Interactions between RuvA and RuvC at Holliday junctions: inhibition of junction cleavage and formation of a RuvA-RuvC-DNA complex

Revealing the DNA Unwinding Activity and Mechanism of Fork Reversal by RecG While Exposed to Variants of Stalled Replication-fork at Single-Molecular Resolution

RecG, belonging to the category of Superfamily-2 plays a vital role in rescuing different kinds of stalled fork. The elemental mechanism of the helicase activity of RecG with several non-homologous stalled fork structures resembling intermediates formed during the process of DNA repair has been investigated in the present study to capture the dynamic stages of genetic rearrangement. The functional characterization has been exemplified through quantifying the response of the substrate in terms of their molecular heterogeneity and dynamical response by employing single-molecule fluorescence methods. An elevated processivity of RecG is observed for the stalled fork where progression of lagging daughter strand is ahead as compared to that of the leading strand. Through precise alteration of its function in terms of unwinding, depending upon the substrate DNA, RecG catalyzes the formation of Holliday junction from a stalled fork DNA. RecG is found to adopt an asymmetric mode of locomotion to unwind the lagging daughter strand for facilitating formation of Holliday junction that acts as a suitable intermediate for recombinational repair pathway. Our results emphasize the mechanism adopted by RecG during its 'sliding back' mode along the lagging daughter strand to be 'active translocation and passive unwinding'. This also provide clues as to how this helicase decides and controls the mode of translocation along the DNA to unwind.

Single-molecule insight into stalled replication fork rescue in Escherichia coli

DNA replication forks stall at least once per cell cycle in Escherichia coli. DNA replication must be restarted if the cell is to survive. Restart is a multi-step process requiring the sequential action of several proteins whose actions are dictated by the nature of the impediment to fork progression. When fork progress is impeded, the sequential actions of SSB, RecG and the RuvABC complex are required for rescue. In contrast, when a template discontinuity results in the forked DNA breaking apart, the actions of the RecBCD pathway enzymes are required to resurrect the fork so that replication can resume. In this review, we focus primarily on the significant insight gained from single-molecule studies of individual proteins, protein complexes, and also, partially reconstituted regression and RecBCD pathways. This insight is related to the bulk-phase biochemical data to provide a comprehensive review of each protein or protein complex as it relates to stalled DNA replication fork rescue.

CRISPR-Cas adaptive immunity and the three Rs

In this summary, we focus on fundamental biology of Clustered Regularly Interspersed Short Palindromic Repeats (CRISPR)-Cas (CRISPR-associated proteins) adaptive immunity in bacteria. Emphasis is placed on emerging information about functional interplay between Cas proteins and proteins that remodel DNA during homologous recombination (HR), DNA replication or DNA repair. We highlight how replication forks may act as ‘trigger points’ for CRISPR adaptation events, and the potential for cascade-interference complexes to act as precise roadblocks in DNA replication by an invader MGE (mobile genetic element), without the need for DNA double-strand breaks.

Targeting Holliday junctions by origin DNA-binding protein of herpes simplex virus type 1

In the present paper, the interactions of the origin binding protein (OBP) of herpes simplex virus type 1 (HSV1) with synthetic four-way Holliday junctions (HJs) were studied using electrophoresis mobility shift assay and the FRET method and compared with the interactions of the protein with duplex and single-stranded DNAs. It has been found that OBP exhibits a strong preference for binding to four-way and three-way DNA junctions and possesses much lower affinities to duplex and single-stranded DNAs. The protein forms three types of complexes with HJs. It forms complexes I and II which are reminiscent of the tetramer and octamer complexes with four-way junction of HJ-specific protein RuvA of Escherichia coli. The binding approaches saturation level when two OBP dimers are bound per junction. In the presence of Mg²⁺ ions (≥2 mM) OBP also interacts with HJ in the stacked arm form (complex III). In the presence of 5 mM ATP and 10 mM Mg²⁺ ions OBP catalyzes processing of the HJ in which one of the annealed oligonucleotides has a 3'-terminal tail containing 20 unpaired thymine residues. The observed preference of OBP for binding to the four-way DNA junctions provides a basis for suggestion that OBP induces large DNA structural changes upon binding to Box I and Box II sites in OriS. These changes involve the bending and partial melting of the DNA at A+T-rich spacer and also include the formation of HJ containing Box I and Box II inverted repeats and flanking DNA sequences.

Identification of Escherichia coli ygaQ and rpmG as novel mitomycin C resistance factors implicated in DNA repair

A genome-wide protein expression screen in Escherichia coli has identified new mitomycin C resistance factors, genes ygaQ and rpmG. These were characterized, revealing that ygaQ encodes a new nuclease enzyme and that RpmG is likely be an “idiosyncratic ribosomal protein” with a role in DNA repair by MutM.

Using the ASKA (A Complete Set of Escherichia coliK-12 ORF Archive) library for genome-wide screening of E. coli proteins we identified that expression of ygaQ and rpmG promotes mitomycin C resistance (MMC^R). YgaQ mediated MMC^R was independent of homologous recombination involving RecA or RuvABC, but required UvrD. YgaQ is an uncharacterized protein homologous with α-amylases that we identified to have nuclease activity directed to ssDNA of 5′ flaps. Nuclease activity was inactivated by mutation of two amino acid motifs, which also abolished MMC^R. RpmG is frequently annotated as a bacterial ribosomal protein, although forms an operon with MutM glycosylase and a putative deubiquitinating (DUB) enzyme, YicR. RpmG associated MMC^R was dependent on MutM. MMC^R from RpmG resembles DNA repair phenotypes reported for ‘idiosyncratic ribosomal proteins’ in eukaryotes.

Regression of replication forks stalled by leading-strand template damage: I. Both RecG and RuvAB catalyze regression, but RuvC cleaves the holliday junctions formed by RecG preferentially

The orderly progression of replication forks formed at the origin of replication in Escherichia coli is challenged by encounters with template damage, slow moving RNA polymerases, and frozen DNA-protein complexes that stall the fork. These stalled forks are foci for genomic instability and must be reactivated. Many models of replication fork reactivation invoke nascent strand regression as an intermediate in the processing of the stalled fork. We have investigated the replication fork regression activity of RecG and RuvAB, two proteins commonly thought to be involved in the process, using a reconstituted DNA replication system where the replisome is stalled by collision with leading-strand template damage. We find that both RecG and RuvAB can regress the stalled fork in the presence of the replisome and SSB; however, RuvAB generates a completely unwound product consisting of the paired nascent leading and lagging strands, whereas RuvC cleaves the Holliday junction generated by RecG-catalyzed fork regression. We also find that RecG stimulates RuvAB-catalyzed regression, presumably because it is more efficient at generating the initial Holliday junction from the stalled fork.

