Mutational analysis of the R64 oriT region: requirement for precise location of the NikA-binding sequence.

Conjugative DNA transfer of IncI1 plasmid R64 is initiated by the introduction of a site- and strand-specific nick into the origin of transfer (oriT). In R64 oriT, 17-bp (repeat A and B) and 8-bp inverted-repeat sequences with mismatches are located 8 bp away from the nick site. The nicking is mediated by R64 NikA and NikB proteins. To analyze the functional organization of the R64 oriT region, various deletion, insertion, and substitution mutations were introduced into a 92-bp minimal R64 oriT sequence and their effects on oriT function were investigated. This detailed analysis confirms our previous prediction that the R64 oriT region consists of an oriT core sequence and additional sequences necessary for full oriT activity. The oriT core sequence consists of the repeat A sequence, which is recognized by R64 NikA protein, and the nick region sequence, which is conserved among various origins of transfer and is most probably recognized by NikB protein. The oriT core sequence is sufficient for NikAB-mediated oriT-specific nicking. Furthermore, it was shown that the repeat A sequence is essential for localization to a precise position relative to the nick site for oriT function. This seems to be required for the formation of a functional ternary complex consisting of NikA and NikB proteins and oriT DNA. The repeat B sequence and 8-bp inverted repeat sequences are suggested to be required for the termination of DNA transfer.     

The oriT region of the Agrobacterium tumefaciens Ti plasmid pTiC58 shares DNA sequence identity with the transfer origins of RSF1010 and RK2/RP4 and with T-region borders.

Ti plasmids of Agrobacterium tumefaciens are conjugal elements whose transfer is induced by certain opines secreted from crown galls. On transmissible plasmids, DNA transfer initiates within a cis-acting site, the origin of conjugal transfer, or oriT. We have localized an oriT on the A. tumefaciens plasmid pTiC58 to a region containing the conjugal transfer loci traI and traII and acc, which is the locus encoding catabolism of the two conjugal opines, agrocinopines A and B. The smallest functional oriT clone, a 65-bp BamHI-ApaI fragment in the recombinant plasmid pDCBA60-11, mapped within the traII locus. The nucleotide sequence for a 665-bp KpnI-EcoRI fragment with oriT activity was determined. DNA sequence alignments showed identities between the pTiC58 oriT and the transfer origins of RSF1010, pTF1, and RK2/RP4 and with the pTiC58 T-region borders. The RSF1010-like sequence on pTiC58 is located in the smallest active oriT clone of pTiC58, while the sequence showing identities with the oriT regions of RK2/RP4 and with T-region borders maps outside this region. Despite their sequence similarities, pTiC58 oriT clones were not mobilized by RP4; nor could vectors containing the RK2/RP4 oriT region or the oriT-mob region from RSF1010 be mobilized by pTiC58. In contrast, other Ti plasmids and a conjugally active Agrobacterium opine catabolic plasmid, pAtK84b, efficiently mobilized pTiC58 oriT clones. In addition, the RSF1010 derivative, pDSK519, was mobilized at moderate frequencies by an Agrobacterium strain harboring only the cryptic plasmid pAtC58 and at very low frequencies by an Agrobacterium host that does not contain any detectable plasmids.     

The relaxosome protein MobC promotes conjugal plasmid mobilization by extending DNA strand separation to the nick site at the origin of transfer

The frequency of conjugal mobilization of plasmid R1162 is decreased approximately 50-fold if donor cells lack MobC, one of the plasmid-encoded proteins making up the relaxosome at the origin of transfer ( oriT  ). The absence of MobC has several different effects on oriT DNA. Site- and strand-specific nicking by MobA protein is severely reduced, accounting for the lower frequency of mobilization. The localized DNA strand separation required for this nicking is less affected, but becomes more sensitive to the level of active DNA gyrase in the cell. In addition, strand separation is not efficiently extended through the region containing the nick site. These effects suggest a model in which MobC acts as a molecular wedge for the relaxosome-induced melting of oriT DNA. The effect of MobC on strand separation may be partially complemented by the helical distortion induced by supercoiling. However, MobC extends the melted region through the nick site, thus providing the single-stranded substrate required for cleavage by MobA.     

