Analysis of the zinc finger domain of TnpA, a DNA targeting protein encoded by mobilizable transposon Tn4555

The mobilizable transposon Tn4555, found in Bacteroides spp., is an important antibiotic resistance element encoding a broad spectrum beta-lactamase. Tn4555 is mobilized by conjugative transposons such as CTn341 which can transfer the transposon to a wide range of bacterial species where it integrates into preferred sites on the host chromosome. Selection of the preferred target sites is mediated by a DNA-binding protein TnpA which has a prominent zinc finger motif at the N-terminus of the protein. In this report the zinc finger motif was disrupted by site directed mutagenesis in which two cysteine residues were changed to serine residues. Elemental analysis indicated that the wild-type protein but not the mutated protein was able to coordinate zinc at a molar ration of 1/1. DNA binding electrophoretic mobility shift assays showed that the ability to bind the target site DNA was not significantly affected by the mutation but there was about a 50% decrease in the ability to bind single stranded DNA. Consistent with these results, electrophoretic mobility shift assays incorporating zinc chelators did not have a significant on affect the binding of DNA target. In vivo, the zinc finger mutation completely prevented transposition/integration as measured in a conjugation assay. This was in contrast to results in which a TnpA knockout was still able to insert into host genomes but there was no preferred target site selection. The phenotype of the zinc finger mutation was not effectively rescued by providing wild-type TnpA in trans. Taken together these results indicated that the zinc finger is not required for DNA binding activity of TnpA but that it does have an important role in transposition and it may mediate protein/protein interactions with integrase or other Tn4555 proteins to facilitate insertion into the preferred sites.     

Transposition genes of the Bacteroides mobilizable transposon Tn4555: role of a novel targeting gene

Conjugative transposons have been identified in several bacterial species, most notably the Gram-positive Enterococci and the Gram-negative Bacteroides. In Bacteroides species, these elements encode a complete conjugative machinery, which mediates their own intercellular transfer, and they can mobilize in trans co-resident elements. One such mobilizable element is the antibiotic resistance transposon, Tn4555, which was previously found to integrate into a specific genome target site via a site-specific recombination mechanism. In this work, we demonstrate that three Tn4555 genes were involved in integration of the element. These were int encoding a lambda-type integrase, which was absolutely required for integration of the transposon, and two accessory genes, which increased the frequency of integration. Interestingly, one of these accessory gene products, TnpA, directed the insertion of Tn4555 into the genome target site; in the absence of tnpA, the insertion pattern was essentially random. This is the first example of a site-specific recombinase that uses a specific targeting protein.     

The Transfer Origin for Bacteroides Mobilizable Transposon Tn4555 Is Related to a Plasmid Family from Gram-Positive Bacteria

Conjugal transfer of Bacteroides mobilizable transposon Tn4555 was examined with an Escherichia coli-based assay system. It was shown that mobilization required the cis-acting oriT_Tn region and that the Tn4555 mobA_Tn gene and RK231 must be present in trans. With alkaline agarose gel electrophoresis and filter blot hybridizations, it was shown that at oriT_Tn there was a site- and strand-specific cleavage event that was dependent on mobA_Tn. The 5′ end of this cleavage site was mapped by primer extension, and the nucleotide sequence surrounding the site had homology to a family of oriT nick sites found in mobilizable plasmids of gram-positive bacteria. Removal of the nick site by deletion of 18 bp surrounding the site resulted in a significant loss of transfer activity.     

The Bacteroides mobilizable transposon Tn4555 integrates by a site-specific recombination mechanism similar to that of the gram-positive bacterial element Tn916.

