The phage T4 protein UvsW drives Holliday junction branch migration

The phage T4 UvsW protein has been shown to play a crucial role in the switch from origin-dependent to recombination-dependent replication in T4 infections through the unwinding of origin R-loop initiation intermediates. UvsW also functions with UvsX and UvsY to repair damaged DNA through homologous recombination, and, based on genetic evidence, has been proposed to act as a Holliday junction branch migration enzyme. Here we report the purification and characterization of UvsW. Using oligonucleotide-based substrates, we confirm that UvsW unwinds branched DNA substrates, including X and Y structures, but shows little activity in unwinding linear duplex substrates with blunt or single-strand ends. Using a novel Holliday junction-containing substrate, we also demonstrate that UvsW promotes the branch migration of Holliday junctions efficiently through more than 1000 bp of DNA. The ATP hydrolysis-deficient mutant protein, UvsW-K141R, is unable to promote Holliday junction branch migration. However, both UvsW and UvsW-K141R are capable of stabilizing Holliday junctions against spontaneous branch migration when ATP is not present. Using two-dimensional agarose gel electrophoresis we also show that UvsW acts on T4-generated replication intermediates, including Holliday junction-containing X-shaped intermediates and replication fork-shaped intermediates. Taken together, these results strongly support a role for UvsW in the branch migration of Holliday junctions that form during T4 recombination, replication, and repair.     

A method for preparing genomic DNA that restrains branch migration of Holliday junctions

The Holliday junction is a central intermediate in genetic recombination. This four-stranded DNA structure is capable of spontaneous branch migration, and is lost during standard DNA extraction protocols. In order to isolate and characterize recombination intermediates that contain Holliday junctions, we have developed a rapid protocol that restrains branch migration of four-way DNA junctions. The cationic detergent hex-adecyltrimethylammonium bromide is used to lyse cells and precipitate DNA. Manipulations are performed in the presence of the cations hexamine cobalt(III) or magnesium, which stabilize Holliday junctions in a stacked-X configuration that branch migrates very slowly. This protocol was evaluated using a sensitive assay for spontaneous branch migration, and was shown to preserve both artificial Holliday junctions and meiotic recombination intermediates containing four-way junctions.     

Illegitimate recombination in Xenopus: characterization of end-joined junctions.

When linear DNAs are injected into Xenopus laevis eggs, they are converted into several different kinds of recombination products. Some molecules undergo homologous recombination by a resection-annealing mechanism; some ends are precisely ligated; and some ends are joined by illegitimate means. The homologous and illegitimate products are also generated in nuclear extracts from stage VI Xenopus oocytes. In order to gain insight into the mechanism(s) of illegitimate end joining, we amplified, cloned and sequenced a number of junctions from eggs and from oocyte extracts. The egg junctions fell into three categories: some with no homology at the join point that may have been produced by blunt-end ligation; some based on small, but significant homologies (5-10 bp); and some with matches of only 1 or 2 nucleotides at the joint. Junctions made in oocyte extracts were largely of the latter type. In the extracts, formation of illegitimate joints required the addition of all four deoxyribonucleoside triphosphates and was inhibited by aphidicolin. This indicates that this process involves DNA synthesis, and mechanisms incorporating this feature are considered. The spectrum of recombination products formed in Xenopus eggs is very reminiscent of those produced from DNA introduced into mammalian cells.     

