Excision of Tn10 from the donor site during transposition occurs by flush double-strand cleavages at the transposon termini.

Tn10 transposition is accomplished without extensive replication of the transposon sequences. Replicative cointegrate formation is precluded by efficient separation of transposon sequences from flanking donor DNA at an early stage in the transposition reaction. We report here that excision of Tn10 from its donor site occurs by a pair of flush double-strand breaks. Breaks occur at each end of the element precisely between the terminal base pair of the element and the first base pair of flanking DNA. This observation provides definitive evidence that cleavage of both strands of the element occurs under the direct control of Tn10 transposase protein. It is highly likely that transposase itself is directly responsible for these cleavages. The implications of this possibility are discussed.     

A mechanism of DNA transposition.

Bacteriophage Mu and many other transposable elements undergo transposition by a process that involves replication of the element. We describe here a mechanism by which such integrative replication may take place. We hve examined electron microscopically the DNA structures generated in host cells after Mu induction and have deduced the following steps in the transposition process, (i) Association. A protein-mediated association is brought about between the transposable element and the target DNA. (ii) Attachment. One end of the element is nicked and attached to a site that undergoes a double-stranded cleavage. (iii) Roll-in replication. While one strand of the target DNA is linked to the nicked strand of the element, the complementary strand of the target DNA is used as a primer for replication into the element such that the replicating DNA is threaded through the replication complex. (iv) Roll-in termination. When the distal end of the element arrives at the replication complex, replication is terminated. The roll-in replication mechanism can also explain laying down of tandem repeats--i.e., amplification of circular DNA sequences.     

Differential roles of the transposon termini in IS91 transposition.

Insertion sequence 91 (IS91) inserts specificallyat GTTC or CTTG target sequences without duplication of the target. Afterinsertion, the right inverted repeat (IRR) lies adjacent to the 3' end ofthe target sequences (or 5' to the complementary sequence CAAG or GAAC). Wehave analyzed the effects of alteration of each terminus of IS91 ontransposition activity in Escherichia coli. IRR is absolutely required fortransposition. Deletion analysis indicates that a 14-bp segment is notsufficient, but an 81-bp sequence within the IRR region is sufficient.Furthermore, the GTTC/CTTG target site is also required. The left invertedrepeat (IRL) of IS91 is dispensable. Plasmid fusions originated by one-endedtransposition of IS91 derivatives lacking IRL occur at about the same frequencyas cointegrate formation observed for the wild-type element. In theone-ended-type fusions, the inserted fragment of donor DNA is flanked at one end(constant end) by IRR and at the other end by a GTTC or CTTG sequence present inthe donor (variable end) in a way that usually results in multiple tandeminsertions of the donor plasmid in the target site. These results are easilyaccommodated by a rolling-circle replicative transposition mechanism. This modelalso draws support from the finding that the IS91 transposase is related insequence to the superfamily of rolling-circle replication proteins and theobservation that IRR shows some conservation in sequence and secondary structurewith the origins of replication of some rolling-circle replicationplasmids.     

Structural requirement for IS50-mediated gene transposition.

Replicative transposition is signaled by the formation of cointegrates in which donor and target replicons are joined by direct repeats of a transposable element. Elements not generating such cointegrates may move by a conservative breaking and joining process. The IS50 elements forming the terminal repeats of Tn5 [which carries the determinant for kanamycin resistance (Kanr)] contain genes and sites necessary for transposition and mediate the movement of any DNA segment they bracket. To determine if IS50 generates cointegrates, the products of transposition from pBR322::Tn5 plasmids to an F factor in recA-Escherichia coli were examined. With monomeric pBR322::Tn5 plasmids, transposition of Kanr (from Tn5) was generally not accompanied by movement of the determinant for ampicillin resistance (Ampr) (from the pBR322 vector). With dimeric pBR322::Tn5 plasmids, by contrast, half of the transpositions of kanr were accompanied by transposition of ampr. Restriction endonuclease analyses indicated that these F-Kanr Ampr chimeras contained inserts of a single copy of the pBR322 vector sequence bracketed by one Tn5 element and one IS50 element or by a pair of Tn5 elements. None of 79 chimeras tested was a true cointegrate. Because IS50 seems to move only a segment of the donor replicon it is proposed that IS50 transposition is conservative.     

