Conjugal transfer of the 5-nitroimidazole resistance plasmid pIP417 from Bacteroides vulgatus BV-17: characterization and nucleotide sequence analysis of the mobilization region.

Three small 5-nitroimidazole (5-Ni) resistance plasmids (pIP417, pIP419, and pIP421) from Bacteroides clinical isolates are transferable by a conjugative process during homologous or heterologous matings. The mobilization properties of pIP417 originated from strain BV-17 of Bacteroides vulgatus were studied. The plasmid was successfully introduced by in vitro conjugation into different strains of Bacteroides and Prevotella species and could be transferred back from these various strains to a plasmid-free 5-Ni-sensitive Bacteroides fragilis strain, indicating that in vivo spread of the resistance gene may occur. The transfer of plasmid pIP417 harbored by the Tc(r) strain BF-2 of B. fragilis was stimulated by low concentrations of tetracycline or chlorotetracycline. This suggests a possible role for coresident conjugative transposons in the dissemination of 5-Ni resistance among gram-negative anaerobes. The nucleotide sequence of the 2.1-kb DNA mobilization region was determined. It contains a putative origin of transfer (oriT) in an A+T-rich-region, including three inverted repeats, and two integration host factor binding sites. The two identified mobilization genes (mobA and mobB) are organized in one operon and were both required for efficient transfer. Southern blotting indicated that the mobilization region of plasmid pIP417 is closely related to that of both the erythromycin resistance plasmid pBFTM1O and the 5-Ni resistance plasmid pIP419 but not to that of the 5-Ni resistance plasmid pIP421.     

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.     

Transferable 5-nitroimidazole resistance in the Bacteroides fragilis group

We report the characterization of a strain of Bacteroides vulgatus, BV17, that exhibits a moderate resistance to 5-nitroimidazoles and carries plasmids of 4.5, 5, 7.7, and 56 kb. A genetic determinant involved in this resistance is carried by the 7.7 +/- 0.2-kb plasmid (pIP417). This plasmid can be introduced and replicated in a sensitive strain of B. fragilis 638R by transformation or by conjugation. In the latter case, the transfer may involve mobilization by the 56-kb conjugative plasmid (pIP418) regularly found in transconjugants but not in transformants.     

Isolation and characterization of cLV25, a Bacteroides fragilis chromosomal transfer factor resembling multiple Bacteroides sp. mobilizable transposons

Horizontal DNA transfer contributes significantly to the dissemination of antibiotic resistance genes in Bacteroides fragilis. To further our understanding of DNA transfer in B. fragilis, we isolated and characterized a new transfer factor, cLV25. cLV25 was isolated from B. fragilis LV25 by its capture on the nonmobilizable Escherichia coli-Bacteroides shuttle vector pGAT400DeltaBglII. Similar to other Bacteroides sp. transfer factors, cLV25 was mobilized in E. coli by the conjugative plasmid R751. Using Tn1000 mutagenesis and deletion analysis of cLV25, two mobilization genes, bmgA and bmgB, were identified, whose predicted proteins have similarity to DNA relaxases and mobilization proteins, respectively. In particular, BmgA and BmgB were homologous to MocA and MocB, respectively, the two mobilization proteins of the B. fragilis mobilizable transposon Tn4399. A cis-acting origin of transfer (oriT) was localized to a 353-bp region that included nearly all of the intergenic region between bmgB and orf22 and overlapped with the 3' end of orf22. This oriT contained a putative nic site sequence but showed no significant similarity to the oriT regions of other transfer factors, including Tn4399. Despite the lack of sequence similarity between the oriTs of cLV25 and Tn4399, a mutation in the cLV25 putative DNA relaxase, bmgA, was partially complemented by Tn4399. In addition to the functional cross-reaction with Tn4399, a second distinguishing feature of cLV25 is that predicted proteins have similarity to proteins encoded not only by Tn4399 but by several Bacteroides sp. transfer factors, including NBU1, NBU2, CTnDOT, Tn4555, and Tn5520.     

