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.     

DNA structure specificity of Rap endonuclease.

The Rap protein of phage lambda is an endonuclease that nicks branched DNA structures. It has been proposed that Rap can nick D-loops formed during phage recombination to generate splice products without the need for the formation of a 4-strand (Holliday) junction. The structure specificity of Rap was investigated using a variety of branched DNA molecules made by annealing partially complementary oligo-nucleotides. On Holliday junctions, Rap endonuclease shows a requirement for magnesium or manganese ions, with Mn(2+)supporting 5-fold more cleavage than Mg(2+). The location of endonuclease incisions was determined on 3'-tailed D-loop, bubble, flayed duplex, 5'-flap and Y junction DNA substrates. In all cases, Rap preferentially cleaves at the branch point of these molecules. With a flayed duplex, incisions are made in the duplex adjacent to the single-strand arms. Comparison of binding and cleavage specificities revealed that Rap is highly structure-specific and exhibits a clear preference for 4- and 3-stranded DNA over Y and flayed duplex DNA. Almost no binding or cleavage was detected with duplex, partial duplex and single-stranded DNA. Thus Rap endonuclease shows a bias for structures that resemble D-loop and Holliday junction recombination intermediates.     

DNA branch nuclease activity of vaccinia A22 resolvase

DNA replication, recombination, and repair can result in formation of diverse branched DNA structures. Many large DNA viruses are known to encode DNA branch nucleases, but several of the expected activities have not previously been found among poxvirus enzymes. Vaccinia encodes an enzyme, A22 resolvase, which is known to be active on four-stranded DNA junctions (Holliday junctions) or Holliday junction-like structures containing three of the four strands. Here we report that A22 resolvase in fact has a much wider substrate specificity than previously appreciated. A22 resolvase cleaves Y-junctions, single-stranded DNA flaps, transitions from double strands to unpaired single strands ("splayed duplexes"), and DNA bulges in vitro. We also report site-directed mutagenesis studies of candidate active site residues. The results identify the likely active site and support a model in which a single active site is responsible for cleavage on Holliday junctions and splayed duplexes. Lastly, we describe possible roles for the A22 resolvase DNA-branch nuclease activity in DNA replication and repair.     

Holliday junction binding and resolution by the Rap structure-specific endonuclease of phage lambda

Rap endonuclease targets recombinant joint molecules arising from phage lambda Red-mediated genetic exchange. Previous studies revealed that Rap nicks DNA at the branch point of synthetic Holliday junctions and other DNA structures with a branched component. However, on X junctions incorporating a three base-pair core of homology or with a fixed crossover, Rap failed to make the bilateral strand cleavages characteristic of a Holliday junction resolvase. Here, we demonstrate that Rap can mediate symmetrical resolution of 50 bp and chi Holliday structures containing larger homologous cores. On two different mobile 50 bp junctions Rap displays a weak preference for cleaving the phosphodiester backbone between 5'-GC dinucleotides. The products of resolution on both large and small DNA substrates can be sealed by T4 DNA ligase, confirming the formation of nicked duplexes. Rap protein was also assessed for its capacity to influence the global conformation of junctions in the presence or absence of magnesium ions. Unlike the known Holliday junction binding proteins, Rap does not affect the angle of duplex arms, implying an unorthodox mode of junction binding. The results demonstrate that Rap can function as a Holliday junction resolvase in addition to eliminating other branched structures that may arise during phage recombination.     

Identification of RecQL1 as a Holliday junction processing enzyme in human cell lines

Homologous recombination provides an effective way to repair DNA double-strand breaks (DSBs) and is required for genetic recombination. During the process of homologous recombination, a heteroduplex DNA structure, or a ‘Holliday junction’ (HJ), is formed. The movement, or branch migration, of this junction is necessary for recombination to proceed correctly. In prokaryotes, the RecQ protein or the RuvA/RuvB protein complex can promote ATP-dependent branch migration of Holliday junctions. Much less is known about the processing of Holliday junctions in eukaryotes. Here, we identify RecQL1 as a predominant ATP-dependent, HJ branch migrator present in human nuclear extracts. A reduction in the level of RecQL1 induced by RNA interference in HeLa cells leads to an increase in sister chromatid exchange. We propose that RecQL1 is involved in the processing of Holliday junctions in human cells.     

