Exogenous isolation of antibiotic resistance plasmids from piggery manure slurries reveals a high prevalence and diversity of IncQ-like plasmids

Antibiotic resistance plasmids were exogenously isolated in biparental matings with piggery manure bacteria as plasmid donors in Escherichia coli CV601 and Pseudomonas putida UWC1 recipients. Surprisingly, IncQ-like plasmids were detected by dot blot hybridization with an IncQ oriV probe in several P. putida UWC1 transconjugants. The capture of IncQ-like plasmids in biparental matings indicates not only their high prevalence in manure slurries but also the presence of efficiently mobilizing plasmids. In order to elucidate unusual hybridization data (weak or no hybridization with IncQ repB or IncQ oriT probes) four IncQ-like plasmids (pIE1107, pIE1115, pIE1120, and pIE1130), each representing a different EcoRV restriction pattern, were selected for a more thorough plasmid characterization after transfer into E. coli K-12 strain DH5alpha by transformation. The characterization of the IncQ-like plasmids revealed an astonishingly high diversity with regard to phenotypic and genotypic properties. Four different multiple antibiotic resistance patterns were found to be conferred by the IncQ-like plasmids. The plasmids could be mobilized by the RP4 derivative pTH10 into Acinetobacter sp., Ralstonia eutropha, Agrobacterium tumefaciens, and P. putida, but they showed diverse patterns of stability under nonselective growth conditions in different host backgrounds. Incompatibility testing and PCR analysis clearly revealed at least two different types of IncQ-like plasmids. PCR amplification of total DNA extracted directly from different manure samples and other environments indicated the prevalence of both types of IncQ plasmids in manure, sewage, and farm soil. These findings suggest that IncQ plasmids play an important role in disseminating antibiotic resistance genes.     

Exogenous Isolation of Antibiotic Resistance Plasmids from Piggery Manure Slurries Reveals a High Prevalence and Diversity of IncQ-Like Plasmids

Antibiotic resistance plasmids were exogenously isolated in biparental matings with piggery manure bacteria as plasmid donors in Escherichia coli CV601 and Pseudomonas putida UWC1 recipients. Surprisingly, IncQ-like plasmids were detected by dot blot hybridization with an IncQ oriV probe in several P. putida UWC1 transconjugants. The capture of IncQ-like plasmids in biparental matings indicates not only their high prevalence in manure slurries but also the presence of efficiently mobilizing plasmids. In order to elucidate unusual hybridization data (weak or no hybridization with IncQ repB or IncQ oriT probes) four IncQ-like plasmids (pIE1107, pIE1115, pIE1120, and pIE1130), each representing a different EcoRV restriction pattern, were selected for a more thorough plasmid characterization after transfer into E. coli K-12 strain DH5α by transformation. The characterization of the IncQ-like plasmids revealed an astonishingly high diversity with regard to phenotypic and genotypic properties. Four different multiple antibiotic resistance patterns were found to be conferred by the IncQ-like plasmids. The plasmids could be mobilized by the RP4 derivative pTH10 into Acinetobacter sp., Ralstonia eutropha, Agrobacterium tumefaciens, and P. putida, but they showed diverse patterns of stability under nonselective growth conditions in different host backgrounds. Incompatibility testing and PCR analysis clearly revealed at least two different types of IncQ-like plasmids. PCR amplification of total DNA extracted directly from different manure samples and other environments indicated the prevalence of both types of IncQ plasmids in manure, sewage, and farm soil. These findings suggest that IncQ plasmids play an important role in disseminating antibiotic resistance genes.     

Nucleotide Sequence and Genetic Characterization of the Novel IncQ-like Plasmid pIE1107

The analysis of the complete nucleotide sequence of the small resistance plasmid pIE1107 revealed a close similarity to the well-known IncQ plasmids. Highly conserved replication proteins and nearly identical origins of replication (oriV) suggest equivalent functions in the related replication systems. However, pIE1107 contains two copies of IncQ-oriV-like DNA which are slightly different regarding the iterons. Upon deletion of a silent copy of IncQ-oriV-like DNA the resulting plasmid is fully compatible with IncQ plasmids, indicating that there is no mutual communication between the replication control of the respective replicons. Experiments with clonedoriV DNA strongly suggest that the replication initiation protein of pIE1107 has specialized into the distinct target-iterons of its ownoriV which differs only by a few nucleotides from theoriV of IncQ plasmids. Implications from the apparent highly specific protein–DNA recognition and from the incompatibility properties of pIE1107 for the evolution of a family of compatible, IncQ-like plasmids are discussed.     