Molecular Evolution of the Pathogenicity Island of Enterotoxigenic Bacteroides fragilis Strains

Enterotoxigenic Bacteroides fragilis (ETBF) strains, which produce a 20-kDa zinc metalloprotease toxin (BFT), have been associated with diarrheal disease in animals and young children. Studying a collection of ETBF and nontoxigenic B. fragilis (NTBF) strains, we found that bft and a second metalloprotease gene (mpII) are contained in an approximately 6-kb pathogenicity island (termed B. fragilis pathogenicity island or BfPAI) which is present exclusively in all 113 ETBF strains tested (pattern I). Of 191 NTBF strains, 100 (52%) lack both the BfPAI and at least a 12-kb region flanking BfPAI (pattern II), and 82 of 191 NTBF strains (43%) lack the BfPAI but contain the flanking region (pattern III). The nucleotide sequence flanking the left end of the BfPAI revealed a region with the same organization as the mobilization region of the 5-nitroimidazole resistance plasmid pIP417 and the clindamycin resistance plasmid pBFTM10, that is, two mobilization genes (bfmA and bfmB) organized in one operon and a putative origin of transfer (oriT) located in a small, compact region. The region flanking the right end of the BfPAI contains a gene (bfmC) whose predicted protein shares significant identity to the TraD mobilization proteins encoded by plasmids F and R100 from Escherichia coli. Nucleotide sequence analysis of one NTBF pattern III strain (strain I-1345) revealed that bfmB and bfmC are adjacent to each other and separated by a 16-bp GC-rich sequence. Comparison of this sequence with the appropriate sequence of ETBF strain 86-5443-2-2 showed that in this ETBF strain the 16-bp sequence is replaced by the BfPAI. This result defined the BfPAI as being 6,036 bp in length and its precise integration site as being between the bfmB and bfmC stop codons. The G+C content of the BfPAI (35%) and the flanking DNA (47 to 50%) differ greatly from that reported for the B. fragilis chromosome (42%), suggesting that the BfPAI and its flanking region are two distinct genetic elements originating from very different organisms. ETBF strains may have evolved by horizontal transfer of these two genetic elements into a pattern II NTBF strain.     

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.     

Conjugal transfer of antibiotic resistance factors in Bacteroides fragilis: the btgA and btgB genes of plasmid pBFTM10 are required for its transfer from Bacteroides fragilis and for its mobilization by IncP beta plasmid R751 in Escherichia coli.

Transferable plasmids play an important role in the dissemination of clindamycin-erythromycin resistance in Bacteroides fragilis. We previously described the isolation and properties of pBFTM10, a 14.9-kb ClnR transfer factor from B. fragilis TMP10. We also reported the isolation of a transfer-deficient deletion derivative of pBFTM10 contained in the B. fragilis-Escherichia coli shuttle vector pGAT400. In the present study we used pGAT400 and a similar shuttle vector, pGAT550, to characterize and sequence a region of pBFTM10 required for its transfer from B. fragilis to B. fragilis or E. coli recipients and for its mobilization by the broad-host-range plasmid R751 from E. coli donors to E. coli recipients. Deletion of certain BglII restriction fragments from pBFTM10 resulted in partial or complete loss of transfer ability. Tn1000 insertions into this same region also resulted in altered transfer properties. We used the sites of Tn1000 insertions to determine the DNA sequence of the transfer region. Two potential open reading frames encoding proteins of 23.2 and 33.8 kDa, corresponding to two genes, btgA or btgB, were identified in the sequence. Tn1000 insertions within btgA or btgB or deletion of all or portions of btgA or btgB resulted in either a transfer deficiency or greatly reduced transfer from B. fragilis donors and alterations in mobilization by R751 in E. coli. A potential oriT sequence showing similarity in organization to the oriT regions of the IncP plasmids was also detected. Thus, pBFTM10 encodes and requires at least two proteins necessary for efficient transfer from B. fragilis. These same functions are expressed in E. coli and are required for mobilization by R751.     

Requirements for strand- and site-specific cleavage within the oriT region of Tn4399, a mobilizing transposon from Bacteroides fragilis.

