IS911-mediated intramolecular transposition is naturally temperature sensitive

It is shown here that the bacterial insertion sequence IS 911 exhibits a temperature-sensitive transposition phenotype. Previous results have demonstrated that elevated levels of the IS 911 transposase OrfAB generate significant quantities of a figure-eight form, created by cleavage and circularization of one of the transposon strands, and of an excised circular form, in which both transposon strands have been circularized. We show here that the level of both types of molecule observed in vivo was greatly reduced at 42°C compared with 37°C. On the other hand, reducing the temperature to 30°C resulted in a significant increase in production. Transposition activity at this temperature was sufficiently high to permit detection in vivo of an excised circular form of a defective single IS 911 chromosomal copy when OrfAB is supplied in trans . A similar temperature–activity profile is observed for a cell-free reaction that uses partially purified OrfAB and generates the figure-eight form uniquely. Moreover, two point mutants of OrfAB were obtained, which render the reactions partially temperature resistant both in vivo and in vitro . These results suggest that some property of transposase itself is sensitive to elevated temperatures.     

Single-stranded DNA intermediates in IS91 rolling-circle transposition

IS91 displays a number of characteristics unique among insertion sequence (IS) elements, suggesting that it transposes by a novel mechanism called rolling-circle (RC) transposition. We reported previously that IS91 transposase (TnpA) amino acid sequence shares a series of five conserved signatures with A proteins of RC replicating phages, including a pair of invariant tyrosines that catalyse two successive transesterification reactions during replication initiation and termination. To analyse their role in IS91 transposition, we constructed a series of TnpA derivatives in which the invariant Tyr-249 and/or Tyr-253 were mutated to either phenylalanine or serine. Mutation of either tyrosine resulted in complete loss of transposition activity in vivo. This result was taken as a first new line of evidence that TnpA is a functional analogue of phiX174 phage A protein. Secondly, RC replication plasmids and phages accumulate single-stranded DNA (ssDNA) intermediates as a result of uncoupled leading and lagging DNA strand synthesis. Using a plasmid carrying an IS91-derived IRLkan-IRR transposable cassette, in which the left (IRL)- and right (IRR)-terminal sequences of IS91 flank a kanamycin resistance gene (kan), we demonstrated the in vivo formation of two new DNA species after induction of transposase expression. The first was a circular ssDNA that contained the transposable cassette covalently joined at its exact termini, whereas the second was a double-stranded circle of the same element. When this experiment was repeated using the mutant transposases described above, the ssDNA and dsDNA intermediates could not be observed, indicating that the integrity of both Y249 and Y253 was essential for their appearance. The presence of ssDNA intermediate products is the first biochemical evidence for a RC mechanism of IS91 transposition.     

The role of tandem IS dimers in IS911 transposition

Using a combined in vivo and in vitro approach, we demonstrated that the transposition products generated by IS911 from a dimeric donor plasmid are different from those generated from a plasmid monomer. When carried by a monomeric plasmid donor, free IS911 transposon circles are generated by intra-IS recombination in which one IS end undergoes attack by the other. These represent transposition intermediates that undergo integration using the abutted left (IRL) and right (IRR) ends of the element, the active IRR-IRL junction, to generate simple insertions. In contrast, the two IS911 copies carried by a dimeric donor plasmid not only underwent intra-IS recombination to generate transposon circles but additionally participated in inter-IS recombination. This also creates an active IRR-IRL junction by generating a head-to-tail IS tandem dimer ([IS]2) in which one of the original plasmid backbone copies is eliminated in the formation of the junction. Both transposon circles and IS tandem dimers are generated from an intermediate in which two transposon ends are retained by a single strand joint to generate a figure 8 molecule. Inter-IS figure 8 molecules generated in vitro could be resolved into the [IS]2 form following introduction into a host strain by transformation. Resolution did not require IS911 transposase. The [IS]2 structure was stable in the absence of transposase but was highly unstable in its presence both in vivo and in vitro. Previous studies had demonstrated that the IRR-IRL junction promotes efficient intermolecular integration and intramolecular deletions both in vivo and in vitro. Integration of the [IS]2 derivative would result in a product that resembles a co-integrate structure. It is also shown here that the IRR-IRL junction of the [IS]2 form and derivative structures can specifically target one of the other ends in an intramolecular transposition reaction to generate transposon circles in vitro. These results not only demonstrate that IS911 (and presumably other members of the IS3 family) is capable of generating a range of transposition products, it also provides a mechanistic framework which explains the formation and activity of such structures previously observed for several other unrelated IS elements. This behaviour is probably characteristic of a large number of IS elements.     