Isolation of a new broad-host-range IncQ-like plasmid, pTC-F14, from the acidophilic bacterium Acidithiobacillus caldus and analysis of the plasmid replicon

A moderately thermophilic (45 to 50 degrees C), highly acidophilic (pH 1.5 to 2.5), chemolithotrophic Acidithiobacillus caldus strain, f, was isolated from a biooxidation process used to treat nickel ore. Trans-alternating field electrophoresis analysis of total DNA from the A. caldus cells revealed two plasmids of approximately 14 and 45 kb. The 14-kb plasmid, designated pTC-F14, was cloned and shown by replacement of the cloning vector with a kanamycin resistance gene to be capable of autonomous replication in Escherichia coli. Autonomous replication was also demonstrated in Pseudomonas putida and Agrobacterium tumefaciens LBA 4404, which suggested that pTC-F14 is a broad-host-range plasmid. Sequence analysis of the pTC-F14 replicon region revealed five open reading frames and a replicon organization like that of the broad-host-range IncQ plasmids. Three of the open reading frames encoded replication proteins which were most closely related to those of IncQ-like plasmid pTF-FC2 (amino acid sequence identities: RepA, 81%; RepB, 78%; RepC, 74%). However, the two plasmids were fully compatible and pTC-F14 represents a new IncQ-like plasmid replicon. Surprisingly, asymmetrical incompatibility was found with the less closely related IncQ plasmid R300B derivative pKE462 and the IncQ-like plasmid derivative pIE1108. Analysis of the pTC-F14 oriV region revealed five direct repeats consisting of three perfectly conserved 22-bp iterons flanked by iterons of 23 and 21 bp. Plasmid pTC-F14 had a copy number of 12 to 16 copies per chromosome in both E. coli, and A. caldus. The rep gene products of pTC-F14 and pTF-FC2 were unable to functionally complement each other's oriV regions, but replication occurred when the genes for each plasmid's own RepA, RepB, and RepC proteins were provided in trans. Two smaller open reading frames were found between the repB and repA genes of pTC-F14, which encode proteins with high amino acid sequence identity (PasA, 81%; PasB, 72%) to the plasmid addiction system of pTF-FC2. This is the second time a plasmid stability system of this type has been found on an IncQ-like plasmid.     

Detection and characterization of broad-host-range plasmids in environmental bacteria by PCR.

Primer systems for PCR amplification of different replicon-specific DNA regions were designed on the basis of published sequences for plasmids belonging to the incompatibility (Inc) groups IncP, IncN, IncW, and IncQ. The specificities of these primer systems for the respective Inc groups were tested with a collection of reference plasmids belonging to 21 different Inc groups. Almost all primer systems were found to be highly specific for the reference plasmid for which they were designed. In addition, the primers were tested with plasmids which had previously been grouped by traditional incompatibility testing to the IncN, IncW, IncP, or IncQ group. All IncQ plasmids gave PCR products with the IncQ primer systems tested. However, PCR products were obtained for only some of the IncN, IncP, and IncW group plasmids. Dot blot and Southern blot analyses of the plasmids revealed that PCR-negative plasmids also failed to hybridize with probes derived from the reference plasmids. The results indicated that plasmids assigned to the same Inc group by traditional methods might be partially or completely different from their respective reference plasmids at the DNA level. With a few exceptions, all plasmids related to the reference plasmid at the DNA level also reacted with the primer systems tested. PCR amplification of total DNA extracted directly from different soil and manure slurry samples revealed the prevalence of IncQ- and IncP-specific sequences in several of these samples. In contrast, IncN- and IncW-specific sequences were detected mainly in DNA obtained from manure slurries.     

Introduction of DNA into Actinomycetes by bacterial conjugation from E. coli--an evaluation of various transfer systems

Gene transfer is a basic requirement for optimizing bioactive natural substances produced by an increasing number of industrially used microorganisms. We have analyzed quantitatively horizontal gene transfer from Escherichia coli to Actinomycetes. The efficiencies of DNA transfer of four different systems were compared that consist of conjugative and mobilizable plasmids with a broad-host range. Three novel binary vector set-ups were constructed based on: (i) the IncQ group of mobilizable plasmids (RSF1010), (ii) IncQ-like pTF-FC2 and (iii) pSB102 that belongs to a new class of broad-host-range plasmids. The established system based on the IncPalpha group of conjugative plasmids served as the reference. For all plasmids constructed, we confirmed the functional integrity of the selected transfer machineries by intrageneric matings between E. coli strains. We demonstrate that the transfer systems introduced in this study are efficient in mediating gene transfer from E. coli to Actinomycetes and are possible alternatives for gene transfer into Actinomycetes for which the IncPalpha-based transfer system is not applicable. The use of plasmids that integrate into the recipients' chromosomes compared to that of plasmids replicating autonomously is shown to allow the access to a wider range of hosts.     