Interactions of human rad54 protein with branched DNA molecules

The Rad54 protein plays an important role during homologous recombination in eukaryotes. The protein belongs to the Swi2/Snf2 family of ATP-dependent DNA translocases. We previously showed that yeast and human Rad54 (hRad54) specifically bind to Holliday junctions and promote branch migration. Here we examined the minimal DNA structural requirements for optimal hRad54 ATPase and branch migration activity. Although a 12-bp double-stranded DNA region of branched DNA is sufficient to induce ATPase activity, the minimal substrate that gave rise to optimal stimulation of the ATP hydrolysis rate consisted of two short double-stranded DNA arms, 15 bp each, combined with a 45-nucleotide single-stranded DNA branch. We showed that hRad54 binds preferentially to the open and not to the stacked conformation of branched DNA. Stoichiometric titration of hRad54 revealed formation of two types of hRad54 complexes with branched DNA substrates. The first of them, a dimer, is responsible for the ATPase activity of the protein. However, branch migration activity requires a significantly higher stoichiometry of hRad54, approximately 10 +/- 2 protein monomers/DNA molecule. This pleomorphism of hRad54 in formation of oligomeric complexes with DNA may correspond to multiple functions of the protein in homologous recombination.     

The role of the SAP motif in promoting Holliday junction binding and resolution by SpCCE1

Holliday junctions are four-way branched DNA structures that are formed during recombination and by replication fork regression. Their processing depends on helicases that catalyze junction branch migration, and endonucleases that resolve the junction into nicked linear DNAs. Here we have investigated the role of a DNA binding motif called SAP in binding and resolving Holliday junctions by the fission yeast mitochondrial resolvase SpCCE1. Mutation or partial/complete deletion of the SAP motif dramatically impairs the ability of SpCCE1 to resolve Holliday junctions in a heterologous in vivo system. These mutant proteins retain the ability to recognize the junction structure and to distort it upon binding. However, once formed the mutant protein-junction complexes are relatively unstable and dissociate much faster than wild-type complexes. We show that binding stability is necessary for efficient junction resolution, and that this may be due in part to a requirement for maintaining the junction in an open conformation so that it can branch migrate to cleavable sites.     

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.     

Action of RecBCD enzyme on cruciform DNA

We tested the hypothesis that RecBCD enzyme of Escherichia coli resolves pre-existing Holliday recombination intermediates by examining the action of the purified enzyme on an open-ended DNA cruciform with limited ability to branch migrate. The enzyme cleaved two strands of the cruciform near its base to produce "recombinant" products, with a marked bias in the direction of cleavage. The two nicks necessary to cleave the cruciform were made separately. Cruciforms whose four termini were blocked by synthetic hairpin-shaped oligonucleotides were not detectably nicked by the enzyme. With one terminus open the enzyme made a nick at the base of the cruciform but not a double-strand cut. With two or more termini open the enzyme made double-strand cuts. We infer that RecBCD enzyme molecules must enter the termini of duplex DNA and approach the cruciform from more than one direction in order to cleave it into recombinant products. Previous results on RecBCD-mediated recombination between phage lambda and lambda dv imply that intracellular RecBCD enzyme can approach pre-existing Holliday junctions from only one direction. We infer that intracellular RecBCD enzyme cannot cleave pre-existing Holliday junctions into recombinants and suggest that the enzyme may cleave Holliday junctions in whose formation it participates.     

RuvAB-directed branch migration of individual Holliday junctions is impeded by sequence heterology

The Holliday junction, the key intermediate of recombination, is generated by strand exchange resulting in a covalent connection between two recombining DNA molecules. Translocation of a Holliday junction along DNA, or branch migration, progressively exchanges one DNA strand for another and determines the amount of information that is transferred between two recombining partners. In Escherichia coli, the RuvAB protein complex promotes rapid and unidirectional branch migration of Holliday junctions. We have studied translocation of Holliday junctions using a quantitative biochemical system together with a 'single-molecule' branch migration assay. We demonstrate that RuvAB translocates the junctions through identical DNA sequences in a processive manner with a broad distribution of individual branch migration rates. However, when the complex encounters short heterologous sequences, translocation of the Holliday junctions is impeded. We conclude that translocation of the junctions through a sequence heterology occurs with a probability of bypass being determined both by the length of the heterologous region and the lifetime of the stalled RuvAB complex.     

Thermodynamics of DNA branching.

