Transposon Tn21 encodes a RecA-independent site-specific integration system

Summary The IncW plasmid R388 and the DNA region of Tn21 containing the Sm^r and the Su^r genes are capable of RecA-independent recombination. This recombination occurs at a relatively high frequency (up to 10^-4 recombinants per recipient molecule) and results in integration of the two plasmids. No detectable repeats are formed in the process. The crossover points have been confined to a 0.4-kb homologous segment in both plasmids which contains a 59-bp DNA sequence presumably involved in the acquisition of new genes by Tn21 and its relatives (Cameron et al. 1986). It is likely that the recombination occurs precisely at this point. At least one trans-acting function (an integrase) is required for the site-specific recombination. It has been localized to a 1456-bp BstEII-BamHI fragment of Tn21 and can efficiently complement the integration of plasmids containing the integration site.     

Resolution of a hybrid cointegrate between transposons Tn501 and Tn1721 defines the recombination site

Summary The related transposons Tn501 and Tn1721 have a 3.8 kb region in common that contains two genes (tnpA and tnpR) and a resolution site (res) required for transposition. Resolvase, the product of tnpR, catalyses site-specific recombination at res, a 186 base pair (bp) sequence located adjacent to tnpR at one end of the homology region. We describe here identification of the crossover site within res. It involved the construction of a plasmid containing copies of res (Tn501) and res (Tn1721) in direct orientation and tnpR-mediated intramolecular recombination between the two homologous (but non-identical) sites. The resulting hybrid contained Tn501 and Tn1721 fused at the crossover point. DNA sequence analysis of the recombinant indicates that recombination occurs in an 11 bp region of exact homology between Tn501 and Tn1721. The recombination site lies 161–172 bp upstream of tnpR at the transition from homology to non-homology between Tn501 and Tn1721 suggesting that site-specific recombination may have played a role in the evolution of these elements.     

Homologous recombination generates T-loop-sized deletions at human telomeres

The t-loop structure of mammalian telomeres is thought to repress nonhomologous end joining (NHEJ) at natural chromosome ends. Telomere NHEJ occurs upon loss of TRF2, a telomeric protein implicated in t-loop formation. Here we describe a mutant allele of TRF2, TRF2DeltaB, that suppressed NHEJ but induced catastrophic deletions of telomeric DNA. The deletion events were stochastic and occurred rapidly, generating dramatically shortened telomeres that were accompanied by a DNA damage response and induction of senescence. TRF2DeltaB-induced deletions depended on XRCC3, a protein implicated in Holliday junction resolution, and created t-loop-sized telomeric circles. These telomeric circles were also detected in unperturbed cells and suggested that t-loop deletion by homologous recombination (HR) might contribute to telomere attrition. Human ALT cells had abundant telomeric circles, pointing to frequent t-loop HR events that could promote rolling circle replication of telomeres in the absence of telomerase. These findings show that t-loop deletion by HR influences the integrity and dynamics of mammalian telomeres.     

Transposon 10 promoted deletions and inversions in the transfer genes of R100-1

Summary The replication of the ColE1 plasmid was studied in extracts from E. coli dnaG mutants. It was found that the synthesis of the complementary strands of ColE1 DNA can be carried out in these extracts in two consecutive steps: (1) synthesis of the leading L strand independent of the dnaG function, and (2) synthesis of the lagging H strand depending upon addition of wild-type dnaG protein. In contrast to L strand synthesis, the latter reaction is insensitive to rifampicin and novobiocin. Both synthetic pathways are however blocked by antiserum directed against dnaB protein. This indicates an additional role of the dnaB protein in duplex DNA replication besides assisting the dnaG protein in the priming of lagging strand synthesis. The T7 gene-4 protein acting in conjunction with T7 DNA polymerase can substitute for both the function of the dnaB and dnaG protein. It is concluded that plasmid replication proceeds by a semi-discontinuous mechanism.     

Isolation and analysis of inhibitors of transposon Tn3 site-specific recombination

We have constructed a genetic bioassay for inhibitors of site-specific recombination by transposon Tn3 resolvase. Of 6,000 compounds tested, 26 inhibited in vivo, and 5 of these 26 inhibited in vitro. At least two inhibitors also inhibit the topoisomerase of resolvase. We have also identified analogs of A1062 which inhibit.     

Simple and efficient generation in vitro of nested deletions and inversions: Tn5 intramolecular transposition.

