Mobilisation of the streptococcal plasmid pMV158: interactions of MobM protein with its cognate oriT DNA region

The streptococcal plasmid pMV158 encodes the relaxase protein, MobM, involved in its mobilisation. Purified MobM protein specifically cleaved supercoiled or single-stranded DNA containing the plasmid origin of transfer, oriT. Gel retardation and DNase I footprinting assays performed with DNA fragments containing the plasmid oriT provided evidence for specific binding of MobM by oriT DNA. Dissection of the MobM-binding sequence revealed that the oriT region protected by MobM spanned 28 nucleotides, and includes an inversely repeated sequence, termed IR2. MobM exhibits a high degree of similarity with the mob gene product of the Streptococcus ferus plasmid pVA380-1. Although the origins of transfer of pMV158 and pVA380-1 show 20% sequence divergence in a 24-bp sequence included in their oriT regions, the pMV158 MobM was able to cleave a supercoiled derivative of pVA380-1 in vitro.     

The origin of greater-than-unit-length plasmids generated during bacterial conjugation

In Gram-negative bacteria, the general mechanism of conjugal plasmid transfer, which is probably similar for many different groups of plasmids, involves the transfer of a single plasmid DNA strand with 5′ to 3′ polarity. Transfer is initiated by nicking of the duplex DNA at a particular site, i.e. the origin of transfer (oriT). We constructed plasmids containing two directly repeated copies of oriT, derived from the broad-host-range plasmid R1162 and flanking the lac operator. The number of lacO copies in the plasmid after transfer could be determined from the colour of transconjugant colonies on medium containing X-Gal. When the oriTs were mutated to prevent initiation and termination of transfer at the same oriTs, almost all of the transconjugant cells contained greater-than-unit-length plasmids with two copies of lacO and three copies of oriT. We show that these molecules were generated by an intramolecular, conjugation dependent mechanism unlikely to depend solely on a pre-existing population of circular or linear multimers in donor cells. We propose that the greater-than-unit-length molecules were instead generated by a rolling-circle mechanism of DNA replication.     

A high security double lock and key mechanism in HUH relaxases controls oriT-processing for plasmid conjugation

Relaxases act as DNA selection sieves in conjugative plasmid transfer. Most plasmid relaxases belong to the HUH endonuclease family. TrwC, the relaxase of plasmid R388, is the prototype of the HUH relaxase family, which also includes TraI of plasmid F. In this article we demonstrate that TrwC processes its target nic-site by means of a highly secure double lock and key mechanism. It is controlled both by TrwC–DNA intermolecular interactions and by intramolecular DNA interactions between several nic nucleotides. The sequence specificity map of the interaction between TrwC and DNA was determined by systematic mutagenesis using degenerate oligonucleotide libraries. The specificity map reveals the minimal nic sequence requirements for R388-based conjugation. Some nic-site sequence variants were still able to form the U-turn shape at the nic-site necessary for TrwC processing, as observed by X-ray crystallography. Moreover, purified TrwC relaxase effectively cleaved ssDNA as well as dsDNA substrates containing these mutant sequences. Since TrwC is able to catalyze DNA integration in a nic-site-containing DNA molecule, characterization of nic-site functionally active sequence variants should improve the search quality of potential target sequences for relaxase-mediated integration in any target genome.     

Characterization of Multiple Regions Involved in Replication and Mobilization of Plasmid pNZ4000 Coding for Exopolysaccharide Production in Lactococcus lactis

