R factor variants with enhanced sex factor activity in Pseudomonas aeruginosa

Summary The R factor R68 readily promotes chromosome transfer in Pseudomonas aeruginosa strain PAT, but shows little such sex factor activity in strain PAO. A variant of this plasmid, R68.45, has been isolated which produces recombinants in PAO plate matings at frequencies of 10^-3–10^-5 per donor cell for markers in the 0–60 min region of the chromosome. Little or no chromosome transfer was shown in liquid media. The kinetics of chromosome transfer were studied by interrupting matings on solid media with nalidixic acid. Five chromosomal markers, mapping in widely spaced regions of the chromosome all entered 3–5 min after initiation of mating. These results, combined with linkage studies, indicate that R68.45, unlike the Pseudomonas sex factors FP2 and FP39, promotes chromosome transfer from a range of origin sites and can thus be used for mapping the region of the P. aeruginosa chromosome later than 40 min.R68.45 and other similar variants were isolated from rare chromosomal recombinants appearing in crosses between PAO(R68) donors and PAO recipients in which selection for argB ⁺ was made. Selection for other chromosomal markers did not result in such variants suggesting that plasmids of the R68.45 type arise by recombination of genetic material between the R68 plasmid and certain regions of the bacterial chromosome.     

Chromosome mobilization by the R plasmid R68.45: a tool in Pseudomonas genetics.

Summary The conjugative plasmid R68.45 mobilizes the chromosome of Pseudomonas aeruginosa strain PAO from multiple sites located in different chromosome regions. In interrupted matings on the plate, selection for any single marker tested resulted in entry times of 3–5 min. When selection was imposed for two markers linked in R68.45-mediated conjugation, double recombinants appeared after a delay which corresponded approximately to the map distance between the two markers as measured by the sex factor FP2. Thus, R68.45 and FP2 appear to promote chromosome transfer at similar rates, but R68.45, unlike FP2, seems to give non-polarized transfer. R68.45 may be used to estimate map distances between linked markers located in those chromosome regions where other sex factors do not produce enough recombinants to permit accurate measurement of entry times.In R68.45 matings on the plate, most recombinants inherited short donor chromosome fragments (usually less than 10 min long) and lost the R plasmid during purification. Used like a large generalized transducing phage, R68.45 has proved valuable in construction of PAO strains with desired genotypes.     

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.     

IS21 insertion in the trfA replication control gene of chromosomally integrated plasmid RP1: a property of stable Pseudomonas aeruginosa Hfr strains

Summary Broad host range IncP-1 plasmids are able to integrate into the chromosome of gram-negative bacteria. Strains carrying an integrated plasmid can be obtained when the markers of a temperature-sensitive (ts) plasmid derivative are selected at non-permissive temperature; in this way Hfr (high frequency) donor strains can be formed. The integrated plasmids, however, tend to be unstable in the absence of continuous selective pressure. In order to obtain stable Hfr donor strains of Pseudomonas aeruginosa PAO, we constructed a derivative of an RP1 (ts) plasmid, pME134, which was defective in the resolvase gene (tnpR) of transposon Tn801. Chromosomal integration of pME134 was selected in a recombination-deficient (rec-102) PAO strain at 43°C. Plasmid integration occurred at different sites resulting in a useful set of Hfr strains that transferred chromosomal markers unidirectionally. The tnpR and rec-102 mutations prevented plasmid excision from the chromosome. In several (but not all) Hfr strains that grew well and retained the integrated plasmid at temperatures below 43°C, the insertion element IS21 of RP1 was found to be inserted into the trfA locus (specifying an essential trans-acting replication funtion) of the integrated plasmid. One such Hfr strain was rendered rec ⁺; from its chromosome the pME134::IS21 plasmid (=pME14) was excised and transferred by conjugation to Escherichia coli where pME14 could replicate autonomously only when a helper plasmid provided the trfA ⁺ function in trans. Thus, it appears that trfA inactivation favours the stability of chromosomally integrated RP1 in P. aeruginosa.     

