Genetic and physical characteristics of an enterotoxin plasmid.

We are engaged in the genetic and physical characterization of an enterotoxin (Ent) plasmid, Ent P307, which contains genes for the production of a hear-labile and a heat-stable enterotoxin. We are using an Escherichia coli K-12 strain, 711 (P307), constructed by S. Falkow, which contains no other plasmids besides Ent P307. Our genetic studies have shown that the plasmid is incompatible with the sex factor F, both in the integrated (Hfr) and the autonomous (F-prime) state. Ent P307 can thus be assigned to incompatibility group FI. An R factor, R386, which belongs to the same incompatibility group, was also found to be incompatibile with Ent P307, whereas five other R factors belonging to different incompatibility groups were compatible with Ent P307. In the presence of Ent P307, conjugal transfer and sensitivity to a male-specific phage of a derepressed F-like R factor, R1drd19, were repressed. Ent P307 is, thus, finO+. Presumably, it also causes repression of its own transfer genes since conjugal transfer of Ent P307 could not be demonstrated. Unlike F, it does not restrict the growth of female-specific phage phiII. From physical studies on extracted deoxyribonucleic acid, the molecular weight of Ent P307 was determined to be 54 X 10(6). By electron microscope heteroduplex analysis, the plasmid was found to be homologous with F in four regions, encompassing about half of its length. One long region and two short ones contain genes for conjugal transfer; the other short region carries genes for replication and incompatibility.     

Molecular Nature of Two Nonconjugative Plasmids Carrying Drug Resistance Genes

Two nonconjugative R-plasmids, N-SuSm and N-Tc, have been characterized. Both were of relatively small size (5 x 10(6) to 6 x 10(6) daltons) and present in multiple copies within their respective bacterial hosts. N-SuSm possessed a guanine plus cytosine content of 55%, whereas N-Tc was 49% guanine plus cytosine. Although these plasmids were inherently nontransmissible they could be mobilized by a large variety of transfer agents including Ent, Hly, and K88. The fi(-) transfer factors tested were far more likely (about 200x) to mobilize these nonconjugative plasmids than were the fi(+) transfer factors tested. Although the mobilization phenomenon was not found to be associated with a detectable level of direct stable recombinational union between N-SuSm or N-Tc with a transfer factor, we were able to demonstrate a low level of recombination between these replicons and a transfer factor by P1-mediated transduction. The isolation of recombinants between transfer factors and nonconjugative plasmids presumably represents one means by which unitary molecular types of R-plasmids arise and by which existing R-plasmids may acquire new resistance determinants.     

Transposition of ampicillin resistance to an enterotoxin plasmid in an Escherichia coli strain of human origin.

We examined a strain of Escherichia coli, serotype O159.H34, of human origin which produced heat-stable and heat-labile enterotoxins, was resistant to ampicillin, and produced colicin. By conjugation and transformation experiments plasmids coding for enterotoxin production (Ent), enterotoxin production and ampicillin resistance (Ap-Ent), ampicillin resistance (Ap), and colicin production were isolated. Both the Ent and Ap-Ent plasmids were autotransferring and belonged to the F-incompatibility complex. However, the Apr Ent+ transconjugants showed differences in their levels of resistance and in their abilities to propagate F-specific phages and to transfer resistance. The results suggested there was transposition from the small Ap plasmid to the Ent plasmid. The Ap-Ent plasmids were larger than the enterotoxin factor and when treated with restriction endonuclease BamHI showed an additional fragment not present in the enterotoxin plasmid. The insertion of ampicillin resistance probably occurred at different sites on the enterotoxin plasmid, resulting in the observed variation in phenotype.     

Repressor gene finO in plasmids R100 and F: constitutive transfer of plasmid F is caused by insertion of IS3 into F finO.

Fertility factor F confers bacterial conjugation, a process which involves at least 20 tra genes. Resistance plasmids such as R100, R6-5, and R1 have homology with F in the tra region. Conjugal transfer of these plasmids is, however, repressed, while transfer of F is constitutive. Repression of R transfer is due to the existence of the two genes, called finO and finP; constitutive transfer of F is believed to be due to a lack of finO in F. In this paper, we report the identification and DNA sequence of the finO gene of R100, encoding a protein of 21,265 daltons. We show that F does actually encode finO, but the gene has been inactivated by insertion of IS3. Lederberg and Tatum (Nature [London] 158:558, 1946), who discovered sexuality in bacteria, may have had an Escherichia coli K-12 strain harboring such an finO F factor, which facilitated the generation of recombinant progeny useful for genetic analysis of bacteria and established the foundation for molecular genetics.     