We characterized the regions involved in replication and mobilization of the 40-kb plasmid pNZ4000, encoding exopolysaccharide (EPS) production in Lactococcus lactis NIZO B40. The plasmid contains four highly conserved replication regions with homologous rep genes (repB1, repB2, repB3, and repB4) that belong to the lactococcal theta replicon family. Subcloning of each replicon individually showed that all are functional and compatible in L. lactis. Plasmid pNZ4000 and genetically labeled derivatives could be transferred to different L. lactis strains by conjugation, and pNZ4000 was shown to be a mobilization plasmid. Two regions involved in mobilization were identified near two of the replicons; both included an oriT sequence rich in inverted repeats. Conjugative mobilization of the nonmobilizable plasmid pNZ124 was promoted by either one of these oriT sequences, demonstrating their functionality. One oriT sequence was followed by a mobA gene, coding for a trans-acting protein, which increased the frequency of conjugative transfer 100-fold. The predicted MobA protein and the oriT sequences show protein and nucleotide similarity, respectively, with the relaxase and with the inverted repeat and nic site of the oriT from the Escherichia coli plasmid R64. The presence on pNZ4000 of four functional replicons, two oriT sequences, and several insertion sequence-like elements strongly suggests that this EPS plasmid is a naturally occurring cointegrate.     

The R1162 Mob Proteins Can Promote Conjugative Transfer from Cryptic Origins in the Bacterial Chromosome

The mobilization proteins of the broad-host-range plasmid R1162 can initiate conjugative transfer of a plasmid from a 19-bp locus that is partially degenerate in sequence. Such loci are likely to appear by chance in the bacterial chromosome and could act as cryptic sites for transfer of chromosomal DNA when R1162 is present. The R1162-dependent transfer of chromosomal DNA, initiated from one such potential site in Pectobacterium atrosepticum, is shown here. A second active site was identified in Escherichia coli, where it is also shown that large amounts of DNA are transferred. This transfer probably reflects the combined activity of the multiple cryptic origins in the chromosome. Transfer of chromosomal DNA due to the presence of a plasmid in the cytoplasm describes a previously unrecognized potential for the exchange of bacterial DNA.The discovery over 50 years ago of bacterial mating by Lederberg and Cavalli-Sforza (summarized by Cavalli-Sforza [10]) was a major step in the development of modern microbial genetics. It was later realized that chromosomal DNA transfer was due to the integration of a plasmid, the F factor. This plasmid is able to effect its own transfer and, in the integrated state, chromosomal DNA as well. A unique site on the plasmid, the origin of transfer (oriT), is essential for this process. A complex of plasmid- and host-encoded proteins assemble at oriT (15); the F-encoded relaxase then cleaves one of the DNA strands, forming a covalent, protein-DNA intermediate (27) that is delivered to the type IV secretion apparatus, also encoded by F (24). The possibility of low-level transfer initiating from chromosomal sites was raised early in the history of conjugation (12). However, it is now clear that the exacting architecture of the oriT DNA-protein complex, both for the F factor and related oriTs, results in a very high degree of sequence and structural specificity, and no secondary origins in the chromosome have been identified.The broad-host-range plasmid R1162 (RSF1010), like the F factor, is also transferred from cell to cell. Although the mechanism of transfer is similar for the two plasmids, the oriTs are structurally very different. In prior studies we have determined that the R1162 oriT is small, structurally simple, and able to accommodate base changes at different positions without a complete loss of function (5, 21). As a result of this relaxed specificity, the R1162 mobilization (Mob) proteins can activate the related but different oriT of another plasmid, pSC101 (28).The R1162 oriT is shown in Fig. ​Fig.1.1. The R1162 relaxase MobA interacts with the core region, highly conserved in the R1162 Mob family (5), and the adjacent, inner arm of the inverted repeat (23). The protein forms at nic a tyrosyl phosphodiester linkage with the 5′ end of the DNA strand (30), which is then unwound from its complement as the protein-DNA complex is passed into the recipient cell. Circular plasmid DNA is reformed by a reverse of the initial protein-DNA transesterification, with the relaxase now binding to the 3′ end of the transferred DNA. This binding requires the complete inverted repeat, which probably forms a hairpin loop to recreate the double-stranded character of the relaxase binding site on duplex DNA.Open in a separate windowFIG. 1.Base sequence of R1162 oriT on the nicked strand. The relaxase cleaves at nic; subsequent transfer is 5′ to 3′ so that most of oriT is transferred last. Below is the consensus sequence of DNA active for initiation of transfer.An important feature of the steps in DNA processing at the R1162 oriT is that an inverted repeat is not required for the initiation of transfer or passage of DNA into a new cell. As a result of this and the permissiveness of the relaxase to base changes within oriT, different sites in the chromosome that are not part of a plasmid oriT might nevertheless be capable of initiating transfer when cloned into a plasmid. We previously identified one such site in the chromosome of Erwinia carotovora subsp. atroseptica (now Pectobacterium atrosepticum) (21). In addition, by testing libraries of oriTs with one or more mutations for relaxase-induced nicking, we found that a large population of DNAs with different sequences was potentially active (21). The consensus sequence for activity, derived from these studies, is shown in Fig. ​Fig.11.I show here that ectopic sites on the bacterial chromosome, active for the initiation of transfer of plasmid DNA, can also serve for the transfer of chromosomal DNA when the Mob proteins are provided in trans. Thus, the presence of R1162 in the cell can result in a cryptic sexuality in bacteria, resulting in the transfer of chromosomal genes. Although such events are likely to be infrequent, the broad-host-range of R1162 and its close relatives, with their ability to reside stably in the cytoplasms of many different bacteria, could be another source of gene exchange for a variety of different species.     