The insertion sequence IS21 of R68.45 and the molecular basis for mobilization of the bacterial chromosome

The IncP-1 plasmid mutant R68.45, which is able to mobilize the chromosomes of many Gram-negative bacteria, was shown to carry a 2.10-kb insertion sequence designated IS21. This sequence transposed to the small multicopy plasmid pED815 at a high frequency (2 × 10^?3) and in two pED815::IS21 derivatives inactivated the tetracycline-resistance and replication functions, respectively. We propose that the chromosome-mobilizing ability of R68.45 is due to the formation of an R68.45-chromosome cointegrate during transposition of IS21. This would account for its high efficiency and the absence of a fixed chromosomal origin of transfer in Pseudomonas aeruginosa PAO, and its ability to function in a variety of bacterial hosts. R68.45 is formed from R68 by duplication of a 2.1-kb DNA segment including a distinctive cluster of seven restriction endonuclease sites. The two copies of the duplicated segment are probably contiguous and so might have arisen by a transition type of mechanism. IS21 is similar in length to the duplicated segment and includes the same set of seven cleavage sites located at similar distances from the two termini. However, the single copy of the duplicated segment in R68 transposed at an undetectably low frequency (<6 × 10^?8); either the duplicated segment and IS21, although overlapping, are not identical, or they are identical but the transposition system is nonfunctional in R68. Our further investigations of R68.45 and of several independently isolated chromosome-mobilizing derivatives of R68 demonstrated that these were indistinguishable from each other and that they did not include any P. aeruginosa PAO DNA. Furthermore, we searched without success for sequences corresponding to IS21, and to the Escherichia coli K-12 insertion sequences IS1, IS2, and IS3, on the chromosomes of P. aeruginosa PAO and PAT and P. putida PPN, and on several Pseudomonas plasmids. The contribution of homology to low-frequency chromosomal mobilization by these plasmids is discussed.     

Conjugational transfer systems of Rhodopseudomonas capsulata mediated by R plasmids

Plasmids RP1, R68.45 and RP4::Mu cts 61 were transferred into Rhodopseudomonas capsulata from Escherichia coli. The frequency of intraspecies transfer of these plasmids in R. capsulata was 10^-4–10^-5 per donor. The plasmids also mobilized chromosomal genes at a low frequency. Phototrophic recombinants from matings between recipient strains defective in the photosynthetic-apparatus and wild type donors were obtained at a frequency of 10^-7–10^-8 per donor.     

Construction of recombination-deficient strains of Pseudomonas aeruginosa

Summary The rec-102 mutation had pleiotropic effects in Pseudomonas aeruginosa: low recombination proficiency in conjugation and transduction; high UV sensitivity; inability to induce pyocin R2 by mitomycin C; and increased susceptibility to mitomycin C and nalidixic acid. The rec-102 locus was mapped by R68.45-mediated conjugation in the 45 min region of the PAO chromosome, between argF and thr-9001. By selection for a marker in this region, rec-102 can be introduced into a P. aeruginosa strain of interest using an R68.45 rec-102 donor. The recombination-deficient strains constructed in this way were phenotypically similar to Escherichia coli recA mutants.     

Spontaneous deletions of the chromosome-mobilizing plasmid R68.45 in Pseudomonas aeruginosa PAO

In Pseudomonas aeruginosa strain PAO the chromosome-mobilizing IncP-1 plasmid R68.45 was unstable whereas the parent plasmid R68 was stable. The instability of R68.45 was observed in rec+ and rec strains within about 100 generations after conjugal transfer of the plasmid and, to a lesser extent, in established R68.45 donor strains. Two phenotypically distinct classes of R68.45 derivatives were obtained: (i) CbR (carbenicillin-resistant), TcR (tetracycline-resistant), KmR (kanamycin-resistant), Tra+ (transfer proficient), Cma- (chromosome-mobilizing ability), lacking the duplicated IS21 copy typical of R68.45 and indistinguishable from R68 by restriction enzyme analysis; (ii) CbR TcR KmS Tra- Cma-, due to deletion of one IS21 copy, the adjacent KmR gene, and a variable part of the Tra-1 region including, in most cases, the origin of transfer (oriT). Both types of deletion derivatives were stable. R68.45 derivatives lacking the Tra-2 region were not recovered spontaneously, but could be constructed in vitro and were stable in strain PAO. Deletion formation of type ii as well as Cma did not depend on homologous recombination and can be ascribed to functions of the duplicated IS21. Chromosome mobilization does not appear to require obligatory transfer of the entire R68.45 plasmid. Four ClaI restriction sites were mapped on R68 extracted from P. aeruginosa. One of these sites was cryptic, presumably because of methylation, when the plasmid was prepared from Escherichia coli (dam+).     