Structural basis of cooperative DNA recognition by the plasmid conjugation factor, TraM

The conjugative transfer of F-like plasmids such as F, R1, R100 and pED208, between bacterial cells requires TraM, a plasmid-encoded DNA-binding protein. TraM tetramers bridge the origin of transfer (oriT) to a key component of the conjugative pore, the coupling protein TraD. Here we show that TraM recognizes a high-affinity DNA-binding site, sbmA, as a cooperative dimer of tetramers. The crystal structure of the TraM-sbmA complex from the plasmid pED208 shows that binding cooperativity is mediated by DNA kinking and unwinding, without any direct contact between tetramers. Sequence-specific DNA recognition is carried out by TraM's N-terminal ribbon-helix-helix (RHH) domains, which bind DNA in a staggered arrangement. We demonstrate that both DNA-binding specificity, as well as selective interactions between TraM and the C-terminal tail of its cognate TraD mediate conjugation specificity within the F-like family of plasmids. The ability of TraM to cooperatively bind DNA without interaction between tetramers leaves the C-terminal TraM tetramerization domains free to make multiple interactions with TraD, driving recruitment of the plasmid to the conjugative pore.     

Conjugal acquisition and stable maintenance of Ent plasmids in nontoxigenic wild-type strains of Escherichia coli

In spite of the ability of the genetic determinants for enterotoxin production to be conjugally transferred, mobilized or transposed, enterotoxigenic Escherichia coli (ETEC) isolated from diarrheal patients is restricted to certain serotypes. Four conjugative enterotoxigenic plasmids (Ent plasmids) encoding either a heat-labile enterotoxin or a heat-stable enterotoxin or both and belonging to one of three incompatibility groups IncFI, IncHl, or IncX, were examined for their transferability to and stability in 157 nonenterotoxigenic Escherichia coli strains belonging to various serotypes and 89 clinical isolates nonenterotoxigenic but belonging to those serotypes in which ETEC from diarrheal patients are usually found. The serotypes of the strains to which Ent plasmids were efficiently transferred and in which they were maintained stably were not always the serotypes in which ETEC had usually been found and vice versa. The frequencies of transfer of four Ent and two R plasmids to each of the 157 recipients were correlated with each other, indicating that the frequency of transfer of the plasmid is not determined by a resident plasmid, if there is one, but by a recipient factor which commonly affects transferability to all donors. These results have led to the conclusion that the reason why only certain serotypes are found among ETEC isolated from diarrheal patients is not the ability of these strains specifically and preferentially to acquire and maintain the Ent plasmids.     

Efficient transfer of conjugative plasmids by multipoint inoculation and some observations on host range and prevalence of R plasmids.

The conjugational transfer of R plasmids was demonstrated using a simple manually operated multipoint inoculator apparatus (MIP) allowing rapid inoculation and later dilution and plating of 25 mating mixtures simultaneously. Forty-five R plasmids belonging to groups F, I, N, and others originally recovered in Escherichia coli K-12 were studied in this as well as in other hosts. The semiquantitative MIP conjugation method was more efficient than conventional matings, particularly when performed in two steps employing E. coli K-12 as intermediate host. Both as donor and as recipient, E. coli K-12 was the most “suitable” general host of the set of plamids studied, although with many plasmids the degree of expression of their transfer functions varied with the host. The expression of fertility in parental bacteria as well as factors in the new host not studied appeared to be of greater importance for the conjugational transfer of a plasmid than the host-specified restriction of plasmid deoxyribonucleic acid by the recipient strain. The MIP conjugation method was successfully used also during screening for transferable R plasmids in gram-negative bacteria present in urine and fecal specimens of humans. The use of a restrictionless mutant instead of a restricting K-12 recipient enabled the detection of additional plasmids. The labor and media-saving MIP conjugation method thus also offers efficiency and is very practical for the performance of large numbers of plasmid matings, for example, in studies of compatibilty, host range, and mobilization of plasmids, as well as for screening purposes.     