Viral and cellular SOS-regulated motor proteins: dsDNA translocation mechanisms with divergent functions

DNA damage attacks on bacterial cells have been known to activate the SOS response, a transcriptional response affecting chromosome replication, DNA recombination and repair, cell division and prophage induction. All these functions require double-stranded (ds) DNA translocation by ASCE hexameric motors. This review seeks to delineate the structural and functional characteristics of the SOS response and the SOS-regulated DNA translocases FtsK and RuvB with the phi29 bacteriophage packaging motor gp16 ATPase as a prototype to study bacterial motors. While gp16 ATPase, cellular FtsK and RuvB are similarly comprised of hexameric rings encircling dsDNA and functioning as ATP-driven DNA translocases, they utilize different mechanisms to accomplish separate functions, suggesting a convergent evolution of these motors. The gp16 ATPase and FtsK use a novel revolution mechanism, generating a power stroke between subunits through an entropy-DNA affinity switch and pushing dsDNA inward without rotation of DNA and the motor, whereas RuvB seems to employ a rotation mechanism that remains to be further characterized. While FtsK and RuvB perform essential tasks during the SOS response, their roles may be far more significant as SOS response is involved in antibiotic-inducible bacterial vesiculation and biofilm formation as well as the perspective of the bacteria-cancer evolutionary interaction.

Interaction of branch migration translocases with the Holliday junction-resolving enzyme and their implications in Holliday junction resolution

Double-strand break repair involves the formation of Holliday junction (HJ) structures that need to be resolved to promote correct replication and chromosomal segregation. The molecular mechanisms of HJ branch migration and/or resolution are poorly characterized in Firmicutes. Genetic evidence suggested that the absence of the RuvAB branch migration translocase and the RecU HJ resolvase is synthetically lethal in Bacillus subtilis, whereas a recU recG mutant was viable. In vitro RecU, which is restricted to bacteria of the Firmicutes phylum, binds HJs with high affinity. In this work we found that RecU does not bind simultaneously with RecG to a HJ. RuvB by interacting with RecU bound to the central region of HJ DNA, loses its nonspecific association with DNA, and re-localizes with RecU to form a ternary complex. RecU cannot stimulate the ATPase or branch migration activity of RuvB. The presence of RuvB·ATPγS greatly stimulates RecU-mediated HJ resolution, but the addition of ATP or RuvA abolishes this stimulatory effect. A RecU·HJ·RuvAB complex might be formed. RecU does not increase the RuvAB activities but slightly inhibits them.

Resolution by unassisted Top3 points to template switch recombination intermediates during DNA replication

The evolutionarily conserved Sgs1/Top3/Rmi1 (STR) complex plays vital roles in DNA replication and repair. One crucial activity of the complex is dissolution of toxic X-shaped recombination intermediates that accumulate during replication of damaged DNA. However, despite several years of study the nature of these X-shaped molecules remains debated. Here we use genetic approaches and two-dimensional gel electrophoresis of genomic DNA to show that Top3, unassisted by Sgs1 and Rmi1, has modest capacities to provide resistance to MMS and to resolve recombination-dependent X-shaped molecules. The X-shaped molecules have structural properties consistent with hemicatenane-related template switch recombination intermediates (Rec-Xs) but not Holliday junction (HJ) intermediates. Consistent with these findings, we demonstrate that purified Top3 can resolve a synthetic Rec-X but not a synthetic double HJ in vitro. We also find that unassisted Top3 does not affect crossing over during double strand break repair, which is known to involve double HJ intermediates, confirming that unassisted Top3 activities are restricted to substrates that are distinct from HJs. These data help illuminate the nature of the X-shaped molecules that accumulate during replication of damaged DNA templates, and also clarify the roles played by Top3 and the STR complex as a whole during the resolution of replication-associated recombination intermediates.

wrwyrggrywrw is a single-chain functional analog of the Holliday junction-binding homodimer, (wrwycr)2

DNA repair pathways in bacteria that use homologous recombination involve the formation and subsequent resolution of Holliday junction (HJ) intermediates. We have previously identified several hexameric peptides that bind to HJs and interfere with HJ processing enzymes in vitro. The peptide WRWYCR and its D-amino acid stereoisomer wrwycr, are potent antibacterial agents. These hexapeptides must form homodimers in order to interact stably with HJs, and inhibit bacterial growth, and this represents a potential limitation. Herein we describe a disulfide bond-independent inhibitor, WRWYRGGRYWRW and its D-stereoisomer wrwyrggrywrw. We have characterized these single-chain, linear analogs of the hexapeptides, and show that in addition to effectively binding to HJs, and inhibiting the activity of DNA repair enzymes that process HJs, they have equal or greater potency against Gram-positive and Gram-negative bacterial growth. The analogs were also shown to cause DNA damage in bacteria, and disrupt the integrity of the bacterial cytoplasmic membrane. Finally, we found that they have little toxicity toward several eukaryotic cell types at concentrations needed to inhibit bacterial growth.

Homologous Recombination-Enzymes and Pathways

Homologous recombination is an ubiquitous process that shapes genomes and repairs DNA damage. The reaction is classically divided into three phases: presynaptic, synaptic, and postsynaptic. In Escherichia coli, the presynaptic phase involves either RecBCD or RecFOR proteins, which act on DNA double-stranded ends and DNA single-stranded gaps, respectively; the central synaptic steps are catalyzed by the ubiquitous DNA-binding protein RecA; and the postsynaptic phase involves either RuvABC or RecG proteins, which catalyze branch-migration and, in the case of RuvABC, the cleavage of Holliday junctions. Here, we review the biochemical properties of these molecular machines and analyze how, in light of these properties, the phenotypes of null mutants allow us to define their biological function(s). The consequences of point mutations on the biochemical properties of recombination enzymes and on cell phenotypes help refine the molecular mechanisms of action and the biological roles of recombination proteins. Given the high level of conservation of key proteins like RecA and the conservation of the principles of action of all recombination proteins, the deep knowledge acquired during decades of studies of homologous recombination in bacteria is the foundation of our present understanding of the processes that govern genome stability and evolution in all living organisms.

The RuvA homologues from Mycoplasma genitalium and Mycoplasma pneumoniae exhibit unique functional characteristics

The DNA recombination and repair machineries of Mycoplasma genitalium and Mycoplasma pneumoniae differ considerably from those of gram-positive and gram-negative bacteria. Most notably, M. pneumoniae is unable to express a functional RecU Holliday junction (HJ) resolvase. In addition, the RuvB homologues from both M. pneumoniae and M. genitalium only exhibit DNA helicase activity but not HJ branch migration activity in vitro. To identify a putative role of the RuvA homologues of these mycoplasmas in DNA recombination, both proteins (RuvA_Mpn and RuvA_Mge, respectively) were studied for their ability to bind DNA and to interact with RuvB and RecU. In spite of a high level of sequence conservation between RuvA_Mpn and RuvA_Mge (68.8% identity), substantial differences were found between these proteins in their activities. First, RuvA_Mge was found to preferentially bind to HJs, whereas RuvA_Mpn displayed similar affinities for both HJs and single-stranded DNA. Second, while RuvA_Mpn is able to form two distinct complexes with HJs, RuvA_Mge only produced a single HJ complex. Third, RuvA_Mge stimulated the DNA helicase and ATPase activities of RuvB_Mge, whereas RuvA_Mpn did not augment RuvB activity. Finally, while both RuvA_Mge and RecU_Mge efficiently bind to HJs, they did not compete with each other for HJ binding, but formed stable complexes with HJs over a wide protein concentration range. This interaction, however, resulted in inhibition of the HJ resolution activity of RecU_Mge.