Initiation and termination of DNA transfer during conjugation of IncI1 plasmid R64: roles of two sets of inverted repeat sequences within oriT in termination of R64 transfer

Intercellular transfer of plasmid DNA during bacterial conjugation initiates and terminates at a specific origin of transfer, oriT. We have investigated the oriT structure of conjugative plasmid R64 with regard to the initiation and termination of DNA transfer. Using recombinant plasmids containing two tandemly repeated R64 oriT sequences with or without mutations, the subregions required for initiation and termination were determined by examining conjugation-mediated deletion between the repeated oriTs. The oriT subregion required for initiation was found to be identical to the 44-bp oriT core sequence consisting of two units, the conserved nick region sequence and the 17-bp repeat A sequence, that are recognized by R64 relaxosome proteins NikB and NikA, respectively. In contrast, the nick region sequence and two sets of inverted repeat sequences within the 92-bp minimal oriT sequence were required for efficient termination. Mutant repeat A sequences lacking NikA-binding ability were found to be sufficient for termination, suggesting that the inverted repeat structures are involved in the termination process. A duplication of the DNA segment between the repeated oriTs was also found after mobilization of the plasmid carrying initiation-deficient but termination-proficient oriT and initiation-proficient but termination-deficient oriT, suggesting that the 3' terminus of the transferred strand is elongated by rolling-circle-DNA synthesis.     

Evidence that DNA helicase I and oriT site-specific nicking are both functions of the F TraI protein

Site-specific and strand-specific nicking at the origin of transfer (oriT) of the F sex factor is the initial step in conjugal DNA metabolism. Then, DNA helicase I, the product of the traI gene, processively unwinds the plasmid from the nick site to generate the single strand of DNA that is transferred to the recipient. The nick at oriT is produced by the combined action of two Tra proteins, TraY and TraZ. The traZ gene was never precisely mapped, as no available point mutation uniquely affected TraZ-dependent oriT nicking. With several new mutations, we have demonstrated that TraZ activity is dependent upon traI DNA sequences. The simplest interpretation of this finding is that the F TraI protein is bifunctional, with DNA unwinding and site-specific DNA nicking activities.     

Location of the nick at oriT of the F plasmid

The oriT locus of the Escherichia coli K12 F plasmid contains a site at which one of the DNA strands is cleaved as a prelude to conjugal transmission to recipient bacteria. We have remapped this site biochemically by using oriT-containing plasmids that were purified from bacteria expressing the F transfer (tra) functions. The strand interruption was found on the transferred strand 137 base-pairs clockwise of the center of the BglII site at 66.7 on the F map. This location is consistent with the locations anticipated from studies of delta traF' plasmids, but it differs from previous results by other investigators. The strand interruption produced a 3'-OH, but the nature of the 5' terminus of the strand on the other side of the nick was not determined. Some DNA sequence motifs in the vicinity of the oriT nick site of F resemble the chromosomal site involved in formation of delta traF'purE plasmids.     

In vitro cleavage of double- and single-stranded DNA by plasmid RSF1010-encoded mobilization proteins.

We have used purified RSF1010 mobilization proteins to reproduce in vitro a strand-specific nicking at the plasmid origin of transfer, oriT. In the presence of Mg2+, the proteins MobA (78-kDa form of RSF1010 DNA primase), MobB, and MobC and supercoiled or linear duplex oriT DNA form large amounts of a cleavage complex, which is characterized by its sensitivity to protein-denaturant treatment. Upon addition of SDS to such a complex, a single strand break is generated in the DNA, and MobA is found linked to the 5' nick terminus, presumably covalently. The double-strand nicking activity of MobA requires, in addition to Mg2+, the presence of MobC and is stimulated by the presence of MobB. The nick site has been shown by DNA sequencing to lie at the position cleaved in vivo during transfer, between nucleotides 3138/3139 in the r strand of RSF1010. We have found that MobA will also cleave DNA at sites other than oriT if the DNA is present in single-stranded form. Breakage in this case occurs in the absence of denaturing conditions, and after prolonged incubation, reclosure can be demonstrated.     