Repair of Heteroduplex DNA in Xenopus Laevis Oocytes

We have hypothesized that the inheritance of heteroallelic markers during recombination of homologous DNAs in Xenopus oocytes is determined by resolution of a heteroduplex intermediate containing multiple single-base mismatches. To test this idea, we prepared synthetic heteroduplexes carrying 8 separate mispairs in vitro and injected them into oocyte nuclei. DNA was recovered and analyzed directly, by Southern blot-hybridization, and indirectly, by cloning individual repair products in bacteria. Mismatch correction was quite efficient in the oocytes; markers on the same strand were commonly co-corrected, indicating a long-patch mechanism; and the distribution of markers was very similar to that obtained by recombination. This supports our interpretation of the recombination outcome in terms of a resection-annealing mechanism. The injected heteroduplexes carried strand breaks (nicks) as a result of their method of preparation. We tested the idea that mismatch correction might be nick-directed by ligating the strands of the heteroduplex substrate to form covalently closed circles. Repair in oocytes was still efficient, and long patches predominated; but the pattern of recovered markers was quite different than with the nicked substrate. This suggests that nicks, when present, do indeed direct repair, but that, in their absence, recognition of specific mismatches governs repair of the ligated heteroduplexes.     

Discrete and continuous mathematical models of DNA branch migration

DNA junctions, known as Holliday junctions, are intermediates in genetic recombination between DNAs. In this structure, two double-stranded DNA helices with similar sequence are joined at a branch point. The branch point can move along these helices when strands with the same sequence are exchanged. Such branch migration is modeled as a random walk. First, we model this process discretely, such that the motion of the branch is represented as transfer between discrete compartments. This is useful in analysing the results of DNA branch migration on junction comprised of synthetic oligonucleotides. The limit in which larger numbers of smaller steps go to continuous motion of the branch is also considered. We show that the behavior of the continuous system is very similar to that of the discrete system when there are more than just a few compartments. Thus, even branch migration on oligonucleotides can be viewed as a continuous process. One consequence of this is that a step size must be assumed when determining rate constants of branch migration.We compare migration where forward and backward movements of the branch are equally probable to biased migration where one direction is favored over the other. In the latter case larger differences between the discrete and continuous cases are predicted, but the differences are still small relative to the experimental error associated with experiments to measure branch migration in oligonucleotides.     

Effect of terminal nonhomologies on homologous recombination in Xenopus laevis oocytes.

Homologous recombination of linear DNA molecules in Xenopus laevis oocytes is very efficient. The predictions of molecular models for this recombination process were tested with substrates with terminal nonhomologies (nonhomologous sequences). It was found that nonhomologies on one or both ends of an otherwise efficient substrate substantially reduced the yield of recombination products. In the case of a single nonhomology, inhibition was observed for all lengths of nonhomology, from 60 to 1,690 bp, being most dramatic for the longer blocks. Examination of time courses of recombination showed that the blocks were largely kinetic; that is, substrates with short nonhomologies eventually yielded substantial levels of completed products. Intermediates that accumulated after the injection of end-blocked substrates were characterized by two-dimensional gel electrophoresis and hybridization with strand-specific oligonucleotide probes. These blocked intermediates were shown to have base-paired junctions, but resolution was prevented by the failure to remove the 3'-ending strand of the original nonhomology. Continuing exonuclease action created a single-strand gap adjacent to the position of the persistent nonhomology. In contrast, the strand that included the unblocked side of the junction could be sealed. These results are consistent with a nonconservative, resection-annealing mechanism of homologous recombination in the oocytes and suggest the absence of any activity that can efficiently remove 3' tails.     

Homologous and illegitimate recombination in developing Xenopus oocytes and eggs.

Exogenous DNA is efficiently recombined when injected into the nuclei of Xenopus laevis oocytes. This reaction proceeds by a homologous resection-annealing mechanism which depends on the activity of a 5'-->3' exonuclease. Two possible functions for this recombination activity have been proposed: it may be a remnant of an early process in oogenesis, such as meiotic recombination or amplification of genes coding for rRNA, or it may reflect materials stored for embryogenesis. To test these hypotheses, recombination capabilities were examined with oocytes at various developmental stages. Late-stage oocytes performed only homologous recombination, whereas the smallest oocytes ligated the restriction ends of the injected DNA but supported no homologous recombination. This transition from ligation to recombination activity was also seen in nuclear extracts from these same stages. Exonuclease activity was measured in the nuclear extracts and found to be low in early stages and then to increase in parallel with recombination capacity in later stages. The accumulation of exonuclease and recombination activities during oogenesis suggests that they are stored for embryogenesis and are not present for oocyte-specific functions. Eggs were also tested and found to catalyze homologous recombination, ligation, and illegitimate recombination. Retention of homologous recombination in eggs is consistent with an embryonic function for the resection-annealing mechanism. The observation of all three reactions in eggs suggests that multiple pathways are available for the repair of double-strand breaks during the extremely rapid cleavage stages after fertilization.     