Identification and characterization of a native Dichelobacter nodosus plasmid, pDN1

The gram-negative anaerobe Dichelobacter nodosus is the primary causative agent of ovine footrot, a mixed bacterial infection of the hoof. We report here the characterization of a novel native plasmid, pDN1, from D. nodosus. Sequence analysis has revealed that pDN1 has a high degree of similarity to broad-host-range plasmids belonging, or related, to Escherichia coli incompatibility group Q. However, in contrast to these plasmids, pDN1 encodes no antibiotic resistance determinants, lacks genes E and F, and hence is smaller than all previously reported IncQ plasmids. In addition, pDN1 belongs to a different incompatibility group than the IncQ plasmids to which it is related. However, pDN1 does contain the replication and mobilization genes that are responsible for the extremely broad host range characteristic of IncQ plasmids, and derivatives of pDN1 replicate in E. coli. In addition, the mobilization determinants of pDN1 are functional, since derivatives of pDN1 are mobilized by the IncPalpha plasmid RP4 in E. coli.     

Monitoring the spread of broad host and narrow host range plasmids in soil microcosms

Abstract: Escherichia coli recipient and E. coli donor strains carrying streptothricin-resistance genes were inoculated together into different soil microcosms. These genes were localized on the narrow host range plasmids of incompatibility (Inc) groups FII, Il, and on the broad host range plasmids of IncP1, IncN, IncW3, and IncQ. The experiments were intended to study the transfer of these plasmids in sterile and non-sterile soil with and without antibiotic selective pressure and in planted soil microcosms. Transfer of all broad host range plasmids from the introduced E. coli donor into the recipient was observed in all microcosm experiments. These results indicate that broad host range plasmids encoding short and rigid pili might spread in soil environments by conjugative transfer. In contrast, transfer of the narrow host range plasmids of IncFII and IncI1, into E. coli recipients was not found in sterile or non-sterile soil. These plasmids encoded flexible pili or flexible and rigid pili, respectively. In all experiments highest numbers of transconjugants were detected for the IncP1-plasmid (pTH16). There was evidence with plasmids belonging to IncP group transferred by conjugation into a variety of indigenous soil bacteria at detectable frequencies. Significantly higher numbers of indigenous transconjugants were obtained for the IncP-plasmid under antibiotic selection pressure, and a greater diversity of transconjugants was detected. Availability of nutrients and rhizosphere exudates stimulated transfer in soil. Furthermore, transfer of the IncN-plasmid (pIE1037) into indigenous bacteria of the rhizosphere community could be detected. The transconjugants were determined by BIOLOG as Serratia liquefaciens . Despite the known broad host range of IncW3 and IncQ-plasmids, transfer into indigenous soil bacteria could not be detected.     

A new IncQ plasmid R89S: Properties and genetic organization

The new small (8.18 kb) streptomycin-resistant multicopy plasmid R89S of the Q group incompatibility is described. In contrast to other IncQ plasmids, replication of R89S is dependent on DNA polymerase 1 and proceeds in the absence of de novo protein synthesis. According to our data up to now, the host spectrum of the plasmid R89S is limited to Enterobacteriaceae. A genetic map of the plasmid R89S has been prepared through the construction of deletion and insertion derivatives. Phenotypic analysis of these derivatives has identified the location of genes encoding resistance to streptomycin, and the region essential for mobilization of R89S. The origin of vegetative replication has been located within a 0.7-kb fragment. Another region highly homologous to oriV of the plasmid RSF1010, but not functioning as an origin of replication, was localized. Two regions involved in the expression of incompatibility have also been identified. The data from the restriction analyses, DNA-DNA hybridization, and genetic experiments enable us to assume that the plasmid R89S is a naturally occurring recombinant between part of an IncQ plasmid and another narrow host range replicon of unknown incompatibility group.     

