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.     

Identification and DNA sequence of the mobilization region of the 5-nitroimidazole resistance plasmid pIP421 from Bacteroides fragilis.

The nucleotide sequence of the DNA mobilization region of the 5-nitroimidazole resistance plasmid pIP421, from strain BF-F239 of Bacteroides fragilis, was determined. It contains a putative origin of transfer (oriT) including three sets of inverted repeats and two sequences reminiscent of specific integration host factor binding sites. The product of the mobilization gene mob421 (42.2 kDa) is a member of the Bacteroides mobilization protein family, which includes the MobA of pBI143, NBUs, and Tn4555. Sequence similarity suggests that it has both oriT binding and nicking activities. The transfer frequency of pIP421 in a B. fragilis donor strain possessing a Tc(r) or Tc(r) Em(r)-like conjugative transposon was significantly enhanced by tetracycline. Moreover, the mobilization region of pIP421 confers the ability to be mobilized from Escherichia coli by an IncP plasmid.     

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.     

Tn4399, a conjugal mobilizing transposon of Bacteroides fragilis.

Conjugal transposons play an important role in the dissemination of antibiotic resistance determinants in the streptococci and have been postulated to exist in Bacteroides fragilis. To investigate the presence of conjugal transposons in B. fragilis, we employed a Tra- derivative of the transfer factor pBFTM10 contained in the chimeric plasmid pGAT400 delta BglII. We attempted to restore transferability to this plasmid from a series of transconjugants generated by crossing B. fragilis TMP230 containing the TET transfer factor with B. fragilis TM4000, a standard recipient. Transconjugant TM4.2321 transferred pGAT400 delta BglII to Escherichia coli HB101 at almost the same frequency as did the Tra+ parental plasmid, pGAT400. Analysis of the transferred plasmids revealed the presence of 9.6 kilobases of additional DNA in every case but at different positions in independent isolates. The presence of this DNA, designated Tn4399, allowed the pGAT400 delta BglII derivatives to retransfer from the TM4000 background to B. fragilis or E. coli recipients. DNA hybridization studies demonstrated the presence of one copy of Tn4399 in TMP230 and three copies at new sites in TM4.2321. Tn4399 is a new B. fragilis transposon with unique transfer properties that may play a role in the dissemination of drug resistance genes. It differs from previously described conjugal transposons by its ability to mobilize nonconjugal plasmids in cis.     

Characterization and DNA sequence of the mobilization region of pLV22a from Bacteroides fragilis.

A 4.2-kb plasmid (pLV22a) native to Bacteroides fragilis LV22 became fused to a transfer-deficient Bacteroides spp.-Escherichia coli shuttle vector by an inverse transposition event, resulting in a transferrable phenotype. The transfer phenotype was attributable to pLV22a, which was also capable of mobilization within E. coli when coresident with the IncP beta R751 plasmid. Transposon mutagenesis with Tn1000 localized the mobilization region to a 1.5-kb DNA segment in pLV22a. The mobilization region has been sequenced, and five open reading frames have been identified. Mutants carrying disruptions in any of the three genes designated mbpA, mbpB, and mbpC and coding for deduced products of 11.3, 30.4, and 17.1 kDa, respectively, cannot be mobilized when coresident with R751. Mutations in all three genes can be complemented in the presence of the respective wild-type genes, indicating that the products of mbpA, mbpB, and mbpC have roles in the mobilization process and function in trans. The deduced 30.4-kDa MbpB protein contains a 14-amino-acid conserved motif that is also found in the DNA relaxases of a variety of conjugal and mobilizable plasmids and the conjugative transposon Tn4399. Deletion analysis and complementation experiments have localized a cis-acting region of pLV22a within mbpA.     

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.     

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.     

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.     

Regions in Bacteroides plasmids pBFTM10 and pB8-51 that allow Escherichia coli-Bacteroides shuttle vectors to be mobilized by IncP plasmids and by a conjugative Bacteroides tetracycline resistance element.

Bacteroides-Escherichia coli shuttle vectors containing a nonmobilizable pBR322 derivative and either pBFTM10 (pDP1, pCG30) or pB8-51 (pEG920) were mobilized by IncP plasmid R751 or pRK231 (an ampicillin-sensitive derivative of RK2) between E. coli strains and from E. coli to Bacteroides recipients. IncI alpha R64 drd-ll transferred these vectors 1,000 times less efficiently than did the IncP plasmids. pDP1, pCG30, and pEG920 could be mobilized from B. uniformis donors to both E. coli and Bacteroides recipients by a conjugative Bacteroides Tcr (Tcr ERL) element which was originally found in a clinical Bacteroides fragilis strain (B. fragilis ERL). However, the shuttle vector pE5-2, which contains pB8-51 cloned in a restriction site that prevents its mobilization by IncP or IncI alpha plasmids, also was not mobilized at detectable frequencies from Bacteroides donors by the Tcr ERL element. The mobilization frequencies of pCG30, pDP1, and pEG920 by the Tcr ERL element in B. uniformis donors to E. coli recipients was about the same as those to isogenic B. uniformis recipients. Transfer of the shuttle vectors from B. uniformis donors to E. coli occurred at the same frequencies when the matings were done aerobically or anaerobically. Growth of the B. uniformis donors in tetracycline (1 microgram/ml) prior to conjugation increased the mobilization frequencies of the vectors to both E. coli and Bacteroides recipients 50 to 100 times.     