The mobilization and origin of transfer regions of a Thiobacillus ferrooxidans plasmid: relatedness to plasmids RSF1010 and pSC101

The components for the mobilization function of a plasmid DNA during conjugation include a cis-acting sequence (the origin of transfer, oriT) and a transacting sequence coding for mobilization (Mob) proteins. By genetic and deletion analysis, we have located the mobilization region of pTF1, a cryptic plasmid previously isolated from a Thiobacillus ferrooxidans strain. Within a 2797 bse-pair sequenced region, several open reading frames (ORFs) were predicted; two of the ORFs are divergently transcribed and they encode proteins of calculated molecular masses, 42.6kD (ORF2) and 11.4kD (ORF6). Surprisingly, these protein sequences are substantially similar to two of the previously characterized mobilization proteins of the Escherichia coli IncQ plasmid, RSF1010. Moreover, the pTF1 ORF2 (now designated MobL) sequence is also found to be similar to a presumed mobilization protein of plasmid pSC101. Regions of sequence identity of plasmids pTF1, RSF1010 and pSC101 include their oriT sites. By alkaline agarose gel electrophoresis and DNA sequencing, we have established the location of the relaxation complex nick site within the oriT of pTF1. An identical nick site, which is adjacent to a characteristic 10 base-pair inverted repeat sequence, is also found for plasmid RSF1010. A recombinant plasmid containing a 42 base-pair synthetic piece of DNA encompassing the pTF1 inverted repeat and nick sequence was shown to be oriT-active.     

Genetic analysis of the mobilization and leading regions of the IncN plasmids pKM101 and pCU1

The conjugative IncN plasmids pKM101 and pCU1 have previously been shown to contain identical oriT sequences as well as conserved restriction endonuclease cleavage patterns within their tra regions. Complementation analysis and sequence data presented here indicate that these two plasmids encode essentially identical conjugal DNA-processing proteins. This region contains three genes, traI, traJ, and traK, transcribed in the same orientation from a promoter that probably lies within or near the conjugal transfer origin (oriT). Three corresponding proteins were visualized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and complementation analysis confirmed that this region contains three tra complementation groups. All three proteins resemble proteins of the IncW plasmid R388 and other plasmids thought to have roles in processing of plasmid DNA during conjugation. The hydropathy profile of TraJ suggests a transmembrane topology similar to that of several homologous proteins. Both traK and traI were required for efficient interplasmid site-specific recombination at oriT, while traJ was not required. The leading region of pKM101 contains three genes (stbA, stbB, and stbC), null mutations in which cause elevated levels of plasmid instability. Plasmid instability was observed only in hosts that are proficient in interplasmid recombination, suggesting that this recombination can potentially lead to plasmid loss and that Stb proteins somehow overcome this, possibly via site-specific multimer resolution.     

Selective binding of actinomycin D and distamycin A to DNA.

The exact sites at which a number of drugs inhibit the nick translation of DNA by E.coli DNA polymerase-I have been pinpointed. In order to do this, a method has been developed for sequencing double-stranded plasmid DNA from the site of a specifically induced nick. The initial experiments have concentrated on analysis of drug inhibition of nick translation in a 200 nucleotide region near the Eco Rl origin of pBR313. Many drugs were found to inhibit nick translation in a highly sequence specific manner. For actinomycin D, significant inhibition occurred at just four sites in the nucleotide sequence under test and only one sequence (pGpCpGpCpGpGp) gave really strong inhibition. Distamycin A gave a different pattern of inhibition with particularly strong stops in just two of the many A-T rich regions in the DNA. Experiments with caffeine suggest that factors in addition to primary sequence are important in determining where major inhibition occurs.     