Relaxase DNA Binding and Cleavage Are Two Distinguishable Steps in Conjugative DNA Processing That Involve Different Sequence Elements of the nic Site

TrwC, the relaxase of plasmid R388, catalyzes a series of concerted DNA cleavage and strand transfer reactions on a specific site (nic) of its origin of transfer (oriT). nic contains the cleavage site and an adjacent inverted repeat (IR₂). Mutation analysis in the nic region indicated that recognition of the IR₂ proximal arm and the nucleotides located between IR₂ and the cleavage site were essential for supercoiled DNA processing, as judged either by in vitro nic cleavage or by mobilization of a plasmid containing oriT. Formation of the IR₂ cruciform and recognition of the distal IR₂ arm and loop were not necessary for these reactions to take place. On the other hand, IR₂ was not involved in TrwC single-stranded DNA processing in vitro. For single-stranded DNA nic cleavage, TrwC recognized a sequence embracing six nucleotides upstream of the cleavage site and two nucleotides downstream. This suggests that TrwC DNA binding and cleavage are two distinguishable steps in conjugative DNA processing and that different sequence elements are recognized by TrwC in each step. IR₂-proximal arm recognition was crucial for the initial supercoiled DNA binding. Subsequent recognition of the adjacent single-stranded DNA binding site was required to position the cleavage site in the active center of the protein so that the nic cleavage reaction could take place.     

Mobilisation of the streptococcal plasmid pMV158: interactions of MobM protein with its cognate oriT DNA region.

The streptococcal plasmid pMV158 encodes the relaxase protein, MobM, involved in its mobilisation. Purified MobM protein specifically cleaved supercoiled or single-stranded DNA containing the plasmid origin of transfer, oriT. Gel retardation and DNase I footprinting assays performed with DNA fragments containing the plasmid oriT provided evidence for specific binding of MobM by oriT DNA. Dissection of the MobM-binding sequence revealed that the oriT region protected by MobM spanned 28 nucleotides, and includes an inversely repeated sequence, termed IR2. MobM exhibits a high degree of similarity with the mob gene product of the Streptococcus ferus plasmid pVA380-1. Although the origins of transfer of pMV158 and pVA380-1 show 20% sequence divergence in a 24-bp sequence included in their oriT regions, the pMV158 MobM was able to cleave a supercoiled derivative of pVA380-1 in vitro. Received: 12 October 1998 / Accepted: 28 February 1999     

