The primase of broad-host-range plasmid R1162 is active in conjugal transfer.

The broad-host-range plasmid R1162 is conjugally mobilized at high frequency by the IncP-1 plasmid R751 but is poorly mobilized by pOX38, a derivative of the F factor. In both cases, the origin of transfer (oriT) and the Mob proteins of R1162 are required, indicating that these plasmids are mobilized by similar mechanisms. R1162 encodes a primase, essential for vegetative replication of the plasmid, that is made both as a separate protein and as the carboxy-terminal domain of MobA, one of the R1162 mobilization proteins (P. Scholz, V. Haring, B. Wittman-Liebold, K. Ashman, M. Bagdasarian, and E. Scherzinger, Gene 75:271-288, 1989). When R751 is the mobilizing vector, the primase is not required for mobilization of plasmids containing cloned mob-oriT R1162 DNA. However, detectable mobilization of such plasmids by pOX38 requires both the primase and its cognate initiation site, oriented for synthesis of the complement to the transferred strand. The long form of the primase is required for optimal transfer: R1162 replicons lacking this form also are not transferred detectably by pOX38 and are less well mobilized by R751. The distance between oriT and the primase initiation site affects the frequency of mobilization, and this effect is polar in the direction of transfer. Our results indicate that the R1162 primase is active in mobilization of R1162 and suggest that the MobA-linked form is an adaptation increasing its effectiveness during transfer.     

Site-specific recombination at oriT of plasmid R1162 in the absence of conjugative transfer.

R1162 is efficiently comobilized during conjugative transfer of the self-transmissible plasmid R751. Bacteriophage M13 derivatives that contain two directly repeated copies of oriT, the site on R1162 DNA required in cis for mobilization, were constructed. Phage DNA molecules underwent recombination during infection of Escherichia coli, with the product retaining a single functional copy of oriT. Recombination was strand specific and depended on R1162 gene products involved in mobilization, but did not require the self-transmissible plasmid vector. Two genes were identified, one essential for recombination and the other affecting the frequency of recombination. Recombination of bacteriophage DNA could form the basis of a simple model for some of the events occurring during conjugation without the complexity of a true mating system.     

Stringent and relaxed recognition of oriT by related systems for plasmid mobilization: implications for horizontal gene transfer

The plasmids R1162 and pSC101 have origins of conjugative transfer (oriTs) and corresponding relaxases that are closely related. The oriTs are made up of a highly conserved core, where DNA is cleaved by the relaxase prior to transfer, and an inverted repeat that differs in size and sequence. We show that in each case the seven base pairs adjacent to the core and within one arm of the inverted repeat are sufficient to determine specificity. Within this DNA there are three AT base pairs located 4 bp from the core. Mutations in the AT base pairs suggest that the relaxase makes essential contacts at these locations to the minor groove of the DNA. The remaining four bases are different for each oriT and are both necessary and sufficient for stringent recognition of oriT by the pSC101 mobilization proteins. In contrast, the R1162 mobilization proteins have a much more relaxed requirement for the base sequence of this specificity region. As a result, the R1162 mobilization proteins can initiate transfer from a variety of sites, including those derived from the chromosome. The R1162 mobilization proteins could therefore contribute to the horizontal gene transfer of DNA from diverse sources.     

Localized denaturation of oriT DNA within relaxosomes of the broad-host-range plasmid R1162

The broad-host-range, multicopy plasmid R1162 is efficiently mobilized during conjugation by the self-transmissible plasmid R751. The relaxosome, a complex of plasmid DNA and R1162-encoded proteins, forms at the origin of transfer ( oriT ) and is required for mobilization. Transfer is initiated by strand- and site-specific nicking of the DNA within this structure. We show by probing with potassium permanganate that oriT DNA is locally melted within the relaxosome, in the region from the inverted repeat to the site that is nicked. Mutations in this region of oriT , and in genes encoding the protein components of the relaxosome, affect both nicking and melting of the DNA. The nicking protein in the relaxosome is MobA, which also ligates the transferred linear, single strand at the termination of a round of transfer. We propose that there is an underlying similarity in the substrates for these two MobA-dependent, DNA-processing reactions. We also show that MobA has an additional role in transfer, beyond the nicking and resealing of oriT DNA.     