Location of the relaxation complex nick site within the minimal origin of transfer region of RK2

Transfer of plasmid DNA during bacterial conjugation begins at a specific site: the origin of transfer (oriT). The oriT region of the broad host range plasmid RK2 is located on a 250 bp fragment. Deletions involving either end of this region reduce transfer function, indicating that an extended sequence is required for optimal oriT activity. The single-strand nick induced by the RK2 DNA-protein relaxation complex is located adjacent to the 19 bp inverted repeat within the minimal oriT sequence. These results provide strong evidence that the plasmid relaxation event induced in vitro represents the nicking reaction that initiates DNA transfer at oriT during conjugation.     

Initiation of DNA synthesis in the transfer origin region of RK2 by the plasmid-encoded primase: detection using defective M13 phage

The broad host range IncP (IncP1) plasmids of gram-negative bacteria encode DNA primases that are involved in conjugal DNA synthesis. The primase of RK2/RP4 is required for efficient DNA transfer to certain gram-negative bacteria, indicating that the enzyme primes complementary strand synthesis in the recipient. In vitro, the primase initiates synthesis of oligoribonucleotides at 3'-dGdT-5' dinucleotides on the template strand. In this report, replication-defective M13 phage are used to assay the ability of the RK2-encoded primase to initiate complementary strand synthesis in vivo on single-strand templates containing the RK2 origin of conjugal transfer (oriT) or the RK2 origin of vegetative replication (oriV). The results show that sequences from either strand of the oriT region serve as efficient substrates for the RK2 primase and can enhance the growth of the defective M13 vectors delta E101 and delta Elac to levels approaching wild-type. The primise-oriT interaction appeared specific, since neither the oriV sequence nor another RK2 region, trfB, significantly enhanced growth of the defective phage, either in the presence or in the absence of the primase. In contrast to ColEl and F, this study also shows that the oriV region of RK2 lacks sites that are recognized by the host-specified DNA priming systems. The results suggest that the oriT region contains sites on both DNA strands that are efficient substrates for the plasmid-encoded primase, facilitating initiation of complementary strand DNA synthesis in both donor and recipient during conjugation.     

The role of oriT in tra-dependent enhanced recombination between mini-F-lac-oriT and lambda plac5.

Recombination between F42lac and lambda plac5 is typically 20- to 50-fold more efficient than recombination between chromosomal lac and lambda plac5. This enhancement of recombination is recBCD-dependent and requires the expression of genes from the tra regulon of the F factor. Also required is oriT, the origin of F factor conjugational transfer, which must be located in-cis to the cellular copy of lac. In this study we show that enhanced recombination is not supported by an oriT point mutant that reduces oriT function in conjugation. We also present evidence that the activation of oriT for recombination enhancement involves the same strand-specific nick that is required for conjugal DNA transfer. Although it is thought that the role of oriT in recombination enhancement is related to the facilitated entry of RecBCD enzyme into the DNA duplex, we were unable to detect any double-strand breakage at oriT.     

Bacteroides fragilis mobilizable transposon Tn5520 requires a 71 base pair origin of transfer sequence and a single mobilization protein for relaxosome formation during conjugation

