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.     

Transmission of F'lac plasmid from Escherichia coli K-12 to bacteria of the genus Erwinia]

The F'lac plasmid was transferred by conjugation from Escherichia coli K-12 W1655 to 21 lac- strains of Erwinia spp. (5.2 . 10(-6) to 6.8 . 10(-2) lac+ exconjugants per donor cell). Erw. herbicola and Erw. chrysanthemi were the better recipients than others. The degree of the stability of lac+ genes in Erwinia exconjugants depends on the strains. Stable exconjugants of Erwinia, which harbored F'lac plasmid, were able to utilize lactose, to transfer lac genes by conjugation to Erwinia spp. and E. coli, and were sensitive to the F-specific phages f1, f2, Qbeta. The F'lac plasmid was eliminated from the exconjugants by the treatment with acridine orange, which indicates that this genetic element is not integrated into the Erwinia chromosome.     

Transfer among Erwinia spp. and other enterobacteria of antibiotic resistance carried on R factors

Antibiotic resistance carried on R factors was transferred by conjugation from Escherichia coli B/r and Shigella flexneri 1a to Erwinia spp. Tetracycline resistance (TetR) carried on R factor R100 drd-56 was transferred from E. coli B/r to strains of Erwinia amylovora, E. aroideae, E. atroseptica, E. chrysanthemi, E. cytolytica, E. dissolvens, E. herbicola, E. nigrifluens, and E. nimipressuralis, but not to strains of Erwinia carotovora, E. carnegieana, E. dieffenbachiae, E. oleraceae, and E. quercina. Multiple antibiotic resistance (chloramphenicol, streptomycin, tetracycline; ChlR-StrR-TetR) carried on R factor SR1 was transferred from a clinical isolate of S. flexneri 1a to strains of E. aroideae, E. chrysanthemi, E. herbicola, and E. nigrifluens, but not to strains of other Erwinia spp. The frequency of this transfer was low with receptive cultures of Erwinia spp. and E. coli (F(-) strain). Antibiotic resistance in the exconjugants showed varying degrees of stability in the presence or absence of acridine orange, depending on the strain tested. The frequencies of segregation to drug susceptibility in the presence of acridine orange, though low, suggest that the elements exist as plasmids in the majority of the Erwinia exconjugants. Multiple antibiotic resistance (ChlR-StrR-TetR) was found to segregate into various resistance classes (ChlR-StrR, StrR-TetR, TetR, StrR, and none) in these exconjugants. The exconjugants of E. amylovora, E. herbicola, and E. nigrifluens, to which R100 drd-56 was transferred from E. coli B/r, were sensitive to the male (F)-specific phage M13. There was a positive correlation between the susceptibility of exconjugants to the F-specific phage M13 and their ability to transfer R100 drd-56 to the recipient cultures of Escherichia coli, Erwinia herbicola, Salmonella typhimurium, and Shigella dysenteriae. Exceptions were, however, noted with Erwinia dissolvens and E. nimipressuralis exconjugants harboring R100 drd-56; these exconjugants, although not susceptible to M13, transferred R100 drd-56 to the recipient cultures. The frequency of transfer of R100 drd-56 and the levels of resistance to tetracycline in Erwinia exconjugants were found to differ markedly depending upon the strain employed. Transfer of multiple antibiotic resistance (ChlR-StrR-TetR) from Erwinia exconjugants was not obtained in preliminary trials with an E. coli F(-) strain as the recipient culture.     

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.     

Host-dependent, thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae.

The thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae, was studied. pJY5 consisted of 61 million daltons of covalently closed circular (CCC) deoxyribonucleic acid (DNA) with a buoyant density of 1.714 g/cm3 (55 mol % guanine plus cytosine). In Escherichia coli, this plasmid replicated stringently at 32 degrees C, but ceased its CCC DNA replication after a short incubation at 42 degrees C, resulting in production of R- segregants. The thermosensitive replication of pJY5 was not overcome by the coexistence of non-thermosensitive R plasmids. The plasmid manifested an inhibitory effect on host bacterial cell growth at 42 degrees C, although the effect was less prominent than that of R plasmids belonging to the T-incompatibility group, Rts1, R401, and R402. When the pJY5 plasmid was transferred into E. cloacae, however, no R- segregants were detected at any culture temperature, even 42 degrees C. Alkaline sucrose gradient analysis revealed that a significant amount of pJY5 CCC DNA was synthesized in E. cloacae at the high temperature but not in E. coli. Furthermore, the growth-inhibitory effect of pJY5 on hosts at 42 degrees C was not observed in E. cloacae. On the other hand, Rts1 and R401 were found to be thermosensitive in E. cloacae as well as in E. coli.     