Increase in tetracycline activity by using surface-active substances]

The antimicrobial effect of cationic and anionic surface-active substances, i.e. catamine AB and sulphonol NP-3 respectively was studied in vitro with respect to gramnegative bacteria. In non-bactericidal concentrations catamine AB significantly increased the efficacy of tetracyclines, while the anionic compound had no such effect. The increase in the tetracycline activity was due to the antibiotic increased absorption (14C-oxytetracycline as an example) on the treatment of gramnegative bacteria with catamine AB and staphylococci with catamine AB and sulphonol NP-3, which was mainly associated with impairement of the cell membrane permeability by the surface-active substances.     

Analysis of the sequence and gene products of the transfer region of the F sex factor.

Bacterial conjugation results in the transfer of DNA of either plasmid or chromosomal origin between microorganisms. Transfer begins at a defined point in the DNA sequence, usually called the origin of transfer (oriT). The capacity of conjugative DNA transfer is a property of self-transmissible plasmids and conjugative transposons, which will mobilize other plasmids and DNA sequences that include a compatible oriT locus. This review will concentrate on the genes required for bacterial conjugation that are encoded within the transfer region (or regions) of conjugative plasmids. One of the best-defined conjugation systems is that of the F plasmid, which has been the paradigm for conjugation systems since it was discovered nearly 50 years ago. The F transfer region (over 33 kb) contains about 40 genes, arranged contiguously. These are involved in the synthesis of pili, extracellular filaments which establish contact between donor and recipient cells; mating-pair stabilization; prevention of mating between similar donor cells in a process termed surface exclusions; DNA nicking and transfer during conjugation; and the regulation of expression of these functions. This review is a compendium of the products and other features found in the F transfer region as well as a discussion of their role in conjugation. While the genetics of F transfer have been described extensively, the mechanism of conjugation has proved elusive, in large part because of the low levels of expression of the pilus and the numerous envelope components essential for F plasmid transfer. The advent of molecular genetic techniques has, however, resulted in considerable recent progress. This summary of the known properties of the F transfer region is provided in the hope that it will form a useful basis for future comparison with other conjugation systems.     

Evidence that the hemolysin/bacteriocin phenotype of Enterococcus faecalis subsp. zymogenes can be determined by plasmids in different incompatibility groups as well as by the chromosome.

The hemolysin (Hly/Bac) determinant in strains of Enterococcus faecalis was found to be present on plasmids in different incompatibility groups (conferring different sex pheromone responses) as well as on the chromosome. Of 33 Hly/Bac plasmids identified in clinical isolates, the related pheromone for 30 was cAD1; the related pheromone for another two (pYI1 and pYI3) or one (pYI2) was cOB1 or cY12, respectively. The representative Hly/Bac plasmids pAD1, pYI1, pOB1, and pYI2, which responded to pheromones cAD1, cOB1, cOB1, and cYI2, respectively, were compatible with one another. As additions to the incompatibility group IncHly of pAD1, groups for pOB1, pYI1, and pYI2 were designated IncHlyII, IncHlyIII, and IncHlyIV, respectively. Eleven of the 30 plasmids conferring a response to cAD1 were very similar to pAD1 on the basis of their restriction endonuclease profiles. EcoRI fragment D, F, or H containing parts of the Hly/Bac gene(s) of pAD1 hybridized to similar EcoRI fragments from each of the other three representatives of incompatibility groups (i.e., pOB1, pYI1, and pYI2) and to homologous DNA representing the chromosome of the plasmid-free Hly/Bac strain YI6-1.     

Effect of lipopolysaccharide mutations on recipient ability of Salmonella typhimurium for incompatibility group H plasmids.

Previous investigations of the incompatibility group F, P, and I plasmid systems revealed the important role of the outer membrane components in the conjugal transfer of these plasmids. We have observed variability in transfer frequency of three incompatibility group H plasmids (IncHI1 plasmid R27, IncHI2 plasmid R478, and a Tn7 derivative of R27, pDT2454) upon transfer into various Salmonella typhimurium lipopolysaccharide (LPS) mutants derived from a common parental strain, SL1027. Recipients with truncated outer core via the rfaF LPS mutation increased the transfer frequency of the IncH plasmids by up to a factor of 10(3). Mutations which resulted in the truncation of the residues following 3-deoxy-D-manno-octulosonic acid, such as the rfaE and rfaD mutations, decreased the transfer frequency to undetectable levels. Addition of phosphorylethanolamine, a component of wild-type LPS, to the media decreased the frequency of transfer of R27 into wild-type and rfaF LPS mutant recipients tested. Reversing the direction of transfer, by mating LPS mutant donors with wild-type recipients, did not affect the frequency of transfer compared to the standard matings of wild-type donor with LPS mutant recipient. These findings demonstrate that conjugation interactions affected by LPS mutation are not specific for the recipient cell. Our results suggest that LPS mutation does not affect conjugation via altered pilus binding but affects some later steps in the conjugative process, and alteration of transfer frequency by O-phosphorylethanolamine and LPS truncation is due to charge-related interactions between the donor and recipient cell.     