Cloning and Identification of Conjugative Transfer Origins in the Rhizobium meliloti Genome

A simple approach was used to identify Rhizobium meliloti DNA regions with the ability to convert a nontransmissible vector into a mobilizable plasmid, i.e., to contain origins of conjugative transfer (oriT, mob). RecA-defective R. meliloti merodiploid populations, where each individual contained a hybrid cosmid from an R. meliloti GR4 gene library, were used as donors en masse in conjugation with another R. meliloti recipient strain, selecting transconjugants for vector-encoded antibiotic resistance. Restriction analysis of cosmids isolated from individual transconjugants resulted in the identification of 11 nonoverlapping DNA regions containing potential oriTs. Individual hybrid cosmids were confirmed to be mobilized from the original recA donors at frequencies ranging from 10⁻² to 10⁻⁵ per recipient cell. DNA hybridization experiments showed that seven mob DNA regions correspond to plasmid replicons: four on symbiotic megaplasmid 1 (pSym1), one on pSym2, and another two on each of the two cryptic plasmids harbored by R. meliloti GR4. Another three mob clones could not be located to any plasmid and were therefore preliminarily assigned to the chromosome. With this strategy, we were able to characterize the oriT of the conjugative plasmid pRmeGR4a, which confirmed the reliability of the approach to select for oriTs. Moreover, transfer of the 11 mob cosmids from R. meliloti into Escherichia coli occurred at frequencies as high as 10⁻¹, demonstrating the R. meliloti gene transfer capacity is not limited to the family Rhizobiaceae. Our results show that the R. meliloti genome contains multiple oriTs that allow efficient DNA mobilization to rhizobia as well as to phylogenetically distant gram-negative bacteria.     

Tn7 insertion mutations affecting the host range of the promiscuous IncP-1 plasmid R18

The genetic basis of plasmid host range has been investigated by Tn7 insertion mutagenesis of the promiscuous plasmid R18 in Pseudomonas aeruginosa. Six mutants have been isolated on the basis of greatly reduced transferability into Escherichia coli C while retaining normal transferability within P. aeruginosa. Their physical mapping shows that two of them map at coordinate 11.72 ± 0.14 kb, in the region of the origin of plasmid replication (oriV) and one at 18.0 ± 0.3 kb, in the trans-acting gene essential for initiation of replication at oriV (trfA). Three map at 48.4 ± 0.5 kb in the region of the origin of plasmid transfer (oriT) and the site at which a single-strand nick is introduced in the plasmid DNA-protein relaxation complex (rlx). Consistent with the postulated defective replication of the oriV and trfA mutants was their inability to transform E. coli C or K12 while being able to transform P. aeruginosa. As expected the oriT/rlx mutants transformed both hosts as effectively as R18. Furthermore the trfA mutant was readily curable by mitomycin C in a DNA polymerase I-proficient P. aeruginosa and spontaneously lost from a polymerase-deficient mutant of P. aeruginosa suggesting a role of this polymerase in the replication of R18. Extensive transfer tests from P. aeruginosa into a range of enteric bacteria, other Pseudomonas species and into other Gram-negative bacteria indicated a complex host range pattern for these mutants. It appears that both plasmid replication and conjugation genes are responsible for host range in addition to the involvement of host gene products.     

Evolving origin-of-transfer sequences on staphylococcal conjugative and mobilizable plasmids—who’s mimicking whom?

