Distribution of plasmid maintenance regions among IncFIV plasmids

The distribution of the IncFI basic replicons among IncFIV plasmids was assessed by DNA hybridization. In addition these and 20 other plasmids from 16 incompatibility groups were screened for the presence of IncIV, an incompatibility determinant recently found on the IncFIV plasmid R124. The IncIV determinant was found commonly but not universally among the IncFIV plasmids. It was also detected on the IncFI reference plasmid R386 and plasmids from IncB, IncI alpha and IncI gamma. The frequency and distribution of IncFI replicons among the IncFIV plasmids is similar to that observed in other F groups. The similarity of the IncFIV plasmids to plasmids of the other IncF groups and the failure to find replicons unique to IncFIV plasmids indicates that their division into a separate incompatibility group is not justified.     

Characterization of the maintenance functions of IncFIV plasmid R124

The genetic arrangement of the regions involved in R124 replication and incompatibility have been located and their homology to the IncFI basic replicons has been assessed. We show that R124 has homology with all three basic replicons, RepFIA, RepFIB, and RepFIC, and that these regions, FIVA, RepFIVB, and RepFIVC, are widely separated on the R124 genome. Cloning of autonomously replicating fragments has shown that RepFIVB and RepFIVC are functional in R124 and express incompatibility. The FIVA region was unable to form a functional replicon and when cloned into pUC8 lacked incompatibility activity. A fourth region of R124 was identified, which although not essential for replication stabilized mini-R124 plasmid replication and exhibited incompatibility with R124. This region, designated IncIV, showed no homology to RepFIA, RepFIB, or RepFIC. Incompatibility expression of IncIV required only the EcoRI fragment E13 but the strength of the reaction was modified in the presence of other fragments. The replication and incompatibility properties of an R124 deletion derivative indicated that R124 can switch its replication to either RepFIVB or RepFIVC when in the presence of an incompatible plasmid. The ambiguous incompatibility reactions reported for R124 is a result of the expression of the two functional replicons, RepFIVB and RepFIVC, and that expressed by IncIV.     

Properties and incompatibility behavior of miniplasmids derived from the bireplicon plasmid pCG86

Summary Many plasmids belonging to the F incompatibility groups contain more than one basic replicon. The chimeric plasmid pCG86 is an example of such a multireplicon plasmid. The two basic replicons of pCG86, RepFIIA/FIC and RepFIB have been cloned and re-ligated, the copy numbers of the clones have been determined, and the incompatibility behavior of plasmids containing the ligated replicons and the individual replicons has been studied. The bireplicon plasmids are not expected to be incompatible as recipients with monoreplicon RepFIB or RepFIIA/RepFIC plasmids, since when one replicon is challenged by an incoming replicon, the other should be able to handle the plasmid's replication. In our studies, we found that challenge with either monoreplicon plasmid resulted in incompatibility. This incompatibility was increased in bireplicon plasmids in which RepFIB was duplicated. We conclude that in the bireplicon plasmids, challenging the replication control of one replicon by an incompatible plasmid can interfere with the replication originating from the second replicon.     

Comparative biology of IncQ and IncQ-like plasmids.

Plasmids belonging to Escherichia coli incompatibility group Q are relatively small (approximately 5 to 15 kb) and able to replicate in a remarkably broad range of bacterial hosts. These include gram-positive bacteria such as Brevibacterium and Mycobacterium and gram-negative bacteria such as Agrobacterium, Desulfovibrio, and cyanobacteria. These plasmids are mobilized by several self-transmissible plasmids into an even more diverse range of organisms including yeasts, plants, and animal cells. IncQ plasmids are thus highly promiscuous. Recently, several IncQ-like plasmids have been isolated from bacteria found in environments as diverse as piggery manure and highly acidic commercial mineral biooxidation plants. These IncQ-like plasmids belong to different incompatibility groups but have similar broad-host-range replicons and mobilization properties to the IncQ plasmids. This review covers the ecology, classification, and evolution of IncQ and IncQ-like plasmids.     