R-plasmid-mediated chromosomal gene transfer in Agrobacterium tumefaciens.

Although several techniques are available for transferring the Ti plasmids from one strain of agrobacterium tumefaciens to another, there are no reproducible methods for analysis of chromosomal markers in this phytopathogen. The R plasmid, R68.45, is known to show chromosomal mobilizing ability in several bacterial genera including the closely related Rhizobia. R68.45 was transferred into the prototrophic A. tumefaciens strain 15955. Ten kanamycin-resistant transconjugant clones were tested for chromosomal mobilizing ability by mating with strain SA10, rifampin- and streptomycin-resistant histidine auxotroph of strain 15955. Of the 10 donor clones, 2 showed high chromosomal mobilizing ability. Between 1,000 and 2,000 His+ colony-forming units per ml were obtained, a value 10 to 20 times greater than can be accounted for by spontaneous reversion. Sequential recloning and matings resulted in the isolation of relatively stable donor cultures. Chromosome gene transfer is dependent upon the presence in the donor of R68.45. Donors lacking an R plasmid or harboring the closely related plasmid RP4 failed to yield His+ transconjugants. With strain SA11, a methionine auxotroph of strain SA10, coinheritance of histidine and methionine independence could be demonstrated. Approximately half of the transconjugants also inherited R68.45. These results indicate that A. tumefaciens 15955 is capable of undergoing host chromosomal genetic exchange.     

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.     

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.     

Revised locations of the hisI and pru (proline utilization) genes on the Pseudomonas aeruginosa chromosome map

Summary The location of genes in the vicinity of the major FP2 origin on the chromosome of Pseudomonas aeruginosa PAO has been revised. The markers hisI (a transduction group of histidine biosynthetic genes) and pru (a gene cluster encoding proline utilization functions) were located in the 90 to 95/0 min chromosome region by a series of plate matings mediated by R68.45. Three-factor-crosses using this plasmid established the following marker order: pur-67 pru hisI/cys-59 proB ilvB/C. Genetic evidence is presented to confirm the previous observations that FP2 can mobilize the chromosome from at least two origins near proB and in both directions. Thus, when markers in this chromosome region are analyzed by FP2 crosses only, the mapping data may be difficult to interpret. This complication can be overcome by the use of R68.45 and Tfr (transposon-facilitated recombination) or Hfr donors.     

In vivo generation of R68.45-pPGH1 hybrid plasmids conferring a Phl+ (meta pathway) phenotype

Summary Plasmid pPGH1 originating from Pseudomonas putida strain H carries all the genes required for the degradation of phenol (or cresols) via the meta cleavage pathway. Besides mobilization of pPGH1 by a plasmid of the incompatibility group P-1, hybrid plasmids conferring the Phl⁺ phenotype could be selected, when R68.45 was the conjugative plasmid. The hybrids contain the complete R68.45 and part of pPGH1. Integration of Phl-DNA of pPGH1 into R68.45 occurred exclusively via the IS21 region of R68.45.Dedicated to Udo Taubeneck on the occasion of his 60th birthday     

Contribution of the Earthworm Lumbricus rubellus (Annelida,Oligochaeta) to the Establishment of Plasmids in Soil Bacterial Communities