Cointegrate formation by Tn5, but not transposition, is dependent on recA.

We have studied the effect of the recA-dependent homologous recombination system of Escherichia coli on both Tn5-mediated cointegrate formation and Tn5 transposition. We demonstrate here that, whereas transposition of Tn5 is independent of the recA gene product (as has been shown by other workers), Tn5-mediated cointegrate formation is strongly dependent on recA. The structures of both the simple transposition products and the cointegrates formed in a recA- background seem to be the same as those produced in a recA+ background. These results provide strong evidence that Tn5 does not transpose via an obligate cointegrate intermediate and suggest that the recA effect on cointegrate formation is exerted during the process of transposition.     

The terminal nucleotide of the Mu genome controls catalysis of DNA strand transfer

Members of the transposase/retroviral-integrase superfamily use a single active site to perform at least two reactions during transposition of a DNA transposon or a retroviral cDNA. They hydrolyze a DNA sequence at the end of the mobile DNA and then join this DNA end to a target DNA (a reaction called DNA strand transfer). Critical to understanding the mechanism of recombination is elucidating how these distinct reactions are orchestrated by the same active site. Here we find that DNA substrates terminating in a dideoxynucleotide allow Mu transposase to hydrolyze a target DNA, combining aspects of both natural reactions. Analyses of the sequence preferences for target hydrolysis and of the structure of the cleaved product indicate that this reaction is promoted by the active site in the conformation that normally promotes DNA strand transfer. Dissecting the DNA requirements for target hydrolysis reveals that the ribose of the last nucleotide of the Mu DNA activates transposase's catalytic potential, even when this residue is not a direct chemical participant. These findings provide insight into the molecular mechanism insuring that DNA strand transfer ordinarily occurs rather than inappropriate DNA cleavage. The required presence of the terminal nucleotide in the transposase active site creates a great advantage for the attached 3'OH to serve as nucleophile.     

DNA length, bending, and twisting constraints on IS50 transposition.

Transposition is a multistep process in which a transposable element DNA sequence moves from its original genetic location to a new site. Early steps in this process include the formation of a transposition complex in which the end sequences of the transposable element are brought together in a structurally precise fashion through the action of the element-encoded transposase protein and the cleavage of the element free from the adjoining DNA. If transposition complex formation must precede DNA cleavage (or nicking), then changing the length of the donor DNA between closely spaced ends should have dramatic effects on the frequency of the transposition. This question has been examined by studying the effects of altering donor DNA length on IS50 transposition. Donor DNA < or = 64 bp severely impaired transposition. Donor DNA > or = 200 bp demonstrated high transposition frequencies with only modest length dependencies. Constructs with donor DNA lengths between 66 and 174 bp demonstrated a dramatic periodic effect on transposition (periodicity approximately 10.5 bp).     

Resolution of cointegrates between transposons gamma delta and Tn3 defines the recombination site.

Transposition of the genetically related insertion elements gamma delta and Tn3 is thought to involve two steps. In the case of transposition from one replicon to another, the first step is fusion of the parent and target replicons with the element appearing in direct orientation at the two junctions. In a subsequent reaction, the cointegrate structure is resolved via a site-specific recombination event. I have constructed two plasmids, each carrying segments of gamma delta and Tn3, that contain the internal resolution site. The tnpR gene product encoded by either Tn3 or gamma delta mediates intramolecular recombination between these two sites. The product of this recombination is a hybrid region that contains gamma delta and Tn3 sequences fused at the point of crossover. DNA sequence analysis of such recombinants indicates that the recombination occurs within a 19-base-pair (bp) region of exact homology between gamma delta and Tn3. The site lies in the 160-bp center intercistronic region, 50 bp before the beginning of the tnpA gene. My results therefore suggest a model for the coupled regulation of the repressor (tnpR) and the transposase (tnpA) genes and site-specific recombination of transposition intermediates. The Tn3/gamma delta recombination system and bacteriophage lambda integration are compared.     