Evidence that IncG (IncP-6) and IncU plasmids form a single incompatibility group

The Escherichia coli IncG and IncU plasmid incompatibility groups were assigned in 1980 and 1981, respectively. Complete plasmid sequences have recently been published for both these groups, and revealed that their replication proteins are related. We show that when cloned at high-copy-number, putative iterons from the previously identified IncG replicon cause strong incompatibility with IncU plasmids. Incompatibility, albeit weaker, was also demonstrated between the two replicons at their normal low-copy-number. This suggests that a single incompatibility group exists. The only known IncG plasmid, Rms149, can replicate in Pseudomonas species where it is designated IncP-6. We recommend that the combined group be known as IncU (IncP-6 in Pseudomonas spp.).     

Molecular homology and incompatibility in the IncFI plasmid Group

The usual grounds for the inclusion of a plasmid in a particular incompatibility group are its mutual incompatibility with a type plasmid of that group, and, in some cases, the demonstration of shared regions of specific homology, presumed to be related to DNA replication. We have found that some plasmids classified as IncFI on genetical grounds share no homology with the previously described incompatibility regions of F on the basis of hybridization of specific radioactive probes to restriction enzyme digests of DNA from these plasmids. Others show homology with some or all of the regions of the F plasmid that can express incompatibility. The incompatibility behaviour of these plasmids has been examined to determine the relationship between the possession of regions of homology and the expression of incompatibility. Three plasmids, ColV3-K30, pHH507 and Entp307, show homology only with the secondary replicon of F and appear to use sequences homologous with the secondary F replicon in their replication. The results are consistent with the propositions that some contemporary IncFI plasmids arose by the integration of several replicons, and, in general, the replicon not being used for replicon expresses its incompatibility, as does the replicon being used for replication. We conclude that incompatibility of two plasmids with F does not necessarily demonstrate relatedness of the plasmids to each other, and that inclusion within the IncFI group can result from the possession of any of several combinations of inc sequences.     

Isolation and location on the R27 map of two replicons and an incompatibility determinant specific for IncHI1 plasmids.

Two replicons were isolated independently from different IncHI1 plasmids. One was isolated from R27, and a second was isolated from pIP522. We demonstrate, by DNA-DNA hybridization experiments, that these maintenance regions are different and that they are specific to, and carried by, all IncHI1 plasmids tested. In view of this specificity we decided to designate the replicon isolated from R27 as RepHI1A and the replicon isolated from pIP522 as RepHI1B. These two autoreplicative regions are not related to a third replicon present in all IncHI1 plasmids that bears homology with RepFIA and that expresses the characteristic incompatibility of IncHI1 subgroup plasmids toward F factor (D. Saul, D. Lane, and P. L. Bergquist, Mol. Microbiol. 2:219-225, 1988; D. E. Taylor, R. W. Hedges, and P. L. Bergquist, J. Gen. Microbiol. 131:1523-1530, 1985). These results demonstrate that all IncHI1 plasmids tested contain at least three replicons. An incompatibility (Inc) region that hybridizes specifically to all the IncHI1 plasmids was previously isolated (M. Couturier, F. Bex, P. L. Bergquist, and W. K. Maas, Microbiol. Rev. 52:375-395, 1988). Although this Inc locus is not located in an autoreplicative region of IncHI1 plasmids, we observed that this locus stabilizes a low-copy-number replicon. This Inc locus is probably a component of an active partition locus involved in the maintenance of IncHI1 plasmids. The nucleotide sequence of the Inc region contains direct repeats of 31 bp. In addition, this incompatibility determinant hybridizes specifically with IncHI1 plasmids but expresses incompatibility toward plasmids of both IncHI subgroups (IncHI1 and IncHI2). In this communication, we present the mapping of these maintenance elements on the R27 genome.     