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.     

A functional origin of transfer (oriT) on the conjugative transposon Tn916.

The origin of transfer (oriT) of the 18-kb conjugative transposon Tn916 has been localized to a 466-bp region which spans nucleotides 15215 to 15681 on the transposon map. The oriT lies within an intercistronic region between open reading frames ORF20 and ORF21 that contains six sets of inverted repeats ranging from 10 to 20 bp in size. The segment contains three sequences showing identity in 9 of 12 bp to the consensus nicking site (nic) of the IncP family of conjugative plasmids found in gram-negative bacteria. Overlapping one of these sequences is a region similar to the nic site of the F plasmid. Functionality was based on the ability of the oriT-containing sequence to provide a cis-acting mobilization of chimeras involving the shuttle vector pWM401 in response to activation in trans by an intact chromosome-borne transposon Tn916 delta E. Cloned segments of 466 or 376 nucleotides resulted in unselected cotransfer of the plasmid at levels of about 40% when selection was for Tn916 delta E, whereas a 110-bp segment resulted in cotransfer at a frequency of about 7%. Mobilization was specific in that gram-positive plasmids, such as pAD1 and pAM beta 1, and the gram-negative plasmids pOX38 (a derivative of F) and RP1 did not mobilize oriT-containing chimeras.     

General organization of the conjugal transfer genes of the IncW plasmid R388 and interactions between R388 and IncN and IncP plasmids.

The complete conjugal transfer gene region of the IncW plasmid R388 has been cloned in multicopy vector plasmids and mapped to a contiguous 14.9-kilobase segment by insertion mutagenesis. The fertility of the cloned region could still be inhibited by a coresident IncP plasmid. The transfer region has been dissected into two regions, one involved in pilus synthesis and assembly (PILW), and the other involved in conjugal DNA metabolism (MOBW). They have been separately cloned. PILW also contains the genes involved in entry exclusion. MOBW contains oriT and the gene products required for efficient mobilization by PILW. MOBW plasmids could also be mobilized efficiently by PILN, the specific pilus of the IncN plasmid pCU1, but not by PILP, the specific pilus of the IncP plasmid RP1.     

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.     

MobB protein stimulates nicking at the R1162 origin of transfer by increasing the proportion of complexed plasmid DNA.

An essential early step in conjugal mobilization of R1162, nicking of the DNA strand that is subsequently transferred, is carried out in the relaxosome, a complex of two plasmid-encoded proteins and DNA at the origin of transfer (oriT). A third protein, MobB, is also required for efficient mobilization. We show that in the cell this protein increases the proportion of molecules specifically nicked at oriT, resulting in lower yields of covalently closed molecules after alkaline extraction. These nicked molecules largely remain supercoiled, with unwinding presumably constrained by the relaxosome. MobB enhances the sensitivity of the oriT DNA to oxidation by permanganate, indicating that the protein acts by increasing the fraction of complexed molecules. Mutations that significantly reduce the amount of complexed DNA in the cell were isolated. However, plasmids with these mutations were mobilized at nearly the normal frequency, were nicked at a commensurate level, and still required MobB. Our results indicate that the frequency of transfer is determined both by the amount of time each molecule is in the nicked form and by the proportion of complexed molecules in the total population.     

Mobilization of Thiobacillus ferrooxidans plasmids among Escherichia coli strains

Nonconjugative Thiobacillus ferrooxidans plasmids were mobilized at high frequencies among Escherichia coli strains by the IncP plasmid RP4 and at low frequencies by the IncN plasmid R46, but not by the IncW plasmid pSa. The mobilization region of a nonconjugative T. ferrooxidans plasmid was located on a 5.3-kilobase T. ferrooxidans DNA fragment.     

Mobilization of Thiobacillus ferrooxidans plasmids among Escherichia coli strains.

Nonconjugative Thiobacillus ferrooxidans plasmids were mobilized at high frequencies among Escherichia coli strains by the IncP plasmid RP4 and at low frequencies by the IncN plasmid R46, but not by the IncW plasmid pSa. The mobilization region of a nonconjugative T. ferrooxidans plasmid was located on a 5.3-kilobase T. ferrooxidans DNA fragment.     

Plasmid and transposon transfer to Thiobacillus ferrooxidans.

