstrated. The Escherichia coli chromosome contains regions which involve preferentially in recA-dependent (between proA and gal, and clockwise from gal) or recA-independent (between leu and proA, and the region counterclockwise from argE) recombination. The seg-2 mutation causes only partial block of both recA-dependent and recA-independent recombination pathways, however it causes dramatic decrease of genetic exchanges leading to the formation of the type II F' plasmids. Both seg- and recA- mutations decrease the frequency of the formation of Tra+ F' transconjugants. The percent of Tra- transconjugants, which remain sensitive to MS2 and Q beta donor specific phages, also drops significantly under the influence of the recA- and seg- alleles. Thus, the recombination involving the F structure in wild type strains and seg- mutants occures preferentially in the points of F outside the regions essential for transfer and sensitivity to male specific phages, while in recA- and recA-ges- strains the points inside these regions (tra operon) frequently involved in F' plasmid looping out. There exist more strict correlation between the fertility and sensitivity to phage Q beta than to phage MS2.     

Effect of Chloramphenicol on Host-Bacteriophage Relationships in the Lactic Streptococci

Chloramphenicol (CM)-resistant mutants of Streptococcus lactis strain ML3 were obtained either as a consequence of continuous transfer of the bacteria in broth containing increasing amounts of CM or by selecting for high-level resistant derivatives after mutagenic treatment of the bacteria. Some CM-resistant cells obtained by the first method were also resistant to the homologous bacteriophage. Cells trained to grow in the presence of CM developed resistance to some heterologous attacking phages but not to phage ml(3). Mutants selected for phage resistance were not resistant to CM. There appear to be two different loci for CM resistance on the bacterial chromosome: the one for high-level resistance is associated with the phage-resistance locus and the other is independent of it. A concentration of CM (280 mug/ml) that was bacteriostatic for ML3 inhibited the intracellular growth of ml(3) phage in strain ML3-CM(r)I, which had been trained to grow in the presence of that CM concentration, despite the fact that cells of this strain were not phage-resistant per se. The drug had no direct virucidal action and did not prevent adsorption to or penetration of phage into the bacterium. Lysogenization did not occur. It is concluded that the block in phage development probably involves inhibition of synthesis of phage components, either involving deoxyribonucleic acid at an early stage or the phage coat protein at a later one.     

Possible dependence of the results of phage typing Ps. aeruginosa strains on the presence of R plasmids

The plasmid composition of 209 strains of Ps. aeruginosa was determined. The strains were isolated from patients, animals and environment in different geographical areas. The number of the plasmid-containing strains averaged 26.8 per cent. The molecular weights of the plasmids varied from less than 10 to more than 150 MD. 41 conjugative plasmids were transmitted to the recipients of Ps. aeruginosa RAO 303. 66 per cent of them had a restrictive effect on the development of phages used in genetic studies, epidemiological phage typing (Lindberg Collection), and medical practice. This resulted in the changing of the phage type of the host strain. Similar results were obtained in the studies with 10 standard R plasmids representing different incompatibility groups. No relation between the spectrum of the phage restriction, group specificity and the other properties of the plasmids was observed. About 50 per cent of the plasmids markedly lowered the sensitivity level of Ps. aeruginosa RAO 303 to the therapeutic pyocyanic phage. The systems of restriction and modification of DNA coded with plasmids were not detected. A possible changing of the phage type of Ps. aeruginosa strains under the effect of R plasmids should be considered in epidemiological assays and respective treatment measures.     

Comparative analysis of the P-1-group plasmids of incompatibility

Wide host range plasmids (IncP-1) R906, R751 and R702 have several cleavage sites for BamHI, HindIII and EcoRI enzymes, in contrast to RP4 plasmid. Using these enzymes, deletion mutants of R906 plasmid have been obtained in vitro which only lost short DNA fragments (1 to 14 kb). A narrow host range pAV1 plasmid of the same incompatibility group has been transformed into the cells of Escherichia coli. pAV1 is stably maintained in the new host and retains its narrow host range in the course of conjugation. Different restriction fragments of R702, R751, R906 and R906-derived deletion mutants hybridize with the nick-translated probe of RP4 DNA. It is suggested that the wide host range plasmids have a similarity in structural and functional organization.     

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.     

