Characterization of a Bacteroides mobilizable transposon, NBU2, which carries a functional lincomycin resistance gene

The mobilizable Bacteroides element NBU2 (11 kbp) was found originally in two Bacteroides clinical isolates, Bacteroides fragilis ERL and B. thetaiotaomicron DOT. At first, NBU2 appeared to be very similar to another mobilizable Bacteroides element, NBU1, in a 2.5-kbp internal region, but further examination of the full DNA sequence of NBU2 now reveals that the region of near identity between NBU1 and NBU2 is limited to this small region and that, outside this region, there is little sequence similarity between the two elements. The integrase gene of NBU2, intN2, was located at one end of the element. This gene was necessary and sufficient for the integration of NBU2. The integrase of NBU2 has the conserved amino acids (R-H-R-Y) in the C-terminal end that are found in members of the lambda family of site-specific integrases. This was also the only region in which the NBU1 and NBU2 integrases shared any similarity (28% amino acid sequence identity and 49% sequence similarity). Integration of NBU2 was site specific in Bacteroides species. Integration occurred in two primary sites in B. thetaiotaomicron. Both of these sites were located in the 3' end of a serine-tRNA gene NBU2 also integrated in Escherichia coli, but integration was much less site specific than in B. thetaiotaomicron. Analysis of the sequence of NBU2 revealed two potential antibiotic resistance genes. The amino acid sequences of the putative proteins encoded by these genes had similarity to resistances found in gram-positive bacteria. Only one of these genes was expressed in B. thetaiotaomicron, the homolog of linA, a lincomycin resistance gene from Staphylococcus aureus. To determine how widespread elements related to NBU1 and NBU2 are in Bacteroides species, we screened 291 Bacteroides strains. Elements with some sequence similarity to NBU2 and NBU1 were widespread in Bacteroides strains, and the presence of linA(N) in Bacteroides strains was highly correlated with the presence of NBU2, suggesting that NBU2 has been responsible for the spread of this gene among Bacteroides strains. Our results suggest that the NBU-related elements form a large and heterogeneous family, whose members have similar integration mechanisms but have different target sites and differ in whether they carry resistance genes.     

NBU1, a mobilizable site-specific integrated element from Bacteroides spp., can integrate nonspecifically in Escherichia coli.

NBU1 is an integrated Bacteroides element that can he mobilized from Bacteroides donors to Bacteroides recipients. Previous studies have shown that a plasmid carrying the internal mobilization region of NBU1 could be transferred by conjugation from Bacteroides thetaiotaomicron to Escherichia coli. In this report, we show that NBU1 can integrate in E. coli. Whereas integration of NBU1 in B. thetaiotaomicron is site specific, integration of NBU1 in E. coli was relatively random, and the insertion frequency of NBU1 into the E. coli chromosome was 100 to 1,000 times lower than the frequency of integration in B. thetaiotaomicron. The frequency of NBU1 integration in E. coli could be increased about 10- to 70-fold, to a value close to that seen with B. thetaiotaomicron, if the primary integration site from B. thetaiotaomicron, BT1-1, was provided on a plasmid in the E. coli recipient or the NBU1 integrase gene, intN1, was provided on a high-copy-number plasmid to increase the amount of integrase available in the recipient. When the primary integration site was available in the recipient, NBU1 integrated site specifically in E. coli. Our results show that NBUs have a very broad host range and are capable of moving from Bacteroides spp. to distantly related species such as E. coli. Moreover, sequence analysis of NBU1 integration sites provided by integration events in E. coli has helped to identify some regions of the NBU1 attachment site that may play a role in the integration process.     

NBU1 integrase: evidence for an altered recombination mechanism

NBU1 is a 10.3 kbp Bacteroides mobilizable transposon. A previous study had identified a 2.7 kbp segment of the excised circular intermediate that was sufficient to mediate integration of the element after transfer. This segment contained an integrase gene, intN1, and a region spanning the ends of the circular form within which integration occurred (attN1). The integrase protein, IntN1, appeared to be a member of the tyrosine recombinase family because it contains the canonical C-terminal RKHRHY [RK(H/K)R(H/W)Y] motif that characterizes members of that family. In this study, we describe an Escherichia coli-based integration assay system that has allowed us to characterize attN1 in detail. We first localized attN1 to a 250 bp region. We then used site-directed mutations to identify directly repeated sequences within attN1 that were required for site-specific integration. The locus of NBU1 site-specific integration in the Bacteroides thetaiotaomicron chromosome, attBT1-1, contains a 14 bp sequence that is identical to a 14 bp sequence that spans the joined ends of the NBU1 attN1 site (common core sequences). The effects of mutations in the common core were different from the expected results if NBU1 integration was similar to lambda integration. In particular single base changes near one end of the common core region, which introduced heterology, actually increased the frequency of integration. By contrast, compensating changes that restored homology in the common core region reduced the integration frequency. The recombination mechanism also differs from the one used by conjugative transposons that have coupling sequences between the sites of strand cleavage and exchange. These results indicate that although NBU1 integrase is considered to be a member of the tyrosine recombinase family, it catalyses an integrative recombination reaction that occurs by a different crossover mechanism.     