The Bacteroides mobilizable transposon Tn4555 is a 12.2-kb molecule that encodes resistance to cefoxitin. Conjugal transposition is hypothesized to occur via a circular intermediate and is stimulated by coresident tetracycline resistance elements and low levels of tetracycline. In this work, the ends of the transposon were identified and found to consist of 12-bp imperfect inverted repeats, with an extra base at one end. In the circular form, the ends were separated by a 6-bp "coupling sequence" which was associated with either the left or the right transposon terminus when the transposon was inserted into the chromosome. Tn4555 does not duplicate its target site upon insertion. Using a conjugation-based transposition assay, we showed that the coupling sequence originated from 6 bases of genomic DNA flanking either side of the transposon prior to excision. Tn4555 preferentially transposed into a 589-bp genomic locus containing a 207-bp direct repeat. Integration occurred before or after the repeated sequence, with one integration site between the two repeats. These observations are consistent with a transposition model based on site-specific recombination. In the bacteriophage lambda model for site-specific recombination, the bacteriophage recombines with the Escherichia coli chromosome via a 7-bp "crossover" region. We propose that the coupling sequence of Tn4555 is analogous in function to the crossover region of lambda but that unlike the situation in lambda, recombination occurs between regions of nonhomologous DNA. This ability to recombine into divergent target sites is also a feature of the gram-positive bacterial transposon Tn916.     

Site-specificity of the chromosomal insertion of Staphylococcus aureus transposon Tn554

Analysis of 15 strains of Staphylococcus aureus containing the transposon Tn554 by a technique (Southern blotting) involving the hybridization of radioactively labeled Tn554 DNA to restriction endonuclease-digested, gel-electrophoresed, high molecular weight S. aureus DNA, revealed that this transposon was present in the same site in all 15 strains examined. One of these strains contained additional Tn554-specific sequences. Tn554, therefore, seems to be highly site-specific, showing the same blotting pattern among natural isolates and a series of strains constructed by transposition under a variety of conditions. The possible role of phage φ11 in Tn554 intercell transfer is discussed, as are possible mechanisms that could account for this element's site-specificity.     

Identification of a circular intermediate in the transfer and transposition of Tn4555, a mobilizable transposon from Bacteroides spp.

Transmissible cefoxitin (FX) resistance in Bacteroides vulgatus CLA341 was associated with the 12.5-kb, mobilizable transposon, Tn4555, which encoded the beta-lactamase gene cfxA. Transfer occurred by a conjugation-like mechanism, was stimulated by growth of donor cells with tetracycline (TC), and required the presence of a Bacteroides chromosomal Tcr element. Transconjugants resistant to either FX, TC, or both drugs were obtained, but only Fxr Tcr isolates could act as donors of Fxr in subsequent matings. Transfer of Fxr could be restored in Fxr Tcs strains by the introduction of a conjugal Tcr element from Bacteroides fragilis V479-1. A covalently closed circular DNA form of Tn4555 was observed in donor cells by Southern hybridization, and the levels of this circular transposon increased significantly in cells grown with TC. Both the cfxA gene and the Tn4555 mobilization region hybridized to the circular DNA, suggesting that this was a structurally intact transposon unit. Circular transposon DNA purified by CsCl-ethidium bromide density gradient centrifugation was used to transform Tcs B. fragilis 638, and Fxr transformants were obtained. Both the circular form and the integrated Tn4555 were observed in transformants, but the circular form was present at less than one copy per chromosomal equivalent. Examination of genomic DNA from Fxr transformants and transconjugants revealed that Tn4555 could insert at a wide variety of chromosomal sites. Multiple transposon insertions were present in many of the transconjugants, indicating that there was no specific barrier to the introduction of a second transposon copy.     

Direct repeats flanking the Bacteroides transposon Tn4351 are insertion sequence elements.

The clindamycin-erythromycin resistance (Ccr Emr) region of the Bacteroides transposon Tn4351 is flanked by direct repeats. This study showed that the direct repeats are insertion sequence (IS) elements. Although both IS elements can mediate transfer of the chloramphenicol (Cmr) marker on pBR328 by cointegrate formation with the conjugal IncW plasmid R388, IS4351R-mediated transfer of Cmr occurred at a consistently lower frequency than did the transfer mediated by IS4351L. Analysis of plasmids from the resultant transconjugants revealed IS-mediated activities such as deletions, tandem duplication of IS4351L, and excision of IS4351R.     