Relaxed specificity of the R1162 nickase: a model for evolution of a system for conjugative mobilization of plasmids

The primary DNA processing protein for conjugative mobilization of the plasmid R1162 is the transesterase MobA, which acts at a unique site on the plasmid, the origin of transfer (oriT). Both MobA and oriT are members of a large family of related elements that are widely distributed among bacteria. Each oriT consists of a highly conserved core and an adjacent region that is required for binding by its cognate MobA. The sequence of the adjacent region is important in determining the specificity of the interaction between the Mob protein and the oriT DNA. However, the R1162 MobA is active on the oriT of pSC101, another naturally occurring plasmid. We show here that MobA can recognize oriTs having different sequences in the adjacent region and, with varying frequencies, can cleave these oriTs at the correct position within the core. Along with the structure of the oriTs themselves, these characteristics suggest a model for the evolution of this group of transfer systems.     

Elements in the co-evolution of relaxases and their origins of transfer

The central elements in the conjugative mobilization of most plasmids are the relaxase and its cognate origin of transfer (oriT). The relaxase of the plasmid R1162, together with its oriT, belong to a large and widely distributed family of related relaxase/oriT pairs. Several of the properties of these elements are considered for R1162 and for other members of this family with a view to understanding how systems for mobilization might have evolved.     

A 38 base-pair segment of DNA is required in cis for conjugative mobilization of broad host-range plasmid R1162

oriT, the region required in cis for conjugative mobilization of broad host-range plasmid R1162, has been localized to a 38 base-pair segment of DNA. The oriT DNA is also required for conjugation-dependent recombination. Point mutations at the HinPI cleavage site within oriT affect both mobilization and recombination, and the crossover location has been mapped to this site. An inverted repeat ten base-pairs from the recombination site is also involved in mobilization and recombination, and may be a recognition site for proteins involved in cleavage of the oriT DNA. The properties of conjugation-dependent recombination suggest that mobilization entails the formation of a linear intermediate that is transferred with both a unique origin and polarity.     

Unidirectional transfer of broad host-range plasmid R1162 during conjugative mobilization. Evidence for genetically distinct events at oriT

A segment of R1162 DNA containing genes for conjugative mobilization (Mob) and the origin of transfer (oriT) was integrated into the Escherichia coli chromosome. Bacterial genes were transferred in a polar fashion during conjugative mobilization of the integrated segment by a self-transmissible plasmid vector. The direction of transfer, together with the properties of mutated derivatives of oriT, indicate that initial cleavage of oriT, and subsequent religation after transfer, entail different mechanisms that can be distinguished genetically.     

A segment of a plasmid gene required for conjugal transfer encodes a site-specific, single-strand DNA endonuclease and ligase.

The polypeptide encoded by a segment of a gene required for the conjugal mobilization of the broad host-range plasmid R1162 has been purified as a beta-galactosidase fusion protein. The hybrid protein binds specifically to a small, double-stranded DNA fragment containing the origin of transfer (oriT), and specifically cleaves oriT single-stranded DNA at the position cleaved during transfer. Only one of the two DNA strands is a substrate. A fraction of the digested DNA is resistant to lambda exonuclease digestion, indicating that some molecules have protein covalently attached at the 5' end. After prolonged incubation with fusion protein, some of the cleaved molecules are religated. In vivo, M13 phage DNA containing two, directly-repeated copies of oriT recombine in cells containing the fusion protein. The single-stranded viral DNA forms are the probable substrates for the protein, the cleaved DNA being subsequently religated to form recombinant molecules. Cleavage of the DNA might be the reverse reaction of the ligation that normally takes place after conjugative transfer of a single, linear plasmid DNA strand.     

Identification and characterization of the origin of conjugative transfer (oriT) and a gene (nes) encoding a single-stranded endonuclease on the staphylococcal plasmid pGO1.

The genes mediating the conjugative transfer of the 52-kb staphylococcal plasmid pGO1 are within a 14.4-kb gene cluster designated trs. However, a clone containing trs alone cannot transfer independently and no candidate oriT has been found within or contiguous to trs. In this study, we identified a 1,987-bp open reading frame (ORF) 24 kb 3' and 13 kb 5' to trs that was essential for conjugative transfer: transposon insertions into the ORF abolished transfer and a plasmid containing the ORF could complement these transposon-inactivated pGO1 mutants for transfer. Analysis of the nucleotide sequence of this ORF revealed significant homology between the amino terminus of its predicted protein and those of several single-stranded endonucleases. In addition, a 12-bp DNA sequence located 100 bp 5' to the ORF's translational start site was identical to the oriT sequences of the conjugative or mobilizable plasmids RSF1010, pTF1, R1162, pSC101, and pIP501. The ability of the ORF, designated nes (for nicking enzyme of staphylococci), to generate a single-stranded nick at the oriT was demonstrated in Escherichia coli by alkaline gel and DNA sequence analysis of open circular plasmid DNA. Plasmids that could be converted to the open circular form by the presence of oriT and nes could also be mobilized at high frequency into Staphylococcus aureus recipients with a second plasmid containing only trs. We propose that the 14.4 kb of trs and the approximately 2.2 kb of the oriT-nes region, coupled with an origin of replication, make up the minimal staphylococcal conjugative replicon.     

