Tn5053 family transposons are res site hunters sensing plasmidal res sites occupied by cognate resolvases

DNA sequence database search revealed that most of Tn5053/Tn402 family transposons inserted into natural plasmids were located in putative res regions upstream of genes encoding various resolvase-like proteins. Some of these resolvase genes belonged to Tn3 family transposons and were closely related to the tnpR genes of Tn1721 and a recently detected Tn5044. Using recombinant plasmids containing fragments of Tn1721 or Tn5044 as targets in transposition experiments, we have demonstrated that Tn5053 displays striking insertional preference for the res regions of these transposons: more than 70% of Tn5053 insertion events occur in clusters inside the target res regions, while most remaining insertion events occur no further than 200 base pairs away from both sides of the res regions. We demonstrate that Tn5053 insertions (both into and outside a res region of the target plasmid) require the presence of a functional cognate resolvase gene either in cis or in trans. To our knowledge, this is the first case when a site-specific recombination system outside a transposon has been shown to be involved in transposition.     

Analysis of insertions of the determinant of drug resistance to kanamycin and chloramphenicol into bacteriophage lambda att80

The insertion sites of elements Tn9 and Tn601 which determine chloramphenicol and kanamycin resistance have been detected restriction analysis. The functioning of transposons i.e. their stability or instability, has been found to influence the specificity of their insertions into the genome of lambda att80 bacteriophage. During transposition from stable integration sites both transposons are inserted into the regions of the lambda att80 bacteriophage genome, definite for each transposon. However, during transposition from the site of unstable integration both determinants of drug resistance are inserted into different regions of the phage genome.     

Transposition of Tn5096 and other IS493 derivatives in Streptomyces griseofuscus.

Tn5096 was constructed by inserting an apramycin resistance gene, aac(3)IV, into IS493 from Streptomyces lividans. By using conventional and pulsed-field gel electrophoresis, Tn5096 and related transposons were shown to insert into many different locations in the Streptomyces griseofuscus chromosome and in two linear plasmids. On insertion into the target site CANTg, 3 bp appeared to be duplicated. Independent transpositions were obtained by delivery of the transposon from a temperature-sensitive plasmid. The frequency of auxotrophy among cultures containing transpositions was about 0.2%.     

Target site choice of the related transposable elements Tc1 and Tc3 of Caenorhabditis elegans.

We have investigated the target choice of the related transposable elements Tc1 and Tc3 of the nematode C. elegans. The exact locations of 204 independent Tc1 insertions and 166 Tc3 insertions in an 1 kbp region of the genome were determined. There was no phenotypic selection for the insertions. All insertions were into the sequence TA. Both elements have a strong preference for certain positions in the 1 kbp region. Hot sites for integration are not clustered or regularly spaced. The orientation of the integrated transposon has no effect on the distribution pattern. We tested several explanations for the target site preference. If simple structural features of the DNA (e.g. bends) would mark hot sites, we would expect the patterns of the two related transposons Tc1 and Tc3 to be similar; however we found them to be completely different. Furthermore we found that the sequence at the donor site has no effect on the choice of the new insertion site, because the insertion pattern of a transposon that jumps from a transgenic donor site is identical to the insertion pattern of transposons jumping from endogenous genomic donor sites. The most likely explanation for the target choice is therefore that the primary sequence of the target site is recognized by the transposase. However, alignment of the Tc1 and Tc3 integration sites does not reveal a strong consensus sequence for either transposon.     

A novel type of transposon generated by insertion element Is102 present in a psc101 derivative

We describe a novel type of transposon in the tetracycline resistance plasmid pYM103, a derivative of pSC101 carrying a single copy of an insertion element IS102. The new transposons we found were identified as DNA segments, approximately 6 kb (Tn1021) and 10 kb (Tn1022) in length, able to mediate the cointegration of pYM1O3 with plasmid Col E1. The resulting cointegrate contains either of these pYM1O3 segments duplicated in a direct orientation at the junctions of the parent plasmids. A direct duplication of a 9 bp sequence at the target site in Col E1 is found at the junctions for cointegration. Both transposons have IS1O2 at one end and also contain different lengths of the pYM103 DNA adjacent to IS102, including the tetracycline resistance gene. Each transposon contains terminal inverted repeats of a short nucleotide sequence. These results and the fact that IS102 can itself mediate plasmid cointegration, giving rise to a duplication of a 9 bp target sequence, indicate that IS102 is responsible for generation of Tn1021 and Tn1022. They are quite different from the common IS-associated transposons, which are always flanked by two copies of an IS element, and may be similar to transposons such as those of the Tn3 family and phage Mu.     

