RP1 properties and fertility inhibition among P, N, W, and X incompatibility group plasmids.

Incompatibility group P plasmids demonstrate strong entry exclusion properties. Stringent incompatibility is also observed in the absence of entry exclusion. These observations have been facilitated by the study of a nontransmissible plasmid, RP1-S2, derived from RP1 by transductional shortening. RP1-S2 retains carbenicillin and tetracycline resistances as well as loci that cause either the loss of P plasmids (incp) or a locus specifying susceptibility to curing (sinp) in the presence of a P plasmid. RP1-S2 can be mobilized by an incompatibility group W plasmid, R388, and also freely forms recombinants with R388. P, N, and W incompatibility group plasmids all encode information for the receptor of the cell wall-adsorbing phage PRD1. Based on the premise that the location of this receptor is analogous to entry exclusion factors for F-like plasmids and hence a regulated transfer region determinant, we tested fertility inhibition relationships among these plasmid groups. We detected both reciprocal and nonreciprocal fertility inhibition relationships for bacteria containing various combinations of W, N, and P group plasmids. The nonreciprocal nature of some combinations, we believe, reflects the identity of the point mutation reading to derepression of the plasmid in question. Reciprocal fertility inhibition, on the other hand, may reflect the reconstruction of a fertility inhibition system through complementation. An X incompatibility group plasmid, known to affect the fertility of an N group plasmid, was also shown to inhibit P plasmid fertility. These observations may indicate a possible evolutionary relationship(s) of plasmids unrelated by the criteria of incompatibility, pilus phage specificity, or plasmid host range.     

Transfer of Drug Resistance Factors to the Dimorphic Bacterium CAULOBACTER CRESCENTUS

The P-type drug resistance factors RP4, RK2, R702, R68.45, and the N-type drug resistance factor R46 are transferred to Caulobacter crescentus at high frequencies. They are stably maintained and their antibiotic resistances are expressed. Experiments with RP4 have shown that intergeneric transfer of RP4 occur at a frequency of 10(-1). C. crescentus strains maintain RP4 as a plasmid, are sensitive to RP4-specific phage, and segregate phage-resistant cells at a frequency of 10(-4) to 10(-5). The RP4 plasmid can be used in several ways: (1) the RP4 plasmid will promote chromosomal exchange between C. crescentus strains at frequencies ranging from 10(-6) to 10(-8); (2) RP4 will promote the transfer of nonconjugative colE1 plasmids from E. coli to C. crescentus; once transferred, the colE1 plasmid is stably maintained under nonselective conditions, can be transferred serially, and segregates independently from RP4; and (3) RP4 can be used to introduce transposons into the C. crescentus chromosome, providing the basis for additional genetic techniques.     

Isolation of an Hfr donor of Pseudomonas aeruginosa PAO by insertion of the plasmid RP1 into the tryptophan synthase gene

Summary A derivative of the IncP-1 plasmid RP1, temperature-sensitive for maintenance, was inserted into the Pseudomonas aeruginosa chromosome by selection for a plasmid marker (carbenicillin resistance) at nonppermissive temperature. In one strain, PAO 1000, the plasmid was stably integrated in the trpA, B gene cluster mapped at 27 min, as shown by the following evidence. (i) Trp⁺ transductants lost all plasmid markers. (ii) Cleared lysates of PAO 1000 showed no plasmid band typical of the autonomous RP1 in agarose gel electrophoresis. (iii) No transfer of carbenicillin resistance by PAO 1000 was detectable. (iv) PAO 1000 mobilised the chromosome from an origin at, or very near, the plasmid insertion site with high frequency (recovery of proximal markers 10^–3 per donor). Matings on the plate with and without interruption of conjugation showed that chromosome transfer was unidirectional. (v) Recombinants from PAO 1000-mediated crosses did not inherit plasmid markers or the trpA, B mutation. A derivative of PAO 1000 was obtained which had lost the Hfr property and all plasmid markers except carbenicillin resistance. This strain (PAO 1001), when carrying the autonomous RP1 plasmid, was capable of unidirectional chromosome mobilisation like PAO 1000, but with 50-fold lower efficiency. We propose that integration of the temperature-sensitive RP1 plasmid in PAO 1000 occurred via transposition of Tnl, the element specifying carbenicillin resistance.     

Evolution and utility of a Pseudomonas aeruginosa drug resistance factor.

We describe the addition to the Pseudomonas aeruginosa sex factor, FP2, of carbenicillin resistance encoded by the RP1 plasmid. This occurred in a step-wise manner as detected by variations in the characteristics of the FP2-RP1 plasmid aggregate. The addition of the carbenicillin resistance marker to FP2 facilitates estimates of FP2 transfer. Transfer frequencies for the presumed cointegrate plasmid, using carbenicillin selection, approached 10(-1) per donor bacterium. The chromosomal mobilization properties of the derived plasmid, designated pR0271, resembled those of the progenitor plasmid FP2. Plasmid pR0271 was also observed to mobilize a nontransmissible drug resistance plasmid sharing genetic homology at frequencies corresponding to those observed for chromosomal markers proximal to the origin of transfer.     