A defined system for the DNA strand-transfer reaction at the initiation of bacteriophage Mu transposition: protein and DNA substrate requirements.

An early step in the transposition of bacteriophage Mu DNA in vitro is a DNA strand-transfer reaction that generates an intermediate DNA structure in which the Mu donor DNA and the target DNA are covalently joined. DNA replication, initiated at the DNA forks in this intermediate, generates a cointegrate product; simple insert products can also be formed from the same intermediate by degradation of a specific segment of the structure, followed by gap repair. This DNA strand-transfer reaction requires ATP, magnesium, the Mu A and Mu B proteins, and a factor supplied by an Escherichia coli cell extract. We have now shown that the host protein factor requirement can be satisfied by purified protein HU. The defined system has been used to determine the DNA substrate requirements for the reaction. The reaction requires the two Mu ends, located on the same DNA molecule, in the same relative orientation to one another as in the phage Mu genome. To participate in the strand-transfer reaction efficiently the mini-Mu plasmid, used as the transposon donor, must be supercoiled; the target DNA molecule may be supercoiled, relaxed circular, or linear.     

Stabilization of diverged tandem repeats by mismatch repair: evidence for deletion formation via a misaligned replication intermediate.

A functional methyl-directed mismatch repair pathway in Escherichia coli prevents the formation of deletions between 101-bp tandem repeats with 4% sequence divergence. Deletions between perfectly homologous repeats are unaffected. Deletion in both cases occurs independently of the homologous recombination gene, recA. Because the methyl-directed mismatch repair pathway detects and excises one strand of a mispaired duplex, an intermediate for RecA-independent deletion of tandem repeats must therefore be a heteroduplex formed between strands of each repeat. We find that MutH endonuclease, which in vivo incises specifically the newly replicated strand of DNA, and the Dam methylase, the source of this strand-discrimination, are required absolutely for the exclusion of "homeologous" (imperfectly homologous) tandem deletion. This supports the idea that the heteroduplex intermediate for deletion occurs during or shortly after DNA replication in the context of hemi-methylation. Our findings confirm a "replication slippage" model for deletion formation whereby the displacement and misalignment of the nascent strand relative to the repeated sequence in the template strand accomplishes the deletion.     

In vitro cleavage and joining at the viral origin of replication by the replication initiator protein of tomato yellow leaf curl virus.

Replication of the single-stranded DNA genome of geminiviruses occurs via a double-stranded intermediate that is subsequently used as a template for rolling-circle replication of the viral strand. Only one of the proteins encoded by the virus, here referred to as replication initiator protein (Rep protein), is indispensable for replication. We show that the Rep protein of tomato yellow leaf curl virus initiates viral-strand DNA synthesis by introducing a nick in the plus strand within the nonanucleotide 1TAATATT decreases 8AC, identical among all geminiviruses. After cleavage, the Rep protein remains bound to the 5' end of the cleaved strand. In addition, we show that the Rep protein has a joining activity, suggesting that it acts as a terminase, thus resolving the nascent viral single strand into genome-sized units.     