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.     

转座子Tn917插入位点侧翼序列的扩增

为了克隆到生防菌株的抗病基因,以一株对灰葡萄孢菌表现很高拮抗活性的蜡样芽孢杆菌B-02菌株为材料,利用转座子标签技术得到拮抗性消失的突变体,进而利用TAIL-PCR技术扩增出Tn917插入位点两侧的未知序列,利用生物信息学分析扩增序列,为进一步研究该基因片段与菌株拮抗性之间的关系奠定了基础。     

Distribution of Tn551 insertion sites responsible for auxotrophy on the Staphylococcus aureus chromosome

A method was devised to efficiently select isolates of Staphylococcus aureus 8325 in which Tn551, a transposon originating on the pI258 plasmid responsible for erythromycin resistance (Emr), had translocated to the host chromosome. This method consisted of selecting for Emr at 43 degrees C with a strain in which the pI258 plasmid was unable to replicate at 43 degrees C because of a temperature-sensitive plasmid mutation. By selecting isolates that were Emr at 43 degrees C and auxotrophic for nutrients not required by the parent strain. Tn551-induced auxotrophic mutants were readily isolated. The incidence of auxotrophic classes was not random; 80% of the isolates in one experiment were Trp-, whereas only a single example of each of some of the other classes was isolated. Among the Trp- mutants, the distribution of trp genes affected and the frequency of precise excision of Tn551 from individual sites varied. When analyzed by transformation, the Tn551-induced ala, his, ilv, lys, rib, thrA, thrB, and trp mutations were shown to occupy sites previously defined by nitrosoguanidine-induced mutations. Tn551-induced mutagenesis provided three previously unrecognized classes of auxotrophs (tyr, met, and thrC), and the Tn551 integration sites resulting in these mutations have been identified. In addition, a chromosomal region (uraB) was identified by Tn551 mutagenesis that is distinct from uraA (previously defined by chemical mutagenesis). Some Tn551-induced mutations (most notably pur) could not be linked to the known linkage groups of the chromosome by transformation. With the exception of two pur mutations, all of the Tn551-induced auxotrophic mutational sites cotransformed at unity with Tn551 and, in cases in which they were selected, prototrophic transformants were always Ems. Thus, the Tn551 and auxotrophic sites are identical.     

Virulence-associated chromosomal loci of Shigella flexneri identified by random Tn5 insertion mutagenesis

Shigellae are the causative agents of bacillary dysentery and are capable of invading epithelial cells, multiplying therein and spreading into adjacent cells. To identify genes on the chromosome associated with the virulence phenotype, 9114 independent Tn5 insertion mutants were isolated in a virulent strain of Shigella flexneri. By using an in vitro assay for intercellular spread or an animal infection model, the Serény test, 50 chromosomal Tn5 mutants with reduced virulence were identified. The 50 mutants were characterized with respect to their virulence phenotypes, including three different mutations that affect invasion of epithelial cells, bacterial metabolism and structure of lipopolysaccharide. Mutants with reduced invasive ability were further characterized and it was found that two of them had decreased levels of IpaB, C and D antigens as well as the mRNA for the ipaBCD operon encoded by the large virulence plasmid, suggesting that positive regulatory elements for the ipaBCD operon are encoded by the chromosome. Assignment of the 50 Tn5 insertions of the mutants to the 19 NotI restriction fragments of the chromosomal DNA has permitted the identification of at least nine virulence-associated chromosomal loci.     

Location of sites of transposon Tn916 insertion in the Mycoplasma mycoides genome.

The genome of Mycoplasma mycoides subsp. mycoides GC1176-2 was cleaved into six large fragments by the endonuclease KpnI which also cleaved the transposon Tn916 once. This has allowed genomic mapping of insertion sites for 50 transformants of GC1176-2 containing Tn916. Almost all of the mapped sites were clearly separate. The transformants provide a bank of genomes each with a KpnI site at a different position to facilitate mapping of gene loci.     