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.     

Transfer and expression of pseudomonas plasmid RP1 in Caulobacter.

This study demonstrates that the host range of Pseudomonas plasmid RP1 includes the genus Caulobacter. Caulobacter was shown to acquire three antibiotic resistance markers located in RP1. A fourth plasmid marker, susceptibility to an RNA bacteriophage, was not expressed, but could be transferred from Caulobacter to Escherichia coli. The lack of phenotypic expression of the phage marker was manifested by the inability of the phage to adsorb or to produce plaques on Caulobacter transcipients. Matings of Pseudomonas aeruginosa and Caulobacter vibrioides CV6 were carried out in the presence of bacteriophage phi6, a DNA phage that infects and kills only swarmer cells of Caulobacter. No decrease in plasmid transfer in the presence of phage phi6 was detected, suggesting that stalked cells, and not swarmer cells, serve as recipients. Our evidence suggests that transfer of chromosomal segments from Caulobacter may be mediated by plasmid RP1; such segments are not stably maintained.     

Properties of RP4, an R Factor Which Originated in Pseudomonas aeruginosa S8

RP4, an R factor derived from Pseudomonas aeruginosa S8 and specifying resistance to carbenicillin, neomycin, kanamycin, and tetracycline, could be isolated as an extrachromosomal satellite of covalently closed circular DNA (CCC-DNA) of molecular weight about 62 million and of buoyant density 1.719 g/cm(3) (60% guanine plus cytosine). When RP4 was compared by hybridization with RP1, an R factor originating in another strain of P. aeruginosa, it was shown that RP4 contains most, if not all, of the base sequences of RP1, and also additional sequences not found in RP1.     

Conjugation in Rhodopseudomonas sphaeroides mediated by R plasmids

Plasmids R68.45, RP4, RP4::Mu cts62, RP1ts::Tn10, RP1ts::Tn9, Rts1 and RP41 were transferred into cells of photosynthetic nitrogen-fixation bacterium Rhodopseudomonas sphaeroides from Escherichia coli and Pseudomonas aeruginosa. The transfer of plasmids occurred with high frequency of 10(-1) to 10(-2) per donor cell in all cases. Mobilization of R. sphaeroides 2R chromosome was obtained by RP4 and Rts1 plasmids at a frequency of 10(-7) to 10(-8) per donor cell in all cases. Mobilization of R. sphaeroides 2R chromosome was obtained by RP4 and Rts1 plasmids at a frequency of 10(-7) to 10(-8) per donor cell. Bacteriophage Mu cts62 could be induced from the plasmid DNA in R. sphaeroides 2R cells and was capable of the lytic growth and producing phage progeny. It was demonstrated that an increase in the efficiency of donor chromosomal genes transfer into recipient cells could be achieved in crosses with the donor carrying RP4::Mcts62 plasmid.     

Plasmid transduction using the D3112DeltaH miniphage in Pseudomonas aeruginosa cells]

Plasmid DNA transduction with mini-D3112 delta H, deletion derivative of phage D3112, which lost the genes essential for phage growth but retained the sites required for transposition and packaging was studied. Unlike D3112, mini-D3112 delta H element can transduce plasmids and plasmid markers at frequencies of 10(-5)-10(-8) in rec+ cells of Pseudomonas aeruginosa. Plasmids R1162 and R388 of the size smaller than phage genome were transduced intact. Large plasmids, like RP4 and R151, were deleted under transduction. By this way, we isolated deletion derivatives of RP4. The smallest derivative pN2 contained a 4.5 kb fragment of RP4. Unlike the latter, pN2 plasmid had narrow host range and did not maintain in Escherichia coli cells.     

Integration of phage Mu into the RP4::D3112A-plasmid in Escherichia coli cells

Hybrid plasmids obtained as a result of Mu phage insertions into the RP4::D3112 plasmid in Escherichia coli cells were studied. Stable maintenance of RP4::D3112 plasmid in E. coli cells was provided by using the D3112 phage genome with a point polar mutation in the A gene which prevented early genes' expression. The presence of D3112A- in the RP4 plasmid has been shown to have no effect on efficiency of phage Mu transposition into this plasmid. Moreover, RP4 and D3112 genomes were equivalent targets for Mu integration. The integration of transposable phage into genome of nonrelated phage can be used as one of the approaches to construct recombinant phage genomes in vivo in the absence of DNA homology.     