Mediator proteins orchestrate enzyme-ssDNA assembly during T4 recombination-dependent DNA replication and repair

Studies of recombination-dependent replication (RDR) in the T4 system have revealed the critical roles played by mediator proteins in the timely and productive loading of specific enzymes onto single-stranded DNA (ssDNA) during phage RDR processes. The T4 recombination mediator protein, uvsY, is necessary for the proper assembly of the T4 presynaptic filament (uvsX recombinase cooperatively bound to ssDNA), leading to the recombination-primed initiation of leading strand DNA synthesis. In the lagging strand synthesis component of RDR, replication mediator protein gp59 is required for the assembly of gp41, the DNA helicase component of the T4 primosome, onto lagging strand ssDNA. Together, uvsY and gp59 mediate the productive coupling of homologous recombination events to the initiation of T4 RDR. UvsY promotes presynaptic filament formation on 3' ssDNA-tailed chromosomes, the physiological primers for T4 RDR, and recent results suggest that uvsY also may serve as a coupling factor between presynapsis and the nucleolytic resection of double-stranded DNA ends. Other results indicate that uvsY stabilizes uvsX bound to the invading strand, effectively preventing primosome assembly there. Instead, gp59 directs primosome assembly to the displaced strand of the D loop/replication fork. This partitioning mechanism enforced by the T4 recombination/replication mediator proteins guards against antirecombination activity of the helicase component and ensures that recombination intermediates formed by uvsX/uvsY will efficiently be converted into semiconservative DNA replication forks. Although the major mode of T4 RDR is semiconservative, we present biochemical evidence that a conservative "bubble migration" mode of RDR could play a role in lesion bypass by the T4 replication machinery.     

Reconstitution of recombination-dependent DNA synthesis in herpes simplex virus 1

The repair of double-strand DNA breaks by homologous recombination is essential for the maintenance of genome stability. In herpes simplex virus 1, double-strand DNA breaks may arise as a consequence of replication fork collapse at sites of oxidative damage, which is known to be induced upon viral infection. Double-strand DNA breaks are also generated by cleavage of viral a sequences by endonuclease G during genome isomerization. We have reconstituted a system using purified proteins in which strand invasion is coupled with DNA synthesis. In this system, the viral single-strand DNA-binding protein promotes assimilation of single-stranded DNA into a homologous supercoiled plasmid, resulting in the formation of a displacement loop. The 3' terminus of the invading DNA serves as a primer for long-chain DNA synthesis promoted by the viral DNA replication proteins, including the polymerase and helicase-primase. Efficient extension of the invading primer also requires a DNA-relaxing enzyme (eukaryotic topoisomerase I or DNA gyrase). The viral polymerase by itself is insufficient for DNA synthesis, and a DNA-relaxing enzyme cannot substitute for the viral helicase-primase. The viral single-strand DNA-binding protein, in addition to its role in the invasion process, is also required for long-chain DNA synthesis. Form X, a topologically distinct, positively supercoiled form of displacement-loop, does not serve as a template for DNA synthesis. These observations support a model in which recombination and replication contribute toward maintaining viral genomic stability by repairing double-strand breaks. They also account for the extensive branching observed during viral replication in vivo.     

Dissecting the roles of MuB in Mu transposition: ATP regulation of DNA binding is not essential for target delivery

Collaboration between MuA transposase and its activator protein, MuB, is essential for properly regulated transposition. MuB activates MuA catalytic activity, selects target DNA, and stimulates transposition into the selected target site. Selection of appropriate target DNA requires ATP hydrolysis by the MuB ATPase. By fusing MuB to a site-specific DNA-binding protein, the Arc repressor, we generated a MuB variant that could select target DNA independently of ATP. This Arc-MuB fusion protein allowed us to test whether ATP binding and hydrolysis by MuB are necessary for stimulation of transposition into selected DNA, a process termed target delivery. We find that with the fusion proteins, MuB-dependent target delivery occurs efficiently under conditions where ATP hydrolysis is prevented by mutation or use of ADP. In contrast, no delivery was detected in the absence of nucleotide. These data indicate that the ATP- and MuA-regulated DNA-binding activity of MuB is not essential for target delivery but that activation of MuA by MuB strictly requires nucleotide-bound MuB. Furthermore, we find that the fusion protein directs transposition to regions of the DNA within 40–750 bp of its own binding site. Taken together, these results suggest that target delivery by MuB occurs as a consequence of the ability of MuB to stimulate MuA while simultaneously tethering MuA to a selected target DNA. This tethered-activator model provides an attractive explanation for other examples of protein-stimulated control of target site selection.     