Transposon mutagenesis: Cloning of chromosomal DNA from the site of Tn916 insertion using polymerase chain reaction

A protocol that allows fast recovery and further analyses of chromosomal DNA adjacent to the Tn916 site of insertion is described. The procedure is based on single specific primer PCR amplification using restricted chromosomal DNA ligated into a suitable vector. Two primers, one Tn916-specific and the second vector-specific, allow amplification of the chromosomal DNA flanking the site of insertion.     

Evidence for a common mechanism for the insertion of the Tn10 transposon and for the generation of Tn10-stimulated deletions

Summary Mutations in and near the Salmonella typhimurium histidine transport operon were generated by insertion of the translocatable tetracycline-resistance element Tn10. Deletion mutants affecting histidine transport genes were subsequently isolated in several of the Tn10-containing strains. Tn10 insertions in hisJ occurred preferentially at one site, designated site A. This same site was also the preferential endpoint of deletions originating from Tn10 insertions at two neighboring sites. Thus, Tn10 insertion and Tn10-stimulated deletion formation appear to involve a common DNA-recogition step.     

Analysis of secondary,integration sites for IS117 in Streptomyces lividans and their role in the generation of chromosomal deletions

IS117, the 2.6 kb mini-circle of Streptomyces coelicolor A3(2), is a transposable element previously shown to be integrated into two distant sites in the chromosome. When introduced into S. lividans, IS117 integrates into one preferred chromosomal site, but when this site was artificially deleted, IS117 integrated into many secondary sites. Nucleotide sequence analysis of several secondary integration sites revealed varying degrees of similarity with the preferred site, but no consensus sequence. Nevertheless, sites more similar to the preferred site tended to be occupied more often than those that are less similar. Insertion of IS117 into secondary sites in the chromosome of S. lividans sometimes mediated chromosomal rearrangements. It was shown that some strains containing IS117 integrated into secondary sites had suffered deletions of chromosomal DNA. Deletions were adjacent to the inserted element and were at least several kilobases long. The proposed model implicates homologous recombination between IS117 copies integrated into two different secondary sites in the same chromosome as a cause of the deletions.     

Secondary sites for integration mediated by the Tn21 integrase

The integrase encoded by the integron of the transposon Tn21 can mediate the site-specific fusion of two plasmids if there is a recombination hot spot (59 bp element) in one of them and the sequence GWTMW in the other. The use of this latter, loosely defined site explains how antibiotic-resistance genes could first become associated with integrons.     

Tn4351 transposes in Bacteroides spp. and mediates the integration of plasmid R751 into the Bacteroides chromosome.

The gene for resistance to erythromycin and clindamycin, which is carried on the conjugative Bacteroides plasmid, pBF4, has been shown previously to be part of an element (Tn4351) that transposes in Escherichia coli. We have now introduced Tn4351 into Bacteroides uniformis 0061 on the following two suicide vectors: (i) the broad-host-range IncP plasmid R751 (R751::Tn4351) and (ii) pSS-2, a chimeric plasmid which contains 33 kilobases of pBF4 (including Tn4351) cloned into the IncQ plasmid RSF1010 and which is mobilized by R751. When E. coli HB101, carrying either R751::Tn4351 or R751 and pSS-2, was mated with B. uniformis under aerobic conditions, Emr transconjugants were detected at a frequency of 10(-6) to 10(-5) (R751::Tn4351) or 10(-8) to 10(-6) (R751 and pSS-2). In matings involving pSS-2, all Emr transconjugants contained simple insertions of Tn4351 in the chromosome, whereas in matings involving R751::Tn4351, about half of the Emr transconjugants had R751 cointegrated with Tn4351 in the chromosome. Of the Emr transconjugants, 13% were auxotrophs. Bacteroides spp. which had R751 cointegrated with Tn4351 in the chromosome did not transfer R751 or Tn4351 to E. coli HB101 or to isogenic B. uniformis, nor did the intergrated R751 mobilize pE5-2, an E. coli-Bacteroides shuttle vector that contains a transfer origin that is recognized by R751.     