Formation of a stable RuvA protein double tetramer is required for efficient branch migration in vitro and for replication fork reversal in vivo

In bacteria, RuvABC is required for the resolution of Holliday junctions (HJ) made during homologous recombination. The RuvAB complex catalyzes HJ branch migration and replication fork reversal (RFR). During RFR, a stalled fork is reversed to form a HJ adjacent to a DNA double strand end, a reaction that requires RuvAB in certain Escherichia coli replication mutants. The exact structure of active RuvAB complexes remains elusive as it is still unknown whether one or two tetramers of RuvA support RuvB during branch migration and during RFR. We designed an E. coli RuvA mutant, RuvA2(KaP), specifically impaired for RuvA tetramer-tetramer interactions. As expected, the mutant protein is impaired for complex II (two tetramers) formation on HJs, although the binding efficiency of complex I (a single tetramer) is as wild type. We show that although RuvA complex II formation is required for efficient HJ branch migration in vitro, RuvA2(KaP) is fully active for homologous recombination in vivo. RuvA2(KaP) is also deficient at forming complex II on synthetic replication forks, and the binding affinity of RuvA2(KaP) for forks is decreased compared with wild type. Accordingly, RuvA2(KaP) is inefficient at processing forks in vitro and in vivo. These data indicate that RuvA2(KaP) is a separation-of-function mutant, capable of homologous recombination but impaired for RFR. RuvA2(KaP) is defective for stimulation of RuvB activity and stability of HJ·RuvA·RuvB tripartite complexes. This work demonstrates that the need for RuvA tetramer-tetramer interactions for full RuvAB activity in vitro causes specifically an RFR defect in vivo.

The Mycoplasma genitalium MG352-encoded protein is a Holliday junction resolvase that has a non-functional orthologue in Mycoplasma pneumoniae

Recombination between repeated DNA elements in the genomes of Mycoplasma species appears to lie at the basis of antigenic variation of several essential surface proteins. It is therefore imperative that the DNA recombinatorial pathways in mycoplasmas be unravelled. Here, we describe the proteins encoded by the Mycoplasma genitalium MG352 and Mycoplasma pneumoniae MPN528a genes (RecU(Mge) and RecU(Mpn) respectively), which share sequence similarity with RecU Holliday junction (HJ) resolvases. RecU(Mge) was found to: (i) bind HJ substrates and large double-stranded DNA molecules and (ii) cleave HJ substrates at the sequence 5'-(G) /(T) C↓(C) /(T) T(A) /(G) G-3' in the presence of Mn(2+). Interestingly, RecU(Mpn) (from M. pneumoniae subtype 2 strains) did not possess obvious DNA binding or cleavage activities, which was found to be caused by the presence of a glutamic acid residue at position 67 of the protein, which is not conserved in RecU(Mge). Additionally, RecU(Mpn) appears not to be expressed by subtype 1 M. pneumoniae strains, as these possess a TAA translation termination codon at position 181-183 of MPN528a. We conclude that RecU(Mge) is a HJ resolvase that may play a central role in recombination in M. genitalium.

DNA Helicases

DNA and RNA helicases are organized into six superfamilies of enzymes on the basis of sequence alignments, biochemical data, and available crystal structures. DNA helicases, members of which are found in each of the superfamilies, are an essential group of motor proteins that unwind DNA duplexes into their component single strands in a process that is coupled to the hydrolysis of nucleoside 5'-triphosphates. The purpose of this DNA unwinding is to provide nascent, single-stranded DNA (ssDNA) for the processes of DNA repair, replication, and recombination. Not surprisingly, DNA helicases share common biochemical properties that include the binding of single- and double-stranded DNA, nucleoside 5'-triphosphate binding and hydrolysis, and nucleoside 5'-triphosphate hydrolysis-coupled, polar unwinding of duplex DNA. These enzymes participate in every aspect of DNA metabolism due to the requirement for transient separation of small regions of the duplex genome into its component strands so that replication, recombination, and repair can occur. In Escherichia coli, there are currently twelve DNA helicases that perform a variety of tasks ranging from simple strand separation at the replication fork to more sophisticated processes in DNA repair and genetic recombination. In this chapter, the superfamily classification, role(s) in DNA metabolism, effects of mutations, biochemical analysis, oligomeric nature, and interacting partner proteins of each of the twelve DNA helicases are discussed.

Mycobacterium tuberculosis RuvA induces two distinct types of structural distortions between the homologous and heterologous Holliday junctions

A central step in the process of homologous genetic recombination is the strand exchange between two homologous DNA molecules, leading to the formation of the Holliday junction intermediate. Several lines of evidence, both in vitro and in vivo, suggest a concerted role for the Escherichia coli RuvABC protein complex in the process of branch migration and the resolution of the Holliday junctions. A number of investigations have examined the role of RuvA protein in branch migration of the Holliday junction in conjunction with its natural cellular partner, RuvB. However, it remains unclear whether the RuvABC protein complex or its individual subunits function differently in the context of DNA repair and homologous recombination. In this study, we have specifically investigated the function of RuvA protein using Holliday junctions containing either homologous or heterologous arms. Our data show that Mycobacterium tuberculosis ruvA complements E. coli DeltaruvA mutants for survival to genotoxic stress caused by different DNA-damaging agents, and the purified RuvA protein binds HJ in preference to any other substrates. Strikingly, our analysis revealed two distinct types of structural distortions caused by M. tuberculosis RuvA between the homologous and heterologous Holliday junctions. We interpret these data as evidence that local distortion of base pairing in the arms of homologous Holliday junctions by RuvA might augment branch migration catalyzed by RuvB. The biological significance of two modes of structural distortion caused by M. tuberculosis RuvA and the implications for its role in DNA repair and homologous recombination are discussed.

ruvA Mutants that resolve Holliday junctions but do not reverse replication forks

RuvAB and RuvABC complexes catalyze branch migration and resolution of Holliday junctions (HJs) respectively. In addition to their action in the last steps of homologous recombination, they process HJs made by replication fork reversal, a reaction which occurs at inactivated replication forks by the annealing of blocked leading and lagging strand ends. RuvAB was recently proposed to bind replication forks and directly catalyze their conversion into HJs. We report here the isolation and characterization of two separation-of-function ruvA mutants that resolve HJs, based on their capacity to promote conjugational recombination and recombinational repair of UV and mitomycin C lesions, but have lost the capacity to reverse forks. In vivo and in vitro evidence indicate that the ruvA mutations affect DNA binding and the stimulation of RuvB helicase activity. This work shows that RuvA's actions at forks and at HJs can be genetically separated, and that RuvA mutants compromised for fork reversal remain fully capable of homologous recombination.