Replicons that contain Tn4399, a conjugal mobilizing transposon isolated from Bacteroides fragilis, can be mobilized in the presence of broad-host-range IncP plasmids RP4 and R751 in Escherichia coli to B. fragilis or E. coli recipients (C. G. Murphy and M. H. Malamy, J. Bacteriol. 175:5814-5823, 1993). To identify the initial DNA processing events involved in Tn4399-mediated mobilization in E. coli, plasmid DNA from pCGM328 (a pUC7 vector that contains the mobilization region of Tn4399) was isolated from donor cells following the release of plasmid DNA from the relaxation complex. Site- and strand-specific cleavage within the oriT region of Tn4399 was detected by denaturing gel electrophoresis and Southern hybridization analysis of this DNA in the presence or absence of IncP plasmids. Mutations in either mocA or mocB, two genes which are encoded by Tn4399 and are required for mobilization, significantly decrease the amount of specifically nicked DNA detected. These results suggest roles for the MocA and MocB gene products in specific processing of Tn4399-containing plasmid DNA prior to mobilization. By isolation of the nicked strand and primer extension of this template, we mapped the precise 5' end of the single-stranded cleavage reaction. The nucleotide position of nicTn4399 is adjacent to two sets of inverted repeats, a genetic arrangement similar to those of previously characterized oriT regions. Two site-directed mutations which remove nicTn4399 (oriT delta 1 and oriT delta 2) cannot be mobilized to recipients when they are present in trans along with functional MocA and MocB proteins and an IncP mobilizing plasmid; they are cis-dominant loss-of-function mutations.     

Location and characteristics of the transfer region of a Bacteroides conjugative transposon and regulation of transfer genes.

Many Bacteroides clinical isolates contain large conjugative transposons, which excise from the genome of a donor and transfer themselves to a recipient by a process that requires cell-to-cell contact. It has been suggested that the transfer intermediate of the conjugative transposons is a covalently closed circle, which is transferred by the same type of rolling circle mechanism used by conjugative plasmids, but the transfer origin of a conjugative transposon has not previously been localized and characterized. We have now identified the transfer origin (oriT) region of one of the Bacteroides conjugative transposons, TcrEmr DOT, and have shown that it is located near the middle of the conjugative transposon. We have also identified a 16-kbp region of the conjugal transposon which is necessary and sufficient for conjugal transfer of the element and which is located near the oriT. This same region proved to be sufficient for mobilization of coresident plasmids and unlinked integrated elements as well as for self-transfer, indicating that all of these activities are mediated by the same transfer system. Previously, we had reported that disruption of a gene, rteC, abolished self-transfer of the element. rteC is one of a set of rte genes that appears to mediate tetracycline induction of transfer activities of the conjugative transposons. On the basis of these and other data, we had proposed that RteC activated expression of transfer genes. We have now found, however, that when the transfer region of TcrEmr DOT was cloned as a plasmid that did not contain rteC and the plasmid (pLYL72) was tested for transfer out of a Bacteroides strain that did not have a copy of rteC in the chromosome, the plasmid was self-transmissible without tetracycline induction. This and other findings suggest that RteC is not an activator transfer genes but is stimulating transfer in some other way.     

The mobilization regions of two integrated Bacteroides elements, NBU1 and NBU2, have only a single mobilization protein and may be on a cassette.

Bacteroides conjugative transposons can act in trans to excise, circularize, and transfer unlinked integrated elements called NBUs (for nonreplicating Bacteroides units). Previously, we localized and sequenced the mobilization region of one NBU, NBU1, and showed that this mobilization region was recognized by the IncP plasmids RP4 and R751, as well as by the Bacteroides conjugative transposons. We report here that the single mobilization protein carried by NBU1 appears to be a bifunctional protein that binds to the oriT region and catalyzes the nicking reaction that initiates the transfer process. We have also localized and sequenced the mobilization region of a second NBU, NBU2. The NBU2 mobilization region was 86 to 90% identical at the DNA sequence to the oriT-mob region of NBU1. The high sequence similarity between NBU1 and NBU2 ended abruptly after the stop codon of the mob gene and about 1 kbp upstream of the oriT region, indicating that the oriT-mob regions of NBU1 and NBU2 may be on some sort of cassette. A region on NBU1 and NBU2 which lies immediately upstream of the oriT region had 66% sequence identity to a region upstream of the oriT region on a mobilizable transposon, Tn4399, an element that had previously appeared to be completely unrelated to the NBUs.     