Complete nucleotide sequences of 84.5- and 3.2-kb plasmids in the multi-antibiotic resistant Salmonella enterica serovar Typhimurium U302 strain G8430

The multi-antibiotic resistant (MR) Salmonella enterica serovar Typhimurium phage type U302 strain G8430 exhibits the penta-resistant ACSSuT-phenotype (ampicillin, chloramphenicol, streptomycin, sulfonamides and tetracycline), and is also resistant to carbenicillin, erythromycin, kanamycin, and gentamicin. Two plasmids, 3.2- and 84.5-kb in size, carrying antibiotic resistance genes were isolated from this strain, and the nucleotide sequences were determined and analyzed. The 3.2-kb plasmid, pU302S, belongs to the ColE1 family and carries the aph(3')-I gene (Kan(R)). The 84.5-kb plasmid, pU302L, is an F-like plasmid and contains 14 complete IS elements and multiple resistance genes including aac3, aph(3')-I, sulII, tetA/R, strA/B, bla(TEM-1), mph, and the mer operon. Sequence analyses of pU302L revealed extensive homology to various plasmids or transposons, including F, R100, pHCM1, pO157, and pCTX-M3 plasmids and TnSF1 transposon, in regions involved in plasmid replication/maintenance functions and/or in antibiotic resistance gene clusters. Though similar to the conjugative plasmids F and R100 in the plasmid replication regions, pU302L does not contain oriT and the tra genes necessary for conjugal transfer. This mosaic pattern of sequence similarities suggests that pU302L acquired the resistance genes from a variety of enteric bacteria and underscores the importance of a further understanding of horizontal gene transfer among the enteric bacteria.     

Conjugative R plasmids isolated from hospital strains of Pseudomonas aeruginosa]

It was shown that Pseudomonas aeruginosa hospital strains isolated from patients and environment in the Republican Centre of Burns in Tbilisi contained conjugative R plasmids. The plasmids were marked pM15 and pM19, respectively. The plasmid pM15 determined resistance to carbenicillin, kanamycin and tetracycline and plasmid pM19 determined resistance to carbenicillin, kanamycin, tetracycline, chloramphenicol, gentamicin and streptomycin. Plasmid pM15 had a molecular weight of 45.8 MD and seven sites for EcoRI, six sites for HindIII and five sites for Hpa-I-restrictase. This plasmid, as others, belongs to the Inc-P1 incompatibility group.     

Conjugation-mediated genetic exchange in Legionella pneumophila.

Genetic exchange mechanisms, to our knowledge, have not been reported for Legionella pneumophila, and consequently, studies on the genetic organization of L. pneumophila have not appeared in the literature. Here, we describe gene transfer mediated by broad host range conjugative plasmids in Legionella spp. Escherichia coli strains carrying plasmids RP1 and R68.45 (IncP1), S-a (IncW), and R40a (IncC), but not plasmids of incompatibility groups FI, FII, and FV, served as donors in matings with L. pneumophila Knoxville 1 (LPK-1). Transconjugants selected by resistance to kanamycin (RP1, R68.45, and S-a) and carbenicillin (R40a) were observed at frequencies of 6.6 X 10(-3), 4.7 X 10(-3), 2.2 X 10(-4), and 5.4 X 10(-5), respectively. Plasmid transfer was not affected by DNase added to the mating medium. After plasmid transfer, LPK-1 stably maintained RP1, R68.45, and S-a, but not R40a. Plasmid-containing LPK-1 isolates also served as donors in agar plate matings with E. coli W1485-1 and naladixic acid-resistant mutants of LPK-1, Legionella micdadei, and Legionella longbeachii. Recombinational exchange of a chromosomal trait was demonstrated when a thymidine auxotroph of L. pneumophila was repaired by R68.45-mediated chromosomal mobilization of a prototrophic donor strain.     

Transfer of nodulation ability in Rhizobium using R68.45 derived plasmids

Summary Nodulation ability was transferred from Rhizobium meliloti L5.30 to the non-nodulating mutant Rhizobium trifolii 24K using plasmid R68.45. Transconjugants selected for the carbenicillin resistance (cb ^r) marker became simultaneously capable of nodulating clover and showed changes in phage sensitivity. Besides the indigenous plasmid of 90 MD (pUCS201), the nodulating transconjugants harbored the newly introduced plasmid pUCS202 (ca. 40 MD). After treatment of the transconjugants with curing agents the simultaneous loss of antibiotic resistance and ability to form nodules were associated with the disappearance of pUCS202. nod and cb ^r genes were cotransferred into R. trifolii strains by conjugation and transformation. There is genetic evidence that the nod gene(s) was integrated into R68.45.     