The contribution of the carthworm Lumbricus rubellus in spreading plasmids from a nonindigenous bacterial species to the soil microbial community was studied with Escherichia coli strains as donor organisms. The selected donor strains harbored marker-gene tagged plasmids with different transfer properties and host ranges. Prototrophic benzoate degrading indigenous bacteria were analyzed as potential recipients. In filter-mating experiments, donor strains were mixed with bacterial cell consortia extracted from earthworm casts (feces) and incubated on nutrient agar at 28°C. Transfer was detected with the broad host range IncP plasmid pRP4luc; with the IncQ plasmid, pSUP104luc, but only when it was present in a mobilizing donor strain; and with the transposon delivery vector pUTlux. No transfer was detected with the nonmobilizable pUCluc and the mobilizable pSUP202luc, both of narrow host range. In microcosm studies with E. coli inoculated soil incubated at 12°C, transconjugants were only detected in casts of L. rubellus but not in bulk soil, indicating that the gut passage was a precondition for plasmid transfer. Plasmid pRP4luc was transferred at higher frequencies than detected in filter mating. Results of the filter matings were confirmed except that transfer of pUTlux could not be detected. The majority of transconjugants isolated in this study lost their acquired plasmid upon further cultivation. Stable transconjugants, however, were obtained and identified at the 16S rRNA gene level as members of the β- and γ-subgroups of Proteobacteria. Incubation of E. coli and selected transconjugants in soil microcosms with L. rubellus demonstrated that the gut passage resulted in a slight but significant reduction of ingested cells. In contrast to the donor strains, however, the population sizes of transconjugants in bulk soil and in casts did not decrease over time. This demonstrated that the transferred plasmids had established themselves in the soil microbial community.     

Conjugal retrotransfer of chromosomal markers inAzotobacter vinelandii

The IncP plasmids R68.45 and pJB3JI mediate retrotransfer (i.e., transfer of chromosomal markers from the recipient bacterium to the original donor) in homologous matings withAzotobacter vinelandii. Retrotransfer is not an early event inAzotobacter. On the contrary, it begins after genetic transfer in the usual direction, i.e., from the donor bacterium to the recipient, has been taking place for some time. Transfer of chromosomal markers mediated by the RP4/Tn5-Mob system does not undergo retrotransfer. The simplest hypothesis compatible with our results is that IncP plasmids that confer a high chromosome-mobilizing ability promote retrotransfer when transferred to the recipient bacteria.     

Conjugative Transfer of Chromosomal Genes between Fluorescent Pseudomonads in the Rhizosphere of Wheat

Bacteria released in large numbers for biocontrol or bioremediation purposes might exchange genes with other microorganisms. Two model systems were designed to investigate the likelihood of such an exchange and some factors which govern the conjugative exchange of chromosomal genes between root-colonizing pseudomonads in the rhizosphere of wheat. The first model consisted of the biocontrol strain CHA0 of Pseudomonas fluorescens and transposon-facilitated recombination (Tfr). A conjugative IncP plasmid loaded with transposon Tn5, in a CHA0 derivative carrying a chromosomal Tn5 insertion, promoted chromosome transfer to auxotrophic CHA0 recipients in vitro. A chromosomal marker (pro) was transferred at a frequency of about 10(sup-6) per donor on wheat roots under gnotobiotic conditions, provided that the Tfr donor and recipient populations each contained 10(sup6) to 10(sup7) CFU per g of root. In contrast, no conjugative gene transfer was detected in soil, illustrating that the root surface stimulates conjugation. The second model system was based on the genetically well-characterized strain PAO of Pseudomonas aeruginosa and the chromosome mobilizing IncP plasmid R68.45. Although originally isolated from a human wound, strain PAO1 was found to be an excellent root colonizer, even under natural, nonsterile conditions. Matings between an auxotrophic R68.45 donor and auxotrophic recipients produced prototrophic chromosomal recombinants at 10(sup-4) to 10(sup-5) per donor on wheat roots in artificial soil under gnotobiotic conditions and at about 10(sup-6) per donor on wheat roots in natural, nonsterile soil microcosms after 2 weeks of incubation. The frequencies of chromosomal recombinants were as high as or higher than the frequencies of R68.45 transconjugants, reflecting mainly the selective growth advantage of the prototrophic recombinants over the auxotrophic parental strains in the rhizosphere. Although under field conditions the formation of chromosomal recombinants is expected to be reduced by several factors, we conclude that chromosomal genes, whether present naturally or introduced by genetic modification, may be transmissible between rhizosphere bacteria.     