In Staphylococcus aureus, most multiresistance plasmids lack conjugation or mobilization genes for horizontal transfer. However, most are mobilizable due to carriage of origin-of-transfer (oriT) sequences mimicking those of conjugative plasmids related to pWBG749. pWBG749-family plasmids have diverged to carry five distinct oriT subtypes and non-conjugative plasmids have been identified that contain mimics of each. The relaxasome accessory factor SmpO, encoded by each conjugative plasmid, determines specificity for its cognate oriT. Here we characterized the binding of SmpO proteins to each oriT. SmpO proteins predominantly formed tetramers in solution and bound 5′-GNNNNC-3′ sites within each oriT. Four of the five SmpO proteins specifically bound their cognate oriT. An F7K substitution in pWBG749 SmpO switched oriT-binding specificity in vitro. In vivo, the F7K substitution reduced but did not abolish self-transfer of pWBG749. Notably, the substitution broadened the oriT subtypes that were mobilized. Thus, this substitution represents a potential evolutionary intermediate with promiscuous DNA-binding specificity that could facilitate a switch between oriT specificities. Phylogenetic analysis suggests pWBG749-family plasmids have switched oriT specificity more than once during evolution. We hypothesize the convergent evolution of oriT specificity in distinct branches of the pWBG749-family phylogeny reflects indirect selection pressure to mobilize plasmids carrying non-cognate oriT-mimics.     

Characterisation of an in vivo system for nicking at the origin of conjugal DNA transfer of the sex factor F

Transfer of the F plasmid between conjugating Escherichia coli cells has been assumed to require endonucleolytic cleavage at a specific site (oriT) on a specific strand of the F molecule. Using a lambda transducing phage which contains oriT we have detected this nicking process in vivo. Nicking of DNA occurred in the strand that included the “transferred” F strand and at a location within the transducing segment consistent with all previous genetic and restriction enzyme cleavage data on the position of oriT in F. Genetic study of the nicking process using Flac tra^? point and deletion mutants, and also λtra phages which carried various parts of the transfer region, indicated that the products of two transfer operon genes, traY and the previously unidentified gene traZ, were directly involved in nicking at oriT. The product of traJ was also required for nicking, but the possibility that this was solely due to the regulatory function of the traJ product could not be excluded. The plasmid specificities of oriT, traY and traZ between F and the related F-like plasmids R1-19 and R100-1 were investigated using the λoriT nicking system, and shown to be consistent with those determined in genetic complementation tests. The differences in specificity observed imply that the oriT sequence of F differs from those of R1-19 and R100-1.The products of the traM and traI genes are known to be required for the initiation of DNA transfer; their possible roles in modulating the activity of the traY Z endonuclease are discussed.     

TraG from RP4 and TraG and VirD4 from Ti plasmids confer relaxosome specificity to the conjugal transfer system of pTiC58

Plasmid conjugation systems are composed of two components, the DNA transfer and replication system, or Dtr, and the mating pair formation system, or Mpf. During conjugal transfer an essential factor, called the coupling protein, is thought to interface the Dtr, in the form of the relaxosome, with the Mpf, in the form of the mating bridge. These proteins, such as TraG from the IncP1 plasmid RP4 (TraG(RP4)) and TraG and VirD4 from the conjugal transfer and T-DNA transfer systems of Ti plasmids, are believed to dictate specificity of the interactions that can occur between different Dtr and Mpf components. The Ti plasmids of Agrobacterium tumefaciens do not mobilize vectors containing the oriT of RP4, but these IncP1 plasmid derivatives lack the trans-acting Dtr functions and TraG(RP4). A. tumefaciens donors transferred a chimeric plasmid that contains the oriT and Dtr genes of RP4 and the Mpf genes of pTiC58, indicating that the Ti plasmid mating bridge can interact with the RP4 relaxosome. However, the Ti plasmid did not mobilize transfer from an IncQ relaxosome. The Ti plasmid did mobilize such plasmids if TraG(RP4) was expressed in the donors. Mutations in traG(RP4) with defined effects on the RP4 transfer system exhibited similar phenotypes for Ti plasmid-mediated mobilization of the IncQ vector. When provided with VirD4, the tra system of pTiC58 mobilized plasmids from the IncQ relaxosome. However, neither TraG(RP4) nor VirD4 restored transfer to a traG mutant of the Ti plasmid. VirD4 also failed to complement a traG(RP4) mutant for transfer from the RP4 relaxosome or for RP4-mediated mobilization from the IncQ relaxosome. TraG(RP4)-mediated mobilization of the IncQ plasmid by pTiC58 did not inhibit Ti plasmid transfer, suggesting that the relaxosomes of the two plasmids do not compete for the same mating bridge. We conclude that TraG(RP4) and VirD4 couples the IncQ but not the Ti plasmid relaxosome to the Ti plasmid mating bridge. However, VirD4 cannot couple the IncP1 or the IncQ relaxosome to the RP4 mating bridge. These results support a model in which the coupling proteins specify the interactions between Dtr and Mpf components of mating systems.     