Regional preference of insertion of Tn501 and Tn802 into RP1 and its derivatives

Summary The sites of insertion of Tn501 into RP1 and into derivatives of this plasmid that either lack the Tn801 (TnA) element or contain it in a different location have been determined. Similarly, the sites of insertion of Tn802 into a derivative of RP1 that lacks the Tn801 element and into recombinants of this plasmid with Tn501 were determined. Hot spots for insertion were observed with both transposons; but it is clear that a particular DNA sequence is not sufficient to define a hot spot, since a particular region does contain many insertions when present in one plasmid but does not do so when part of another.     

Insertion and excision of Bacteroides conjugative chromosomal elements.

Many strains of Bacteroides harbor large chromosomal elements that can transfer themselves from the chromosome of the donor to the chromosome of the recipient. Most of them carry a tetracycline resistance (Tcr) gene and have thus been designated Tcr elements. In the present study, we have used transverse alternating field electrophoresis to show that all but one of the Tcr elements screened were approximately 70 to 80 kbp in size. The exception (Tcr Emr 12256) was 150 to 200 kbp in size and may be a hybrid element. All of the Tcr elements inserted in more than one site, but insertion was not random. The Tcr elements sometimes cotransfer unlinked chromosomal segments, or nonreplicating Bacteroides units (NBUs). Transverse alternating field electrophoresis analysis showed that insertion of NBUs was not random and that the NBUs did not insert near the Tcr element. Although attempts to clone one or both ends of a Tcr element have not been successful, ends of a cryptic element (XBU4422) were cloned previously and shown to be homologous to the ends of Tcr elements. We have obtained DNA sequences of junction regions between XBU4422 and its target from several different insertions. Comparison of junction sequences with target sequences showed that no target site duplication occurred during insertion and that XBU4422 carried 4 to 5 bp of adjacent chromosomal DNA when it excised from the chromosome and inserted in a plasmid. We identified a short region of sequence similarity between one of the ends of XBU4422 and its target site that may be important for insertion. This sequence contained an 8-bp segment that was identical to the recombinational hot spot sequence on Tn21. XBU4422 could exise itself from plasmids into which it inserted. In most cases, the excision left a single additional A behind in the target site, but precise excision was seen in one case.     

Multicopy integration of mini‐Tn7 transposons into selected chromosomal sites of a Salmonella vaccine strain

Chromosomal integration of expression modules for transgenes is an important aspect for the development of novel Salmonella vectors. Mini‐Tn7 transposons have been used for the insertion of one such module into the chromosomal site attTn7, present only once in most Gram‐negative bacteria. However, integration of multiple mini‐Tn7 copies might be suitable for expression of appropriate amounts of antigen or combination of different modules. Here we demonstrate that integration of a 9.6 kb mini‐Tn7 harbouring the luciferase luxCDABE (lux) occurs at the natural attTn7 site and simultaneously other locations of the Salmonella chromosome, which were engineered using λ‐Red recombinase to contain one or two additional artificial attTn7 sites (a‐attTn7). Multicopy integration even at closely spaced attTn7 sites was unexpected in light of the previously reported distance‐dependent Tn7 target immunity. Integration of multiple copies of a mini‐Tn7 containing a gfp cassette resulted in increasing green fluorescence of bacteria. Stable consecutive integration of two mini‐Tn7 encoding lacZ and lux was achieved by initial transposition of lacZ‐mini‐Tn7, subsequent chromosomal insertion of a‐attTn7 and a second round of transposition with lux‐mini‐Tn7. Mini‐Tn7 thus constitutes a versatile method for multicopy integration of expression cassettes into the chromosome of Salmonella and possibly other bacteria.