Adsorption of bacteriophages specific for Pseudomonas aeruginosa R factors RP1 and R1822

Short, thick pili were found by electron microscopy on bacteria carrying the P group drug resistance plasmids RP1 and R1822. The R1822-specific phage PRR1 was seen to adsorb to the bases of the pili. Three RP1-specific phages, one filamentous (Pf3), and two with very thick capsids (PR3, PR4), were seen to attach all around the surface of $\text{P. aeruginosa}$ cells, and were thought to be somatic, since pilus phages appear to be strictly polar on this species. PR3 and PR4 also lysed a strain of $\text{E. coli}$ containing an N group plasmid, suggesting a relationship between the N and P group plasmids.     

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.     

Intergeneric mobilization of Rhizobium nif genes to Agrobacterium and Klebsiella.

Summary The P-1 incompatibility group plasmid RP1 transfers itself from Escherichia coli J53 to the clover endosymbiont bacterium Rhizobium trifolii strain T1 at low frequency in agar surface matings. R. trifolii T1 R-plasmid recipients display a phenotype identical to the wild-type parent strain in all respects except RP1 antibiotic resistances, allowing straightforward donor counterselection and differentiation of excojugants in further intergeneric plasmid transfer experiments. Hence RP1 can readily transfer itself intergenerically from R. trifolii T1 to the related plant pathogenic organism Agrobacterium tumefaciens and to a strain of the free-living diazotroph Klebsiella pneumoniae.Using R. trifolii T1 (RP1) as donor and as recipient LBA 4006, an avirulent strain of A. tumefaciens lacking the tumour-inducing (Ti) plasmid, selection was made for intergeneric transfer of the R-plasmid and its potential as vector of nitrogen-fixation genes evaluated by subsequent indirect screening. Exconjugant Agrobacteria were obtained which carried RP1 resistance markers and, given specific physiological conditions, would reduce acetylene under air. This is the first report of expression of nif genes in a hybrid strain of A. tumefaciens and is of interest since the Ti plasmid of this organism has been suggested as a natural vector for the introduction of these genes into plants. Plasmid RP1 also cotransferred Rhizobium nif genes to KP52, a strain of K. pneumoniae M5al, with deletion by phage eduction of the chromosomal genes for histidine biosynthesis, one of the nif regulatory genes (nif A), the gene for molybdenum cofactor (nif B) and for an electron transport protein of the nitrogen-fixation pathway (nif F). KP52 exconjugants carried RP1 drug resistances and reduced acetylene under anaerobic conditions.     

Genetic transfer of Pseudomonas aeruginosa R factors to plant pathogenic Erwinia species.

The R factors RP1, R68 and R91 were freely transmissible to and from Pseudomonas aeruginosa, Salmonella typhimurium, and various plant pathogenic Erwinia spp. The antibiotic resistance spectrum of R+ Erwinia recipients was similar to those of other bacteria harboring these R factors, but maximum resistance levels differed with each recipient. The sponstaneous elimination of these factors from the Erwinia strains and the ability to transfer multiple antibiotic resistance suggest that these exist as plasmids in these hosts. Several, but not all, RP1-carrying Erwinia strains were sensitive to the RP1 specific phage PRR1. The R factor R18-1 was also transferred from P. aeruginosa to Erwinia spp. R18-1 was unstable in all Erwinia strains. Stable strains were isolated in which R18-1 could not be eliminated by sodium dodecyl sulfate and could not be transferred to other strains.     

Host dependence of RP1-specified resistance to ampicillin: differential expression in Escherichia coli and Rhizobium leguminosarum.

Rhizobium leguminosarum L4 is able to serve as a host for the plasmid RP1. Properties of R. leguminosarum [RP1] plasmid carrier suggest that the expression of RP1-coded Apr gene(s) is inhibited in this host, although the determinants of transfer and resistance to kanamycin and tetracycline are expressed. This system exemplifies a differential expression of plasmid genes in a new host.     

An explanation for the apparent host specificity of Pseudomonas plasmid R91 expression.

Pseudomonas aeruginosa strain 9169 has been reported to contain a plasmid that expresses resistance to carbenicillin (Cb), kanamycin (Km), and tetracycline (Tc) in Escherichia coli but resistance only to Cb in certain Pseudomonas recipients. The triply resistant plasmid in E. coli belonged to incompatibility (Inc) group P or P-1, whereas the singly resistant plasmid in P. aeruginosa was compatible with IncP-1 plasmids and other plasmids of established Inc specificity but incompatible with plasmid pSR1 that is here used to define a new Pseudomonas Inc group P-10. Additional physical and genetic studies showed that strain 9169 contained not one but two plasmids: IncP-1 plasmid R91a, determining the Cb Km Tc phenotype, and IncP-10 plasmid R91, determining Cb that differed in molecular weight and in EcoRI and BamHI restriction endonuclease recognition sites. Plasmid multiplicity rather than host effects on plasmid gene expression can account for differences in the phenotype of strain 9169 transconjugants to E. coli and P. aeruginosa.