Phage t: a group T plasmid-dependent bacteriophage

Phage t was isolated from sewage from Pretoria. It formed plaques only on Escherichia coli and Salmonella typhimurium strains that carried plasmids belonging to incompatibility group T. Five of six group T plasmids permitted visible lysis of R+ host strains. There was no visible lysis of E. coli J53-2 or S. typhimurium LT2trpA8 carrying the T plasmid Rts1 although the strains supported phage growth as indicated by at least a 10-fold increase in phage titre. The latter strains transferred the plasmid at high frequency to E. coli strain CSH2 and the resulting transconjugants plated the phage. Proteus mirabilis strain PM5006(R402) failed to support phage growth although it transferred the plasmid and concomitant phage sensitivity to E. coli J53-2. The phage was hexagonal in outline, RNA-containing, resistant to chloroform and adsorbed to the shafts of pili determined by T plasmids.     

High-level resistance to streptomycin inEscherichia coli with R1 plasmid and the analysis of genetic determinants

Some properties of streptomycin-resistant mutants of Escherichia coli were analyzed. In a R+ culture, the phenotype under study may be significantly selected at a frequency of 10(-5) on media with higher streptomycin level. The lrs mutation is present in the cells prior to the action of streptomycin and remains in the cells even after curing of the R1 plasmid. The mapping of the lrs gene by conjugation with a concomitant transfer of chromosome and the R1 plasmid in different Hfr strains of E. coli failed to establish the localization of this gene in the tested chromosome regions. The presence of a cryptic plasmid was detected in cells with the lrs mutation after curing of the R1 plasmid. This plasmid codes neither fertility functions nor chloramphenicol-acetyltransferase, streptomycin-adenyltransferase, or ampicillin-beta-lactamase.     

Integration of R plasmid Rts1 to the gal region of the Escherichia coli chromosome.

An R plasmid Rts1 was integrated into the gal region of the chromosome of Escherichia coli XA-7012 (galE) strain by the directed transposition technique. The integration of the Rts1 genome was confirmed mainly by conjugation studies and also by transduction experiments using phage P1. As a result, it was found that the integrated genome contained genes responsible for kanamycin resistance, conjugal transferability, and for autonomous replication. As reported previously, Rts1 is temperature sensitive in replication and inhibits the growth of the host at nonpermissive temperature. However, although a plasmid derived from the integrated Rts1 genome still demonstrates temperature sensitivity upon transfer and high level of kanamycin resistance, this plasmid no longer displays temperature sensitivity in replication and the inhibitory effect on the host. These results indicate that the temperature sensitivity of replication of Rts1 and its inhibitory effect on the host cell are due to the presence of a gene or gene cluster on the Rts1 genome and that the gene(s) is clearly discriminated from the one responsible for the temperature sensitivity of transfer.     

Phage X: a plasmid-dependent, broad host range, filamentous bacterial virus

Phage X was isolated from sewage as plating on Escherichia coli or Salmonella typhimurium strains harbouring the incompatibility group X plasmid R6K. It also plated on a strain of Serratia marcescens carrying this plasmid. It failed to form plaques on Proteus mirabilis, P. morganii or Providencia alcalifaciens harbouring R6K, but did multiply on them. No phage increase occurred with homologous R- strains. Phage X also plated or registered an increase in titre on E. coli or S. typhimurium strains carrying various plasmids of incompatibility groups M, N, P-1, U or W as well as the unassigned plasmid R775. It adsorbed to pili determined by a group P-10 plasmid in a Pseudomonas aeruginosa strain but did not multiply on this organism. The phage was filamentous and curly, resistant to ribonuclease and diethyl ether and sensitive to chloroform. It adsorbed to the tips of pili.     

Plasmids in Escherichia coli controlling citrate-utilizing ability.