Branch Migration Prevents DNA Loss during Double-Strand Break Repair

The repair of DNA double-strand breaks must be accurate to avoid genomic rearrangements that can lead to cell death and disease. This can be accomplished by promoting homologous recombination between correctly aligned sister chromosomes. Here, using a unique system for generating a site-specific DNA double-strand break in one copy of two replicating Escherichia coli sister chromosomes, we analyse the intermediates of sister-sister double-strand break repair. Using two-dimensional agarose gel electrophoresis, we show that when double-strand breaks are formed in the absence of RuvAB, 4-way DNA (Holliday) junctions are accumulated in a RecG-dependent manner, arguing against the long-standing view that the redundancy of RuvAB and RecG is in the resolution of Holliday junctions. Using pulsed-field gel electrophoresis, we explain the redundancy by showing that branch migration catalysed by RuvAB and RecG is required for stabilising the intermediates of repair as, when branch migration cannot take place, repair is aborted and DNA is lost at the break locus. We demonstrate that in the repair of correctly aligned sister chromosomes, an unstable early intermediate is stabilised by branch migration. This reliance on branch migration may have evolved to help promote recombination between correctly aligned sister chromosomes to prevent genomic rearrangements.     

Branch migration of three-strand recombination intermediates by RecG, a possible pathway for securing exchanges initiated by 3''-tailed duplex DNA.

RecG protein is required for normal levels of recombination and DNA repair in Escherichia coli. This 76 kDa polypeptide is a junction-specific DNA helicase that acts post-synaptically to drive branch migration of Holliday junction intermediates made by RecA during the strand exchange stage of recombination. To gain further insight into the role of RecG, we studied its activity on three-strand intermediates formed by RecA between circular single-stranded and linear duplex DNAs. Once RecA is removed, RecG drives branch migration of these intermediates by a junction-targeted activity that depends on hydrolysis of ATP. RuvAB has a similar activity. However, when RecG is added to a RecA strand exchange reaction it severely reduces the accumulation of joint molecule intermediates by driving branch migration of junctions in the reverse direction to that catalysed by RecA strand exchange. In comparison, RuvAB has little effect on the reaction. We discuss how reverse branch migration by RecG, which acts counter of the 5'-->3' polarity of RecA binding and strand exchange, could serve to promote or abort the early stages of recombination, depending on the orientation of the single DNA strand initiating the exchange relative to the adjacent duplex region.     

Escherichia coli RuvBL268S: a mutant RuvB protein that exhibits wild-type activities in vitro but confers a UV-sensitive ruv phenotype in vivo.

The RuvABC proteins of Escherichia coli process recombination intermediates during genetic recombination and DNA repair. RuvA and RuvB promote branch migration of Holliday junctions, a process that extends heteroduplex DNA. Together with RuvC, they form a RuvABC complex capable of Holliday junction resolution. Branch migration by RuvAB is mediated by RuvB, a hexameric ring protein that acts as an ATP-driven molecular pump. To gain insight into the mechanism of branch migration, random mutations were introduced into the ruvB gene by PCR and a collection of mutant alleles were obtained. Mutation of leucine 268 to serine resulted in a severe UV-sensitive phenotype, characteristic of a ruv defect. Here, we report a biochemical analysis of the mutant protein RuvBL268S. Unexpectedly, the purified protein is fully active in vitro with regard to its ATPase, DNA binding and DNA unwinding activities. It also promotes efficient branch migration in combination with RuvA, and forms functional RuvABC-Holliday junction resolvase complexes. These results indicate that RuvB may perform some additional, and as yet undefined, function that is necessary for cell survival after UV-irradiation.     

