Structural elements required for replication and incompatibility of the Rhizobium etli symbiotic plasmid

The symbiotic plasmid of Rhizobium etli CE3 belongs to the RepABC family of plasmid replicons. This family is characterized by the presence of three conserved genes, repA, repB, and repC, encoded by the same DNA strand. A long intergenic sequence (igs) between repB and repC is also conserved in all members of the plasmid family. In this paper we demonstrate that (i) the repABC genes are organized in an operon; (ii) the RepC product is essential for replication; (iii) RepA and RepB products participate in plasmid segregation and in the regulation of plasmid copy number; (iv) there are two cis-acting incompatibility regions, one located in the igs (incalpha) and the other downstream of repC (incbeta) (the former is essential for replication); and (v) RepA is a trans-acting incompatibility factor. We suggest that incalpha is a cis-acting site required for plasmid partitioning and that the origin of replication lies within incbeta.     

Identification of the partitioning site within the repABC-type replicon of the composite Paracoccus versutus plasmid pTAV1

The replicator region of composite plasmid pTAV1 of Paracoccus versutus (included in mini-replicon pTAV320) belongs to the family of repABC replicons commonly found in plasmids harbored by Agrobacterium and Rhizobium spp. The repABC replicons encode three genes clustered in an operon, which are involved in partitioning (repA and repB) and replication (repC). In order to localize the partitioning site of pTAV320, the two identified incompatibility determinants of this mini-replicon (inc1, located in the intergenic sequence between repB and repC; and inc2, situated downstream of the repC gene) were PCR amplified and used together with purified RepB fusion protein (homologous to the type B partitioning proteins binding to the partitioning sites) in an electrophoretic mobility shift assay. The protein bound only inc2, forming two complexes in a protein concentration-dependent manner. The inc2 region contains two long (14-bp) repeated sequences (R1 and R2). Disruption of these sequences completely eliminates RepB binding ability. R1 and R2 have sequence similarities with analogous repeats of another repABC replicon of plasmid pPAN1 of Paracoccus pantotrophus DSM 82.5 and with centromeric sequences of the Bacillus subtilis chromosome. Excess RepB protein resulted in destabilization of the inc2-containing plasmid in Escherichia coli. On the other hand, the inc2 region could stabilize another unstable replicon in P. versutus when RepA and RepB were delivered in trans, proving that this region has centromere-like activity. Thus, it was demonstrated that repA, repB, and inc2 constitute a functional system for active partitioning of pTAV320.     

Sequence diversity of the plasmid replication gene repC in the Rhizobiaceae

The repABC operon is essential for stable maintenance of some Rhizobiaceae plasmids and of pTAV320 from Paracoccus versutus. These plasmids are the largest described family of homologous, yet compatible replicons. The repC gene is essential for plasmid replication, and previous work identified four distinct sequence groups (repC1, repC2, repC3, and repC4) that appear to define different compatibility classes. Probes for these different groups were used to characterize plasmids in Rhizobium leguminosarum population studies and three new repC sequence groups, repC5, repC6, and repC7 were identified. The general repC primers were modified to amplify a wider range of repC sequences and repC sequences were identified in Sinorhizobium and Mesorhizobium type strains. We also showed that the repC3 group-specific primers described previously do not amplify all repC3 sequences and developed a new repC3 amplification strategy.     

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.     

Cell-cell signaling and the Agrobacterium tumefaciens Ti plasmid copy number fluctuations

The Agrobacterium tumefaciens oncogenic Ti plasmids replicate and segregate to daughter cells via repABC cassettes, in which repA and repB are plasmid partitioning genes and repC encodes the replication initiator protein. repABC cassettes are encountered in a growing number of plasmids and chromosomes of the alpha-proteobacteria, and findings from particular representatives of agrobacteria, rhizobia and Paracoccus have began to shed light on their structure and functions. Amongst repABC replicons, Ti plasmids and particularly the octopine-type Ti have recently stood as model in regulation of repABC basal expression, which acts in plasmid copy number control, but also appear to undergo pronounced up-regulation of repABC, upon interbacterial and host-bacterial signaling. The last results in considerable Ti copy number increase and collective elevation of Ti gene expression. Inhibition of the Ti repABC is in turn conferred by a plant defense compound, which primarily affects Agrobacterium virulence and interferes with cell-density perception. Altogether, the above suggest that the entire Ti gene pool is subjected to the bacterium-eukaryote signaling network, a phenomenon quite unprecedented for replicons thought of as stringently controlled. It remains to be seen whether similar copy number variations characterize related replicons or if they are of even broader significance in plasmid biology.     

The expression of a novel antisense gene mediates incompatibility within the large repABC family of alpha-proteobacterial plasmids

Large extrachromosomal replicons in many members of the alpha-proteobacteria encode genes that are required for plant or animal pathogenesis or symbiosis. Most of these replicons encode repABC genes that control their replication and faithful segregation during cell division. In addition to its chromosome, the plant endosymbiont Sinorhizobium meliloti also maintains the 1.4 Mb pSymA and 1.7 Mb pSymB symbiotic megaplasmids both of which are repABC-type replicons. In all repABC loci that have been characterized, an apparently untranslated intergenic region between the repB and repC genes encodes a strong incompatibility determinant (referred to as incalpha). Here we report the isolation of mutations within the incalpha regions of pSymA and pSymB that eliminate incompatibility. These mutations map to and inactivate a promoter in the intergenic region that drives the expression of an approximately 56 nucleotide untranslated RNA molecule that mediates incompatibility. This gene, that we have named incA, is transcribed antisense to the repABC genes. Our analysis suggests that the incA gene is conserved in repABC loci from a diverse spectrum of bacteria.     