Action of various surface-active substances on the genetic transmission of R-plasmids in E. coli]

The effect of 4 groups of surface active-substances (SAS) on conjugation and transduction transfer of plasmid RIdrd from the donor of E. coli J 5-3 to the recipient of E. coli C600 was studied. It was shown that the anionic SAS (8 compounds) had the highest inhibitory effect. They completely inhibited both the conjugation and the transduction transfer of R-plasmids. The amphoteric SAS, i. e. tego-51 and ampholan had the same effect only on the transduction R-transfer. The conjugation R-transfer was inhibited by the above compounds to a significant extent but not completely, i. e. by 70.8 and 361.9 times respectively. The effect of the non-ionogenic preparations, i. e. sintanol DT-7 was even less (the inhibition coefficients of 54.8 and 22.8 on conjuction and transduction respectively). The cationic SAS, i. e. catamine AB and HIPC-200 had no effect on the genetic R-transfer. It was shown that the anionic SAS had a phagocytic effect on phage Plks. It is of interest to note that the anionic SAS, i. e. sintanol NP-3 effectively suppressed the conjugation transfer even in a concentration of 100 gamma/ml which was 1000 times lower than the subbacteriostatic one. The effectiveness of the anionic SAS did not depend on the length of the dydrocarbon chain and was the same in separate homologues and their mixtures. The high inhibitory activity of most of the SAS and especially the anionic ones with respect to both the conjugation and the transduction R-transfer was of interest.     

Mapping andfi character determination of R factors ofEnterobacter cloacae DF13

In conjugation experiments betweenEnterobacter cloacae DF13 andEscherichia coli K12, resistances against tetracycline, sulfanilamide, streptomycin, and chloramphenicol were nearly always transferred simultaneously. These properties could be transferred fromE. coli exconjugants by transduction to a drug-sensitiveE. coli K12 strain with bacteriophage P1kc. It may be inferred thatEnt. cloacae DF 13 harbours a multiple R factor, which promotes its own transfer. This R factor was found to be of thefi ⁺ type. The molecular nature of this R factor was studied by labelling the DNA of an exconjugant with³H-thymidine, careful lysis, sedimentation of the chromosomal DNA, and characterization of the circular DNA by sucrose-gradient centrifugation, equilibriumdensity centrifugation in CsCl containing ethidium bromide and by electron microscopy. By these methods the multiple R factor was identified as a circular DNA molecule with a contour length of 22.6 Μm, corresponding to a molecular weight of 45 × 10⁶ daltons. A segregant R factor harbouring resistance against tetracycline only, was found to have a contour length of 16.0 Μm and a sedimentation constant of 58 S. In addition to the multiple R factor, the wild-type strain harboured a plasmid with a sedimentation constant of 38 S, corresponding to a molecular weight of 16 × 10⁶ daltons. The function of this plasmid is unknown. After many transfers on agar slants spontaneous segregation of the R factor was observed and several types of segregants were obtained. In most segregants, resistance against streptomycin could not be transferred by conjugation and could not be mobilized by other sex factors. Some of these segregants had acquired a requirement for methionine; in these, the streptomycin-resistance determinant may be integrated into the chromosome. The resistance pattern of the various types of segregants and exconjugants allowed to draw a circular map of the R factor. The order of markers is ---tet---rtf---sul---str---cml-. After short-term conjugation experiments most exconjugants were found to have received resistance against sulfanilamides only. This resistance determinant does not promote its own transfer by conjugation but could be mobilized by other sex factors. An exconjugant become resistant against tetracycline and sulfanilamide, was found to harbour two independent plasmids of which only that carrying resistance against tetracycline promoted its own transfer. Consequently a second R factor, determining resistance against sulfanilamide alone must be present inEnt. cloacae DF13. This R factor was identified as a circular DNA molecule with a sedimentation constant of 26 S, a contour length of 2.6 Μm and a buoyant density of 1.709. From a strain harbouring the independent R(SA) plasmid and an R(TC) fragment of the multiple R factor, transductants resistant against sulfanilamide were obtained. These were found to harbour an R(SA) plasmid with properties of a defective Rfi ⁺ transfer factor. Most probably these plasmids resulted from recombination between the R(SA) plasmid and the Rtf region of the R(TC) fragment. The author published previously under the name of “G. A. Tieze”. The technical assistance of Miss J.T.M.P.A. Havermans, Mrs. A. Mak-Zuidervaart, and Mr. M. V. M. Lafleur is gratefully acknowledged. The authors thank Dr. E. F. J. van Bruggen and Dr. D. Ellens for the electronmicroscopical measurements.     