DNA replication is the process by which DNA strands are copied to ensure the transmission of the genetic material to daughter cells. Chromosome replication is not a continuous process but is subjected to accidental arrests, owing to the encounter of obstacles or to the dysfunctioning of a replication protein. In bacteria, inactivated replication forks restart but they are most often remodeled before restarting. Interestingly, enzymes involved in homologous recombination, the process that rearranges chromosomes, are also involved in fork-remodeling reactions. The subject of the present study is RuvAB, a highly conserved bacterial complex used as the model enzyme for resolution of recombination intermediates, which we found to also act at blocked forks. We describe here the isolation and characterization of ruvA mutants that have specifically lost the capability to act at inactivated replication forks, although they remain fully capable of homologous recombination. The existence of such ruvA mutants, their properties and those of the purified RuvA mutant proteins, indicate that the action of RuvAB at replication forks is more demanding that its action at recombination intermediates, but have nevertheless been preserved during evolution.

Functional significance of octameric RuvA for a branch migration complex from Thermus thermophilus

The RuvAB complex promotes migration of Holliday junction at the late stage of homologous recombination. The RuvA tetramer specifically recognizes Holliday junction to form two types of complexes. A single tetramer is bound to the open configuration of the junction DNA in complex I, while the octameric RuvA core structure sandwiches the same junction in complex II. The hexameric RuvB rings, symmetrically bound to both sides of RuvA on Holliday junction, pump out DNA duplexes, depending upon ATP hydrolysis. We investigated functional differences between the wild-type RuvA from Thermus thermophilus and mutants impaired the ability of complex II formation. These mutant RuvA, exclusively forming complex I, reduced activities of branch migration and ATP hydrolysis, suggesting that the octameric RuvA is essential for efficient branch migration. Together with our recent electron microscopic analysis, this finding provides important insights into functional roles of complex II in the coordinated branch migration mechanism.

Evidence that a RecQ helicase slows senescence by resolving recombining telomeres

RecQ helicases, including Saccharomyces cerevisiae Sgs1p and the human Werner syndrome protein, are important for telomere maintenance in cells lacking telomerase activity. How maintenance is accomplished is only partly understood, although there is evidence that RecQ helicases function in telomere replication and recombination. Here we use two-dimensional gel electrophoresis (2DGE) and telomere sequence analysis to explore why cells lacking telomerase and Sgs1p (tlc1 sgs1 mutants) senesce more rapidly than tlc1 mutants with functional Sgs1p. We find that apparent X-shaped structures accumulate at telomeres in senescing tlc1 sgs1 mutants in a RAD52- and RAD53-dependent fashion. The X-structures are neither Holliday junctions nor convergent replication forks, but instead may be recombination intermediates related to hemicatenanes. Direct sequencing of examples of telomere I-L in senescing cells reveals a reduced recombination frequency in tlc1 sgs1 compared with tlc1 mutants, indicating that Sgs1p is needed for tlc1 mutants to complete telomere recombination. The reduction in recombinants is most prominent at longer telomeres, consistent with a requirement for Sgs1p to generate viable progeny following telomere recombination. We therefore suggest that Sgs1p may be required for efficient resolution of telomere recombination intermediates, and that resolution failure contributes to the premature senescence of tlc1 sgs1 mutants.

Because telomeres are situated at the ends of chromosomes, they are both essential for chromosome integrity and particularly susceptible to processes that lead to loss of their own DNA sequences. The enzyme telomerase can counter these losses, but there are also other means of telomere maintenance, some of which depend on DNA recombination. The RecQ family of DNA helicases process DNA recombination intermediates and also help ensure telomere integrity, but the relationship between these activities is poorly understood. Family members include yeast Sgs1p and human WRN and BLM, which are deficient in the Werner premature aging syndrome and the Bloom cancer predisposition syndrome, respectively. We have found that the telomeres of yeast cells lacking both telomerase and Sgs1p accumulate structures that resemble recombination intermediates. Further, we provide evidence that the inability of cells lacking Sgs1p to process these telomere recombination intermediates leads to the premature arrest of cell division. We predict that similar defects in the processing of recombination intermediates may contribute to telomere defects in human Werner and Bloom syndrome cells.

Yeast cells lacking the RecQ helicase Sgs1p show an accumulation of telomere recombination intermediates associated with premature senescence.

Electron microscopic single particle analysis of a tetrameric RuvA/RuvB/Holliday junction DNA complex

During the late stage of homologous recombination in prokaryotes, RuvA binds to the Holliday junction intermediate and executes branch migration in association with RuvB. The RuvA subunits form two distinct complexes with the Holliday junction: complex I with the single RuvA tetramer on one side of the four way junction DNA, and complex II with two tetramers on both sides. To investigate the functional roles of complexes I and II, we mutated two residues of RuvA (L125D and E126K) to prevent octamer formation. An electron microscopic analysis indicated that the mutant RuvA/RuvB/Holliday junction DNA complex formed the characteristic tripartite structure, with only one RuvA tetramer bound to one side of the Holliday junction, demonstrating the unexpected stability of this complex. The novel bent images of the complex revealed an intriguing morphological similarity to the structure of SV40 large T antigen, which belongs to the same AAA+ family as RuvB.

Three-dimensional structural views of branch migration and resolution in DNA homologous recombination

The processing of the Holliday junction by various proteins is a major event in DNA homologous recombination and is crucial to the maintenance of genome stability and biological diversity. The proteins RuvA, RuvB and RuvC play central roles in the late stage of recombination in prokaryotes. Recent atomic views of these proteins, including protein-protein and protein-junction DNA complexes, provide new insights into branch migration mechanisms: RuvA is likely to be responsible for base-pair rearrangements, whereas RuvB, classified as a member of the AAA(+) family, functions as a pump to pull DNA duplex arms without segmental unwinding. The mechanism of junction resolution by RuvC in the RuvABC resolvasome remains to be elucidated.

Holliday junction-binding peptides inhibit distinct junction-processing enzymes

Holliday junctions (HJ) are the central intermediates in both homologous recombination and site-specific recombination performed by tyrosine recombinases such as the bacteriophage lambda Integrase (Int) protein. Previously, our lab identified peptide inhibitors of Int-mediated recombination that prevent the resolution of HJ intermediates. We now show that two of these inhibitors bind HJ DNA in the square-planar conformation even in the absence of Int protein. The peptides prevent unwinding of branched DNA substrates by the RecG helicase of Escherichia coli and interfere with the resolution of HJ substrates by the RuvABC complex. Our results suggest that these peptides target all proteins that process HJ in the square-planar conformation. These inhibitors should be extremely useful for dissecting homologous recombination and recombination-dependent repair in vitro and in vivo.