Theoretical analysis of DNA branch migration in the presence of a slow reversible initiation step

Branched DNA structures include several DNA regions connected by three- or four-way DNA junctions. Branched DNAs can be intermediates in DNA replication and recombination in living organisms and in sequence-specific DNA targeting in vitro. Branched DNA structures are usually metastable and irreversibly dissociate to non-branched products via a DNA strand exchange process commonly known as DNA branch migration. The key parameter in the DNA dissociation process is its characteristic time, which depends on the length of the dissociating DNA structure. Here, we predict that the presence of a slow reversible initiation step, which precedes DNA branch migration, can alter, to almost linear dependence, the "classic" quadratic dependence of the dissociation time on the length of the dissociating DNA structure. This prediction can be applied to dissociation of Y-like DNA structures and double D-loop DNA hybrids, which are DNA structures similar to replication bubbles. In addition, the slow initiation step can increase the effect of DNA sequence heterologies within the structure on its kinetic stability. Applications of our analysis for genetic manipulations with branched DNA structures are discussed.     

Holliday junction resolution in human cells: two junction endonucleases with distinct substrate specificities

Enzymatic activities that cleave Holliday junctions are required for the resolution of recombination intermediates and for the restart of stalled replication forks. Here we show that human cell-free extracts possess two distinct endonucleases that can cleave Holliday junctions. The first cleaves Holliday junctions in a structure- and sequence-specific manner, and associates with an ATP-dependent branch migration activity. Together, these activities promote branch migration/resolution reactions similar to those catalysed by the Escherichia coli RuvABC resolvasome. Like RuvC-mediated resolution, the products can be religated. The second, containing Mus81 protein, cuts Holliday junctions but the products are mostly non-ligatable. Each nuclease has a defined substrate specificity: the branch migration-associated resolvase is highly specific for Holliday junctions, whereas the Mus81-associated endonuclease is one order of magnitude more active upon replication fork and 3'-flap structures. Thus, both nucleases are capable of cutting Holliday junctions formed during recombination or through the regression of stalled replication forks. However, the Mus81-associated endonuclease may play a more direct role in replication fork collapse by catalysing the cleavage of stalled fork structures.     

T-T base mismatches enhance drug binding at the branch site in a four-arm DNA junction.

Base mismatches--non Watson-Crick pairing between bases--can arise in duplex DNA as a consequence of mutational events or by recombination. In a duplex, the sequence of the two bases involved, and those flanking the site of mismatch, determines the local structure and extent of destabilization of the helix. Base mismatches can arise also in recombination of nonhomologous strands, and their occurrence in Holliday recombination intermediates can influence the outcome of general or specialized recombination events. We have previously reported that the branch site in a DNA junction can interact selectively with a variety of ligands. Here we describe the thermodynamics of junctions containing T-T mismatches flanking the branch and show that these structures bind methidium and other intercalators with higher affinity than junctions lacking mismatches.     