Truncated forms of IS911 transposase downregulate transposition

IS911 naturally produces transposase (OrfAB) derivatives truncated at the C-terminal end (OrfAB-CTF) and devoid of the catalytic domain. A majority species, OrfAB*, was produced at higher levels at 42 degrees C than at 30 degrees C suggesting that it is at least partly responsible for the innate reduction in IS911 transposition activity at higher temperatures. An engineered equivalent of similar length, OrfAB[1-149], inhibited transposition activity in vivo or in vitro when produced along with full-length transposase. We isolated several point mutants showing higher activity than the wild-type IS911 at 42 degrees C. These fall into two regions of the transposase. One, located in the N-terminal segment of OrfAB, lies between or within two regions involved in protein multimerization. The other is located within the C-terminal catalytic domain. The N-terminal mutations resulted in reduced levels of OrfAB* while the C-terminal mutation alone appeared not to affect OrfAB* levels. Combination of N- and C-terminal mutations greatly reduced OrfAB* levels and transposition was concomitantly high even at 42 degrees C. The mechanism by which truncated transposase species are generated and how they intervene to reduce transposition activity is discussed. While transposition activity of these multiply mutated derivatives in vivo was resistant to temperature, the purified OrfAB derivatives retained an inherent temperature-sensitive phenotype in vitro. This clearly demonstrates that temperature sensitivity of IS911 transposition is a complex phenomenon with several mechanistic components. These results have important implications for the several other transposons and insertion sequences whose transposition has also been shown to be temperature-sensitive.     

Efficient transposition of IS911 circles in vitro.

An in vitro system has been developed which supports efficient integration of transposon circles derived from the bacterial insertion sequence IS911. Using relatively pure preparations of IS911-encoded proteins it has been demonstrated that integration into a suitable target required both the transposase, OrfAB, a fusion protein produced by translational frameshifting between two consecutive open reading frames, orfA and orfB, and OrfA, a protein synthesized independently from the upstream orfA. Intermolecular reaction products were identified in which one or both transposon ends were used. The reaction also generated various intramolecular transposition products including adjacent deletions and inversions. The circle junction, composed of abutted left and right IS ends, retained efficient integration activity when carried on a linear donor molecule, demonstrating that supercoiling in the donor molecule is not necessary for the reaction. Both two-ended integration and a lower level of single-ended insertions were observed under these conditions. The frequency of these events depended on the spacing between the transposon ends. Two-ended insertion was most efficient with a natural spacing of 3 bp. These results demonstrate that transposon circles can act as intermediates in IS911 transposition and provide evidence for collaboration between the two major IS911-encoded proteins, OrfA and OrfAB.     

IS911 partial transposition products and their processing by the Escherichia coli RecG helicase

Insertion of bacterial insertion sequence IS911 can often be directed to sequences resembling its ends. We have investigated this type of transposition and shown that it can occur via cleavage of a single end and its targeted transfer next to another end. The single end transfer (SET) events generate branched DNA molecules that contain a nicked Holliday junction and can be considered as partial transposition products. Our results indicate that these can be processed by the Escherichia coli host independently of IS911-encoded proteins. Such resolution depends on the presence of homologous DNA regions neighbouring the cross-over point in the SET molecule. Processing is often accompanied by sequence conversion between donor and target sequences, suggesting that branch migration is involved. We show that resolution is greatly reduced in a recG host. Thus, the branched DNA-specific helicase, RecG, involved in processing of potentially lethal DNA structures such as stalled replication forks, also intervenes in the resolution of partial IS911 transposition products.     