The role of RuvA octamerization for RuvAB function in vitro and in vivo

RuvA plays an essential role in branch migration of the Holliday junction by RuvAB as part of the RuvABC pathway for processing Holliday junctions in Escherichia coli. Two types of RuvA-Holliday junction complexes have been characterized: 1) complex I containing a single RuvA tetramer and 2) complex II in which the junction is sandwiched between two RuvA tetramers. The functional differences between the two forms are still not clear. To investigate the role of RuvA octamerization, we introduced three amino acid substitutions designed to disrupt the E. coli RuvA tetramer-tetramer interface as identified by structural studies. The mutant RuvA was tetrameric and interacted with both RuvB and junction DNA but, as predicted, formed complex I only at protein concentrations up to 500 nm. We present biochemical and surface plasmon resonance evidence for functional and physical interactions of the mutant RuvA with RuvB and RuvC on synthetic junctions. The mutant RuvA with RuvB showed DNA helicase activity and could support branch migration of synthetic four-way and three-way junctions. However, junction binding and the efficiency of branch migration of four-way junctions were affected. The activity of the RuvA mutant was consistent with a RuvAB complex driven by one RuvB hexamer only and lead us to propose that one RuvA tetramer can only support the activity of one RuvB hexamer. Significantly, the mutant failed to complement the UV sensitivity of E. coli DeltaruvA cells. These results indicate strongly that RuvA octamerization is essential for the full biological activity of RuvABC.

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.

Modulation of DNA repair and recombination by the bacteriophage lambda Orf function in Escherichia coli K-12

The orf gene of bacteriophage lambda, fused to a promoter, was placed in the galK locus of Escherichia coli K-12. Orf was found to suppress the recombination deficiency and sensitivity to UV radiation of mutants, in a Delta(recC ptr recB recD)::P(tac) gam bet exo pae cI DeltarecG background, lacking recF, recO, recR, ruvAB, and ruvC functions. It also suppressed defects of these mutants in establishing replication of a pSC101-related plasmid. Compared to orf, the recA803 allele had only small effects on recF, recO, and recR mutant phenotypes and no effect on a ruvAB mutant. In a fully wild-type background with respect to known recombination and repair functions, orf partially suppressed the UV sensitivity of ruvAB and ruvC mutants.

Interplay between DNA replication, recombination and repair based on the structure of RecG helicase

Recent studies in Escherichia coli indicate that the interconversion of DNA replication fork and Holliday junction structures underpins chromosome duplication and helps secure faithful transmission of the genome from one generation to the next. It facilitates interplay between DNA replication, recombination and repair, and provides means to rescue replication forks stalled by lesions in or on the template DNA. Insight into how this interconversion may be catalysed has emerged from genetic, biochemical and structural studies of RecG protein, a member of superfamily 2 of DNA and RNA helicases. We describe how a single molecule of RecG might target a branched DNA structure and translocate a single duplex arm to drive branch migration of a Holliday junction, interconvert replication fork and Holliday junction structures and displace the invading strand from a D loop formed during recombination at a DNA end. We present genetic evidence suggesting how the latter activity may provide an efficient pathway for the repair of DNA double-strand breaks that avoids crossing over, thus facilitating chromosome segregation at cell division.

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.

Molecular views of recombination proteins and their control

The efficient repair of double-strand breaks in DNA is critical for the maintenance of genome stability and cell survival. Homologous recombination provides an efficient and faithful pathway of repair, especially in replicating cells, in which it plays a major role in tumour avoidance. Many of the enzymes that are involved in recombination have been isolated, and the details of this pathway are now being unravelled at the molecular level.

The RuvABC resolvasome

The RuvABC resolvasome of Escherichia coli catalyses the resolution of Holliday junctions that arise during genetic recombination and DNA repair. This process involves two key steps: branch migration, catalysed by the RuvB protein that is targeted to the Holliday junction by the structure specific RuvA protein, and resolution, which is catalysed by the RuvC endonuclease. We have quantified the interaction of the RuvA protein with synthetic Holliday junctions and have shown that the binding of the protein is highly structure-specific, and leads to the formation of a complex containing two tetramers of RuvA per Holliday junction. Our data are consistent with two tetramers of RuvA binding to the DNA recombination intermediate in a co-operative manner. Once formed this complex prevents the binding of RuvC to the Holliday junction. However, the formation of a RuvAC complex can be observed following sequential addition of the RuvC and RuvA proteins. Moreover, by examining the DNA recognition properties of a mutant RuvA protein (E55R, D56K) we show that the charge on the central pin is critical for directing the structure-specific binding by RuvA.

Substrate specificity of RusA resolvase reveals the DNA structures targeted by RuvAB and RecG in vivo

RusA endonuclease cleaves Holliday junctions by introducing paired strand incisions 5' to CC dinucleotides. Coordinated catalysis is achieved when both subunits of the homodimer interact simultaneously with cleavage sites located symmetrically. This requirement confers Holliday junction specificity. Uncoupled catalysis occurs when binding interactions are disturbed. Genetic studies indicate that uncoupling occurs rarely in vivo, and DNA cleavage is therefore restricted to Holliday junctions. We exploited the specificity of RusA to identify the DNA substrates targeted by the RuvAB and RecG branch-migration proteins in vivo. We present evidence that replication restart in UV-irradiated cells relies on the processing of stalled replication forks by RecG helicase and of Holliday junctions by the RuvABC resolvasome, and that RuvAB alone may not promote repair.

Holliday junction binding and processing by the RuvA protein of Mycoplasma pneumoniae

The RuvA, RuvB and RuvC proteins of Escherichia coli act together to process Holliday junctions formed during recombination and DNA repair. RuvA has a well-defined DNA binding surface that is sculptured specifically to accommodate a Holliday junction and allow subsequent loading of RuvB and RuvC. A negatively charged pin projecting from the centre limits binding of linear duplex DNA. The amino-acid sequences forming the pin are highly conserved. However, in certain Mycoplasma and Ureaplasma species the structure is extended by four amino acids and two acidic residues forming a crucial charge barrier are missing. We investigated the significance of these differences by analysing RuvA from Mycoplasma pneumoniae. Gel retardation and surface plasmon resonance assays revealed that this protein binds Holliday junctions and other branched DNA structures in a manner similar to E. coli RuvA. Significantly, it binds duplex DNA more readily. However it does not support branch migration mediated by E. coli RuvB and when bound to junction DNA is unable to provide a platform for stable binding of E. coli RuvC. It also fails to restore radiation resistance to an E. coli ruvA mutant. The data presented suggest that the modified pin region retains the ability to promote junction-specific DNA binding, but acts as a physical obstacle to linear duplex DNA rather than as a charge barrier. They also indicate that such an obstacle may interfere with the binding of a resolvase. Mycoplasma species may therefore process Holliday junctions via uncoupled branch migration and resolution reactions.