Use of transposon-transposase complexes to create stable insertion mutant strains of Francisella tularensis LVS

Francisella tularensis is a highly virulent zoonotic bacterial pathogen capable of infecting numerous different mammalian species, including humans. Elucidation of the pathogenic mechanisms of F. tularensis has been hampered by a lack of tools to genetically manipulate this organism. Herein we describe the use of transposome complexes to create insertion mutations in the chromosome of the F. tularensis live vaccine strain (LVS). A Tn5-derived transposon encoding kanamycin resistance and lacking a transposase gene was complexed with transposase enzyme and transformed directly into F. tularensis LVS by electroporation. An insertion frequency of 2.6 x 10(-8) +/- 0.87 x 10(-8) per cell was consistently achieved using this method. There are 178 described Tn5 consensus target sites distributed throughout the F. tularensis genome. Twenty-two of 26 transposon insertions analyzed were within known or predicted open reading frames, but none of these insertions was associated with the Tn5 target site. Analysis of the insertions of sequentially passed strains indicated that the transposons were maintained stably at the initial insertion site after more than 270 generations. Therefore, transformation by electroporation of Tn5-based transposon-transposase complexes provided an efficient mechanism for generating random, stable chromosomal insertion mutations in F. tularensis.     

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.     

DNA sequences of and complementation by the tnpR genes of Tn21, Tn501 and Tn1721

DNA sequences that encode the tnpR genes and internal resolution (res) sites of transposons Tn21 and Tn501, and the res site and the start of the tnpR gene of Tn1721 have been determined. There is considerable homology between all three sequences. The homology between Tn21 and Tn501 extends further than that between Tn1721 and Tn501 (or Tn21), but in the homologous regions, Tn1721 is 93% homologous with Tn501, while Tn21 is only 72-73% homologous. The tnpR genes of Tn21 and Tn501 encode proteins of 186 amino acids which show homology with the tnpR gene product of Tn3 and with other enzymes that carry out site-specific recombination. However, in all three transposons, and in contrast to Tn3, the tnpR gene is transcribed towards tnpA gene, and the res site is upstream of both. The res site of Tn3 shows no obvious homology with the res regions of these three transposons. Just upstream of the tnpR gene and within the region that displays common homology between the three elements, there is a 50 bp deletion in Tn21, compared to the other two elements. A TnpR- derivative of Tn21 was complemented by Tn21, Tn501 and Tn1721, but not by Tn3.     

Four genes, two ends, and a res region are involved in transposition of Tn5053: a paradigm for a novel family of transposons carrying either a mer operon or an integron

The complete nucleotide sequence of an 8447 bp-long mercury-resistance transposon (Tn 5053 ) has been determined. Tn 5053 is composed of two modules: (i) the mercury-resistance module and (ii) the transposition module. The mercury-resistance module carries a mer operon, merRTPFAD , and appears to be a single-ended relic of a transposon closely related to the classical mercury-resistance transposons Tn 21 and Tn 501 . The transposition module of Tn 5053 is bounded by 25 bp terminal inverted repeats and contains four genes involved in transposition, i.e. tniA, tniB, tniQ , and tniR . Transposition of Tn 5053 occurs via cointegrate formation mediated by the products of the tniABQ genes, followed by site-specific cointegrate resolution. This is catalysed by the product of the tniR gene at the res region, which is located upstream of tniR . The same pathway of transposition is used by Tn 402 (Tn 5090 ) which carries the integron of R751. Transposition genes of Tn 5053 and Tn 402 are interchangeable. Sequence analysis suggests that Tn 5053 and Tn 402 are representatives of a new family of transposable elements, which fall into a recently recognized superfamily of transposons including retroviruses, insertion sequences of the IS 3 family, and transposons Tn 552 and Tn 7 . We suggest that the tni genes were involved in the dissemination of integrons.     

Mu Transposon Insertion Sites and Meiotic Recombination Events Co-Localize with Epigenetic Marks for Open Chromatin across the Maize Genome

The Mu transposon system of maize is highly active, with each of the ∼50–100 copies transposing on average once each generation. The approximately one dozen distinct Mu transposons contain highly similar ∼215 bp terminal inverted repeats (TIRs) and generate 9-bp target site duplications (TSDs) upon insertion. Using a novel genome walking strategy that uses these conserved TIRs as primer binding sites, Mu insertion sites were amplified from Mu stocks and sequenced via 454 technology. 94% of ∼965,000 reads carried Mu TIRs, demonstrating the specificity of this strategy. Among these TIRs, 21 novel Mu TIRs were discovered, revealing additional complexity of the Mu transposon system. The distribution of >40,000 non-redundant Mu insertion sites was strikingly non-uniform, such that rates increased in proportion to distance from the centromere. An identified putative Mu transposase binding consensus site does not explain this non-uniformity. An integrated genetic map containing more than 10,000 genetic markers was constructed and aligned to the sequence of the maize reference genome. Recombination rates (cM/Mb) are also strikingly non-uniform, with rates increasing in proportion to distance from the centromere. Mu insertion site frequencies are strongly correlated with recombination rates. Gene density does not fully explain the chromosomal distribution of Mu insertion and recombination sites, because pronounced preferences for the distal portion of chromosome are still observed even after accounting for gene density. The similarity of the distributions of Mu insertions and meiotic recombination sites suggests that common features, such as chromatin structure, are involved in site selection for both Mu insertion and meiotic recombination. The finding that Mu insertions and meiotic recombination sites both concentrate in genomic regions marked with epigenetic marks of open chromatin provides support for the hypothesis that open chromatin enhances rates of both Mu insertion and meiotic recombination.     