Molecular Characterization of a Multidrug Resistance IncF Plasmid from the Globally Disseminated Escherichia coli ST131 Clone

Escherichia coli sequence type 131 (E. coli ST131) is a recently emerged and globally disseminated multidrug resistant clone associated with urinary tract and bloodstream infections. Plasmids represent a major vehicle for the carriage of antibiotic resistance genes in E. coli ST131. In this study, we determined the complete sequence and performed a comprehensive annotation of pEC958, an IncF plasmid from the E. coli ST131 reference strain EC958. Plasmid pEC958 is 135.6 kb in size, harbours two replicons (RepFIA and RepFII) and contains 12 antibiotic resistance genes (including the bla _CTX-M-15 gene). We also carried out hyper-saturated transposon mutagenesis and multiplexed transposon directed insertion-site sequencing (TraDIS) to investigate the biology of pEC958. TraDIS data showed that while only the RepFII replicon was required for pEC958 replication, the RepFIA replicon contains genes essential for its partitioning. Thus, our data provides direct evidence that the RepFIA and RepFII replicons in pEC958 cooperate to ensure their stable inheritance. The gene encoding the antitoxin component (ccdA) of the post-segregational killing system CcdAB was also protected from mutagenesis, demonstrating this system is active. Sequence comparison with a global collection of ST131 strains suggest that IncF represents the most common type of plasmid in this clone, and underscores the need to understand its evolution and contribution to the spread of antibiotic resistance genes in E. coli ST131.     

Comparative characterization of repABC-type replicons of Paracoccus pantotrophus composite plasmids

The repABC replicons have an unusual structure, since they carry genes coding for partitioning (repA, repB) and replication (repC) proteins, which are organized in an operon. So far, the presence of these compact bi-functional modules has been reported only in the megaplasmids of the Rhizobiaceae and within the plasmid pTAV1 (107kb) of Paracoccus versutus. We studied the distribution of repABC-type replicons within bacteria belonging to the genus Paracoccus. We found that repABC replicons occur only in the group of pTAV1-like plasmids: pKLW1, pHG16-a, pWKS2, and pPAN1, harbored by different strains of Paracoccus pantotrophus. A partial sequencing approach followed by phylogenetic analysis revealed that these replicons constitute a distinct evolutionary branch of repABC replicons. Incompatibility studies showed that they represent two incompatibility groups designated IncABC1 (pTAV1, pKLW1, and pHG16-a) and IncABC2 (pPAN1). Sequence comparison using available databases allowed the identification, within plasmid pRS241d of Rhodobacter sphaeroides 2.4.1, of an additional sequence highly homologous to the paracoccal repABC replicons, which has been included in comparative analyses.     

Identification of a megaplasmid centromere reveals genetic structural diversity within the repABC family of basic replicons

The basic replication unit of many plasmids and second chromosomes in the alpha-proteobacteria consists of a repABC locus that encodes the trans- and cis-acting components required for both semiautonomous replication and replicon maintenance in a cell population. In terms of physical genetic organization and at the nucleotide sequence level, repABC loci are well conserved across various genera. As with all repABC-type replicons that have been genetically characterized, the 1.4 Mb pSymA and 1.7 Mb pSymB megaplasmids from the plant endosymbiont Sinorhizobium meliloti encode strong incompatibility (inc) determinants. We have identified a novel inc sequence upstream of the repA2 gene in pSymA that is not present on pSymB and not reported in other repABC plasmids that have been characterized. This region, in concert with the repA and repB genes, stabilizes a test plasmid indicating that it constitutes a partitioning (par) system for the megaplasmid. Purified RepB binds to this sequence and binding may be enhanced by RepA. We have isolated 19 point mutations that eliminate incompatibility, reduce RepB binding or the stabilization phenotype associated with this sequence and all of these map to a 16-nucleotide palindromic sequence centred 330 bp upstream of the repA2 gene. An additional five near-perfect repeats of this palindrome are located further upstream of the repA2 gene and we show that they share some conservation with known RepB binding sites in different locations on other repABC plasmids and to two sequences found on the tumour inducing plasmid of Agrobacterium tumefaciens. These additional palindromes also bind RepB but one of them does not display obvious incompatibility effects. A heterogenic distribution of par sequences demonstrates unexpected diversity in the structural genetic organization of repABC loci, despite their obvious levels of similarity.     