Branched DNA molecules arise transiently as intermediates in genetic recombination or on extrusion of cruciforms from covalent circular DNA duplexes that contain palindromic sequences. The free energy of these structures relative to normal DNA duplexes is of interest both physically and biologically. Oligonucleotide complexes that can form stable branched structures, DNA junctions, have made it possible to model normally unstable branched states of DNA such as Holliday recombinational intermediates. We present here an evaluation of the free energy of creating four-arm branch points in duplex DNA, using a system of two complementary junctions and four DNA duplexes formed from different combinations of the same set of eight 16-mer strands. The thermodynamics of formation of each branched structure from the matching pair of intact duplexes have been estimated in two experiments. In the first, labeled strands are allowed to partition between duplexes and junctions in a competition assay on polyacrylamide gels. In the second, the heats of forming branched or linear molecules from the component strands have been determined by titration microcalorimetry at several temperatures. Taken together these measurements allow us to determine the standard thermodynamic parameters for the process of creating a branch in an otherwise normal DNA duplex. The free energy for reacting two 16-mer duplexes to yield a four-arm junction in which the branch site is incapable of migrating is + 1.1 (+/- 0.4) kcal mol-1 (at 18 degrees C, 10 mM-Mg2+). Analysis of the distribution of duplex and tetramer products by electrophoresis confirms that the free energy difference between the four duplexes and two junctions is small at this temperature. The associated enthalpy change at 18 degrees C is +27.1 (+/- 1.3) kcal mol-1, while the entropy is +89 (+/- 30) cal K-1 mol-1. The free energy for branching is temperature dependent, with a large unfavorable enthalpy change compensated by a favorable entropy term. Since forming one four-stranded complex from two duplexes should be an entropically unfavorable process, branch formation is likely to be accompanied by significant changes in hydration and ion binding. A significant apparent delta Cp is also observed for the formation of one mole of junction, +0.97 (+/-0.05) kcal deg-1 mol-1.     

ATP-dependent branch migration of Holliday junctions promoted by the RuvA and RuvB proteins of E. coli.

The RuvA and RuvB proteins of E. coli, which are induced as part of the cellular response to DNA damage, act together to promote the branch migration of Holliday junctions. Addition of purified RuvA and RuvB to a RecA-mediated recombination reaction stimulates the rate of strand exchange and the formation of hetero-duplex DNA. Stimulation does not occur via interaction with RecA; instead, RuvA and RuvB act directly upon recombination intermediates (Holliday junctions) made by RecA. We show that RuvAB-mediated branch migration requires ATP and can bypass UV-induced DNA lesions. At high RuvB concentrations, the requirement for RuvA is overcome, indicating that the RuvB ATPase provides the motor force for branch migration. RuvA protein provides specificity by binding to the Holliday junction, thereby reducing the requirement for RuvB by 50-fold. The newly discovered biochemical properties of RuvA, RuvB, and RuvC are incorporated into a model for the postreplicational repair of DNA following UV irradiation.     

Torsional control of double-stranded DNA branch migration

DNA branched junctions are analogues of Holliday junction recombination intermediates. Partially mobile junctions contain a limited amount of homology flanking the branch point. A partially mobile DNA branched junction has been incorporated into a synthetic double-stranded circular DNA molecule. The junction is flanked by four homologous nucleotide pairs, so that there are five possible locations for the branch point. Two opposite arms of the branched junction are joined to form the circular molecule, which contains 262 nucleotides to the base of the junction. This molecule represents a system whereby torque applied to the circular molecule can have an impact on the junction, by relocating its branch point. Ligation of the molecule produces two topoisomers; about 87% of the product is a relaxed molecule, and the rest is a molecule with one positive supercoil. The position of the branch point is assayed by cleaving the molecule with endonuclease VII. We find that the major site of the branch point in the relaxed topoisomer is at the maximally extruded position in the relaxed molecule. Upon the addition of ethidium, the major site of the branch point migrates to the minimally extruded position. © 1998 John Wiley & Sons, Inc. Biopoly 45: 69–83, 1998     

Partial suppression of the fission yeast rqh1(-) phenotype by expression of a bacterial Holliday junction resolvase

A key stage during homologous recombination is the processing of the Holliday junction, which determines the outcome of the recombination reaction. To dissect the pathways of Holliday junction processing in a eukaryote, we have targeted an Escherichia coli Holliday junction resolvase to the nuclei of fission yeast recombination-deficient mutants and analysed their phenotypes. The resolvase partially complements the UV and hydroxyurea hypersensitivity and associated aberrant mitoses of an rqh1(-) mutant. Rqh1 is a member of the RecQ subfamily of DNA helicases that control recombination particularly during S-phase. Significantly, overexpression of the resolvase in wild-type cells partly mimics the loss of viability, hyper-recombination and 'cut' phenotype of an rqh1(-) mutant. These results indicate that Holliday junctions form in wild-type cells that are normally removed in a non-recombinogenic way, possibly by Rqh1 catalysing their reverse branch migration. We propose that in the absence of Rqh1, replication fork arrest results in the accumulation of Holliday junctions, which can either impede sister chromatid segregation or lead to the formation of recombinants through Holliday junction resolution.     