Multiple gene products and sequences required for excision of the mobilizable integrated Bacteroides element NBU1

NBU1 is an integrated 10.3-kbp Bacteroides element, which can excise and transfer to Bacteroides or Escherichia coli recipients, where it integrates into the recipient genome. NBU1 relies on large, >60-kbp, conjugative transposons for factors that trigger excision and for mobilization of the circular form to recipients. Previously, we showed that a single integrase gene, intN1, was necessary and sufficient for integration of NBU1 into its target site on the Bacteroides or E. coli genome. We now show that an unexpectedly large region of NBU1 is required for excision. This region includes, in addition to intN1, four open reading frames plus a large region downstream of the fourth gene, prmN1. This downstream sequence was designated XRS, for "excision-required sequence." XRS contains the oriT of the circular form of NBU1 and about two-thirds of the adjacent mobilization gene, mobN1. This is the first time an oriT, which is involved in conjugal transfer of the circular form, has been implicated in excision. Disruption of the gene immediately downstream of intN1, orf2, completely abolished excision. The next open reading frame, orf2x, was too small to be disrupted, so we still do not know whether it plays a role in the excision reaction. Deletions were made in each of two open reading frames downstream of orf2x, orf3 and prmN1. Both of these deletions abolished excision, indicating that these genes are also essential for excision. Attempts to complement various mutations in the excision region led us to realize that a portion of the excision region carrying prmN1 and part of the XRS (XRS(HIII)) inhibited excision when provided in trans on a multicopy plasmid (8 to 10 copies per cell). However, a fragment carrying prmN1, XRS, and the entire mobilization gene, mobN1, did not have this effect. The smaller fragment may be interfering with excision by attracting proteins made by the intact NBU1 and thus removing them from the excision complex. Our results show clearly that excision is a complex process that involves several proteins and a cis-acting region (XRS) which includes the oriT. We suggest that this complex excision machinery may be necessary to allow NBU1 to coordinate nicking at the ends during excision and nicking at the oriT during conjugal transfer, to prevent premature nicking at the oriT before NBU1 has excised and circularized.     

Characterization of the mobilization region of a Bacteroides insertion element (NBU1) that is excised and transferred by Bacteroides conjugative transposons.

Many Bacteroides clinical isolates carry large conjugative transposons that, in addition to transferring themselves, excise, circularize, and transfer smaller, unlinked chromosomal DNA segments called NBUs (nonreplicating Bacteroides units). We report the localization and DNA sequence of a region of one of the NBUs, NBU1, that was necessary and sufficient for mobilization by Bacteroides conjugative transposons and by IncP plasmids. The fact that the mobilization region was internal to NBU1 indicates that the circular form of NBU1 is the form that is mobilized. The NBU1 mobilization region contained a single large (1.4-kbp) open reading frame (ORF1), which was designated mob. The oriT was located within a 220-bp region upstream of mob. The deduced amino acid sequence of the mob product had no significant similarity to those of mobilization proteins of well-characterized Escherichia coli group plasmids such as RK2 or of either of the two mobilization proteins of Bacteroides plasmid pBFTM10. There was, however, a high level of similarity between the deduced amino acid sequence of the mob product and that of the product of a Bacteroides vulgatus cryptic open reading frame closely linked to a cefoxitin resistance gene (cfxA).     

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.     

Two independent conjugal transfer systems operating in Bacteroides fragilis V479-1.

Bacteroides fragilis V479-1 (also designated strain 92) has previously been shown to contain a conjugative plasmid, pBF4, that specifies resistance to clindamycin (Cc). A report of inducible tetracycline (Tc) resistance in this strain suggested that this phenotype was also plasmid associated (G. Privitera et al., Nature [London] 278:657-659, 1979) and prompted further investigation. Mating experiments with V469-1 and a Cc-sensitive derivative of V479-1, V598, showed that Tc resistance transfer occurred by a conjugation-like event which was insensitive to DNase, was not mediated by donor culture cell-free filtrates, and required cell-to-cell contact. Results from transfer experiments with V479-1 indicated that Tc and Cc resistance determinants were not linked and segregated independently in matings. Progeny recovered from matings with the V479-1 or V598 donor strain were able to transfer the Tc resistance marker in secondary crosses. Tc resistance transfer from V479-1 or V598 was greatly stimulated by pregrowth in the presence of Tc but not Cc. pBF4-mediated Cc resistance transfer was not affected by pregrowth in the presence of Cc or Tc. Filter blot DNA hybridization studies revealed that pBF4 sequences were not involved in either the Tc resistant phenotype or its associated conjugal transfer properties. The Tc resistance transfer element was not associated with pBF4 or any other extrachromosomal DNA element.     