The wing of the enhancer-binding domain of Mu phage transposase is flexible and is essential for efficient transposition.

A tetramer of the Mu transposase (MuA) pairs the recombination sites, cleaves the donor DNA, and joins these ends to a target DNA by strand transfer. Juxtaposition of the recombination sites is accomplished by the assembly of a stable synaptic complex of MuA protein and Mu DNA. This initial critical step is facilitated by the transient binding of the N-terminal domain of MuA to an enhancer DNA element within the Mu genome (called the internal activation sequence, IAS). Recently we solved the three-dimensional solution structure of the enhancer-binding domain of Mu phage transposase (residues 1-76, MuA76) and proposed a model for its interaction with the IAS element. Site-directed mutagenesis coupled with an in vitro transposition assay has been used to assess the validity of the model. We have identified five residues on the surface of MuA that are crucial for stable synaptic complex formation but dispensable for subsequent events in transposition. These mutations are located in the loop (wing) structure and recognition helix of the MuA76 domain of the transposase and do not seriously perturb the structure of the domain. Furthermore, in order to understand the dynamic behavior of the MuA76 domain prior to stable synaptic complex formation, we have measured heteronuclear 15N relaxation rates for the unbound MuA76 domain. In the DNA free state the backbone atoms of the helix-turn-helix motif are generally immobilized whereas the residues in the wing are highly flexible on the pico- to nanosecond time scale. Together these studies define the surface of MuA required for enhancement of transposition in vitro and suggest that a flexible loop in the MuA protein required for DNA recognition may become structurally ordered only upon DNA binding.     

Shuttle mutagenesis: a method of transposon mutagenesis for Saccharomyces cerevisiae.

We have extended the method of transposon mutagenesis to the eukaryote, Saccharomyces cerevisiae. A bacterial transposon containing a selectable yeast gene can be transposed into a cloned fragment of yeast DNA in Escherichia coli, and the transposon insertion can be returned to the yeast genome by homologous recombination. Initially, the cloned yeast DNA fragment to be mutagenized was transformed into an E. coli strain containing an F factor derivative carrying the transposable element. The culture was grown to allow transposition and cointegrate formation and, upon conjugation, recipients were selected that contained yeast sequences with transposon insertions. The yeast DNA was removed from the vector by restriction endonuclease digestion, and the transposon insertion was transformed into yeast. The procedure required a minimum number of manipulations, and each transconjugant colony contained an independent insertion. We describe 12 transposon Tn3 derivatives for this procedure as well as several cloning vectors to facilitate the method.     

The error-free component of the RAD6/RAD18 DNA damage tolerance pathway of budding yeast employs sister-strand recombination

Evidence for an error-free DNA damage tolerance process in eukaryotes (also called postreplication repair) has existed for more than two decades, but its underlying mechanism, although known to be different from that in prokaryotes, has remained elusive. We have investigated this mechanism in Saccharomyces cerevisiae, in which it is the major component of the RAD6/RAD18 pathway, by transforming an isogenic set of rad1Delta excision-defective strains with plasmids that carry a single thymine-thymine pyrimidine (6-4) pyrimidinone photoadduct in each strand at staggered positions 28 base pairs apart. C-C mismatches placed opposite each of the T-T photoproducts permit unambiguous detection of the events that can lead to the completion of replication: sister-strand recombination or translesion replication on one or the other strand. Despite the severe block to replication that these lesions impose, we find that more than half of the plasmids were fully replicated in a rad1Delta strain and that >90% of them achieved this end by recombination between partially replicated sister strands within the interlesion region. Approximately 60-70% of these events depended on the error-free component of the RAD6/RAD18 pathway, with the remaining events depended on RAD52; these two processes account for almost all of the recombination, which depended neither on DNA polymerase zeta nor on mismatch repair. We conclude that the error-free component of the RAD6/RAD18 pathway completes replication by a mechanism employing recombination between partially replicated sister strands, possibly by means of transient template strand switching or copy choice.     