Retrotransfer of IncP1-like plasmids from aquatic bacteria

The first observation of plasmid retrotransfer by plasmids isolated from environmental sources is reported. A high incidence of retrotransferring ability amongst plasmids isolated from epilithic bacteria was found; some of these plasmids retrotransferred an IncQ plasmid at very high frequencies. Despite the broad host-range of the majority of the plasmids, only five out of 12 could be assigned to an incompatibility group by DNA hybridization. All five were designated IncP1; this revealed a limitation of probes derived from clinical sources for use with environmental isolates. Incompatibility testing by plate mating suggested that four additional plasmids displayed varying, albeit lower, degrees of incompatibility to the IncP1 plasmid RP1.     

The evolution of pTF-FC2 and pTC-F14, two related plasmids of the IncQ-family

Two plasmids, pTF-FC2 and pTC-F14, that belong to the IncQ-like plasmid family were isolated from two related bacteria, Acidithiobacillus ferrooxidans and Acidithiobacillus caldus, respectively. The backbone regions of the two plasmids share a sufficiently high amount of homology to indicate that they must have originated from the same ancestral plasmid. Although some of their replication proteins could complement each other, the plasmids have evolved sufficiently for their replicons to have become compatible. This compatibility has occurred by changes in the iteron sequence, RepC (iteron binding protein) specificity and the regulation properties of the RepB primase. Two of the five mobilization genes have remained highly conserved, whereas the other three genes appear to have evolved such that each plasmid is mobilized most efficiently by a different self-transmissible plasmid. Plasmids pTF-FC2 and pTC-F14 do not appear to compete at the level of mobilization. The antitoxins of the toxin-antitoxin (TA) plasmid stability systems were partly able to neutralize the toxins of the other plasmid and also to partly cross-regulate the TA systems of the other plasmid with the antitoxin of pTF-FC2 being the most effective cross-regulator. Other aspects of the evolution of the two plasmids are described and the danger of making the assumption that incompatibly of IncQ-like plasmids is a reflection of the degree of relatedness of two plasmids is discussed.     

Comparative study of non-conjugative R-plasmids from enterobacteria and Pseudomonas aeruginosa

Nonconjugative R-plasmids pBS76 and pBS94 (Sm Su), pBS95 and pBS96 (Sm Su Ap) isolated from clinical strains of Pseudomonas aeruginosa and plasmids pKMR281-pKMN284 (Sm Su), pKMR285-pKMR286 (Sm Su Tc) isolated from clinical strains of enterobacteria have been studied. Restriction maps of these plasmids are presented in the paper with some of plasmid genes for antibiotic resistance localized on them. The resistance determinants of plasmids pBS95 and pBS96 are shown to be included in transposon Tn3612 analogous to Tn3. Plasmids pBS76, pBS94-96 are of the wide host range and belong to incompatibility group P4 (IncQ). Plasmids pKMR281-pKMR286 are mutually incompatible and share the conspicuous DNA homology. They are inherited only by enterobacteria and are compatible with IncQ plasmids but in contrast to them are mobilized by RP4 plasmid with lower frequency.     

Diversity, biology and evolution of IncQ-family plasmids

Plasmids of IncQ-family are distinguished by having a unique strand-displacement mechanism of replication that is capable of functioning in a wide variety of bacterial hosts. In addition, these plasmids are highly mobilizable and therefore very promiscuous. Common features of the replicons have been used to identify IncQ-family plasmids in DNA sequence databases and in this way several unstudied plasmids have been compared to more well-studied IncQ plasmids. We propose that IncQ plasmids can be divided into four subgroups based on a number of mutually supportive criteria. The most important of these are the amino acid sequences of their three essential replication proteins and the observation that the replicon of each subgroup has become fused to four different lineages of mobilization genes. This review of IncQ-family plasmid diversity has highlighted several events in the evolution of these plasmids and raised several questions for further research.     