We have exploited the intramolecular transposition preference of the Tn 5 in vitro transposition system to test its effectiveness as a tool for generation of nested families of deletions and inversions. A synthetic transposon was constructed containing an ori, an ampicillin resistance (Ampr) gene, a multi-cloning site (MCS) and two hyperactive end sequences. The donor DNA that adjoins the transposon contains a kanamycin resistance (Kanr) gene. Any Amprreplicating plasmid that has undergone a transposition event (Kans) will be targeted primarily to any insert in the MCS. Two different size targets were tested in the in vitro system. Synthetic transposon plasmids containing either target were incubated in the presence of purified transposase (Tnp) protein and transformed. Transposition frequencies (Ampr/Kans) for both targets were found to be 30-50%, of which >95% occur within the target sequence, in an apparently random manner. By a conservative estimate 10(5) or more deletions/inversions within a given segment of DNA can be expected from a single one-step 20 microl transposition reaction. These nested deletions can be used for structure-function analysis of proteins and for sequence analysis. The inversions provide nested sequencing templates of the opposite strand from the deletions.     

Xer-mediated site-specific recombination at cer generates Holliday junctions in vivo.

Normal segregation of the Escherichia coli chromosome and stable inheritance of multicopy plasmids such as ColE1 requires the Xer site-specific recombination system. Two putative lambda integrase family recombinases, XerC and XerD, participate in the recombination reactions. We have constructed an E. coli strain in which the expression of xerC can be tightly regulated, thereby allowing the analysis of controlled recombination reactions in vivo. Xer-mediated recombination in this strain generates Holliday junction-containing DNA molecules in which a specific pair of strands has been exchanged in addition to complete recombinant products. This suggests that Xer site-specific recombination utilizes a strand exchange mechanism similar or identical to that of other members of the lambda integrase family of recombination systems. The controlled in vivo recombination reaction at cer requires recombinase and two accessory proteins, ArgR and PepA. Generation of Holliday junctions and recombinant products is equally efficient in RuvC- and RuvC+ cells, and in cells containing a multicopy RuvC+ plasmid. Controlled XerC expression is also used to analyse the efficiency of recombination between variant cer sites containing sequence alterations and heterologies within their central regions.     

Physical structures of Tn10-promoted deletions and inversions: role of 1400 bp inverted repetitions.

We report here the physical structures of deletions and inversions promoted by the translocatable tetracycline-resistance element Tn10. DNA/DNA heteroduplex and restriction enzyme analyses of alterations in the genome of bacteriophage lambda suggest that both types of DNA alterations almost always originate at the internal termini of the 1400 bp terminal inverted repetitions of Tn10. Tn10-promoted deletions remove a single contiguous DNA segment beginning at one such terminus; Tn10-promoted inversions are more complex, and involve both an inversion and a specific deletion of Tn10 DNA.     

Transposon-encoded site-specific recombination: nature of the Tn3 DNA sequences which constitute the recombination site res.

The tnpR gene of transposon Tn3 encodes a site-specific recombination enzyme that acts at res, a DNA region adjacent to tnpR, to convert co-integrate intermediates of interreplicon transposition to the normal transposition end-products. We have used two complementary approaches to study the nature of the Tn3 recombination region, res. Firstly, the DNA-binding sites for tnpR protein were determined in DNase I protection experiments. These identified a 120-bp region between the tnpA and tnpR genes that can be subdivided into three separate protein-binding sites. Genetic dissection experiments indicate that few, if any, other sequences in addition to this 120-bp region are required for res function. Moreover, we have shown that the two directly repeated res regions within a molecule are unequal partners in the recombination reaction: a truncated res region, which is unable to recombine with a second identical res region, can recombine efficiently with an intact res region. This demonstration, along with the observation that tnpR/res recombination acts efficiently on directly repeated res regions within a molecule but inefficiently both on inverted res regions in the same molecule and in the fusion reaction between res regions in different molecules, leads us to propose that one-dimensional diffusion (tracking) of tnpR protein along DNA is used to locate an initial res region, and then to bring a second directly repeated res region into a position that allows recombination between the res regions.     

Analysis of inhibitors of the site-specific recombination reaction mediated by Tn3 resolvase

The Tn3-encoded resolvase protein promotes a site-specific recombination reaction between two directly repeated copies of the recombination site res. Several inhibitors that block this event in vitro have been isolated. In this study four of these inhibitors were tested on various steps in the recombination reaction. Two inhibitors. A9387 and A1062, inhibit resolvase binding to the res site. Further, DNase I footprinting revealed that at certain concentrations of A9387 and A1062, resolvase was preferentially bound to site I of res, the site containing the recombinational crossover point. The two other inhibitors, A20812 and A21960, do not affect resolvase binding and bending of the DNA but inhibit synapse formation between resolvase and two directly repeated res sites.     