Excision, transfer, and integration of NBU1, a mobilizable site-selective insertion element.

The Bacteroides species harbor a family of conjugative transposons called tetracycline resistance elements (Tcr elements) that transfer themselves from the chromosome of a donor to the chromosome of a recipient, mobilize coresident plasmids, and also mediate the excision and circularization of members of a family of 10- to 12-kbp insertion elements which share a small region of DNA homology and are called NBUs (for nonreplicating Bacteroides units). The NBUs are sometimes cotransferred with Tcr elements, and it was postulated previously that the excised circular forms of the NBUs were plasmidlike forms and were transferred like plasmids and then integrated into the recipient chromosome. We used chimeric plasmids containing one of the NBUs, NBU1, and a Bacteroides-Escherichia coli shuttle vector to show that this hypothesis is probably correct. NBU1 contained a region that allowed mobilization by both the Tcr elements and IncP plasmids, and we used these conjugal elements to allow us to estimate the frequencies of excision, mobilization, and integration of NBU1 in Bacteroides hosts to be approximately 10(-2), 10(-5) to 10(-4), and 10(-2), respectively. Although functions on the Tcr elements were required for the excision-circularization and mobilization of NBU1, no Tcr element functions were required for integration into the recipient chromosome. Analysis of the DNA sequences at the integration region of the circular form of NBU1, the primary insertion site in the Bacteroides thetaiotaomicron 5482 chromosome, and the resultant NBU1-chromosome junctions showed that NBU1 appeared to integrate into the primary insertion site by recombining within an identical 14-bp sequence present on both NBU1 and the target, thus leaving a copy of the 14-bp sequence at both junctions. The apparent integration mechanism and the target selection of NBU1 were different from those of both XBU4422, the only member of the conjugal Tcr elements for which these sequences are known, and Tn4399, a mobilizable Bacteroides transposon. The NBUs appear to be a distinct type of mobilizable insertion element.     

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.     

Construction and characterization of a Bacteroides thetaiotaomicron recA mutant: transfer of Bacteroides integrated conjugative elements is RecA independent.

We report the construction and analysis of a Bacteroides thetaiotaomicron recA disruption mutant and an investigation of whether RecA is required for excision and integration of Bacteroides mobile DNA elements. The recA mutant was deficient in homologous recombination and was more sensitive than the wild-type strain to DNA-damaging agents. The recA mutant was also more sensitive to oxygen than the wild type, indicating that repair of DNA contributes to the aerotolerance of B. thetaiotaomicron. Many Bacteroides clinical isolates carry self-transmissible chromosomal elements known as conjugative transposons. These conjugative transposons can also excise and mobilize in trans a family of unlinked integrated elements called nonreplicating Bacteroides units (NBUs). The results of a previous study had raised the possibility that RecA plays a role in excision of Bacteroides conjugative transposons, but this hypothesis could not be tested in Bacteroides spp. because no RecA-deficient Bacteroides strain was available. We report here that the excision and integration of the Bacteroides conjugative transposons, as well as NBU1 and Tn4351, were unaffected by the absence of RecA activity.     

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).     

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.     

Conjugative transposition of Tn916 requires the excisive and integrative activities of the transposon-encoded integrase.

Transposon Tn916 is a 16.4-kb broad-host-range conjugative transposon originally detected in the chromosome of Enterococcus faecalis DS16. Transposition of Tn916 and related transposons involves excision of a free, nonreplicative, covalently closed circular intermediate that is substrate for integration. Excisive recombination requires two transposon-encoded proteins, Xis-Tn and Int-Tn, whereas the latter protein alone is sufficient for integration. Here we report that conjugative transposition of Tn916 requires the presence of a functional integrase in both donor and recipient strains. We have constructed a mutant, designated Tn916-int1, by replacing the gene directing synthesis of Int-Tn by an allele inactivated in vitro. In mating experiments, transfer of Tn916-int1 from Bacillus subtilis to E. faecalis was detected only when the transposon-encoded integrase was supplied by trans-complementation in both the donor and the recipient. These results suggest that conjugative transposition of Tn916 requires circularization of the element in the donor followed by transfer and integration of the nonreplicative intermediate in the recipient.     