The citrate-utilizing ability of 19 out of 22 citrate-positive Escherichia coli strains isolated from pig sewage was transferred via conjugation to E. coli K-12. The conjugal transfer of citrate-utilizing (Cit) abilities was thermosensitive and concurrent with transfer of drug resistance. Weakly citrate-positive colonies were readily obtained in conjugation experiments. Their Cit characters could be transmitted to the other E. coli strains at a similar frequency in the retransfer experiments, and the transconjugants obtained still showed same characteristic growth on Simmons citrate agar plates. The 19 thermosensitive plasmids conferring citrate utilization and drug resistance were Fi-, and 16 of these plasmids belonged to incompatibility group H1. However, occasionally two conjugative plasmids (pOH3122-1 and pOH3124-1) carrying only the citrate utilization were also obtained in the conjugation experiments, and they were Fi+ and compatible with 19 reference R plasmids. In the two citrate-positive E. coli strains, it was suggested that the conjugative Cit plasmid showing Fi+ character and the more thermosensitive H1 plasmid conferring both the Cit character and drug resistance coexisted in the strain. The characterization of citrate utilization plasmids derived from pig farm sewage is discussed.     

Plasmids in Escherichia coli controlling citrate-utilizing ability.

The citrate-utilizing ability of 19 out of 22 citrate-positive Escherichia coli strains isolated from pig sewage was transferred via conjugation to E. coli K-12. The conjugal transfer of citrate-utilizing (Cit) abilities was thermosensitive and concurrent with transfer of drug resistance. Weakly citrate-positive colonies were readily obtained in conjugation experiments. Their Cit characters could be transmitted to the other E. coli strains at a similar frequency in the retransfer experiments, and the transconjugants obtained still showed same characteristic growth on Simmons citrate agar plates. The 19 thermosensitive plasmids conferring citrate utilization and drug resistance were Fi-, and 16 of these plasmids belonged to incompatibility group H1. However, occasionally two conjugative plasmids (pOH3122-1 and pOH3124-1) carrying only the citrate utilization were also obtained in the conjugation experiments, and they were Fi+ and compatible with 19 reference R plasmids. In the two citrate-positive E. coli strains, it was suggested that the conjugative Cit plasmid showing Fi+ character and the more thermosensitive H1 plasmid conferring both the Cit character and drug resistance coexisted in the strain. The characterization of citrate utilization plasmids derived from pig farm sewage is discussed.     

Chromosome-plasmid interaction in Escherichia coli K-12 carrying a thermosensitive plasmid, Rts1, in autonomous and in integrated states.

An Hfr strain of Escherichia coli K-12 was obtained by integrative suppression with a thermosensitive plasmid, Rts1. The R plasmid was integrated into the chromosome between rif and thr, and transfer of the chromosome occurred counterclockwise. The thermosensitivity of host cell growth due to the dnaA mutation was markedly but not completely reduced in this integratively suppressed Hfr strain. When the dnaA mutation was removed by transducing the dnaA+ genome to this Hfr, the thermosensitivity of cell growth due to existence of Rts1 was suppressed in contrast to strains carrying it autonomously. Thermosensitivity of cell growth appeared again when the plasmid was detached from the chromosome to exist autonomously. Contrary to the effect on cell growth, the transfer of the chromosome and the plasmid itself and the ability to "restrict" T-even phages were still thermosensitive in all of these strains carrying Rts1, irrespective of its state of existence. The detached plasmid as well as the original Rts1 were segregated upon growth at 42 C. These data are discussed in relation to chromosome-plasmid interaction. One of the most important conculusions is that some plasmid genes, related to their replication, are phenotypically suppressed by the chromosome when it is integrated.     

Energy supply for transport of plasmid R 100-1 during conjugation of Escherichia coli cells

It was shown that the transfer of plasmid R 100-1 during conjugation of donor and recipient cells of E. coli is suppressed under treatment of the cells by oxidative phosphorylation uncouplers. Studies on recipient cells devoid of their H+-ATPase activity due to mutation showed that the transfer of the plasmid into the cells is repressed after a switch-off of the respiratory chain, the only generator of proton motive force in the mutated cells. In the absence of arsenate the plasmid transfer from the donor into the recipient cells possessing intact H+-ATPase occurs independently of inhibition of the cell respiratory activity by cyanide. However, the presence of arsenate in the conjugation medium induces the sensitivity of the plasmid transfer process to cyanide. In the absence of cyanide the cell conjugation is suppressed by 60 mM arsenate. A kinetic study of different steps of cell conjugation showed that the generation of proton motive force in recipient cells is necessary for the occurrence of plasmid transport. It was assumed that the generation of both proton motive force and phosphorylated high energy compounds is a necessary prerequisite for plasmid transport during conjugation of donor and recipient cells.     

