Model for RuvAB-mediated branch migration of Holliday junctions

During RuvAB-mediated Holliday-junction migration two opposite arms of double-stranded DNA (dsDNA) are driven to translocate unidirectional by two respective ring-like hexameric RuvB proteins. However, how the RuvB protein, powered by ATP hydrolysis, drives unidirectional translocation of dsDNA is not clear. Here a model is presented for this mechanochemical-coupling mechanism. In the model, the unidirectional translocation is resulted from both the ATP hydrolysis-induced rotation (power stroke) of the RuvB subunits and the passage of the strong DNA binding from the previous to next RuvB subunits during the sequential ATPase activities around the ring. Using the model, the relationship between the power-stroke size, the step size of DNA translocation and the ratio of the rotational rate of DNA over that of RuvB relative to RuvA is predicted.     

p53 blocks RuvAB promoted branch migration and modulates resolution of Holliday junctions by RuvC

The Holliday junction is the central intermediate in homologous recombination. Branch migration of this four-stranded DNA structure is a key step in genetic recombination that affects the extent of genetic information exchanged between two parental DNA molecules. Here, we have constructed synthetic Holliday junctions to test the effects of p53 on both spontaneous and RuvAB promoted branch migration as well as the effect on resolution of the junction by RuvC. We demonstrate that p53 blocks branch migration, and that cleavage of the Holliday junction by RuvC is modulated by p53. These findings suggest that p53 can block branch migration promoted by proteins such as RuvAB and modulate the cleavage by Holliday junction resolution proteins such as RuvC. These results suggest that p53 could have similar effects on eukaryotic homologues of RuvABC and thus have a direct role in recombinational DNA repair.     

Direct evidence for spontaneous branch migration in antiparallel DNA Holliday junctions

The Holliday junction is a central intermediate in genetic recombination. It contains four strands of DNA that are paired into four double helical arms flanking a branch point. In naturally occurring Holliday junctions, the sequence flanking the branch point contains 2-fold (homologous) symmetry. As a consequence of this symmetry, the junction can undergo a conformational isomerization known as branch migration, which relocates the site of branching. In the absence of proteins and in the presence of Mg(2+), the four arms are known to stack in pairs, forming two helical domains whose orientations are antiparallel. Nevertheless, the mechanistic models proposed for branch migration are all predicated on a parallel alignment of helical domains. Here, we have used antiparallel DNA double crossover molecules to demonstrate that branch migration can occur in antiparallel Holliday junctions. We have constructed a DNA double crossover molecule with three crossover points. Two adjacent branch points in this molecule are flanked by symmetric sequences. The symmetric crossover points are held immobile by the third crossover point, which is flanked by asymmetric sequences. Restriction of the helices that connect the immobile junction to the symmetric junctions releases this constraint. The restricted molecule undergoes branch migration, even though it is constrained to an antiparallel conformation.     

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.     

The Fanconi anemia protein FANCM can promote branch migration of Holliday junctions and replication forks

Fanconi anemia (FA) is a genetically heterogeneous cancer-prone disorder associated with chromosomal instability and cellular hypersensitivity to DNA crosslinking agents. The FA pathway is suspected to play a crucial role in the cellular response to DNA replication stress. At a molecular level, however, the function of most of the FA proteins is unknown. FANCM displays DNA-dependent ATPase activity and promotes the dissociation of DNA triplexes, but the physiological significance of this activity remains elusive. Here we show that purified FANCM binds to Holliday junctions and replication forks with high specificity and promotes migration of their junction point in an ATPase-dependent manner. Furthermore, we provide evidence that FANCM can dissociate large recombination intermediates, via branch migration of Holliday junctions through 2.6 kb of DNA. Our data suggest a direct role for FANCM in DNA processing, consistent with the current view that FA proteins coordinate DNA repair at stalled replication forks.     

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.     

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.     