The R1162 relaxase/primase contains two, type IV transport signals that require the small plasmid protein MobB

The relaxase of the plasmid R1162 is a large protein essential for conjugative transfer and containing two different and physically separate catalytic activities. The N-terminal half cleaves one of the DNA strands at the origin of transfer (oriT) and becomes covalently linked to the 5' terminal phosphate; the C-terminal half is a primase essential for initiation of plasmid vegetative replication. We show here that the two parts of the protein are independently transported by the type IV pathway. Part of the domain containing the catalytic activity, as well as an adjacent region, is required in each case, but the required regions do not physically overlap. Both transport systems contribute to the overall frequency of conjugative transfer. MobB is a small protein, encoded within mobA but in a different reading frame, that stabilizes the relaxase at oriT. MobB is required for efficient type IV transport of both the complete relaxase and its two, separate functional halves. MobB inserts into the membrane and could thus stabilize the association between the relaxase and the type IV transfer apparatus.     

Analysis of the mobilization region of the broad-host-range IncQ-like plasmid pTC-F14 and its ability to interact with a related plasmid, pTF-FC2

Plasmid pTC-F14 is a 14.2-kb plasmid isolated from Acidithiobacillus caldus that has a replicon that is closely related to the promiscuous, broad-host-range IncQ family of plasmids. The region containing the mobilization genes was sequenced and encoded five Mob proteins that were related to those of the DNA processing (Dtr or Tra1) region of IncP plasmids rather than to the three-Mob-protein system of the IncQ group 1 plasmids (e.g., plasmid RSF1010 or R1162). Plasmid pTC-F14 is the second example of an IncQ family plasmid that has five mob genes, the other being pTF-FC2. The minimal region that was essential for mobilization included the mobA, mobB, and mobC genes, as well as the oriT gene. The mobD and mobE genes were nonessential, but together, they enhanced the mobilization frequency by approximately 300-fold. Mobilization of pTC-F14 between Escherichia coli strains by a chromosomally integrated RP4 plasmid was more than 3,500-fold less efficient than the mobilization of pTF-FC2. When both plasmids were coresident in the same E. coli host, pTC-F14 was mobilized at almost the same frequency as pTF-FC2. This enhanced pTC-F14 mobilization frequency was due to the presence of a combination of the pTF-FC2 mobD and mobE gene products, the functions of which are still unknown. Mob protein interaction at the oriT regions was unidirectionally plasmid specific in that a plasmid with the oriT region of pTC-F14 could be mobilized by pTF-FC2 but not vice versa. No evidence for any negative effect on the transfer of one plasmid by the related, potentially competitive plasmid was obtained.     

Probing the activation of the replicative origin of broad host-range plasmid R1162 with Tus, the E.coli anti-helicase protein.

The E.coli Tus protein is an anti-helicase involved in the termination of chromosome replication. The binding site for this protein, ter, was cloned into derivatives of the broad host-range plasmid R1162. The ter site caused the orientation-specific termination of plasmid replication fork movement in cell extracts containing Tus. Plasmids were constructed so that two sites for initiation of R1162 replication flanked the iteron-containing domain of the origin. In these plasmids, the site next to the AT-rich region within the iteron-containing domain was more active. In addition, when ter was placed between the more active site and the iterons, initiation of replication from this site was specifically inhibited. The data support a model for entry of the essential, plasmid-encoded helicase at one side of the direct repeats, and for its movement primarily in one direction away from these repeats to activate the initiation sites for DNA replication.     

Recombination between directly repeated origins of conjugative transfer cloned in M13 bacteriophage DNA models ligation of the transferred plasmid strand.