Genetic Transfer of Episomic Elements Among Erwinia Species and Other Enterobacteria: F′lac+

The episomic element F'lac(+) was transferred, probably by conjugation, from Escherichia coli to Lac(-) strains of Erwinia herbicola, Erwinia amylovora, and Erwinia chrysanthemi (but not to several other Erwinia spp. In preliminary trials). The lac genes in the exconjugants of the Erwinia spp. showed varying degrees of stability depending on the strain (stable in E. herbicola strains Y46 and Y74 and E. amylovora strain EA178, but markedly unstable in E. chrysanthemi strain EC16). The lac genes and the sex factor (F) were eliminated from the exconjugants by treatment with acridine orange, thus suggesting that both lac and F are not integrated in the Erwinia exconjugants. All of the tested Lac(+) exconjugants of E. herbicola strains Y46 and Y74 and E. amylovora strain EA178, but not of E. chrysanthemi strain EC 16, were sensitive to the F-specific phage M13. The heterogenotes (which harbored F'lac(+)) of E. herbicola strains Y46 and Y74, E. amylovora strain EA178, and E. chrysanthemi strain EC16 were able to transfer lac genes by conjugation to strains of E. herbicola, E. amylovora, E. chrysanthemi, Escherichia coli, and Shigella dysenteriae. The frequency of such transfer from Lac(+) exconjugants of Erwinia spp. was comparable to that achieved by using E. coli F'lac(+) as donors, thus indicating the stability, expression, and restriction-and-modification properties of the sex factor (F) in Erwinia spp.     

Conjugation transfer of the pAMbeta1 plasmid to Bacillus anthracis

The possibility of conjugational transfer of the plasmid pAM beta 1 in the cells of different strains of Bacillus anthracis has been established. The efficiency of the plasmid replicon transfer in interspecies transfer B. thuringiensis X B. anthracis was n.10(-7), while in interspecies transfer it was n.10(-6). The capability of mobilization of extrachromosomal replicon pTG141 for conjugational transfer has been demonstrated. Bacillus anthracis transconjugants harbouring the pAM beta 1 plasmid have acquired the donor properties in conjugation.     

Use of cloned DNA methylase genes to increase the frequency of transfer of foreign genes into Xanthomonas campestris pv. malvacearum.

In vitro-packaged cosmid libraries of DNA from the bacterium Xanthomonas campestris pv. malvacearum were restricted 200- to 1,000-fold when introduced into Mcr+ strains of Escherichia coli compared with restriction in the Mcr- strain HB101. Restriction was predominantly associated with the mcrBC+ gene in E. coli. A plasmid (pUFR052) encoding the XmaI and XmaIII DNA methylases was isolated from an X. campestris pv. malvacearum library by a screening procedure utilizing Mcr+ and Mcr- E. coli strains. Transfer of plasmids from E. coli strains to X. campestris pv. malvacearum by conjugation was enhanced by up to five orders of magnitude when the donor cells contained pUFR052 as well as the plasmid to be transferred. Subcloning of pUFR052 revealed that at least two regions of the plasmid were required for full modification activity. Use of such modifier plasmids is a simple, novel method that may allow the efficient introduction of genes into any organism in which restriction systems provide a potent barrier to such gene transfer.     

Cell-to-cell transformation in Escherichia coli: a novel type of natural transformation involving cell-derived DNA and a putative promoting pheromone

Escherichia coli is not assumed to be naturally transformable. However, several recent reports have shown that E. coli can express modest genetic competence in certain conditions that may arise in its environment. We have shown previously that spontaneous lateral transfer of non-conjugative plasmids occurs in a colony biofilm of mixed E. coli strains (a set of a donor strain harbouring a plasmid and a plasmid-free recipient strain). In this study, with high-frequency combinations of strains and a plasmid, we constructed the same lateral plasmid transfer system in liquid culture. Using this system, we demonstrated that this lateral plasmid transfer was DNase-sensitive, indicating that it is a kind of transformation in which DNase-accessible extracellular naked DNA is essential. However, this transformation did not occur with purified plasmid DNA and required a direct supply of plasmid from co-existing donor cells. Based on this feature, we have termed this transformation type as 'cell-to-cell transformation'. Analyses using medium conditioned with the high-frequency strain revealed that this strain released a certain factor(s) that promoted cell-to-cell transformation and arrested growth of the other strains. This factor is heat-labile and protease-sensitive, and its roughly estimated molecular mass was between ～9 kDa and ～30 kDa, indicating that it is a polypeptide factor. Interestingly, this factor was effective even when the conditioned medium was diluted 10(-5)-10(-6), suggesting that it acts like a pheromone with high bioactivity. Based on these results, we propose that cell-to-cell transformation is a novel natural transformation mechanism in E. coli that requires cell-derived DNA and is promoted by a peptide pheromone. This is the first evidence that suggests the existence of a peptide pheromone-regulated transformation mechanism in E. coli and in Gram-negative bacteria.     