Concerted deletions and inversions are caused by mitotic recombination between delta sequences in Saccharomyces cerevisiae.

Deletions of a tyrosine tRNA suppressor gene, SUP4-o, are mediated by recombination between short repeated delta sequences in Saccharomyces cerevisiae. The arrangement of the five solo delta sequences that surround the SUP4 locus was established by DNA sequence analysis. Seven deletion classes were identified by genomic blotting. DNA sequence analysis also showed that the delta sequences within a 6.5-kilobase region of the SUP4 locus were the endpoints of these events. In three of these classes, an adjacent interval surrounded by delta sequences was inverted in concert with the deletion. The frequency of all deletion classes decreased in strains that contained mutations in the recombination and repair gene RAD52. We present two gene conversion mechanisms by which these rearrangements could have been generated. These models may also explain deletions between repeated sequences in other systems.     

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.     

Tn7: a target site-specific transposon

The bacterial transposon Tn7 is an unusual mobile DNA segment. Most transposable elements move at low-frequency and display little target site-selectivity. By contrast, Tn7 inserts at high-frequency into a single specific site in the chromosomes of many bacteria. In the absence of this specific site, called attTn7 in Escherichia coli where Tn7 has been most extensively studied, Tn7 transposes at low-frequency and inserts into many different sites. Much has recently been learned about Tn7 transposition from both genetic and biochemical studies. The Tn7 recombination machinery is elaborate and includes a large number of Tn7-encoded proteins, probably host-encoded proteins and also rather large cis-acting transposition sequences at the transposon termini and at the target site. Dissection of the Tn7 transposition mechanism has revealed that the DNA strand breakage and joining reactions that underlie the translocation of Tn7 have several unusual features.     

Complementation of transposition of tnpA mutants of Tn3, Tn21, Tn501, and Tn1721

The transposons Tn21, Tn501, and Tn1721 are related to Tn3. Transposition-deficient mutants (tnpA) of these elements were used to test for complementation of transpostion. Transposition of tnpA mutants of Tn501 and Tn1721 was restored by the presence in trans of Tn21, Tn501, and Tn1721, but transposition of a tnpA mutant of Tn21 was restored in trans only by Tn21 itself. Tn3 did not complement transposition of Tn21, Tn501, or Tn1721, and these elements did not complement transposition of Tn3.     

Cyanobacterial Transposons Tn5469 and Tn5541 Represent a Novel Noncomposite Transposon Family

A noncomposite transposon, designated Tn5541, was isolated from strain Fd33 of the filamentous cyanobacterium Fremyella diplosiphon UTEX 481. Sequence analysis showed that Tn5541 is structurally and genetically very similar to Tn5469, which is also endogenous to F. diplosiphon. Both Tn5469 and Tn5541 encode homologous forms of an unusual composite transposase and a protein of unknown function. DNA hybridization analysis showed that like Tn5469, Tn5541 was not widely distributed among cyanobacterial genera. A similar analysis showed that Tn5469 and Tn5541 were equally limited to and present as multiple genomic copies in three of six distinct strains comprising the Tolypothrix 1 cluster of heterocyst-forming filamentous cyanobacteria. These and other distinguishing features suggest that Tn5469 and Tn5541 represent a novel noncomposite transposon family.     

Transposon Tn951 (TnLac) is defective and related to Tn3

Summary Tn951 is flanked by two perfect inverted repeats of 41 bp which include the 38 bp sequence of the IR of Tn3. Tn951 also contains the last 100 bp of the tnpA gene but with at least two mutations. However, beyond nucleotide 137 the sequences diverge and hybridization experiments show that Tn951 lacks at least the first two thirds of the tnpA gene.In agreement with these observations Tn951 does not transpose by itself at a detectable frequency but can be complemented by the tnpA gene of Tn801 or Tn3. Tn501, Tn1721 and gamma delta do not complement Tn951 transposition.Transposition of Tn951 duplicates 5 bp of target DNA sequence.     

The R46 site-specific recombination system is a homologue of the Tn3 and gamma delta (Tn1000) cointegrate resolution system

The nucleotide sequence of the R46 site-specific recombination system has been determined. The organization of the recombination gene (perR46) and the site at which it acts (per site), together with the extensive sequence homology displayed with the tnpR genes and res sites of the transposons Tn3 and gamma delta (Tn1000), suggests that they have been derived from a Tn3-like element. These site-specific recombination functions of R46 play a role in plasmid maintenance.