Crystal structure of the fission yeast mitochondrial Holliday junction resolvase Ydc2

Resolution of Holliday junctions into separate DNA duplexes requires enzymatic cleavage of an equivalent strand from each contributing duplex at or close to the point of strand exchange. Diverse Holliday junction-resolving enzymes have been identified in bacteria, bacteriophages, archaea and pox viruses, but the only eukaryotic examples identified so far are those from fungal mitochondria. We have now determined the crystal structure of Ydc2 (also known as SpCce1), a Holliday junction resolvase from the fission yeast Schizosaccharomyces pombe that is involved in the maintenance of mitochondrial DNA. This first structure of a eukaryotic Holliday junction resolvase confirms a distant evolutionary relationship to the bacterial RuvC family, but reveals structural features which are unique to the eukaryotic enzymes. Detailed analysis of the dimeric structure suggests mechanisms for junction isomerization and communication between the two active sites, and together with site-directed mutagenesis identifies residues involved in catalysis.

Action of RuvAB at replication fork structures

The replicative apparatus often encounters blocks to its progression that necessitate removal of the block and reloading of the replication machinery. In Escherichia coli, a major pathway of replication restart involves unwinding of the stalled fork to generate a four-stranded Holliday junction, which can then be cleaved by the RuvABC helicase-endonuclease. This fork regression may be catalyzed by RecG but is thought to occur even in its absence. Here we test whether RuvAB helicase can also catalyze the unwinding of forked DNA to form Holliday junctions. We find that fork DNA is unwound in the direction required for Holliday junction formation only if the loading of RuvB is restricted to the parental duplex DNA arm. If the binding of RuvB is unrestricted, then RuvAB preferentially unwinds forks in the opposite direction. This is probably related to the greater efficiency of two opposed RuvB hexamers operating across a junction compared with a single hexamer. These data argue against RuvAB acting directly at damaged replication forks and imply that other mechanisms must operate in vivo to catalyze Holliday junction formation.

Formation of Holliday junctions by regression of nascent DNA in intermediates containing stalled replication forks: RecG stimulates regression even when the DNA is negatively supercoiled

Replication forks formed at bacterial origins often encounter template roadblocks in the form of DNA adducts and frozen protein-DNA complexes, leading to replication-fork stalling and inactivation. Subsequent correction of the corrupting template lesion and origin-independent assembly of a new replisome therefore are required for survival of the bacterium. A number of models for replication-fork restart under these conditions posit that nascent strand regression at the stalled fork generates a Holliday junction that is a substrate for subsequent processing by recombination and repair enzymes. We show here that early replication intermediates containing replication forks stalled in vitro by the accumulation of excess positive supercoils could be cleaved by the Holliday junction resolvases RusA and RuvC. Cleavage by RusA was inhibited by the presence of RuvA and was stimulated by RecG, confirming the presence of Holliday junctions in the replication intermediate and supporting the previous proposal that RecG could catalyze nascent strand regression at stalled replication forks. Furthermore, RecG promoted Holliday junction formation when replication intermediates in which the replisome had been inactivated were negatively supercoiled, suggesting that under intracellular conditions, the action of RecG, or helicases with similar activities, is necessary for the catalysis of nascent strand regression.

Fission yeast nascent polypeptide-associated complex binds to four-way DNA junctions

The four-way DNA junction (X-junction) is both a central intermediate of recombination reactions and, in some cases, a controlling element in transcription and the initiation of DNA replication. Many different proteins have been found to bind to X-junctions in a structure-specific manner. In some cases, this ability only reflects the proteins' general predilection for distorted DNAs but in others the interaction is highly specific and usually signifies that the X-junction is the real target for the protein in vivo. Here we identify the Schizosaccharomyces pombe (Sp) nascent polypeptide associated complex (NAC) as a potent binder of X-junction DNA. NAC is highly conserved in eukaryotes and has reported functions in transcription and the targeting of proteins within the cytosol. NAC is composed of alpha and beta subunits. Each SpNAC subunit has the capacity to bind X-junction DNA, but optimal binding depends on a heterodimer of subunits. Competition assays and binding comparisons using a range of different DNA substrates reveal that SpNAC is highly selective for the X-junction structure. By comparative gel electrophoresis we show that the X-junction is held in its open square conformation when bound by SpNAC. Junction binding is inhibited by concentrations of magnesium ions that are sufficient to "stack" the X-junction, suggesting that SpNAC recognises only the open junction structure. Finally, SpNAC can bind to X-junctions that are already bound by a tetramer of the Escherichia coli RuvA protein, indicating that it interacts with only one face of the junction. The possible biological significance of X-junction binding by SpNAC is discussed.

The X philes: structure-specific endonucleases that resolve Holliday junctions

Genetic recombination is a critical cellular process that promotes evolutionary diversity, facilitates DNA repair and underpins genome duplication. It entails the reciprocal exchange of single strands between homologous DNA duplexes to form a four-way branched intermediate commonly referred to as the Holliday junction. DNA molecules interlinked in this way have to be separated in order to allow normal chromosome transmission at cell division. This resolution reaction is mediated by structure-specific endonucleases that catalyse dual-strand incision across the point of strand cross-over. Holliday junctions can also arise at stalled replication forks by reversing the direction of fork progression and annealing of nascent strands. Resolution of junctions in this instance generates a DNA break and thus serves to initiate rather than terminate recombination. Junction resolvases are generally small, homodimeric endonucleases with a high specificity for branched DNA. They use a metal-binding pocket to co-ordinate an activated water molecule for phosphodiester bond hydrolysis. In addition, most junction endonucleases modulate the structure of the junction upon binding, and some display a preference for cleavage at specific nucleotide target sequences. Holliday junction resolvases with distinct properties have been characterized from bacteriophages (T4 endo VII, T7 endo I, RusA and Rap), Bacteria (RuvC), Archaea (Hjc and Hje), yeast (CCE1) and poxviruses (A22R). Recent studies have brought about a reappraisal of the origins of junction-specific endonucleases with the discovery that RuvC, CCE1 and A22R share a common catalytic core.

Branch migration and Holliday junction resolution catalyzed by activities from mammalian cells

During homologous recombination, DNA strand exchange leads to Holliday junction formation. The movement, or branch migration, of this junction along DNA extends the length of the heteroduplex joint. In prokaryotes, branch migration and Holliday junction resolution are catalyzed by the RuvA and RuvB proteins, which form a complex with RuvC resolvase to form a "resolvasome". Mammalian cell-free extracts have now been fractionated to reveal analogous activities. An ATP-dependent branch migration activity, which migrates junctions through >2700 bp, cofractionates with the Holliday junction resolvase during several chromatographic steps. Together, the two activities promote concerted branch migration/resolution reactions similar to those catalyzed by E. coli RuvABC, highlighting the preservation of this essential pathway in recombination and DNA repair from prokaryotes to mammals.