DNA recombination: holliday junctions dynamics and branch migration

Holliday junctions are critical intermediates for homologous, site-specific recombination, DNA repair, and replication. A wealth of structural information is available for immobile four-way junctions, but the controversy on the mechanism of branch migration of Holliday junctions remains unsolved. Two models for the mechanism of branch migration were suggested. According to the early model of Alberts-Meselson-Sigal (Sigal, N., and Alberts, B. (1972) J. Mol. Biol. 71, 789-793 and Meselson, M. (1972) J. Mol. Biol. 71, 795-798), exchanging DNA strands around the junction remain parallel during branch migration. Kinetic studies of branch migration (Panyutin, I. G., and Hsieh, P. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 2021-2025) suggest an alternative model in which the junction adopts an extended conformation. We tested these models using a Holliday junction undergoing branch migration and time-lapse atomic force microscopy, an imaging technique capable of imaging DNA dynamics. The single molecule atomic force microscopy experiments performed in the presence and in the absence of divalent cations show that mobile Holliday junctions adopt an unfolded conformation during branch migration that is retained despite a broad range of motion in the arms of the junction. This conformation of the junction remains unchanged until strand separation. The data obtained support the model for branch migration having the extended conformation of the Holliday junction.     

Dissociation of synthetic Holliday junctions by E. coli RecG protein.

The RecG protein of Escherichia coli is needed for normal levels of recombination and for repair of DNA damaged by ultraviolet light, mitomycin C and ionizing radiation. The true extent of its involvement in these processes is masked to a large degree by what appears to be a functional overlap with the products of the three ruv genes. RuvA and RuvB act together to promote branch migration of Holliday junctions, while RuvC catalyses the resolution of these recombination intermediates into viable products by endonuclease cleavage. In this paper, we describe the overproduction and purification of RecG and demonstrate that the overlap extends to the biochemistry. We show that the 76 kDa RecG protein is a DNA-dependent ATPase, like RuvB. Using gel retardation assays we demonstrate that it binds specifically to a synthetic Holliday junction, like RuvA and RuvC. Finally, we show that in the presence of ATP and Mg2+, RecG dissociates these junctions to duplex products, like RuvAB. We suggest that RecG and RuvAB provide alternative activities than can promote branch migration of Holliday junctions in recombination and DNA repair.     

Distribution of Exchanges upon Homologous Recombination of Exogenous DNA in Xenopus Laevis Oocytes

Homologous recombination between DNA molecules injected into Xenopus oocyte nuclei was investigated by examining the recovery of information from differentially marked parental sequences. The injected recombination substrate was a linear DNA with terminal direct repeats of 1246 bp; one repeat differed from the other by eight single base-pair substitutions, distributed throughout the region of homology, each of which created or destroyed a restriction enzyme site. Recombination products were recovered and analyzed for their content of the diagnostic sites, either directly by Southern blot-hybridization or after cloning in bacteria. The majority (76%) of the cloned products appeared to be the result of simple exchanges-i.e., there was one sharp transition from sequences derived from one parent to sequences derived from the other. These simple exchanges were concentrated near the ends of the homologous interval and, thus, near the sites of the original molecular ends. Placing marked sites on only one side of the homologous overlap showed that marker recovery was governed largely by the positions of the molecular ends and not by the markers themselves. When a terminal nonhomology was present at one end of the substrate, the yield of recombinants was sharply decreased, but the pattern of exchanges was not affected, suggesting that products from end-blocked substrates arise by the same recombination pathway. Because of considerable evidence supporting a nonconservative, resection-annealing mechanism for recombination in oocytes, we interpret the distribution of exchanges as resulting from long-patch repair of extensive heteroduplex intermediates.     

The E.coli RuvAB proteins branch migrate Holliday junctions through heterologous DNA sequences in a reaction facilitated by SSB.

During genetic recombination a heteroduplex joint is formed between two homologous DNA molecules. The heteroduplex joint plays an important role in recombination since it accommodates sequence heterogeneities (mismatches, insertions or deletions) that lead to genetic variation. Two Escherichia coli proteins, RuvA and RuvB, promote the formation of heteroduplex DNA by catalysing the branch migration of crossovers, or Holliday junctions, which link recombining chromosomes. We show that RuvA and RuvB can promote branch migration through 1800 bp of heterologous DNA, in a reaction facilitated by the presence of E.coli single-stranded DNA binding (SSB) protein. Reaction intermediates, containing unpaired heteroduplex regions bound by SSB, were directly visualized by electron microscopy. In the absence of SSB, or when SSB was replaced by a single-strand binding protein from bacteriophage T4 (gene 32 protein), only limited heterologous branch migration was observed. These results show that the RuvAB proteins, which are induced as part of the SOS response to DNA damage, allow genetic recombination and the recombinational repair of DNA to occur in the presence of extensive lengths of heterology.     