A molecular analysis of a broad-host-range plasmid isolated from Thiobacillus ferrooxidans

Abstract: A 12.4-kb plasmid, pTF-FC2, that was isolated from Thiobacillus ferrooxidans and which is capable of replication in a wide range of Gram-negative bacteria, has been sequenced. The extent of the regions involved in both replication and mobilization have been delineated. The site of initiation of replication ( oriV ) has been localized on a 185-bp fragment and the origin of transfer ( oriT ) on a 138-bp fragment. Three proteins that were essential for replication and four that were essential for mobilization have been identified. The origin of replication was clearly similar to that of the IncQ plasmids although no complementation or incompatibility between pTF-FC2 and the IncQ plasmid, R300B, was detected. There was a clear similarity in the size,location and amino acid sequence of the proteins of the pTF-FC2 mobilization region with those of the TraI region of the IncP plasmids, RP4 and R751.Two inverted repeated sequences which had 37/38-bp and 38/38-bp sequence identity with the Tn 21 transposon were identified. The C-terminal part of a transposase and the N-terminal portion of a resolvase were located between the inverted repeats. These open reading frames are most likely the remnants of a defective transposon. A protein with homology to a mercury- resistance regulator was also present within the transposon-like element although no gene encoding for mercury reductase could be indentified.     

Genome organization of the plasmid of IncQ/P4 group and its vector derivatives

The genome organization and functioning of IncQ/P4 plasmids are reviewed. Based on these plasmids, cloning vectors have been constructed for broad host range of gram-negative bacteria. Together with one- and two-replicon vectors for cloning via insertion inactivation of markers, specialized plasmid vectors are described: cosmids, promoter-probe vectors, vectors for direct selection of recombinant molecules. Examples of using broad host range vectors for gene cloning and expression in non-enteric gram-negative bacteria are presented.     

Analysis of the complete nucleotide sequence of an Actinobacillus pleuropneumoniae streptomycin-sulfonamide resistance plasmid, pMS260

pMS260 is an 8.1-kb non-conjugative but mobilizable plasmid that was isolated from Actinobacillus pleuropneumoniae and encodes streptomycin (SM) and sulfonamide (SA) resistances. The analysis of the complete nucleotide sequence of the plasmid revealed a high degree of similarity between pMS260 and the broad-host-range IncQ family plasmids. pMS260 had a single copy of an origin of vegetative replication (oriV). This sequence was identical to a functional oriV of the IncQ-like plasmid pIE1130 that had been exogenously isolated from piggery manure. However, pMS260 did not carry the second IncQ plasmid RSF1010-like oriV region present in pIE1130. A pIE1130-identical transfer origin was also found in pMS260. In addition, the deduced amino acid sequences from 10 open reading frames identified in pMS260 were entirely or nearly identical to those from genes for the replication, mobilization, and SM-SA resistance of pIE1130, indicating that pMS260 belongs to the IncQ-1 gamma subgroup. pMS260 is physically indistinguishable from pIE1130 apart from two DNA regions that contain the chloramphenicol and kanamycin resistance genes (catIII and aphI, respectively) and the second oriV-like region of pIE1130. The codon bias analysis of each gene of pIE1130 and the presence of potential recombination sites in the sulII-strA intergenic regions suggest that pIE1130 seems to have acquired the catIII and aphI genes more recently than the other genes of pIE1130. Therefore, pMS260 may be the ancestor of pIE1130. Information regarding the broad-host-range replicon of pMS260 will be useful in the development of genetic systems for a wide range of bacteria including A. pleuropneumoniae.     

Association of tellurium resistance and bacteriophage inhibition conferred by R plasmids.

Concomitant resistance to tellurium compounds (Ter) and inhibition of coli-phage development (Phi) are properties mediated by many H2 incompatibility group R plasmids which have been isolated from diverse bacterial and geographic sources. Ter plasmids from tellurium-resistant bacteria that were isolated from sewage and industrial wastes also mediated phage inhibition. Of these Ter plasmids, three from Citrobacter freundii belonged to the H incompatibility group, whereas three from Klebsiella pneumoniae did not.     

Maintenance of broad-host-range incompatibility group P and group Q plasmids and transposition of Tn5 in Bartonella henselae following conjugal plasmid transfer from Escherichia coli.

The first demonstration of conjugal plasmid transfer from Escherichia coli to Bartonella henselae is reported. Transconjugants bearing plasmids of incompatibility groups P (IncP) and Q (IncQ), expressing various resistance markers, were generated. Tn5 transposons delivered on suicide plasmids by conjugation showed transpositional insertion into random chromosomal sites.     