The ruv proteins of Thermotoga maritima: branch migration and resolution of Holliday junctions

In homologous recombination in bacteria, the RuvAB Holliday junction-specific helicase catalyzes Holliday junction branch migration, and the RuvC Holliday junction resolvase catalyzes formation of spliced or patched structures. RuvAB and RuvC from the hyperthermophile Thermotoga maritima were expressed in Escherichia coli and purified to homogeneity. An inverted repeat sequence with unique termini was produced by PCR, restriction endonuclease cleavage, and head-to-tail ligation. A second inverted repeat sequence was derived by amplification of a second template containing a three-nucleotide insertion. Reassociation products from a mixture of these two sequences were homoduplex linear molecules and heteroduplex heat-stable Holliday junctions, which acted as substrates for both T. maritima RuvAB and RuvC. The T. maritima RuvAB helicase catalyzed energy-dependent Holliday junction branch migration at 70 degrees C, leading to heteroduplex linear duplex molecules with two three-nucleotide loops. Either ATP or ATP gamma S hydrolysis served as the energy source. T. maritima RuvC resolved Holliday junctions at 70 degrees C. Remarkably, the cleavage site was identical to the preferred cleavage site for E. coli RuvC [(A/T)TT(downward arrow)(G/C)]. The conservation of function and the ease of purification of wild-type and mutant thermophilic proteins argues for the use of T. maritima proteins for additional biochemical and structural studies.

Analysis of conserved basic residues associated with DNA binding (Arg69) and catalysis (Lys76) by the RusA holliday junction resolvase

Holliday junctions are key intermediates in both homologous recombination and DNA repair, and are also formed from replication forks stalled at lesions in the template strands. Their resolution is critical for chromosome segregation and cell viability, and is mediated by a class of small, homodimeric endonucleases that bind the structure and cleave the DNA. All the enzymes studied require divalent metal ions for strand cleavage and their active centres are characterised by conserved aspartate/glutamate residues that provide ligands for metal binding. Sequence alignments reveal that they also contain a number of conserved basic residues. We used site-directed mutagenesis to investigate such residues in the RusA resolvase. RusA is a 120 amino acid residue polypeptide that can be activated in Escherichia coli to promote recombination and repair in the absence of the Ruv proteins. The RuvA, RuvB and RuvC proteins form a complex on Holliday junction DNA that drives coupled branch migration (RuvAB) and resolution (RuvC) reactions. In contrast to RuvC, the RusA resolvase does not interact directly with a branch migration motor, which simplifies analysis of its resolution activity. Catalysis depends on three highly conserved acidic residues (Asp70, Asp72 and Asp91) that define the catalytic centre. We show that Lys76, which is invariant in RusA sequences, is essential for catalysis, but not for DNA binding, and that an invariant asparagine residue (Asn73) is required for optimal activity. Analysis of DNA binding revealed that RusA may interact with one face of an open junction before manipulating its conformation in the presence of Mg(2+) as part of the catalytic process. A well-conserved arginine residue (Arg69) is linked with this critical stage. These findings provide the first insights into the roles played by basic residues in DNA binding and catalysis by a Holliday junction resolvase.

The acidic pin of RuvA modulates Holliday junction binding and processing by the RuvABC resolvasome

Holliday junctions are four-way branched DNA structures formed during recombination, replication and repair. They are processed in Escherichia coli by the RuvA, RuvB and RuvC proteins. RuvA targets the junction and facilitates loading of RuvB helicase and RuvC endonuclease to form complexes that catalyse junction branch migration (RuvAB) and resolution (RuvABC). We investigated the role of RuvA in these reactions and in particular the part played by the acidic pin located on its DNA-binding surface. By making appropriate substitutions of two key amino acids (Glu55 and Asp56), we altered the charge on the pin and investigated how this affected junction binding and processing. We show that two negative charges on each subunit of the pin are crucial. They facilitate junction targeting by preventing binding to duplex DNA and also constrain branch migration by RuvAB in a manner critical for junction processing. These findings provide the first direct evidence that RuvA has a mechanistic role in branch migration. They also provide insight into the coupling of branch migration and resolution by the RuvABC resolvasome.

Cleavage of holliday junctions by the Escherichia coli RuvABC complex

The Escherichia coli RuvABC proteins process recombination intermediates during genetic recombination and recombinational repair. Although early biochemical studies indicated distinct RuvAB-mediated branch migration and RuvC-mediated Holliday junction resolution reactions, more recent studies have shown that the three proteins act together as a "resolvasome" complex. In this work we have used recombination intermediates made by RecA to determine whether the RuvAB proteins affect the sequence specificity of the RuvC resolvase. We find that RuvAB proteins do not alter significantly the site specificity of RuvC-dependent cleavage, although under certain conditions, they do affect the efficiency of cleavage at particular sites. The presence of RecA also influences cleavage at some sites. We also show that the RuvAB proteins act upon transient strand exchange intermediates made using substrates that have the opposite polarity of those preferred by RecA. Together, our results allow us to develop further a model for the recombinational repair of DNA lesions that lead to the formation of post-replication gaps during DNA replication. The novel features of this model are as follows: (i) the RuvABC resolvasome recognizes joints made by RecA; (ii) resolution by RuvABC occurs at specific sites containing the RuvC consensus cleavage sequence 5'-(A/T)TT downward arrow(G/C)-3'; and (iii) Holliday junction resolution often occurs close to the initiating gap without significant heteroduplex DNA formation.

Functional interactions of Mycobacterium leprae RuvA with Escherichia coli RuvB and RuvC on holliday junctions

The Mycobacterium leprae RuvA homologue (MlRuvA) was over-expressed in Escherichia coli and purified to homogeneity. The DNA-binding specificity and the functional interactions of MlRuvA with E. coli RuvB and RuvC (EcRuvB and EcRuvC) were examined using synthetic Holliday junctions. MlRuvA bound specifically to Holliday junctions and produced similar band-shift patterns as EcRuvA. Moreover, MlRuvA formed functional DNA helicase and branch-migration enzymes with EcRuvB, although the heterologous enzyme had a lower efficiency. These results demonstrate that the RuvA homologue of M. leprae is a functional branch-migration subunit. Whereas MlRuvA promoted branch-migration in combination with EcRuvB, it was unable to stimulate branch-migration-dependent resolution in a RuvABC complex. The inability to stimulate RuvC was not due to its failure to form heterologous RuvABC complexes on junctions, since such complexes were detected by co-immunoprecipitation. Most likely, the stability of the heterologous RuvABC complex and, possibly, the interactions between RuvA and RuvC were impaired, as gel-shift experiments failed to show mixed MlRuvA-EcRuvC-junction complexes. These results demonstrate that branch-migration per se and the assembly of a RuvABC complex on the Holliday junction are insufficient for RuvAB-dependent resolution of the junction by RuvC, suggesting that specific and intimate interactions between all three proteins are required for the function of a RuvABC "resolvasome".