Conjugal TOL Transfer from Pseudomonas putida to Pseudomonas aeruginosa: Effects of Restriction Proficiency, Toxicant Exposure, Cell Density Ratios, and Conjugation Detection Method on Observed Transfer Efficiencies

The effects of restriction proficiency and premating exposure to toxicants on conjugal transfer of the TOL plasmid between Pseudomonas spp. was investigated by examinations of filter matings. A Pseudomonas putida KT2442-derived strain carrying a gfp-tagged variant of the TOL plasmid was used as a donor, and both restriction-deficient (PAO1162N) and -proficient (PAO2002N) Pseudomonas aeruginosa strains were used as recipients. The in situ enumeration of conjugation events allowed us to obtain frequency estimates that were unbiased by transconjugant growth or plasmid retransfer. We observed a strong dependence of the plasmid transfer frequency on the initial donor-to-recipient ratio of surface matings, which invalidated the use of mass action-based plasmid transfer kinetic estimators. Careful control of the initial parental cell densities permitted evaluations of the true effects of restriction proficiency and toxicant exposure on TOL transfer. At standard donor-to-recipient ratios (10⁻³ for PAO1162N and 2 × 10¹ for PAO2002N) and total cell densities (10⁵ cells/mm² for PAO1162N and 10⁶ cells/mm² for PAO2002N), plasmid transfer frequencies without toxicant exposure were approximately 10⁻⁷ (events/mm²)⁻¹ for PAO1162N and 10⁻¹¹ (events/mm²)⁻¹ for PAO2002N based on in situ observations of conjugation events. The enumeration of transconjugants via selective plating yielded transfer frequencies that were up to 1 order of magnitude lower. Premating exposure to sodium dodecyl sulfate (1 to 10 mM) significantly increased the transfer frequency for the restriction-proficient strain PAO2002N (P < 0.05) but not for the restriction-deficient strain PAO1162N. On the other hand, premating exposure to ethanol, toluene, or phenol had no positive effect on the plasmid transfer frequency. Clearly, restriction proficiency provides a strong barrier to interspecific transfer of the TOL plasmid, and this barrier was only marginally attenuated by recipient exposure to toxicants within the ranges examined.     

Plasmid R68.45 and S-a transduction by the temperate bacteriophage 59 of Erwinia carotovora 268

Temperature bacteriophage 59 of Erwinia carotovera 268 had transduced extrachromosomal DNA: plasmids of R68.45 and S-a. Before plasmid transduction experiments the suitable donor strains of indicator culture Erwinia horticola 450 harbouring R68.45 and S-a were created. The frequency of plasmid R68.45 transfer from Pseudomonas putida to E. horticola 450-8 by conjugation was equal to 5 x 10(-8) per a donor cell and in the case of S-a--from E. coli C600 for the same recipient cells--was 2 x 10(-6). Bacteriophage 59 has transduced only separate markers of plasmid R68.45, since plasmid S-a is probably transduced by the phage as an intact unit.     

Mapping of the gene specifying aminoglycoside 3''-phosphotransferase II on the Pseudomonas aeruginosa chromosome.

We examined the aminoglycoside inactivation enzymes in Pseudomonas aeruginosa strains, seven clinical isolates and seven laboratory strains without plasmids. All strains were found to possess the enzyme aminoglycoside 3'-phosphotransferase II [APH(3')-II]. We isolated an APH(3')-II-deficient mutant from a PAO strain by mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. By plasmid (FP5 or R68.45)-mediated conjugation, we determined the locus of the gene specifying the APH(3')-II between trp-6 and pro-82 on the PAO chromosome and designated this gene aphA. It was concluded that the intrinsic resistance of P. aeruginosa to kanamycins, neomycins, paromomycins, ribostamycin, and butirosins was due to this newly determined gene.     

Transformation of Pseudomonas aeruginosa and Escherichia coli with resistance plasmid DNA: formation of smaller conjugative plasmids from RPI.

Summary Sheared DNA from RPI, an R plasmid from a strain of Pseudomonas aeruginosa, was used to transform other strains of P. aeruginosa and Escherichia coli. From transformed cells other plasmids like RPI were isolated. These deletion plasmids were conjugally transferrable and confer resistance mainly against carbenicillin and tetracycline.