Plasmid Stability in Pseudomonas fluorescens in the Rhizosphere

Plasmids belonging to various incompatibility (Inc) groups were introduced into the efficiently root-colonizing strain Pseudomonas fluorescens WCS365, and their stabilities in complex and minimal media and in the rhizospheres of tomato, wheat, and potato plants grown under gnotobiotic conditions without selection pressure were tested. The IncP plasmid was found to be highly unstable under all conditions tested, whereas the IncQ and IncW plasmids showed intermediate stabilities and the plasmids pVSP41 and pWTT2081, for which the Inc group is unknown, both containing the origin of replication (rep) and stability (sta) regions of the Pseudomonas aeruginosa pVS1 replicon, were stably maintained under all conditions tested. Growth experiments in which cells of strain WCS365 carrying the plasmid pWTT2081 were grown in the presence of WCS365 without the plasmid showed that the presence of pWTT2081 acts as a burden. We conclude that pVSP41 and pWTT2081 are valuable as stable vectors for the functional analysis of genes involved in root colonization, provided that control cells carry the empty vector.     

Comparative Biology of Two Natural Variants of the IncQ-2 Family Plasmids,pRAS3.1 and pRAS3.2

Plasmids pRAS3.1 and pRAS3.2 are two closely related, natural variants of the IncQ-2 plasmid family that have identical plasmid backbones except for two differences. Plasmid pRAS3.1 has five 6-bp repeat sequences in the promoter region of the mobB gene and four 22-bp iterons in its oriV region, whereas pRAS3.2 has only four 6-bp repeats and three 22-bp iterons. Plasmid pRAS3.1 was found to have a higher copy number than pRAS3.2, and we show that the extra 6-bp repeat results in an increase in mobB and downstream mobA/repB expression. Placement of repB (primase) behind an arabinose-inducible promoter in trans resulted in an increase in repB expression and an approximately twofold increase in the copy number of plasmids with identical numbers of 22-bp iterons. The pRAS3 plasmids were shown to have a previously unrecognized toxin-antitoxin plasmid stability module within their replicons. The ability of the pRAS3 plasmids to mobilize the oriT regions of two other plasmids of the IncQ-2 family, pTF-FC2 and pTC-F14, suggested that the mobilization proteins pRAS3 are relaxed and can mobilize oriT regions with substantially different sequences. Plasmids pRAS3.1 and pRAS3.2 were highly incompatible with plasmids pTF-FC2 and pTC-F14, and this incompatibility was removed on inactivation of an open reading frame situated downstream of the mobCDE mobilization genes rather than being due to the 22-bp oriV-associated iterons. We propose that the pRAS3 plasmids represent a third, γ incompatibility group within the IncQ-2 family plasmids.Plasmids of the IncQ family are small (<20 kb), have a broad host range, and are highly promiscuous due to their ability to be mobilized very efficiently by self-transmissible plasmids such as the IncP plasmids. They have been divided into two families, IncQ-1 and IncQ-2, based on the amino acid sequence relatedness of their RepA (helicase), RepB (primase), and RepC (DNA-binding) replication proteins and because the mobilization proteins of the two families are unrelated, consisting of three or five genes, respectively (31). IncQ-1 group plasmids include RSF1010 and the near-identical R1162, pDN1, pIE1107, pIE1115, and pIE1130, while IncQ-2 plasmids include pTF-FC2, pTC-F14, and pRAS3.IncQ-2 plasmids pRAS3.1 and pRAS3.2 were isolated in Norway from the fish pathogens Aeromonas salmonicida subsp. salmonicida and atypical A. salmonicida, respectively, while investigating plasmids that conferred resistance to tetracycline (21). The two plasmids encode identical replication and mobilization proteins, with the most important differences in the plasmid backbone being that pRAS3.1 has four 22-bp iterons in its oriV region and five 6-bp repeat sequences upstream of its mobB gene, whereas pRAS3.2 has only three iterons and four 6-bp repeat sequences. No biological studies were carried out in the initial report of the pRAS3 plasmids. As a contribution to our studies on the evolution of IncQ plasmids, our longer-term aim is to address the question of why two natural versions of the plasmid exist. Here we report on the major differences in the biology of the two plasmids. In addition, we discovered the presence of repC and mobB genes that were not detected when the sequence of pRAS3 plasmids was previously reported. We also discovered a putative toxin-antitoxin (TA) postsegregational system different from that found in other members of the IncQ plasmids and tested it for functionality.The IncQ-1 plasmids are subdivided into incompatibility groups α, β, and γ, (31), whereas the IncQ-2 plasmids are subdivided into two incompatibility groups, α and β (14). In this work we also report on the incompatibility between the pRAS3 plasmids and other members of the IncQ-2 plasmid family as well as the IncQ-1 family plasmids. Furthermore, we compare the functional relatedness of the pRAS3 mobilization system with that of previously studied IncQ-2 plasmids.