Resolution of Holliday junction analogs by T4 endonuclease VII can be directed by substrate structure

Endonuclease VII is an enzyme from bacteriophage T4 capable of resolving four-arm Holliday junction intermediates in recombination. Since natural Holliday junctions have homologous (2-fold) sequence symmetry, they can branch migrate, creating a population of substrates that have the branch point at different sites. We have explored the substrate requirements of endonuclease VII by using immobile analogs of Holliday junctions that lack this homology, thereby situating the branch point at a fixed site in the molecule. We have found that immobile junctions whose double-helical arms contain fewer than nine nucleotide pairs do not serve as substrates for resolution by endonuclease VII. Scission of substrates with 2-fold symmetrically elongated arms produces resolution products that are a function of the particular arms that are lengthened. We have confirmed that the scission products are those of resolution, rather than nicking of individual strands, by using shamrock junction molecules formed from a single oligonucleotide strand. A combination of end-labeled and internally labeled shamrock molecules has been used to demonstrate that all of the scission is due to coordinated cleavage of DNA on opposite sides of the junction, 3' to the branch point. Endonuclease VII is known to cleave the crossover strands of Holliday junctions in this fashion. The relationship of the long arms to the cleavage direction suggests that the portion of the enzyme which requires the minimum arm length interacts with the pair of arms containing the 3' portion of the crossover strands on the bound surface of the antiparallel junction.     

Functional interactions between the holliday junction resolvase and the branch migration motor of Escherichia coli.

Homologous recombination generates genetic diversity and provides an important cellular pathway for the repair of double-stranded DNA breaks. Two key steps in this process are the branch migration of Holliday junctions followed by their resolution into mature recombination products. In E.coli, branch migration is catalysed by the RuvB protein, a hexameric DNA helicase that is loaded onto the junction by RuvA, whereas resolution is promoted by the RuvC endonuclease. Here we provide direct evidence for functional interactions between RuvB and RuvC that link these biochemically distinct processes. Using synthetic Holliday junctions, RuvB was found to stabilize the binding of RuvC to a junction and to stimulate its resolvase activity. Conversely, RuvC facilitated interactions between RuvB and the junction such that RuvBC complexes catalysed branch migration. The observed synergy between RuvB and RuvC provides new insight into the structure and function of a RuvABC complex that is capable of facilitating branch migration and resolution of Holliday junctions via a concerted enzymatic mechanism.     

Recognition and manipulation of branched DNA by the RusA Holliday junction resolvase of Escherichia coli.

Homologous recombination is a fundamental cellular process that shapes and reshapes the genomes of all organisms and promotes repair of damaged DNA. A key step in this process is the resolution of Holliday junctions formed by homologous DNA pairing and strand exchange. In Escherichia coli , a Holliday junction is processed into recombinant products by the concerted activities of the RuvA and RuvB proteins, which together drive branch migration, and RuvC endonuclease, which resolves the structure. In the absence of RuvABC, recombination can be promoted by increasing the expression of the RusA endonuclease, a Holliday junction resolvase encoded by a cryptic prophage gene. Here, we describe the DNA binding properties of RusA. We found that RusA was highly selective for branched molecules and formed complexes with these structures even in the presence of a large excess of linear duplex DNA. However, it does bind weakly to linear duplex DNA. Under conditions where there was no detectable binding to duplex DNA, RusA formed a highly structured complex with a synthetic Holliday junction that was remarkably stable and insensitive to divalent metal ions. The duplex arms were found to adopt a specific alignment within this complex that approximated to a tetrahedral conformation of the junction.     

Fission yeast Mus81.Eme1 Holliday junction resolvase is required for meiotic crossing over but not for gene conversion

Most models of homologous recombination invoke cleavage of Holliday junctions to explain crossing over. The Mus81.Eme1 endonuclease from fission yeast and humans cleaves Holliday junctions and other branched DNA structures, leaving its physiological substrate uncertain. We report here that Schizosaccharomyces pombe mus81 mutants have normal or elevated frequencies of gene conversion but 20- to 100-fold reduced frequencies of crossing over. Thus, gene conversion and crossing over can be genetically separated, and Mus81 is required for crossing over, supporting the hypothesis that the fission yeast Mus81.Eme1 protein complex resolves Holliday junctions in meiotic cells.     

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.