Homology among nearly all plasmids infecting three Bacillus species.

We have surveyed naturally occurring plasmids in strains of Bacillus subtilis and the closely related species B. mojavensis and B. licheniformis. Previous studies have failed to find host-benefitting functions for plasmids of these species, suggesting that these plasmids are nonmutualistic. Only one type of plasmid was found in each plasmid-bearing strain, suggesting that most of the plasmids infecting these Bacillus species are in the same incompatibility group. A sample of 18 plasmids from these species ranged in size from 6.9 to 16 kb, with all but 6 plasmids falling into three size groups. These groups differed in the sizes of their host ranges and geographical ranges. All but 1 of the 18 plasmids from these three host species are homologous with one another. The cryptic plasmids from these three species are far less diverse than are plasmids (from other species) that are known to benefit their bacterial hosts. The low-level diversity among these cryptic plasmids is consistent with the hypothesis that host-benefitting adaptations play an important role in fostering the coexistence of plasmid populations, but other explanations for the low-level plasmid diversity are possible. Comparison of the phylogenies of the plasmids with those of their hosts suggests that Bacillus plasmids are horizontally transferred in nature at a low rate similar to that found for the colicin plasmids of Escherichia coli.     

Distribution of sequences homologous to the impCAB operon of TP110 among bacterial plasmids of different incompatibility groups

Summary Mutagenic DNA repair is a function of many naturally occurring plasmids belonging to several different incompatibility groups. A DNA probe corresponding to the impCAB operon of the IncIl plasmid TP110, which encodes such functions, was used to investigate the distribution of homologous sequences in both related and unrelated plasmids. Southern blotting was used to demonstrate considerable sequence conservation amongst a number of plasmid types, with imp-related sequences being found on plasmids belonging to the I1, I1/B, B and FIV incompatibility groups. However, no homology was detected amongst plasmids of the N and L/M incompatibility groups, many of which carry functionally similar gene clusters. It appears that sequences determining mutagenic repair functions have been largely conserved within any one incompatibility group, but that significant divergent evolution has occurred between groups.     

Cloning and characterization of a replicon region of the IncHII plasmid pHH1457

A replicative region of the large conjugative plasmid pHH1457 (incompatibility group HII (IncHII)) was cloned. A 1.4-kbp region, in a stable pSBII14 clone, containing a PolI-independent replicon and determinants for the HII incompatibility phenotype, was selected and characterized. High incompatibility with IncHII plasmids was corroborated. Independent replication of the insert was demonstrated by ligation to an antibiotic resistance cassette. pSBII14 was used as a probe to identify IncHII plasmids from other members of the H complex: IncHI (IncHI1, IncHI2 and IncHI3 subgroups). Hybridization experiments revealed a high homology with the replication region of IncHII plasmids, but not with IncHI1 or IncHI3 plasmid prototypes. Homology with IncHI2 plasmids was observed, suggesting the presence of IncHII-like replicons among this subgroup of plasmids. This is the first report of the characterization of an IncHII plasmid maintenance region.     