Tn5520 is the smallest known bacterial mobilizable transposon and was isolated from an antibiotic resistant Bacteroides fragilis clinical isolate. When a conjugation apparatus is provided in trans, Tn5520 is mobilized (transferred) efficiently within, and from, both Bacteroides spp. and Escherichia coli. Only two genes are present on Tn5520; one encodes an integrase, and the other a multifunctional mobilization (Mob) protein BmpH. BmpH is essential for Tn5520 mobility. The focus of this study was to identify the Tn5520 origin of conjugative transfer (oriT) and to study BmpH-oriT binding. We delimited the functional Tn5520 oriT to a 71 bp sequence upstream of the bmpH gene. A plasmid vector harbouring this minimal 71 bp oriT was mobilized at the same frequency as that of intact Tn5520. The minimal oriT contains one 17 bp inverted repeat (IR) sequence. We constructed and tested multiple IR mutants and showed that the IR was essential in its entirety for mobilization. A nick site sequence (5'-GCTAC-3') was also identified within the minimal oriT; this sequence resembled nick sites found in plasmids of Gram positive origin. We further showed that mutation of a highly conserved GC dinucleotide in the nick site sequence completely abolished mobilization. We also purified BmpH and showed that it specifically bound a Tn5520 oriT fragment in electrophoretic mobility shift assays. We also identified non-nick site sequences within the minimal oriT that were essential for mobilization. We hypothesize that transposon-based single Mob protein systems may contribute to efficient gene dissemination from Bacteroides spp., because fewer DNA processing proteins are required for relaxosome formation.     

Specific binding of integrase to the origin of transfer (oriT) of the conjugative transposon Tn916

Purified integrase protein (Int) of the conjugative transposon Tn916 was shown, using nuclease protection experiments, to bind specifically to a site within the origin of conjugal transfer of the transposon, oriT. A sequence similar to the ends of the transposon that are bound by the C-terminal DNA-binding domain of Int was present in the protected region. However, Int binding to oriT required both the N- and C-terminal DNA-binding domains of Int, and the pattern of nuclease protection differed from that observed when Int binds to the transposon ends and flanking DNA. Binding of Int to oriT may be part of a mechanism to prevent premature conjugal transfer of Tn916 prior to excision from the donor DNA.     

Characterization of the functional sites in the oriT region involved in DNA transfer promoted by sex factor plasmid R100.

We have previously identified three sites, named sbi, ihfA, and sbyA, specifically recognized or bound by the TraI, IHF, and TraY proteins, respectively; these sites are involved in nicking at the origin of transfer, oriT, of plasmid R100. In the region next to these sites, there exists the sbm region, which consists of four sites, sbmA, sbmB, sbmC, and sbmD; this region is specifically bound by the TraM protein, which is required for DNA transfer. Between sbmB and sbmC in this region, there exists another IHF-binding site, ihfB. The region containing all of these sites is located in the proximity of the tra region and is referred to as the oriT region. To determine whether these sites are important for DNA transfer in vivo, we constructed plasmids with various mutations in the oriT region and tested their mobilization in the presence of R100-1, a transfer-proficient mutant of R100. Plasmids with either deletions in the sbi-ihfA-sbyA region or substitution mutations introduced into each specific site in this region were mobilized at a greatly reduced frequency, showing that all of these sites are essential for DNA transfer. By binding to ihfA, IHF, which is known to bend DNA, may be involved in the formation of a complex (which may be called oriT-some) consisting of TraI, IHF, and TraY that efficiently introduces a nick at oriT. Plasmids with either deletions in the sbm-ihfB region or substitution mutations introduced into each specific site in this region were mobilized at a reduced frequency, showing that this region is also important for DNA transfer. By binding to ihfB, IHF may also be involved in the formation of another complex (which may be called the TraM-IHF complex) consisting of TraM and IHF that ensures DNA transfer with a high level of efficiency. Several-base-pair insertions into the positions between sbyA and sbmA affected the frequency of transfer in a manner dependent upon the number of base pairs, indicating that the phasing between sbyA and sbmA is important. This in turn suggests that both oriT-some and the TraM-IHF complex should be in an appropriate position spatially to facilitate DNA transfer.     