IS911 transposition is regulated by protein-protein interactions via a leucine zipper motif

Efficient intermolecular transposition of bacterial insertion sequence IS911 involves the activities of two element-encoded proteins: the transposase, OrfAB, and a regulatory factor, OrfA. OrfA shares the majority of its amino acid sequence with the N-terminal part of OrfAB. This includes a putative helix-turn-helix and three of four heptads of a leucine zipper motif. OrfA strongly stimulates OrfAB-mediated intermolecular transposition both in vivo and in vitro. The present results support the notion that this is accomplished by direct interaction between these two proteins via the leucine zipper. We used both a genetic approach, based on gene fusions with phage lambda repressor, and a physical approach, involving co-immunoprecipitation, to show that OrfA not only undergoes oligomerisation but is capable of engaging with OrfAB to form heteromultimers, and that the leucine zipper is necessary for both types of interaction. Furthermore, mutation of the leucine zipper in OrfA inactivated its regulatory function. Previous observations demonstrated that the integrity of the leucine zipper motif was also important for OrfAB binding to the IS911 terminal inverted repeats. Here, we show, in gel shift experiments, using a derivative of OrfAB deleted for the C-terminal catalytic domain, OrfAB[1-149], that the protein is capable of pairing two inverted repeats to generate a species resembling a "synaptic complex". Preincubation of OrfAB[1-149] with OrfA dramatically reduced formation of this complex and favored formation of an alternative complex devoid of OrfA. Together these results suggest that OrfA exerts its regulatory effect by interacting transiently with OrfAB via the leucine zipper and modifying OrfAB binding to the inverted repeats.     

IS10 transposition is regulated by DNA adenine methylation

We show that dam- mutants are a major class of E. coli mutants with increased IS10 activity. IS10 has two dam methylation sites, one within the transposase promoter and one within the inner terminus where transposase presumably binds. Absence of methylation results in increased activity of both promoter and terminus, and completely accounts for increased transposition in dam- strains. Transposition of Tn903 and Tn5 are also increased in dam- strains, probably for analogous reasons. Transposition is also increased when IS10 is hemimethylated. One hemimethylated species is much more active than the other and is estimated to be at least 1000 times more active than a fully methylated element. Evidence is presented that the promoter and inner terminus of IS10 are coordinately activated in a dam-dependent fashion, presumably because they are hemimethylated at the same time. Thus, in dam+ strains, IS10 will transpose preferentially when DNA is hemimethylated. We suggest specifically that IS10 transposition may preferentially occur immediately after passage of a chromosomal replication fork.     

DNA intermediates in transposition of phage Mu

Transposable genetic elements can insert into DNA sites that have no homology to themselves. Evidence that there is a physical linkage between a transposable element and its target DNA sequence during transposition comes from studies on bacteriophage Mu DNA transposition in which plasmids containing Mu DNA have been shown to attach to host DNA. We report the isolation of key structures, seen after induction of Mu DNA replication, after cloning lac operator into Mu DNA and using the lac repressor-operator interaction to trap Mu DNA on nitrocellulose filters. We have localized Mu sequences within these structures in the electron microscope by visualizing the lac operator-repressor interaction after binding with ferritin-conjugated antibody. This analysis shows that key structures contain replicating Mu DNA linked to non-Mu DNA and that replication can begin at either end of Mu.     

Requirement of IS911 replication before integration defines a new bacterial transposition pathway

Movement of transposable elements is often accompanied by replication to ensure their proliferation. Replication is associated with both major classes of transposition mechanisms: cut-and-paste and cointegrate formation (paste-and-copy). Cut-and-paste transposition is often activated by replication of the transposon, while in cointegrate formation replication completes integration. We describe a novel transposition mechanism used by insertion sequence IS911, which we call copy-and-paste. IS911 transposes using a circular intermediate (circle), which then integrates into a target. We demonstrate that this is derived from a branched intermediate (figure-eight) in which both ends are joined by a single-strand bridge after a first-strand transfer. In vivo labelling experiments show that the process of circle formation is replicative. The results indicate that the replication pathway not only produces circles from figure-eight but also regenerates the transposon donor plasmid. To confirm the replicative mechanism, we have also used the Escherichia coli terminators (terC) which, when bound by the Tus protein, inhibit replication forks in a polarised manner. Finally, we demonstrate that the primase DnaG is essential, implicating a host-specific replication pathway.     