Distribution of Bacillus megaterium QM B1551 plasmids among other B. megaterium strains and Bacillus species

Bacillus megaterium QM B1551 contains seven plasmids. Two are small rolling circle plasmids and five are theta-replicating plasmids with cross-hybridizing replicons that define a new family of very homologous yet compatible theta replicons. Previous sequencing of several of the plasmids has shown genes with high similarity to those on the genomes and plasmids of other Gram-positive bacteria. To test the possible distribution of these plasmids, nine other B. megaterium strains and 20 other Bacillus or related species were tested for the presence of similar replicons, and specific flanking DNA by both hybridization and PCR. The theta replicons were widespread among the B. megaterium strains, and two had one or more of the rolling circle plasmids, but none of the plasmid replicon regions were observed in the other Bacillus or related species. It appears from the data that even though some plasmids carry genes suggesting horizontal transfer, their replicons seem to be unique to B. megaterium, or rarely present in related species.     

Interactions between octopine and nopaline plasmids in Agrobacterium tumefaciens.

Transfer of octopine Ti plasmids to strains already carrying an octopine Ti plasmid was found to occur at the same (high) frequency as transfer to Ti plasmid lacking recipients, showing that resident Ti plasmids do not exhibit entry exclusion towards incoming Ti plasmids. The resident octopine Ti plasmid was lost by the recipient after the entrance of the incoming Ti plasmid, which is indicative of the incompatibility between the Ti plasmids. Octopine Ti plasmids were found to become established only infrequently in recipients with a nopaline Ti plasmid and, vice versa, nopaline Ti plasmids were only rarely established in recipients with an octopine Ti plasmid. Rare clones in which the incoming octopine (nopaline) Ti plasmid had been established despite the presence of a nopaline (octopine) Ti plasmid appeared to harbor cointegrates consisting of the entire incoming Ti plasmid and the entire resident Ti plasmid. The integration event invariably had occurred in a region of the plasmids that is highly conserved in evolution and that is essential for oncogenicity. These results show that octopine and nopaline Ti plasmids cannot be maintained as separate replicons by one and the same cell. Therefore, be definition, these plasmids belong to the same incompatibility group, which has been names inc Rh-1. Agrobacterial non-Ti octopine and nopaline plasmids were found to belong to another incompatibility group. The tumorigenic properties of strains harboring two different Ti plasmids, in a cointegrate structure, were indicative of the virulence genes of both of them being expressed. The agrobacterial non-Ti octopine and nopaline plasmids did not influence the virulence properties encoded by the Ti plasmid.     

Incompatibility groups and the classification of fi - resistance factors

Incompatibility between R factors has been reported by several authors, and four incompatibility groups have already been described by Datta and Hedges among Rfi(-) factors. The stability of 12 plasmids in pairs was studied after 116 crosses, and five new groups were found, designated 5, 6, 7, 8, and 9. Each plasmid studied belongs to one single group. Incompatibility between plasmids in pairs is a clear-cut phenomenon, is easy to observe, and can provide a reliable method for recognizing and classifying resistance factors, and for tracing their spread among bacterial species.     

Nucleotide sequence of the surface exclusion genes traS and traT from the IncF0 lac plasmid pED208.

pED208 is a 90-kilobase conjugative plasmid belonging to the incompatibility group IncF0 lac. The surface exclusion system from this plasmid was cloned and sequenced, and two genes demonstrated exclusion ability. traS encoded a 186-amino-acid hydrophobic protein which, when transcribed from a vector promoter, caused exclusion of pED208. The product of traT (TraTp) was a 245-residue protein which was highly expressed independently of a vector promoter in Escherichia coli minicells. The TraTp from pED208 was homologous with traT products from the IncF plasmids R-100 and F (80% homology), but recombinants containing the pED208 surface exclusion system excluded F poorly.     

The distribution of beta-lactamase genes on plasmids found in Pseudomonas.

Seven types of β-lactamases distinguished by analytic isoelectric focusing have been found on 24 Pseudomonas plasmids belonging to at least eight incompatibility groups. TEM-1- and TEM-2-type enzymes that are determined by transposable genetic elements are distributed among five different incompatibility groups. The other β-lactamase types are found on plasmids in single incompatibility groups. β-Lactamases unique to Pseudomonas plasmids occur on plasmids not transmissible to enterobacteria by conjugation.