Identification of genes required for excision of CTnDOT, a Bacteroides conjugative transposon

Integrated self-transmissible elements called conjugative transposons have been found in many different bacteria, but little is known about how they excise from the chromosome to form the circular intermediate, which is then transferred by conjugation. We have now identified a gene, exc, which is required for the excision of the Bacteroides conjugative transposon, CTnDOT. The int gene of CTnDOT is a member of the lambda integrase family of recombinases, a family that also contains the integrase of the Gram-positive conjugative transposon Tn916. The exc gene was located 15 kbp from the int gene, which is located at one end of the 65 kbp element. The exc gene, together with the regulatory genes, rteA, rteB and rteC, were necessary to excise a miniature form of CTnDOT that contained only the ends of the element and the int gene. Another open reading frame (ORF) in the same operon and upstream of exc, orf3, was not essential for excision and had no significant amino acid sequence similarity to any proteins in the databases. The deduced amino acid sequence of the CTnDOT Exc protein has significant similarity to topoisomerases. A small ORF (orf2) that could encode a small, basic protein comparable with lambda and Tn916 excision proteins (Xis) was located immediately downstream of the CTnDOT int gene. Although Xis proteins are required for excision of lambda and Tn916, orf2 had no effect on excision of the element. Excision of the CTnDOT mini-element was not affected by the site in which it was integrated, another difference from Tn916. Our results demonstrate that the Bacteroides CTnDOT excision system is tightly regulated and appears to be different from that of any other known integrated transmissible element, including those of some Bacteroides mobilizable transposons that are mobilized by CTnDOT.     

Characterization of a new type of Bacteroides conjugative transposon, Tcr Emr 7853.

Results of previous investigations suggested that the conjugative transposons found in human colonic Bacteroides species were all members of a closely related family of elements, exemplified by Tcr Emr DOT. We have now found a new type of conjugative transposon, Tcr Emr 7853, that does not belong to this family. Tcr Emr 7853 has approximately the same size as the Tcr Emr DOT-type elements (70 to 80 kbp) and also carries genes encoding resistance to tetracycline (Tcr) and erythromycin (Emr); however, it differs from previously described conjugative transposons in a number of ways. Its transfer is not regulated by tetracycline and its transfer genes are not controlled by the regulatory genes rteA and rteB, which are found on Tcr Emr DOT and related conjugative transposons. Its ends do not cross-hybridize with the ends of Tcr Emr DOT-type conjugative transposons, and the Emr gene it carries does not cross-hybridize with ermF, the Emr gene found on all previously studied Bacteroides conjugative transposons. There is only one region with high sequence similarity between Tcr Emr 7853 and previously characterized elements, the region that contains the Tcr gene, tetQ. This sequence similarity ends 145 bp upstream of the start codon and 288 bp downstream from the stop codon. A 2-kbp region upstream of tetQ on Tcr Emr 7853 cross-hybridized with four additional EcoRV fragments of Bacteroides thetaiotaomicron 7853 DNA other than the one that contained tetQ. These additional cross-hybridizing bands were not part of Tcr Emr 7853, but one of them cotransferred with Tcr Emr 7853 in some matings. Thus, at least one of the additional cross-hybridizing bands may be associated with another conjugative element or with an element that is mobilized by Tcr Emr 7853. DNA that cross-hybridized with the upstream region was found in one clinical isolate of Bacteroides ovatus and four Tcr isolates of Prevotella ruminicola.     

Tetrameric structure of a serine integrase catalytic domain

The serine integrases have recently emerged as powerful new chromosome engineering tools in various organisms and show promise for therapeutic use in human cells. The serine integrases are structurally and mechanistically unrelated to the bacteriophage lambda integrase but share a similar catalytic domain with the resolvase/invertase enzymes typified by the resolvase proteins from transposons Tn3 and gammadelta. Here we report the crystal structure and solution properties of the catalytic domain from bacteriophage TP901-1 integrase. The protein is a dimer in solution but crystallizes as a tetramer that is closely related in overall architecture to structures of activated gammadelta-resolvase mutants. The ability of the integrase tetramer to explain biochemical experiments performed in the resolvase and invertase systems suggests that the TP901 integrase tetramer represents a unique intermediate on the recombination pathway that is shared within the serine recombinase superfamily.     