DNA recognition by F factor TraI36: highly sequence-specific binding of single-stranded DNA

The TraI protein has two essential roles in transfer of conjugative plasmid F Factor. As part of a complex of DNA-binding proteins, TraI introduces a site- and strand-specific nick at the plasmid origin of transfer (oriT), cutting the DNA strand that is transferred to the recipient cell. TraI also acts as a helicase, presumably unwinding the plasmid strands prior to transfer. As an essential feature of its nicking activity, TraI is capable of binding and cleaving single-stranded DNA oligonucleotides containing an oriT sequence. The specificity of TraI DNA recognition was examined by measuring the binding of oriT oligonucleotide variants to TraI36, a 36-kD amino-terminal domain of TraI that retains the sequence-specific nucleolytic activity. TraI36 recognition is highly sequence-specific for an 11-base region of oriT, with single base changes reducing affinity by as much as 8000-fold. The binding data correlate with plasmid mobilization efficiencies: plasmids containing sequences bound with lower affinities by TraI36 are transferred between cells at reduced frequencies. In addition to the requirement for high affinity binding to oriT, efficient in vitro nicking and in vivo plasmid mobilization requires a pyrimidine immediately 5' of the nick site. The high sequence specificity of TraI single-stranded DNA recognition suggests that despite its recognition of single-stranded DNA, TraI is capable of playing a major regulatory role in initiation and/or termination of plasmid transfer.     

Streptococcal plasmid pIP501 has a functional oriT site.

DNA sequence analysis suggested the presence of a plasmid transfer origin-like site (oriT) in the gram-positive conjugative plasmid pIP501. To test the hypothesis that the putative oriT site in pIP501 played a role in conjugal transfer, we conducted plasmid mobilization studies in Enterococcus faecalis. Two fragments, 49 and 309 bp, which encompassed the oriT region of pIP501, were cloned into pDL277, a nonconjugative plasmid of gram-positive origin. These recombinant plasmids were mobilized by pVA1702, a derivative of pIP501, at a frequency of 10(-4) to 10(-5) transconjugants per donor cell, while pDL277 was mobilized at a frequency of 10(-8) transconjugants per donor cell. These results indicated that the oriT-like site was needed for conjugal mobilization. To demonstrate precise nicking at the oriT site, alkaline gel and DNA-sequencing analyses were performed. Alkaline gel electrophoresis results indicated a single-stranded DNA break in the predicted oriT site. The oriT site was found upstream of six open reading frames (orf1 to orf6), each of which plays a role in conjugal transfer. Taken together, our conjugal mobilization data and the in vivo oriT nicking seen in Escherichia coli argue compellingly for the role of specific, single-stranded cleavage in plasmid mobilization. Thus, plasmid mobilization promoted by pVA1702 (pIP501) works in a fashion similar to that known to occur widely in gram-negative bacteria.     

The integrase of the conjugative transposon Tn916 directs strand- and sequence-specific cleavage of the origin of conjugal transfer, oriT, by the endonuclease Orf20

Orf20 of the conjugative transposon Tn916 was purified as a chimeric protein fused to maltose binding protein (MBP-Orf20). The chimeric protein possessed endonucleolytic activity, cleaving both strands of the Tn916 origin of conjugal transfer (oriT) at several distinct sites and favoring GT dinucleotides. Incubation of the oriT DNA with purified Tn916 integrase (Int) and MBP-Orf20 resulted in strand- and sequence-specific cleavage of oriT at a TGGT motif in the transferred strand. This motif lies immediately adjacent to a sequence in oriT previously shown to be protected from DNase I cleavage by Int. The endonucleolytic cleavages produced by Orf20 generated a 3' OH group that could be radiolabeled by dideoxy ATP and terminal transferase. The production of a 3' OH group distinguished these Orf20-dependent cleavage events from those catalyzed by Int at the ends of Tn916. Thus, Orf20 functions as the relaxase of Tn916, nicking oriT as the first step in conjugal DNA transfer. Remarkably for a tyrosine recombinase, Tn916 Int acts as a specificity factor in the reaction, conferring both strand and sequence specificities on the endonucleolytic cleavage activity of Orf20.