Transposition of the phage D3112 genome in Escherichia coli cells

It has been demonstrated that the genome of phage D3112 of Preudomonas aeruginosa can be transposed into Escherichia coli chromosome as a component of the hybrid plasmid RP4 TcrKms::D3112. Also, transposition of D3112 from E. coli (D3112) chromosome into RP4 plasmid occurs. The phage stimulates the chromosome mobilizing activity of RP4 plasmid, similar to other transposons. E. coli (RP4::D3112) cells were previously shown to form no colonies at 30 degrees C. Auxotrophic mutants and mutants incapable of utilizing different carbohydrates were found among E. coli clones survived after a long incubation at 30 degrees C (at frequencies approximately 10(-3) - 10(-4). These mutants inherited stably the capability to produce D3112 phage. E. coli auxotrophic mutants have arisen indeed as a consequence of phage integration into the E. coli chromosome, since prototrophic transductants derived from these mutants after their treatment with generalized transducing P1 phage have lost the ability to produce D3112 phage. Clones with mutations in Km or Tc genes of RP4 plasmid, occurring at high frequencies (about 3%) were found after introduction of RP4 into E. coli (D3112). These mutant RP4 plasmids carry insertions of D3112 genomes. Clones of E. coli which lost mutant plasmids still produce D3112 and retain their initial auxotrophic mutations.     

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.     

Inheritance of biodegradation plasmids in the cells of homo- and heterologous hosts

A systematic analysis of the inheritance of D plasmids of the IncP-9 group (α-, β-, γ-, δ-, ?-, ζ-, η-, and θ-subgroups), IncP-7, as well as of those of undefined systematic affiliation in the cells of homologous (Pseudomonas putida) and heterologous (Escherichia coli) hosts was performed for the first time. For this purpose, mini-Tn5 transposons determining resistance to kanamycin (or streptomycin) were introduced into all the D plasmids under study. It has been established that all IncP-9 plasmids can be transmitted to the cells of a heterologous host E. coli (with the exception of plasmid pSVS15 from gq-subgroup). IncP-7 plasmids and those of undefined systematic affiliation do not possess this property and can be transmitted and stably inherited only in P. putida. The distinctive feature of most IncP-9 plasmids (α-, β-, δ-, ?-, and ζ-subgroups) is strict dependence of their inheritance on the temperature factor. At 37°C, the plasmids of δ-, ζ-, and θ-subgroups are unstable in P. putida cells, while in E. coli nearly all plasmids of this systematic group are unstable. The exceptions are the plasmids of η- and γ-subgroups. Inheritance of these plasmids does not depend on temperature. At 28°C and 37°C, the η plasmid is not maintained stably (inheritance stability is 2%), while the γ-plasmid has almost 100% stability.     

Increased abundance of IncP-1beta plasmids and mercury resistance genes in mercury-polluted river sediments: first discovery of IncP-1beta plasmids with a complex mer transposon as the sole accessory element

Although it is generally assumed that mobile genetic elements facilitate the adaptation of microbial communities to environmental stresses, environmental data supporting this assumption are rare. In this study, river sediment samples taken from two mercury-polluted (A and B) and two nonpolluted or less-polluted (C and D) areas of the river Nura (Kazakhstan) were analyzed by PCR for the presence and abundance of mercury resistance genes and of broad-host-range plasmids. PCR-based detection revealed that mercury pollution corresponded to an increased abundance of mercury resistance genes and of IncP-1beta replicon-specific sequences detected in total community DNA. The isolation of IncP-1beta plasmids from contaminated sediments was attempted in order to determine whether they carry mercury resistance genes and thus contribute to an adaptation of bacterial populations to Hg pollution. We failed to detect IncP-1beta plasmids in the genomic DNA of the cultured Hg-resistant bacterial isolates. However, without selection for mercury resistance, three different IncP-1beta plasmids (pTP6, pTP7, and pTP8) were captured directly from contaminated sediment slurry in Cupriavidus necator JMP228 based on their ability to mobilize the IncQ plasmid pIE723. These plasmids hybridized with the merRTDeltaP probe and conferred Hg resistance to their host. A broad host range and high stability under conditions of nonselective growth were observed for pTP6 and pTP7. The full sequence of plasmid pTP6 was determined and revealed a backbone almost identical to that of the IncP-1beta plasmids R751 and pB8. However, this is the first example of an IncP-1beta plasmid which had acquired only a mercury resistance transposon but no antibiotic resistance or biodegradation genes. This transposon carries a rather complex set of mer genes and is inserted between Tra1 and Tra2.     