Examination of an inverted repeat within the F factor origin of transfer: context dependence of F TraI relaxase DNA specificity

Prior to conjugative transfer of plasmids, one plasmid strand is cleaved in a site- and strand-specific manner by an enzyme called a relaxase or nickase. In F and related plasmids, an inverted repeat is located near the plasmid strand cleavage site, and others have proposed that the ability of this sequence to form a hairpin when in single-stranded form is important for transfer. Substitutions were introduced into a cloned F oriT region and their effects on plasmid transfer were assessed. For those substitutions that substantially reduced transfer, the results generally correlated with effects on in vitro binding of oligonucleotides to the F TraI relaxase domain rather than with predicted effects on hairpin formation. One substitution shown previously to dramatically reduce both plasmid transfer and in vitro binding to a 17-base oligonucleotide had little apparent effect on binding to a 30-base oligonucleotide that contained the hairpin region. Results from subsequent experiments strongly suggest that the relaxase domain can bind to hairpin oligonucleotides in two distinct manners with different sequence specificities, and that the protein binds the oligonucleotides at the same or overlapping sites.     

Site-specific integration of foreign DNA into minimal bacterial and human target sequences mediated by a conjugative relaxase

Background

Bacterial conjugation is a mechanism for horizontal DNA transfer between bacteria which requires cell to cell contact, usually mediated by self-transmissible plasmids. A protein known as relaxase is responsible for the processing of DNA during bacterial conjugation. TrwC, the relaxase of conjugative plasmid R388, is also able to catalyze site-specific integration of the transferred DNA into a copy of its target, the origin of transfer (oriT), present in a recipient plasmid. This reaction confers TrwC a high biotechnological potential as a tool for genomic engineering.

Methodology/Principal Findings

We have characterized this reaction by conjugal mobilization of a suicide plasmid to a recipient cell with an oriT-containing plasmid, selecting for the cointegrates. Proteins TrwA and IHF enhanced integration frequency. TrwC could also catalyze integration when it is expressed from the recipient cell. Both Y18 and Y26 catalytic tyrosil residues were essential to perform the reaction, while TrwC DNA helicase activity was dispensable. The target DNA could be reduced to 17 bp encompassing TrwC nicking and binding sites. Two human genomic sequences resembling the 17 bp segment were accepted as targets for TrwC-mediated site-specific integration. TrwC could also integrate the incoming DNA molecule into an oriT copy present in the recipient chromosome.

Conclusions/Significance

The results support a model for TrwC-mediated site-specific integration. This reaction may allow R388 to integrate into the genome of non-permissive hosts upon conjugative transfer. Also, the ability to act on target sequences present in the human genome underscores the biotechnological potential of conjugative relaxase TrwC as a site-specific integrase for genomic modification of human cells.     