When two, directly-repeated copies of the origin of transfer (oriT) of the conjugatively mobilizable, broad host-range plasmid R1162 are cloned into bacteriophage M13mp9 DNA, they undergo recombination in the presence of one of the R1162-encoded proteins required for mobilization [Meyer, R. (1989) J. Bacteriol., 171, 799-806]. Mutations in the outer arm of the inverted repeat within oriT inhibit this recombination. These mutations also affect a late step in transfer. We propose that recombination on the phage DNA models the processing of single-stranded DNA after entry into a recipient cell. The two, directly-repeated oriTs are not equivalent during the recombination reaction, because they are differently affected by the outer-arm mutations. A mutation was also isolated that reduces the specificity of the cleavage site in one of the two oriTs. Together, the results with the mutations suggest that phage recombinants can form only when the first cleavage occurs at one of the two oriTs. This is followed by the resulting free 3' end joining to the 5' end at the cleavage site of the other oriT.     

Mutagenesis of the Tra1 core region of RK2 by using Tn5: identification of plasmid-specific transfer genes.

The conjugation system of the IncP alpha plasmid RK2/RP4 is encoded by transfer regions designated Tra1, Tra2, and Tra3. The Tra1 core region, cloned on plasmid pDG4 delta 22, consists of the origin of transfer (oriT) and 2.6 kilobases of flanking DNA providing IncP alpha plasmid-specific functions that allow pDG4 delta 22 to be mobilized by the heterologous IncP beta plasmid R751. Tn5 insertions in pDG4 delta 22 define a minimal 2.2-kilobase region required for plasmid-specific transfer of oriT. The Tra1 core contains the traJ and traK genes as well as an 18-kilodalton open reading frame downstream of traJ. The traJ and traK genes were shown to be required for transfer by complementation of inserts within these genes. Genetic evidence for the role of the 18-kilodalton open reading frame in transfer was obtained, although this protein has not been detected in cell lysates. These studies indicate that at least three transfer proteins are involved in plasmid-specific interactions at oriT.     

Nucleotide sequence and functions of the oriT operon in IncI1 plasmid R64.

Two transfer genes of IncI1 plasmid R64, tentatively designated nikA and nikB, were cloned and sequenced. They are located adjacent to the origin of transfer (oriT) and appear to be organized into an operon, which we call the oriT operon. On the basis of the DNA sequence, nikA and nikB were concluded to encode proteins with 110 and 899 amino acid residues, respectively. Complementation analysis indicated that these two genes are indispensable for the transfer of R64 but are not required for the mobilization of ColE1. By the maxicell procedure, the product of nikA was found to be a 15-kDa protein. On treating a cleared lysate prepared from cells harboring a plasmid containing oriT, nikA, and nikB with sodium dodecyl sulfate or proteinase K, superhelical plasmid DNA in the cleared lysate was converted to an open circular form (relaxation). Relaxation of plasmid DNA was found to require the oriT sequence in cis and the nikA and nikB sequences in trans. It would thus follow that the products of nikA and nikB genes form a relaxation complex with plasmid DNA at the oriT site.     

Cloning the origin of transfer region of the resistance plasmid R1

The insertion of a 7.7-kb EcoRI fragment of the resistance plasmid R1 into pBR325 yielded a plasmid which is mobilizable by pDB12, a multicopy derivative of R1drd-19 lacking most of the resistance determinants. The vector alone was not mobilizable in this system. From this observation we conclude that we have cloned the origin of transfer (oriT) of R1. After inserting a 5.3-kb PvuII-EcoRI fragment of the 7.7-kb region into pUC9 the DNA was cleaved randomly with DNaseI and BamHI linkers were attached to the ends. A subsequent BamHI digestion and electrophoretic separation of the resulting DNA molecules by their size allowed us to generate an ordered series of stepwise shortened plasmids. Plasmids with a deletion of approximately 3400 bp could no longer be mobilized. Since the next larger plasmid with 284 additional base pairs could be mobilized, we are able to confine the oriT location within this extra nucleotide stretch. The DNA sequence of this region was determined. Dominant features within the DNA region are a high AT content and five inverted repeats, which might function as recognition or substrate sites for proteins of the conjugational transfer system.     

Single-stranded circular DNA generated from broad host range plasmid R1162 and its derivatives

Extraction of R1162 plasmid DNA with the alkaline lysis method yields considerable amounts of single-stranded circular plasmid DNA. Destabilization of plasmid DNA is stimulated by the R1162 mob region in cis. The formation of single-stranded circular DNA is initiated at a specific site on the plasmid, presumably the origin of transfer (oriT).