Incompatibility Exhibited by Colicin Plasmids E1, E2, and E3 in Escherichia coli

Escherichia coli strains were made multiply colicinogenic for the colicin plasmids E1, E2, or E3 (Col E1, Col E2, or Col E3, respectively) by both a deoxyribonucleic acid transformation system and bacterial conjugation. The multiply colicinogenic bacteria constructed exhibited an immunity to the colicins produced by all the plasmids they carried and also produced colicins corresponding to all the plasmids they carried. An incompatibility was observed among the plasmids. In doubly colicinogenic cells where the presence of two plasmids was established, Col E2 was lost more frequently than Col E3. In triply colicinogenic cells, Col E1, Col E2, and Col E3 were lost, with Col E3 being lost least frequently. A significant reduction in the acquisition of a conjugationally transferred Col E1 plasmid by cells colicinogenic for Col E1 was demonstrated.     

The effect of a cationic surface-active substance (catamine AB) on the physiological-morphological properties of B. cereus and E. coli

Catamine AB (0.05-0.5%) promotes transfer of B. cereus st 96, and E. coli st. 906 cell cultures into metabolic rest. Detergent-treated cells have no energetic metabolism and autolytic processes, have high light-scattering coefficient, and peculiar ultrastructural organization. Viable cells can be observed in the detergent-treated cell suspension after 1 year of incubation. Difference in action of different catamine AB concentrations on stationary and exponential B. cereus cells has been revealed.     

Conjugative plasmids in Neisseria gonorrhoeae.

A conjugation system initially discovered in beta-lactamase-producing gonococci mobilized small non-selftransmissible R plasmids encoding beta-lactamase (penicillinase) production into other gonococci, Neisseria, and Escherichia coli. This conjugation system was mediated by a separate selftransmissible plasmid of 23.9 X 10(6) daltons, pFA2. Conjugative plasmids capable of mobilizing R plasmids were also found in nearly 8% of the non-penicillinase-producing gonococci. These were similar to pFA2 in size, buoyant density, and restriction endonuclease digest patterns but were less efficient than pFA2 in mobilization of the penicillinase plasmid pFA3. The presence of conjugative plasmids in gonococci isolated before the appearance of penicillinase-producing strains indicates that a conjugation system for plasmid transfer predated the appearance of R plasmids in gonococci.     

Ammonia Inhibition of Plasmid pRmeGR4a Conjugal Transfer between Rhizobium meliloti Strains

We have examined nutritional factors influencing conjugal transfer of the two nonsymbiotic large plasmids, pRmeGR4a and pRmeGR4b, of Rhizobium meliloti GR4. To monitor transfer, each plasmid was tagged with a different antibiotic resistance marker. Transfer of plasmid pRmeGR4b was dependent upon the presence of plasmid pRmeGR4a on the same donor cell. Transconjugants for pRmeGR4b were obtained at frequencies 5-to 10-fold higher than transconjugants carrying both plasmids, indicating that mobilization of pRmeGR4b by pRmeGR4a probably occurred in trans. Conjugal transfer of the tagged plasmids between R. meliloti strains was tested on minimal medium supplemented with single amino acids, nitrate, or ammonium as the single nitrogen source. A higher number of transconjugants was obtained when glutamate was the only nitrogen source, whereas conjugation was virtually undetectable on ammonium. No relationship was found between donor or recipient growth rate and plasmid transfer rate on a given nitrogen source. Furthermore, in media containing both glutamate and ammonium as nitrogen sources, transfer was reduced almost 100-fold compared with that in media containing glutamate alone. Inhibition was readily detected at 2.5 mM or higher concentrations of either ammonium chloride or ammonium sulfate and appeared to be specific for exogenously supplied ammonium. Inhibition of conjugal transfer between R. meliloti strains by ammonium was only observed for rhizobial plasmids, not for a heterologous plasmid such as RP4. Apparently, ammonium did not affect the plasmid-encoded transfer machinery, as it had no influence on rhizobial plasmid transfer from R. meliloti to Agrobacterium tumefaciens. The effect of ammonium seemed to take place on R. meliloti recipient cells, thereby reducing the efficiency of plasmid conjugation, probably by affecting mating pair formation or stabilization.     