Challenging a Paradigm: the Role of DNA Homology in Tyrosine Recombinase Reactions

Summary: A classical feature of the tyrosine recombinase family of proteins catalyzing site-specific recombination, as exemplified by the phage lambda integrase and the Cre and Flp recombinases, is the ability to recombine substrates sharing very limited DNA sequence identity. Decades of research have established the importance of this short stretch of identity within the core regions of the substrates. Since then, several new enzymes that challenge this paradigm have been discovered and require the role of sequence identity in site-specific recombination to be reconsidered. The integrases of the conjugative transposons such as Tn916, Tn1545, and CTnDOT recombine substrates with heterologous core sequences. The integrase of the mobilizable transposon NBU1 performs recombination more efficiently with certain core mismatches. The integration of CTX phage and capture of gene cassettes by integrons also occur by altered mechanisms. In these systems, recombination occurs between mismatched sequences by a single strand exchange. In this review, we discuss literature that led to the formulation of the current strand-swapping isomerization model for tyrosine recombinases. The review then focuses on recent developments on the recombinases that challenged the paradigm that was derived from the studies of early systems.     

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.     

Characterization of a novel integrative element, ICESt1, in the lactic acid bacterium Streptococcus thermophilus

The 35.5-kb ICESt1 element of Streptococcus thermophilus CNRZ368 is bordered by a 27-bp repeat and integrated into the 3' end of a gene encoding a putative fructose-1,6-biphosphate aldolase. This element encodes site-specific integrase and excisionase enzymes related to those of conjugative transposons Tn5276 and Tn5252. The integrase was found to be involved in a site-specific excision of a circular form. ICESt1 also encodes putative conjugative transfer proteins related to those of the conjugative transposon Tn916. Therefore, ICESt1 could be or could be derived from an integrative conjugative element.     

A multicomponent system is required for tetracycline-induced excision of Tn4555

Bacteroides spp. are the predominant organisms in the intestinal tract, and they also are important opportunistic pathogens. Antibiotic therapy of Bacteroides infections often is complicated by the prevalence of drug-resistant organisms which acquire resistance genes from a variety of mobile genetic elements including conjugative transposons (CTns) and mobilizable transposons (MTns). Tn4555 is an MTn that encodes beta-lactam resistance, and it is efficiently mobilized by the Bacteroides CTns via a tetracycline (TET)-inducible mechanism. In this study a model system with CTn341 and a Tn4555 minielement was used to examine Tn4555 excision from the chromosome. Using PCR and mobilization assays it was established that excision was stimulated by TET in the presence of CTn341. In order to determine which Tn4555 genes were required for excision, int, tnpA, tnpC, xis, and mobA mutants were examined. The results indicated that int plus two additional genes, tnpC and xis, were required for optimal excision. In addition, there was no requirement for the mobA gene, as had been shown for another MTn, NBU1. The Xis protein sequence is related to a family of plasmid excisionases, but the TnpC gene product did not match anything in the sequence databases. Evidence also was obtained that suggested that Xis is involved in the control of TET-induced excision and in control of mobilization by CTn341. Overall, these results indicate that excision of MTns is a complex process that requires multiple gene products.     

Integration and excision of a newly discovered bacteroides conjugative transposon, CTnBST

Conjugative transposons (CTns) are major contributors to the spread of antibiotic resistance genes among Bacteroides species. CTnBST, a newly discovered Bacteroides conjugative transposon, carries an erythromycin resistance gene, ermB, and previously has been estimated to be about 100 kbp in size. We report here the locations and sequencing of both of its ends. We have also located and sequenced the gene that catalyzes the integration of CTnBST, intBST. The integrase gene encodes a 377-amino-acid protein that has the C-terminal R-K-H-R-H-Y motif that is characteristic of members of the tyrosine recombinase family of integrases. DNA sequence comparisons of the ends of CTnBST, the joined ends of the circular intermediate, and the preferred site into which the circular form of CTnBST had integrated revealed that the preferred integration site (attB1) contained an 18-bp sequence of identity to the crossover region, attBST, on CTnBST. Although this site was used in about one-half of the integration events, sequence analysis of these integration events revealed that both CTnBST and a miniature form of CTnBST (miniBST) integrated into a variety of other sites in the chromosome. All of the sites had two conserved regions, AATCTG and AAAT. These two regions flanked a 2-bp sequence, bp 10 and bp 11 of the 18-bp sequence, that varied in some of the different sites and sometimes in the attBST sequences. Our results suggest that CTnBST integrates site selectively and that the crossover appears to occur within a 12-bp region that contains the two regions of conserved sequences.     