Novel helper phage design: intergenic region affects the assembly of bacteriophages and the size of antibody libraries

Abstract Phagemid vectors for display of proteins/peptides on the surface of filamentous phage utilize a plasmid genome carrying the phage origin of replication, along with the gene fused to a fragment of gene III. Generation of phage particles displaying the fusion protein also requires superinfection of the host bacterium with a helper virus. We describe here the construction of a new gene III mutant of M13 KO7 bacteriophage and compare its ability to act as helper phage with two mutants derived from Fd tet (fKN 16 and fCA 55). Furthermore, we investigate their capability to act as helper phages in SAP selection, where non-infectious helper phage, expressing antibody fragments but not protein 3, can still infect by first reacting with a soluble antigen-protein 3 fusion protein. Gene III mutants were found to be non-infectious, and high titers of infective particles were obtained only when the helper phage was grown in cells harbouring a gene III-containing plasmid. An amplification of the phage titer of 10⁶× was achieved in M13-derived phages, when used for the selection of specific antibody fragments.     

质粒在大肠杆菌对噬菌体抗性中的作用

The introduction of the ColV, I-K94 or R124 plasmid into Escherichia coli K12 resulted in resistance to certain phages. Derivatives of E. coli carrying the plasmid R124 and ColV, I-K94 were resistance to the phages T4, Mel comparing with the plasmid-free parent and the plasmid ColV, I-K94 conferred resistance to the phage Tull*. It suggested that an envelope change caused by the plasmids might be responsible for the resistance because most of the phages fell to absorb to the plasmid-bearing E. coli cells.     

Plasmids for naphthalene biodegradation incompatible with IncP-2 and IncP-7 group plasmids

Fourteen conjugative naphthalene degradative plasmids have been classified by incompatibility. It is shown that the plasmids of IncP-9 group are characterized by the minor entry exclusion, with respect to the R plasmids belonging to IncP-2 or IncP-7 groups. On the other hand, the naphthalene degradative plasmids of incompatibility group P-7 exhibit a markedly pronounced entry exclusion, with respect to the R plasmids of the same incompatibility groups. Two naphthalene degradative plasmids reveal incompatibility with the reference plasmids of two Inc groups (P-2 and P-7). These plasmids control also resistance of bacterial cells to potassium tellurite, which is characteristic of the IncP-2 plasmids. Two other naphthalene degradative plasmids are capable of stable coexistence with the IncP-2, P-7 or P-9 reference plasmids.     

Multiplicity of the integration sites of Mu-like bacteriophages into Pseudomonas aeruginosa chromosome and plasmids

It has been shown that D3112 prophage can be integrated into different chromosomal sites of Pseudomonas aeruginosa. The other Mu-like phages (B3, B39, PM69) are capable to insert their genomes during infection process into the plasmids RPL11, RMS148, RMS163. Their integration is occasionally accompanied by formation of mutations in plasmid genes. The certain types of auxotrophic and morphological mutants (thi, met, pigmented, met - pigmented) can be found at a frequency about 10% among survivors after a long (48 h) incubation at 42 degrees C of PAO (D3112cts15) or PAO (B39cts1) lysogens. The spectrum of mutants might depend on the time of heat induction. After a short exposure (10-20 min), arg and pigmented mutants can be found. Accumulation of certain kinds of mutants after heat induction is quite a specific phenomenon for Mu-like phages; heat induction of PAO (F116ts245) does not lead to selection of these specific bacterial mutants (F116 is unrelated to Mu-like phages and has extrachromosomal location).     

Lysogenic conversion caused by phage phi 80. III. The mapping of the conversion gene and additional characterization of the phenomenon

The cor gene specifies lysogenic conversion caused by the lambdoid phage phi 80. The cor gene product inhibits tonA function in infected and lysogenic cells. The cells harboring pBR322 plasmid with the cloned cor gene of phi 80 became resistant to the phages T1 and phi 80 (TonA phenotype). The cor gene was mapped between 24 and 13 genes on the phi 80 phage genetic map. It is not essential for phage lytic growth. Its presence in lysogens leads up to accumulation of tonA mutants in a cell population.