A target specificity switch in IS911 transposition: the role of the OrfA protein

The role played by insertion sequence IS911 proteins, OrfA and OrfAB, in the choice of a target for insertion was studied. IS911 transposition occurs in several steps: synapsis of the two transposon ends (IRR and IRL); formation of a figure-of-eight intermediate where both ends are joined by a single-strand bridge; resolution into a circular form carrying an IRR-IRL junction; and insertion into a DNA target. In vivo, with OrfAB alone, an IS911-based transposon integrated with high probability next to an IS911 end located on the target plasmid. OrfA greatly reduced the proportion of these events. This was confirmed in vitro using a transposon with a preformed IRR-IRL junction to examine the final insertion step. Addition of OrfA resulted in a large increase in insertion frequency and greatly increased the proportion of non-targeted insertions. The intermolecular reaction leading to targeted insertion may resemble the intramolecular reaction involving figure-of-eight molecules, which leads to the formation of circles. OrfA could, therefore, be considered as a molecular switch modulating the site-specific recombination activity of OrfAB and facilitating dispersion of the insertion sequence (IS) to 'non-homologous' target sites.     

Transient promoter formation: a new feedback mechanism for regulation of IS911 transposition

IS911 transposition involves a free circular transposon intermediate where the terminal inverted repeat sequences are connected. Transposase synthesis is usually driven by a weak promoter, p(IRL), in the left end (IRL). Circle junction formation creates a strong promoter, p(junc), with a -35 sequence located in the right end and the -10 sequence in the left. p(junc) assembly would permit an increase in synthesis of transposase from the transposon circle, which would be expected to stimulate integration. Insertion results in p(junc) disassembly and a return to the low p(IRL)- driven transposase levels. We demonstrate that p(junc) plays an important role in regulating IS911 transposition. Inactivation of p(junc) strongly decreased IS911 transposition when transposase was produced in its natural configuration. This novel feedback mechanism permits transient and controlled activation of integration only in the presence of the correct (circular) intermediate. We have also investigated other members of the IS3 and other IS families. Several, but not all, IS3 family members possess p(junc) equivalents, underlining that the regulatory mechanisms adopted to fine-tune transposition may be different.     

Bias between the left and right inverted repeats during IS911 targeted insertion

IS911 is a bacterial insertion sequence composed of two consecutive overlapping open reading frames (ORFs [orfA and orfB]) encoding the transposase (OrfAB) as well as a regulatory protein (OrfA). These ORFs are bordered by terminal left and right inverted repeats (IRL and IRR, respectively) with several differences in nucleotide sequence. IS911 transposition is asymmetric: each end is cleaved on one strand to generate a free 3′-OH, which is then used as the nucleophile in attacking the opposite insertion sequence (IS) end to generate a free IS circle. This will be inserted into a new target site. We show here that the ends exhibit functional differences which, in vivo, may favor the use of one compared to the other during transposition. Electromobility shift assays showed that a truncated form of the transposase [OrfAB(1-149)] exhibits higher affinity for IRR than for IRL. While there was no detectable difference in IR activities during the early steps of transposition, IRR was more efficient during the final insertion steps. We show here that the differential activities between the two IRs correlate with the different affinities of OrfAB(1-149) for the IRs during assembly of the nucleoprotein complexes leading to transposition. We conclude that the two inverted repeats are not equivalent during IS911 transposition and that this asymmetry may intervene to determine the ordered assembly of the different protein-DNA complexes involved in the reaction.     

Assembly of a strong promoter following IS911 circularization and the role of circles in transposition.