Efficient plasmid mobilization by pIP501 in Lactococcus lactis subsp. lactis.

pIP501 is a streptococcal conjugative plasmid which can be transmitted among numerous gram-positive strains. To identify a minimal mobilization (mob) locus of pIP501, DNA fragments of pIP501 were cloned into nonconjugative target plasmids and tested for mobilization by pIP501. We show that nonmobilizable plasmids containing a specific fragment of pIP501 are transmitted at high frequencies between Lactococcus lactis subsp. lactis strains if transfer (tra) functions are provided in trans by a pIP501 derivative. Independent transfer of the mobilized plasmid was observed in up to 44% of transconjugants. A 2.2-kb segment containing mob was sequenced. This DNA segment is characterized by three palindromes (palI, palII, and palIII) and a 202-amino-acid open reading frame (ORFX) of unknown function. The smallest DNA fragment conferring high frequency mobilization was localized to a 1.0-kb region (extending from pIP501 coordinates 3.60 to 4.60 on the 30.2-kb map) which contains palI (delta G = -27 kcal/mol [ca. -110,000 J/mol]). A 26-bp sequence identical to palI is present on pIP501, upstream of the plasmid copy control region. Further homologies with the palI sequence are also found with the related Enterococcus faecalis conjugative plasmid pAM beta 1. The region containing mob maps outside the previously described segment mediating pIP501 conjugation. Our results with recA strains indicate that the mob site is a hot spot for cointegrate formation.     

Genetic transfer systems in Bacteroides: cloning and mapping of the transferable tetracycline-resistance locus

Conjugation systems that transfer antibiotic resistance in the absence of detectable plasmids are common in Bacteroides, but the mechanism of transfer is poorly understood. We found that linked transfer of tetracycline (TcR) and clindamycin (ClR) resistance by Bacteroides fragilis strain 1126 is induced by growth in either Tc or Cl. We cloned the transferable TcR locus as a 13 kb fragment on the shuttle vector pPH6 in Escherichia coli and showed that this region expresses TcR in Bacteroides but not E. coli. The TcR gene was mapped to a 3 kb region and the ClR gene was shown not to be present in the 13 kb insert. Homologous TcR genes are found in B. fragilis V479 and 1792. Using pulsed-field electrophoresis, the transferable TcR gene was shown to be physically associated with high molecular-weight DNA, suggesting that it is located on the chromosome. A new TcR shuttle vector, pPH7 delta 1.1, was constructed to facilitate use of this selective marker in Bacteroides genetics.     

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.     

Investigating the basis of substrate recognition in the pC221 relaxosome

The nicking of the origin of transfer (oriT) is an essential initial step in the conjugative mobilization of plasmid DNA. In the case of staphylococcal plasmid pC221, nicking by the plasmid-specific MobA relaxase is facilitated by the DNA-binding accessory protein MobC; however, the role of MobC in this process is currently unknown. In this study, the site of MobC binding was determined by DNase I footprinting. MobC interacts with oriT DNA at two directly repeated 9 bp sequences, mcb1 and mcb2, upstream of the oriT nic site, and additionally at a third, degenerate repeat within the mobC gene, mcb3. The binding activity of the conserved sequences was confirmed indirectly by competitive electrophoretic mobility shift assays and directly by Surface Plasmon Resonance studies. Mutation at mcb2 abolished detectable nicking activity, suggesting that binding of this site by MobC is a prerequisite for nicking by MobA. Sequential site-directed mutagenesis of each binding site in pC221 has demonstrated that all three are required for mobilization. The MobA relaxase, while unable to bind to oriT DNA alone, was found to associate with a MobC-oriT complex and alter the MobC binding profile in a region between mcb2 and the nic site. Mutagenesis of oriT in this region defines a 7 bp sequence, sra, which was essential for nicking by MobA. Exchange of four divergent bases between the sra of pC221 and the related plasmid pC223 was sufficient to swap their substrate identity in a MobA-specific nicking assay. Based on these observations we propose a model of layered specificity in the assembly of pC221-family relaxosomes, whereby a common MobC:mcb complex presents the oriT substrate, which is then nicked only by the cognate MobA.     

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.