The broad-host-range IncP plasmids RP4, R68.45, RP1::Tn501, and pUB307 were transferred to acidophilic, obligately chemolithotrophic Thiobacillus ferrooxidans from Escherichia coli by conjugation. A genetic marker of kanamycin resistance was expressed in T. ferrooxidans. Plasmid RP4 was transferred back to E. coli from T. ferrooxidans. The broad-host-range IncQ vector pJRD215 was mobilized to T. ferrooxidans with the aid of plasmid RP4 integrated in the chromosome of E. coli SM10. pJRD215 was stable, and all genetic markers (kanamycin/neomycin and streptomycin resistance) were expressed in T. ferrooxidans. By the use of suicide vector pSUP1011, transposon Tn5 was introduced into T. ferrooxidans. The influence of some factors on plasmid transfer from E. coli to T. ferrooxidans was investigated. Results showed that the physiological state of donor cells might be important to the mobilization of plasmids. The transfer of plasmids from E. coli to T. ferrooxidans occurred in the absence of energy sources for both donor and recipient.     

Bacteroides fragilis transfer factor Tn5520: the smallest bacterial mobilizable transposon containing single integrase and mobilization genes that function in Escherichia coli

Many bacterial genera, including Bacteroides spp., harbor mobilizable transposons, a class of transfer factors that carry genes for conjugal DNA transfer and, in some cases, antibiotic resistance. Mobilizable transposons are capable of inserting into and mobilizing other, nontransferable plasmids and are implicated in the dissemination of antibiotic resistance. This paper presents the isolation and characterization of Tn5520, a new mobilizable transposon from Bacteroides fragilis LV23. At 4,692 bp, it is the smallest mobilizable transposon reported from any bacterial genus. Tn5520 was captured from B. fragilis LV23 by using the transfer-deficient shuttle vector pGAT400DeltaBglII. The termini of Tn5520 contain a 22-bp imperfect inverted repeat, and transposition does not result in a target site repeat. Tn5520 also demonstrates insertion site sequence preferences characterized by A-T-rich nucleotide sequences. Tn5520 has been sequenced in its entirety, and two large open reading frames whose predicted protein products exhibit strong sequence similarity to recombinase-integrase enzymes and mobilization proteins, respectively, have been identified. The transfer, mobilization, and transposition properties of Tn5520 have been studied, revealing that Tn5520 mobilizes plasmids in both B. fragilis and Escherichia coli at high frequency and also transposes in E. coli.     

The Bacillus subtilis conjugative transposon ICEBs1 mobilizes plasmids lacking dedicated mobilization functions

Integrative and conjugative elements (ICEs, also known as conjugative transposons) are mobile elements that are found integrated in a host genome and can excise and transfer to recipient cells via conjugation. ICEs and conjugative plasmids are found in many bacteria and are important agents of horizontal gene transfer and microbial evolution. Conjugative elements are capable of self-transfer and also capable of mobilizing other DNA elements that are not able to self-transfer. Plasmids that can be mobilized by conjugative elements are generally thought to contain an origin of transfer (oriT), from which mobilization initiates, and to encode a mobilization protein (Mob, a relaxase) that nicks a site in oriT and covalently attaches to the DNA to be transferred. Plasmids that do not have both an oriT and a cognate mob are thought to be nonmobilizable. We found that Bacillus subtilis carrying the integrative and conjugative element ICEBs1 can transfer three different plasmids to recipient bacteria at high frequencies. Strikingly, these plasmids do not have dedicated mobilization-oriT functions. Plasmid mobilization required conjugation proteins of ICEBs1, including the putative coupling protein. In contrast, plasmid mobilization did not require the ICEBs1 conjugative relaxase or cotransfer of ICEBs1, indicating that the putative coupling protein likely interacts with the plasmid replicative relaxase and directly targets the plasmid DNA to the ICEBs1 conjugation apparatus. These results blur the current categorization of mobilizable and nonmobilizable plasmids and indicate that conjugative elements play a role in horizontal gene transfer even more significant than previously recognized.     

Formation of delta tra F' plasmids: specific recombination at oriT

Delta tra F' plasmids can be isolated from matings between Hfr donors and recA- recipients, with selection for transfer of proximal chromosomal genes. Previous experiments indicate that F DNA from the neighborhood of the transfer origin up to the proximal junction with the chromosomal DNA is present on these plasmids, together with chromosomal segments, some of which belong to distinct size classes. We have sequenced across the novel joints contained in five delta tra FproA+ plasmids and in five delta tra FpurE+ plasmids, and we have compared these with the F sequence near oriT and with a chromosomal site near purE. The previously reported specificity in formation of some of these classes is confirmed at the nucleotide sequence level. The F DNA in nine of these novel joints extended beyond the nicking sites identified by others in lambda oriT+ bacteriophages up to a position between two sequenced oriT- mutations. Small plasmids containing these novel joints are mobilized in trans by pOX38 at frequencies less than 5 X 10(-7) times the mobilization frequencies for similar plasmids that contain oriT. The relations of these findings to the location of the nicking site at oriT are discussed.