When supplied with high levels of the IS911-encoded transposase, IS911-based transposons can excise as circles in which the right and left terminal inverted repeats are abutted. Formation of the circle junction is shown here to create a promoter, p(junc), which is significantly stronger than the indigenous promoter, pIRL, and is also capable of driving expression of the IS911 transposition proteins. High transposase expression from the circular transposon may promote use of the circle as an integration substrate. The results demonstrate that IS911 circles are highly efficient substrates for insertion into a target molecule in vivo. Insertion leads to the disassembly of p(junc) and thus to a lower level of synthesis of the transposition proteins. The observation that normal levels of IS911 transposition proteins supplied by wild-type copies of IS911 are also capable of generating transposon circles, albeit at a low level, reinforces the idea that the transposon circles might form part of the natural transposition cycle of IS911. These observations form the elements of a feedback control mechanism and have been incorporated into a model describing one possible pathway of IS911 transposition.     

Crystal structure and functional implications of Pyrococcus furiosus hef helicase domain involved in branched DNA processing

DNA and RNA frequently form various branched intermediates that are important for the transmission of genetic information. Helicases play pivotal roles in the processing of these transient intermediates during nucleic acid metabolism. The archaeal Hef helicase/ nuclease is a representative protein that processes flap- or fork-DNA structures, and, intriguingly, its C-terminal half belongs to the XPF/Mus81 nuclease family. Here, we report the crystal structure of the helicase domain of the Hef protein from Pyrococcus furiosus. The structure reveals a novel helical insertion between the two conserved helicase core domains. This positively charged extra region, structurally similar to the "thumb" domain of DNA polymerase, plays critical roles in fork recognition. The Hef helicase/nuclease exhibits sequence similarity to the Mph1 helicase from Saccharomyces cerevisiae; XPF/Rad1, involved in DNA repair; and a putative Hef homolog identified in mammals. Hence, our findings provide a structural basis for the functional mechanisms of this helicase/nuclease family.     

One-ended insertion of IS911.

An apparently nonreplicative integration reaction mediated by the insertion sequence IS911 has been analyzed. It is shown to involve the right-end inverted repeat (IRR) of the element and sequences in the flanking vector DNA. The flanking sequences appear to behave as a surrogate IS911 end, since integration is greatly reduced when limited similarities with IRR are eliminated by site-directed mutagenesis. Data are presented which suggest that the activity of the IRR junction results from the proximity of the transposase gene and may therefore reflect preferential transposase recognition of IRR in cis.     

Escherichia coli insertion sequence IS150: transposition via circular and linear intermediates

IS150, a member of the widespread IS3 family, contains two consecutive out-of-phase open reading frames, orfA and orfB, that partially overlap. These open reading frames encode three proteins, InsA, InsB, and the InsAB protein, which is jointly encoded by both open reading frames by means of programmed translational frameshifting. We demonstrate that the InsAB protein represents the IS150 element's transposase. In vivo, the wild-type IS150 element generates circular excision products and linear IS150 molecules. Circular and linear species have previously been detected with mutant derivatives of other members of the IS3 family. Our finding supports the assumption that these products represent true transposition intermediates of members of this family. Analysis of the molecular nature of these two species suggested that the circular forms are precursors of the linear molecules. Elimination of InsA synthesis within the otherwise intact element led to accumulation of large amounts of the linear species, indicating that the primary role of InsA may be to prevent abortive production of the linear species and to couple generation of these species to productive insertion events.     

Resolving branched DNA intermediates with structure-specific nucleases during replication in eukaryotes

Genome duplication requires that replication forks track the entire length of every chromosome. When complications occur, homologous recombination-mediated repair supports replication fork movement and recovery. This leads to physical connections between the nascent sister chromatids in the form of Holliday junctions and other branched DNA intermediates. A key role in the removal of these recombination intermediates falls to structure-specific nucleases such as the Holliday junction resolvase RuvC in Escherichia coli. RuvC is also known to cut branched DNA intermediates that originate directly from blocked replication forks, targeting them for origin-independent replication restart. In eukaryotes, multiple structure-specific nucleases, including Mus81–Mms4/MUS81–EME1, Yen1/GEN1, and Slx1–Slx4/SLX1–SLX4 (FANCP) have been implicated in the resolution of branched DNA intermediates. It is becoming increasingly clear that, as a group, they reflect the dual function of RuvC in cleaving recombination intermediates and failing replication forks to assist the DNA replication process.