Crystal structure of the holliday junction DNA in complex with a single RuvA tetramer

In the major pathway of homologous DNA recombination in prokaryotic cells, the Holliday junction intermediate is processed through its association with RuvA, RuvB, and RuvC proteins. Specific binding of the RuvA tetramer to the Holliday junction is required for the RuvB motor protein to be loaded onto the junction DNA, and the RuvAB complex drives the ATP-dependent branch migration. We solved the crystal structure of the Holliday junction bound to a single Escherichia coli RuvA tetramer at 3.1-A resolution. In this complex, one side of DNA is accessible for cleavage by RuvC resolvase at the junction center. The refined junction DNA structure revealed an open concave architecture with a four-fold symmetry. Each arm, with B-form DNA, in the Holliday junction is predominantly recognized in the minor groove through hydrogen bonds with two repeated helix-hairpin-helix motifs of each RuvA subunit. The local conformation near the crossover point, where two base pairs are disrupted, suggests a possible scheme for successive base pair rearrangements, which may account for smooth Holliday junction movement without segmental unwinding.

Modulation of RuvB function by the mobile domain III of the Holliday junction recognition protein RuvA

In prokaryotes, RuvA-RuvB complexes play a crucial role in the migration of the Holliday junction, which is a key intermediate of homologous recombination. RuvA binds to the Holliday junction and enhances the ATPase activity of RuvB required for branch migration. RuvA adopts a unique domain structure, which assembles into a tetrameric molecule. The previous mutational and proteolytic analyses suggested that mutations in a carboxyl-terminal domain (domain III) impair binding of RuvA to RuvB. In order to clarify the functional role of each domain in vitro, we established the recombinant expression systems, which allow us to analyze structural and biochemical properties of each domain separately. A small-angle X-ray scattering solution study, combined with X-ray crystallographic analyses, was applied to the tetrameric full-length RuvA and its tetrameric NH2 region (domains I and II) lacking the domain III. These results demonstrated that domain III can be completely separate from the tetrameric major core of the NH2 region and freely mobile in solution, through a remarkably flexible loop. Biochemical analyses indicated that domain III not only interacts with RuvB, but also modulates its ATPase activity. This modulation may facilitate the dynamic coupling between RuvA and RuvB during branch migration.

RuvAB-mediated branch migration does not involve extensive DNA opening within the RuvB hexamer

The Escherichia coli RuvA and RuvB proteins promote the branch migration of Holliday junctions during the late stages of homologous recombination and DNA repair (reviewed in [1]). Biochemical and structural studies of the RuvAB-Holliday junction complex have shown that RuvA binds directly to the Holliday junction [2] [3] [4] [5] [6] and acts as a specificity factor that promotes the targeting of RuvB [7] [8], a hexameric ring protein that drives branch migration [9] [10] [11]. Electron microscopic visualisation of the RuvAB complex revealed that RuvA is flanked by two RuvB hexamers, which bind DNA arms that lie diametrically opposed across the junction [8]. ATP-dependent branch migration occurs as duplex DNA is pumped out through the centre of each ring. Because RuvB possesses well-conserved helicase motifs and RuvAB exhibits a 5'-3' DNA helicase activity in vitro [12], the mechanism of branch migration is thought to involve DNA opening within the RuvB ring, which provides a single strand for the unidirectional translocation of the protein along DNA. We have investigated whether the RuvB ring can translocate along duplex DNA containing a site-directed interstrand psoralen crosslink. Surprisingly, we found that the crosslink failed to inhibit branch migration. We interpret these data as evidence against a base-by-base tracking model and suggest that extensive DNA opening within the RuvB ring is not required for DNA translocation by RuvB.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

Helicase-defective RuvB(D113E) promotes RuvAB-mediated branch migration in vitro

In Escherichia coli, the RuvA and RuvB proteins interact at Holliday junctions to promote branch migration leading to the formation of heteroduplex DNA. RuvA provides junction-binding specificity and RuvB drives ATP-dependent branch migration. Since RuvB contains sequence motifs characteristic of a DNA helicase and RuvAB exhibit helicase activity in vitro, we have analysed the role of DNA unwinding in relation to branch migration. A mutant RuvB protein, RuvB(D113E), mutated in helicase motif II (the DExx box), has been purified to homogeneity. The mutant protein forms hexameric rings on DNA similar to those formed by wild-type protein and promotes branch migration in the presence of RuvA. However, RuvB(D113E) exhibits reduced ATPase activity and is severely compromised in its DNA helicase activity. Models for RuvAB-mediated branch migration that invoke only limited DNA unwinding activity are proposed.

Assembly of the Escherichia coli RuvABC resolvasome directs the orientation of holliday junction resolution

Genetic recombination can lead to the formation of intermediates in which DNA molecules are linked by Holliday junctions. Movement of a junction along DNA, by a process known as branch migration, leads to heteroduplex formation, whereas resolution of a junction completes the recombination process. Holliday junctions can be resolved in either of two ways, yielding products in which there has, or has not, been an exchange of flanking markers. The ratio of these products is thought to be determined by the frequency with which the two isomeric forms (conformers) of the Holliday junction are cleaved. Recent studies with enzymes that process Holliday junctions in Escherichia coli, the RuvABC proteins, however, indicate that protein binding causes the junction to adopt an open square-planar configuration. Within such a structure, DNA isomerization can have little role in determining the orientation of resolution. To determine the role that junction-specific protein assembly has in determining resolution bias, a defined in vitro system was developed in which we were able to direct the assembly of the RuvABC resolvasome. We found that the bias toward resolution in one orientation or the other was determined simply by the way in which the Ruv proteins were positioned on the junction. Additionally, we provide evidence that supports current models on RuvABC action in which Holliday junction resolution occurs as the resolvasome promotes branch migration.

Identification of three aspartic acid residues essential for catalysis by the RusA holliday junction resolvase

RusA is a Holliday junction resolvase encoded by the cryptic prophage DLP12 of Escherichia coli K-12 that can be activated to promote homologous recombination and DNA repair in resolution-deficient mutants lacking the RuvABC proteins. Database searches with the 120 amino acid residue RusA sequence identified 11 homologues from diverse species, including one from the extreme thermophile Aquifex aeolicus, which suggests that RusA may be of ancient bacterial ancestry. A multiple alignment of these sequences revealed seven conserved or invariant acidic residues in the C-terminal half of the E. coli protein. By making site-directed mutations at these positions and analysing the ability of the mutant proteins to promote DNA repair in vivo and to resolve junctions in vitro, we identified three aspartic acid residues (D70, D72 and D91) that are essential for catalysis and that provide the first insight into the active-site mechanism of junction resolution by RusA. Substitution of any one of these three residues with asparagine reduces resolution activity >80-fold. The mutant proteins retain the ability to bind junction DNA regardless of the DNA sequence or of the mobility of the crossover. They interfere with the function of the RuvABC proteins in vivo, when expressed from a multicopy plasmid, an effect that is reproducible in vitro and that reflects the fact that the RusA proteins have a higher affinity for junction DNA in the presence of Mg2+ than do the RuvA and RuvC proteins. The D70N protein has a greater affinity for junctions in Mg2+ than does the wild-type, which indicates that the negatively charged carboxyl group of the aspartate residue plays a critical role at the active site of RusA. Electrostatic repulsions between D70, D72 and D91 may help to form a classical Mg2+-binding pocket.