Polar localization of replicon origins in the multipartite genomes of Agrobacterium tumefaciens and Sinorhizobium meliloti

The origins of replication of many different bacteria have been shown to reside at specific subcellular locations, but the mechanisms underlying their positioning and segregation are still being elucidated. In particular, little is known about the replication of multipartite genomes in bacteria. We determined the cellular positions of the origins of the replicons in the alpha proteobacteria Agrobacterium tumefaciens and Sinorhizobium meliloti and found that they are located at the poles of the cells. Our work demonstrates the conserved extreme polar localization of circular chromosome origins in these alpha proteobacteria and is also the first to specify the cellular location of origin regions from the repABC family. The cellular location of a derivative of the RK2 plasmid is distinct from that of the alpha proteobacterium genomic replicon origins but is conserved across bacteria. Colocalization experiments with the genomic replicons of A. tumefaciens revealed that the repABC replicons, although preferentially positioned at the cell pole, colocalize only rarely. For the repABC replicons in this organism, occupying discrete spatial locations may contribute to their coexistence and stable inheritance.     

Diversity and evolution of repABC type plasmids in Rhodobacterales

The repABC operon is the prevalent replication unit of alphaproteobacterial plasmids. Their semi-autonomy is ensured by the essential replicase gene repC as well as the repAB partitioning cassette. While conserved repAB modules are widespread among bacterial plasmids and homologues are even responsible for chromosome partitioning, repC genes are exclusively present in Alphaproteobacteria . RepABC operons contain two strong incompatibility regions, namely a small regulative antisense RNA gene ( incα ) and a palindromic centromere region ( incβ ), which were previously used to classify these replicons. The present survey pursued a complementary strategy essentially following the rationale that all plasmids identified from a single bacterium are per se compatible. We established a novel classification scheme for plasmids based on comprehensive phylogenetic analyses of repC , repA and repB genes. Our case study is focused on the Roseobacter clade ( Rhodobacterales ), one of the most successful lineages of the marine bacterioplankton. Its global significance was shown in several studies and the interest in these organisms is reflected by more than 40 upcoming genome projects. Based on phylogenetic RepC analyses we identified nine compatibility groups that are expected to stably coexist within the same cell. This prediction is supported by RepA and RepB phylogenies, moreover independent evidence is delivered by the group specificity of highly conserved palindromes ( incβ ).     

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.     

Identification of pTi-SAKURA DNA region conferring enhancement of plasmid incompatibility and stability

In Agrobacterium tumefaciens, the stability of Ti plasmids differs depending on the strain. So far, little is known about genes that cause the difference in stability. The repABC operon is responsible for replication and incompatibility of Ti plasmids. We constructed recombinant plasmids carrying the repABC operon and different portions of pTi-SAKURA. Cells having the recombinant plasmids that harbored a 2.6-kbp NheI fragment of pTi-SAKURA were found to be transformed via conjugation 100-fold less frequently with a small incompatible repABC plasmid than cells having the recombinant plasmids lacking the 2.6-kbp NheI fragment. Since the phenomenon occurred only when the resident and incoming plasmids belonged to the same incompatibility group, it was suggested that the 2.6-kbp NheI fragment bears the potential enhancing incompatibility. The fragment contained an operon consisting of two open reading frames, tiorf24 and tiorf25. tiorf24 is an orphan gene, whereas tiorf25 is a homologue of a group of plasmid stability genes. Removal of the 2.6-kbp fragment from the resident pTi-SAKURA increased the resident plasmid ejection ratio by the incoming repABC plasmid, whereas addition of the fragment to pTiC58 decreased the ejection ratio, and the loss ratio during growth at 37 degrees C. These data suggest that tiorf24 and tiorf25 are responsible for the stability of pTi-SAKURA, and reduce, in the host bacterium, the frequency of ejection of the resident plasmid, presumably through an incompatibility mechanism.     

Characterization of the replication origin of the myxobacterial self-replicative plasmid pMF1

Thus far, pMF1 is the only endogenous myxobacterial plasmid whose replication mechanism is unclear. In this study, we determined that the plasmid replicates via the theta-mode. The pMF1.14 gene, located in the pMF1.13-pMF1.15 operon (repABC), encodes an essential replication initiation protein that was predicted to have no typical DNA/protein binding motifs but contains rich disordered regions. The pMF1 replication-related essential cis-acting DNA region, approximate 370bp, was located within pMF1.14, and was found to contain several directly and inverted atypical repeats. The unique characteristics of the pMF1 replicon are suggested to be the reason for its strict narrow host range in Myxococcus cells.     

Rhizobium etli CFN42 contains at least three plasmids of the repABC family: a structural and evolutionary analysis

In this paper, we report the identification of replication/partition regions of plasmid p42a and p42b of Rhizobium etli CFN42. Sequence analysis reveals that both replication/partition regions belong to the repABC family. Phylogenetic analysis of all the complete repABC replication/partition regions reported to date, shows that repABC plasmids coexisting in the same strain arose most likely by lateral transfer instead of by duplication followed by divergence. A model explaining how new incompatibility groups originate, is proposed.     

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.