Electron microscope heteroduplex studies of sequence relations among plasmids of Escherichia coli: II. Structure of drug resistance (R) factors and f factors

The colicinogenic plasmid Col V-K94 and the class of transferable drug-resistance factors that inhibit fertility of the sex factor, F, are believed to be genetically similar to F. Heteroduplexes between these various F-like plasmids were studied by electron microscopy in order to identify and define the DNA segments that contain genes coding for fertility and other common functions. It was found that approximately 44% of the F factor is homologous to several different fi⁺ R factors and to Col V-K94, and that all of the homology between these plasmids and F is restricted to a region comprising only one-half of the F-factor molecule. These data, and previously reported electron microscope mapping of deletions of F factors, suggest that the genes active in the process of transfer are contained in one-half of the F factor, and therefore imply that the other half of F might not be required for expression of its fertility functions.DNA sequence homology among the R factors R6, R100 and R1 was also studied by heteroduplex formation. All of the DNA sequences contained in R100 were observed to be present in R6, and approximately 85% of the DNA sequences of R1 were included in R6. In the $\text{R1}\text{R6}$ heteroduplex, homology is distributed equally in the R-factor region homologous to the F factor, and the region containing antibiotic-resistance determinants (i.e. the segment deleted in the resistance transfer factor unit, RTF). The position of certain drugresistance determinants has been mapped by using various R-factor deletion mutants and correlating the pattern of drug resistance with the sequence homology observed among different R factors. Unlike the other resistance-determinant genes identified, the tetracycline marker has been mapped in the segment of R6 that is largely homologous to the F factor.Inverted repeats, which consist of DNA segments repeated in reverse sequence on the same single strand of DNA, were observed in R6, R100 and Col V-K94. One inverted repeat of R6 is located near the tetraeycline marker. Further duplication of one of the complementary sequences of the inverted repeat, and insertion of this duplication into the plasmid genome apparently inactivates the tetracycline-resistance determinant of R6.     

Further characterization of the F fertility inhibition systems of "unusual" Fin+ plasmids.

Flac mutants insensitive to transfer inhibition by R factors. JR66a and R485 were isolated and characterized. Representative mutations were cis dominant and are therefore presumed to be at the sites of action, fisU and fisV, respectively, of the FinU and FinV transfer inhibition systems encoded by JR66a and R485. The mutants were used to confirm that the FinU and FinV fertility inhibition systems are different from each other and from the FinOP, FinQ, and FinW systems of R100, R62, and R455, respectively. Together with traO and fisQ mutants of Flac, the new mutants were also used to investigate the nature of the F fertility inhibition systems encoded by a further group of "unusual" Fin+ plasmids. Of these, two incompatibility group X plasmids were found to carry finO+ genes, and of five incompatibility group I plasmids, three encoded FinQ systems, one the FinU system, and one a new system (FinR). Transfer of a variety of derepressed F-like plasmids was inhibited by the FinQ, FinU, and FinV systems, but a quantitatively very different levels; this emphasizes the differences as well as the similarities between the conjugation systems of F-like plasmids.     

The conjugational transfer of plasmids to Legionella strains

In experiments on conjugation the transfer of a number of R-plasmids having a wide range of hosts, such as plasmids RP1, R68.45, RP4, N3, RK2, S-a, those having a narrow range of hosts, such as plasmid R64, to strains of different Legionella species was shown. The frequency of transfer varied from 3.1 X 10(-3) to 9.4 X 10(-7). The fact that the conjugation transfer was confirmed by the reverse transfer of plasmids from Legionella transconjugates to Escherichia coli strain K12, as well as by the detection of the DNA of the transferred plasmid by means of electrophoresis in agar gel. Plasmid RP1 showed different behavior in transconjugates of various Legionella species after several passages in a medium free of antibiotics. In the Legionella strain under study the unstable preservation of plasmid R64 was observed.