Branch migration of Holliday junctions: identification of RecG protein as a junction specific DNA helicase.

The product of the recG gene of Escherichia coli is needed for normal recombination and DNA repair in E. coli and has been shown to help process Holliday junction intermediates to mature products by catalysing branch migration. The 76 kDa RecG protein contains sequence motifs conserved in the DExH family of helicases, suggesting that it promotes branch migration by unwinding DNA. We show that RecG does not unwind blunt ended duplex DNA or forked duplexes with short unpaired single-strand ends. It also fails to unwind a partial duplex (52 bp) classical helicase substrate containing a short oligonucleotide annealed to circular single-stranded DNA. However, unwinding activity is detected when the duplex region is reduced to 26 bp or less, although this requires high levels of protein. The unwinding proceeds with a clear 3' to 5' polarity with respect to the single strand bound by RecG. Substantially higher levels of unwinding are observed with substrates containing a three-way duplex branch. This is attributed to RecG's particular affinity for junction DNA which we demonstrate would be heightened by single-stranded DNA binding protein in vivo. Reaction requirements for unwinding are the same as for branch migration of Holliday junctions, with a strict dependence on hydrolysis of ATP. These results define RecG as a new class of helicase that has evolved to catalyse the branch migration of Holliday junctions.     

Resolution of undistorted symmetric immobile DNA junctions by vaccinia topoisomerase I

Holliday junctions are intermediates in genetic recombination. They consist of four strands of DNA that flank a branch point. In natural systems, their sequences have 2-fold (homologous) sequence symmetry. This symmetry enables the molecules to undergo an isomerization, known as branch migration, that relocates the site of the branch point. Branch migration leads to polydispersity, which makes it difficult to characterize the physical properties of the junction and the effects of the sequence context flanking the branch point. Previous studies have reported two symmetric junctions that do not branch migrate: one that is immobilized by coupling to an asymmetric junction in a double crossover context, and a second that is based on molecules containing 5',5' and 3',3' linkages. Both are flawed by distorting the structure of the symmetric junction from its natural conformation. Here, we report an undistorted symmetric immobile junction based on the use of DNA parallelogram structures. We have used a series of these junctions to characterize the junction resolution reaction catalyzed by vaccinia virus DNA topoisomerase. The resolution reaction entails cleavage and rejoining at CCCTT/N recognition sites arrayed on opposing sides of the four-arm junction. We find that resolution is optimal when the scissile phosphodiester (Tp/N) is located two nucleotides 5' to the branch point on the helical strand. Covalent topoisomerase-DNA adducts are precursors to recombinant strands in all reactions, as expected. Kinetic analysis suggests a rate limiting step after the first-strand cleavage.     

Unusual stability of recombination intermediates made by Escherichia coli RecA protein.

The structure and stability of recombination intermediates made by RecA protein have been investigated following deproteinization. The intermediates consist of two duplex DNA molecules connected by a junction, as visualized by electron microscopy. Although we expected the structures to be highly unstable due to branch migration of the junction, this was not the case. Instead, we found that the intermediates were stable at 37 degrees C. At 56 degrees C, greater than 60% of the intermediates remained after 6 h of incubation. Only at higher temperatures was significant branch migration observed. This unexpected stability suggests that the formation of extensive lengths of heteroduplex DNA in Escherichia coli is likely to require the continued action of proteins, and does not occur via spontaneous branch migration. We show that heteroduplex DNA may be formed in vitro by ATP-dependent strand exchange catalysed by RecA protein or by the RuvA and RuvB proteins of E. coli.