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.     

Localization of insertion into E. coli chromosome of Tn7-like transposons controlling resistance to trimethoprim and streptothricin

To localize the insertion sites for Tn7-like transposons Tn1824, Tn1825 and Tn1826 the EcoRI-cleaved fragments of E. coli recA+ and recA- strains chromosome carrying the transposons were hybridized. It was shown that transposition of Tn7-like elements takes place in the strictly defined region of E. coli chromosome, like it had been previously described for transposon Tn7.     

Microarray analysis of Mu transposition in Salmonella enterica, serovar Typhimurium: transposon exclusion by high-density DNA binding proteins

All organisms contain transposons with the potential to disrupt and rearrange genes. Despite the presence of these destabilizing sequences, some genomes show remarkable stability over evolutionary time. Do bacteria defend the genome against disruption by transposons? Phage Mu replicates by transposition and virtually all genes are potential insertion targets. To test whether bacteria limit Mu transposition to specific parts of the chromosome, DNA arrays of Salmonella enterica were used to quantitatively measure target site preference and compare the data with Escherichia coli. Essential genes were as susceptible to transposon disruption as non‐essential ones in both organisms, but the correlation of transposition hot spots among homologous genes was poor. Genes in highly transcribed operons were insulated from transposon mutagenesis in both organisms. A 10 kb cold spot on the pSLT plasmid was near parS, a site to which the ParB protein binds and spreads along DNA. Deleting ParB erased the plasmid cold spot, and an ectopic parS site placed in the Salmonella chromosome created a new cold spot in the presence of ParB. Our data show that competition between cellular proteins and transposition proteins on plasmids and the chromosome is a dominant factor controlling the genetic footprint of transposons in living cells.     

Nucleotide sequences at the ends of the mercury resistance transposon, Tn501.

The nucleotide sequences at the ends of the mercury-resistance transposon, Tn501, have been determined. The terminal sequences are inverted repeated sequences 38 nucleotide pairs in length, which differ in 3 nucleotide pairs. The transposon is flanked by directly repeated sequences of 5 nucleotide pairs, originating from a single pentanucleotide sequence in the recipient replicon. There is no obvious homology between recipient replicons at the site of insertion of the transposon. The structures of the ends of Tn501 are compared with those of other transposons and insertion sequences. The use of Tn501 to locate an EcoRI site within a genetically defined sequence of interest is discussed.     

DNA sequence analysis of the transposon Tn3: three genes and three sites involved in transposition of Tn3.

The complete nucleotide sequence of the transposon Tn3 and of 20 mutations which affect its transposition are reported. The mutations, generated in vitro by random insertion of synthetic restriction sites, proved to contain small duplications or deletions immediately adjacent to the new restriction site. By determining the phenotype and DNA sequence of these mutations we were able to generate an overlapping phenotypic and nucleotide map. This 4957 bp transposon encodes three polypeptides which account for all but 350 bp of its total coding capacity. These proteins are the transposase, a high molecular weight polypeptide (1015 amino acids) encoded by the tnpA gene; the Tn3-specific repressor, a low molecular weight polypeptide (185 amino acids) encoded by the tnpR gene; and the 286 amino acid beta-lactamase. The 38 bp inverted repeats flanking Tn3 appear to be absolutely required in cis for Tn3 to transpose. Genetic data suggest that Tn3 contains a third site (Gill et al., 1978), designated IRS (internal resolution site), whose absence results in the insertion of two complete copies of Tn3 as direct repeats into the recipient DNA. We suggest that these direct repeats of complete copies of Tn3 are intermediates in transposition, and that the IRS site is required for recombination and subsequent segregation of the direct repeats to leave a single copy of Tn3 (Gill et al., 1978). A 23 nucleotide sequence within the amino terminus of the transposase which shares strong sequence homology with the inverted repeat may be the internal resolution site.     

Structural and functional analysis of Tn4430: identification of an integrase-like protein involved in the co-integrate-resolution process

The 4149-bp transposon Tn4430 from Bacillus thuringiensis is delineated by 38-bp inverted repeats and codes for a 113-kd protein that shares homology with the transposases (TnpA) of Tn3, Tn21 and Tn501. Through transpositional recombination, this protein generates the formation of co-integrates between both donor and target replicons, with duplication of Tn4430 molecules. These features are characteristic of transposons of the Tn3 family (class II elements). The second step of the transposition process, the co-integrate resolution, is mediated by a 32-kd protein. This protein (TnpI) displays regional similarities with site-specific recombinases of the integrase family, such as Int of bacteriophage lambda, Cre of bacteriophage P1 or TnpA and TnpB of the Tn554 transposon. Moreover, the 250-bp sequence upstream to the tnpI gene contains several structural features that are reminiscent of the attP attachment site of phage lambda. This unique association between the integrase-like TnpI recombinase and the TnpA transposase qualifies Tn4430 as a member of a new group within the class II mobile genetic elements.