Control of transposase activity within a transpososome by the configuration of the flanking DNA segment of the transposon

The multiple steps of DNA transposition take place within a large complex called the transpososome, in which a pair of transposon DNA ends are synapsed by a multimer of the transposase protein. The final step, a DNA strand transfer reaction that joins the transposon ends to the target DNA strands, entails no net change in the number of high-energy chemical bonds. Physiology demands that, despite remaining stably associated with the transpososome, the strand transfer products undergo neither the reverse reaction nor any further cleavage reactions. Accordingly, when the Mu or Tn10 strand transfer complex was produced in vitro through transposase-catalyzed reaction steps, reverse reactions were undetectable. In contrast, when the Mu or Tn10 strand transfer complexes were assembled from DNA already having the structure of the strand transfer product, we detected a reaction that resembled reversal of target DNA strand transfer. The stereoselectivity of phosphorothioate-containing substrates indicated that this reaction proceeds as the pseudoreversal of the normal target DNA strand transfer step. Comparison of the reactivity of closely related Mu substrate DNA structures indicated that the configuration of the flanking DNA outside of the transposon sequence plays a key role in preventing the transposon end cleavage reaction after the strand transfer step.     

Strand displacement amplification as an in vitro model for rolling-circle replication: deletion formation and evolution during serial transfer.

Strand displacement amplification is an isothermal DNA amplification reaction based on a restriction endonuclease nicking its recognition site and a polymerase extending the nick at its 3' end, displacing the downstream strand. The reaction resembles rolling-circle replication of single-stranded phages and small plasmids. The displaced sense strand serves as target for an antisense reaction and vice versa, resulting in exponential growth and the autocatalytic nature of this in vitro reaction as long as the template is the limiting agent. We describe the optimization of strand displacement amplification for in vitro evolution experiments under serial transfer conditions. The reaction was followed and controlled by use of the fluorescent dye thiazole orange binding to the amplified DNA. We were able to maintain exponential growth conditions with a doubling time of 3.0 min throughout 100 transfers or approximately 350 molecular generations by using an automatic handling device. Homology of in vitro amplification with rolling-circle replication was mirrored by the occurring evolutionary processes. Deletion events most likely caused by a slipped mispairing mechanism as postulated for in vivo replication took place. Under our conditions, the mutation rate was high and a molecular quasi-species formed with a mutant lacking internal hairpin formation ability and thus outgrowing all other species under dGTP/dCTP deficiency.     

Identification and purification of a Drosophila protein that binds to the terminal 31-base-pair inverted repeats of the P transposable element.

We have used DNase I footprinting and partially fractionated nuclear extracts from Drosophila Kc tissue culture cells to identify DNA-binding proteins that interact with the terminal repeats of P transposable elements. We have identified a binding activity that interacts specifically with a region of the 31-base-pair terminal inverted repeats that is directly adjacent to the duplication of target site DNA. Binding occurs to both the 5' and 3' inverted terminal repeats irrespective of the sequence of the duplicated target DNA. UV photochemical crosslinking studies suggest that the binding activity resides in a polypeptide of 65-70 kDa. Biochemical fractionation and oligonucleotide affinity chromatography have been used to purify the binding activity to near homogeneity and identify a polypeptide of 66 kDa in the highly purified preparations. The site to which binding occurs is included in a region absolutely required for P element transposition, suggesting that this binding protein may be a cellular factor involved in P element transposition.