Further characterization of the R plasmid Rts1 and its mutant pTW2: replication and incompatibility of the plasmid.

Incompatibility of the R plasmid Rts1 and its replication mutant pTW2 was studied in recA host cells of Escherichia coli. When the R plasmid R401, belonging to the same incompatibility group as Rts1, was used as a test plasmid, R401 was eliminated preferentially from (Rts-R401)+ cells irrespective of the direction of transfer. In contrast, pTW2 and R401 were mutually excluded. The decreased incompatibility of pTW2 was confirmed by a direct incompatibility test in which a derivative of Rts1 expelled pTW2 exclusively. Alkaline sucrose gradients of pTW2 and Rts1 DNA indicated that approximately one-fourth of the Rts1 genome was deleted in pTW2. In addition, both the various temperature-dependent properties of Rts1 and the inhibitory effect on phage T4 development were also lost in pTW2. A possible mechanism that regulates the stringent replication of Rts1 is discussed.     

Plasmid recombination stimulated by restriction endonuclease EcoRI in vivo: formation of recombinant plasmids in recA+-cells of E. coli

The possible participation of restriction endonuclease EcoRI in recombination of compatible nonhomologous plasmids in E. coli cells has been studied. To study the process, plasmids RP4 and R245 have been transferred by conjugation into the recipient cells of E. coli harbouring one of isogenic plasmids, pSA14 and pSA25, different for the genes coding restriction endonuclease EcoRI. The genetic analysis of transconjugant phenotypes, coded by the plasmids, has permitted to register the recombinant plasmids after compatibility of parent plasmids in E. coli cells. Recombination of plasmid RP4 with the plasmid pSA14, carrying EcoRI genes, has been registered in E. coli cells, producing the restriction endonuclease, while plasmid recombination has not been found in the cells harbouring plasmid pSA25, isogenic for all genes, except for EcoRI genes, with plasmid pSA14. Restriction endonuclease EcoRI is concluded to stimulate site specific recombination of nonhomologous compatible plasmids in vivo. EcoRI-mediated recombination of plasmid R245 with plasmid pSA14 is discussed.     

Plasmids Controlling Synthesis of Hemolysin in Escherichia coli: Molecular Properties

Covalently closed extrachromosomal deoxyribonucleic acid (DNA) was isolated from alpha-hemolytic wild-type strains of Escherichia coli. Most strains examined were able to transfer the hemolytic property with varying frequencies to nonhemolytic recipient strains. Out of eight naturally isolated alphahemolytic E. coli strains, four contained a set of three different supercoiled DNAs with sedimentation coefficients of 76S (plasmid A), 63S (plasmid B), and 55S (plasmid C). The sedimentation coefficients and the contour lengths of the isolated molecules correspond to molecular weights of 65 x 10(6), 41 x 10(6), and 32 x 10(6). Three alpha-hemolytic wild-type strains carried only one plasmid with a molecular weight of 41 x 10(6), and one strain harbored two plasmids with molecular weights of 41 x 10(6) and 32 x 10(6). Alpha-hemolytic transconjugants were obtained by conjugation of E. coli K-12 with the hemolytic wild-type strains. A detailed examination revealed that plasmids with the same sizes as plasmids B and C of the wild-type strains can be transferred separately or together to the recipients. Both plasmids possess the hemolytic determinant and transfer properties. Plasmid A appears to be, at least in one wild-type strain, an additional transfer factor without a hemolytic determinant. In one case a hemolytic factor was isolated, after conjugation, that is larger in size than plasmid A and appears to be a recombinant of both plasmids B and C.