Intracellular location of NRl-plasmid DNA inEscherichia coli minicells

Intracellular location of plasmid NR1 (M = 58 Mg/mol, stringent control of replication, 1–2 copies perEscherichia coli chromosomal equivalent) was studied and compared with that of plasmid R6KΔ1 (M = 21 Mg/mol, relaxed control of replication, 10–15 copies perE. coli chromosomal equivalent), both inE. coli minicells. Considerable difference in relative distribution of molecules of these two plasmid DNA’s between the cytoplasm and the membrane fraction was found when components of the corresponding minicell lyzates were fractionated by sedimentation in a double-linear gradient of caesium chlorid and sucrose. Also the difference in relative numbers of NR1 DNA and R6KΔ1 DNA molecules stably associated with the membrane of minicells, determined by electron-microscopic examination of the fractions containing plasmid DNA-membrane complexes, was evaluated as statistically significant. The association of NR1 DNA molecules withE. coli minicell membrane was found to be a much more frequent event than such association of R6KΔ1 molecules. The absolute amount of plasmid DNA associated with membrane in a single minicell corresponds to one molecule for both NR1 and R6KAΔ1.     

<Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>-mediated transformation of plants by the pTF-FC2 plasmid is efficient and strictly dependent on the MobA protein

In the transformation of plants by Agrobacterium tumefaciens the VirD2 protein has been shown to pilot T-DNA during its transfer to the plant cell nucleus. Other studies have shown that the MobA protein of plasmid RSF1010 is capable of mediating its transfer from Agrobacterium cells to plant cells by a similar process. We have demonstrated previously that plasmid pTF-FC2, which has some similarity to RSF1010, is also able to transfer DNA efficiently. In this study, we performed a mutational analysis of the roles played by A. tumefaciens VirD2 and pTF-FC2 MobA in DNA transfer-mediated by A. tumefaciens carrying pTF-FC2. We show that MobA+/VirD2+ and MobA+/VirD2– strains were equally proficient in their ability to transfer a pTF-FC2-derived plasmid DNA to plants and to transform them. However, the MobA–/VirD2+ strain showed a DNA transfer efficiency of 0.03% compared with that of the other two strains. This sharply contrasts with our results that VirD2 can rather efficiently cleave the oriT sequence of pFT-FC2 in vitro. We therefore conclude that MobA plays a major VirD2-independent role in plant transformation by pTF-FC2.     

Location of two relaxation nick sites in R6K and single sites in pSC101 and RSF1010 close to origins of vegetative replication: implication for conjugal transfer of plasmid deoxyribonucleic acid.

A nick-labeling method has been used to localize the relaxation complex nick sites in three plasmids (pSC101, RSF1010, and R6K) that differ markedly in their host range, deoxyribonucleic acid replication, and conjugal transfer properties. Single specific relaxation sites were located in pSC101 and RSF1010, but surprisingly two distinct sites could be identified in the bi-origin plasmid R6K. In all cases, relaxation nick sites, which are thought to be origins of plasmid conjugal transfer, were shown to be located near origins of vegetative replication. This result suggests a functional interaction between these two types of deoxyribonucleic acid loci, and we speculate here that application events initiated at origins of replication may constitute an integral part of the process of conjugal transfer of small plasmids among bacteria. Consistent with this proposal is the finding that inhibition of vegetative replication of the pSC101 and ColE1 plasmids results in a severe inhibition of their conjugal transfer ability.     

The origin of transfer (oriT) of the conjugative plasmid R46: characterization by deletion analysis and DNA sequencing

Summary The origin of transfer (oriT) is the sequence within which conjugal transfer of plasmid DNA is initiated, and is absolutely required in cis for plasmid mobilization. We have cloned oriT from the 52 kb IncN plasmid R46 on a 600 bp fragment, and mapped the limits of the relevant sequence by deletion analysis and transposon mutagenesis. The nucleotide sequence of the oriT region contains 13 direct repeats of an 11 bp consensus sequence, 3 different pairs of 10 bp inverted repeats, and a segment that is extremely A-T rich. The direct repeats are within a region required for high frequency transfer and their sequence is such that their periodic alignment along the helix may induce curvature of the DNA. Analysis of Tn1725 insertions within the sequenced fragment of R46 revealed that, unlike most other transposons, transposition of Tn1725 can cause target sequence duplications of three different sizes.