Broad host range gene transfer: plasmids and conjugative transposons

Abstract Conjugation is the primary route of broad host range DNA transfer between different genera of bacteria. Plasmids are the most familiar conjugative elements, but there are also self-transmissible integrated elements called conjugative transposons. Conjugative transposons have been found in many genera of gram-positive bacteria, in mycoplasmas and in gram negative bacteria such as Bacteriodes spp. and Moraxella spp., and they have a very broad host range. The best-studied conjugative transposons are: the ones related to Tn 916 , a 16 kb conjugative transposon found originally in Gram-positive bacteria; Tn 5276 , a 70 kb conjugative transposon from Lactococcus lactis ; and a group of large (> 70 kb) conjugative transposons found in Bacteroides spp. Transfer of conjugative transposons takes place in three steps: excision to form a circular intermediate, transfer of one strand of the circular intermediate to a recipient, and integration into the recipient genome. Some conjugative transposons integrate almost randomly, whereas other integrate site-specifically. Conjugative transposons not only transfer themselves but also mobilize co-resident plasmids, either by providing transfer functions in trans or by inserting themselves into the plasmid. In addition, the conjugative transposons found in Bacteroides spp. can excise and mobilize unlinked integrated elements, called NBUs. Transfer of many of the Bacteroides conjugative transposons is regulated by tetracycline, whereas transfer of Tn 916 and other conjugative transposons appears to be constitutive. The conjugative transposons are clearly widespread in clinical isolates, but their distribution in environmental isolates remains to be determined.     

Characterization of the 13-kilobase ermF region of the Bacteroides conjugative transposon CTnDOT

The conjugative transposon CTnDOT is virtually identical over most of its length to another conjugative transposon, CTnERL, except that CTnDOT carries an ermF gene that is not found on CTnERL. In this report, we show that the region containing ermF appears to consist of a 13-kb chimera composed of at least one class I composite transposon and a mobilizable transposon (MTn). Although the ermF region contains genes also carried on Bacteroides transposons Tn4351 and Tn4551, it does not contain the IS4351 element which is found on these transposons. In CTnDOT, insertion of the ermF region occurred near a stem-loop structure at the end of orf2, an open reading frame located immediately downstream of the integrase (int) gene of CTnDOT, and in a region known to be important for excision of CTnERL and CTnDOT. The chimera that comprises the ermF region can apparently no longer excise and circularize, but it contains a functional mobilization region related to that described for the Bacteroides MTn Tn4399. Analysis of 19 independent Bacteroides isolates showed that the ermF region is located in the same position in all of the strains analyzed and that the compositions of the ermF region are almost identical in these strains. Therefore, it appears that CTnDOT-like elements present in community and clinical isolates of Bacteroides were derived from a common ancestor and proliferated in the diverse Bacteroides population.     

Integration and excision of a Bacteroides conjugative transposon, CTnDOT

Bacteroides conjugative transposons (CTns) are thought to transfer by first excising themselves from the chromosome to form a nonreplicating circle, which is then transferred by conjugation to a recipient. Earlier studies showed that transfer of most Bacteroides CTns is stimulated by tetracycline, but it was not known which step in transfer is regulated. We have cloned and sequenced both ends of the Bacteroides CTn, CTnDOT, and have used this information to examine excision and integration events. A segment of DNA that contains the joined ends of CTnDOT and an adjacent open reading frame (ORF), intDOT, was necessary and sufficient for integration into the Bacteroides chromosome. Integration of this miniature form of the CTn was not regulated by tetracycline. Excision of CTnDOT and formation of the circular intermediate were detected by PCR, using primers designed from the end sequences. Sequence analysis of the PCR products revealed that excision and integration involve a 5-bp coupling sequence-type mechanism possibly similar to that used by CTn Tn916, a CTn found originally in enterococci. PCR analysis also demonstrated that excision is a tetracycline-regulated step in transfer. The integrated minielement containing intDOT and the ends of CTnDOT did not excise, nor did a larger minielement that also contained an ORF located immediately downstream of intDOT designated orf2. Thus, excision involves other genes besides intDOT and orf2. Both intDOT and orf2 were disrupted by single-crossover insertions. Analysis of the disruption mutants showed that intDOT was essential for excision but orf2 was not. Despite its proximity to the integrase gene, orf2 appears not to be essential for excision.