RuvA is a sliding collar that protects Holliday junctions from unwinding while promoting branch migration

The RuvAB proteins catalyze branch migration of Holliday junctions during DNA recombination in Escherichia coli. RuvA binds tightly to the Holliday junction, and then recruits two RuvB pumps to power branch migration. Previous investigations have studied RuvA in conjunction with its cellular partner RuvB. The replication fork helicase DnaB catalyzes branch migration like RuvB but, unlike RuvB, is not dependent on RuvA for activity. In this study, we specifically analyze the function of RuvA by studying RuvA in conjunction with DnaB, a DNA pump that does not work with RuvA in the cell. Thus, we use DnaB as a tool to dissect RuvA function from RuvB. We find that RuvA does not inhibit DnaB-catalyzed branch migration of a homologous junction, even at high concentrations of RuvA. Hence, specific protein-protein interaction is not required for RuvA mobilization during branch migration, in contrast to previous proposals. However, low concentrations of RuvA block DnaB unwinding at a Holliday junction. RuvA even blocks DnaB-catalyzed unwinding when two DnaB rings are acting in concert on opposite sides of the junction. These findings indicate that RuvA is intrinsically mobile at a Holliday junction when the DNA is undergoing branch migration, but RuvA is immobile at the same junction during DNA unwinding. We present evidence that suggests that RuvA can slide along a Holliday junction structure during DnaB-catalyzed branch migration, but not during unwinding. Thus, RuvA may act as a sliding collar at Holliday junctions, promoting DNA branch migration activity while blocking other DNA remodeling activities. Finally, we show that RuvA is less mobile at a heterologous junction compared to a homologous junction, as two opposing DnaB pumps are required to mobilize RuvA over heterologous DNA.     

Enzymatic formation and resolution of Holliday junctions in vitro

E. coli RecA protein promotes homologous pairing and reciprocal strand exchange reactions between duplex DNA molecules in vitro. Reaction intermediates contain Holliday junctions that are driven along the DNA at a maximal rate approaching 1000 bases per minute. T4 endonuclease VII cleaves Holliday junctions in vitro, and its inclusion in RecA-mediated reactions leads to the rapid formation of heteroduplex products. Product analysis indicates patch and splice recombinant molecules similar to those expected from in vivo recombination events. The combined formation and resolution of Holliday junctions has led us to propose a model for resolution based on the structure of RecA-DNA helices. One feature of this model is that resolution, which gives rise to the two types of recombinant product, may occur without need for isomerization of the junction.     

Polarity and bypass of DNA heterology during branch migration of Holliday junctions by human RAD54, BLM, and RECQ1 proteins

Several proteins have been shown to catalyze branch migration (BM) of the Holliday junction, a key intermediate in DNA repair and recombination. Here, using joint molecules made by human RAD51 or Escherichia coli RecA, we find that the polarity of the displaced ssDNA strand of the joint molecules defines the polarity of BM of RAD54, BLM, RECQ1, and RuvAB. Our results demonstrate that RAD54, BLM, and RECQ1 promote BM preferentially in the 3'→5' direction, whereas RuvAB drives it in the 5'→3' direction relative to the displaced ssDNA strand. Our data indicate that the helicase activity of BM proteins does not play a role in the heterology bypass. Thus, RAD54 that lacks helicase activity is more efficient in DNA heterology bypass than BLM or REQ1 helicases. Furthermore, we demonstrate that the BLM helicase and BM activities require different protein stoichiometries, indicating that different complexes, monomers and multimers, respectively, are responsible for these two activities. These results define BM as a mechanistically distinct activity of DNA translocating proteins, which may serve an important function in DNA repair and recombination.     

Novel properties of the Thermus thermophilus RuvB protein, which promotes branch migration of Holliday junctions

Branch migration of Holliday junctions, which are central DNA intermediates in homologous recombination, is promoted by the RuvA-RuvB protein complex, and the junctions are resolved by the action of the RuvC protein in Escherichia coli. We report here the cloning of the ruvB gene from a thermophilic eubacterium, Thermus thermophilus HB8 (Tth), and the biochemical characterization of the gene product expressed in E. coli. The Tth ruvB gene could not complement the UV sensitivity of an E. coli ruvB deletion mutant and made the wild-type strain more sensitive to UV. In contrast to E. coli RuvB, whose ATPase activity is strongly enhanced by supercoiled DNA but only weakly enhanced by linear duplex DNA, the ATPase activity of Tth RuvB was efficiently and equally enhanced by supercoiled and linear duplex DNA. Tth RuvB hydrolyzed a broader range of nucleoside triphosphates than E. coli RuvB. In addition, Tth RuvB, in the absence of RuvA protein, promoted branch migration of a synthetic Holliday junction at 60°?C in an ATP-dependent manner. The protein, as judged by its ATPase activity, required ATP for thermostability. Since a RuvA protein has not yet been identified in T. thermophilus, we used E. coli RuvA to examine the effects of RuvA on the activities of Tth RuvB. E. coli RuvA greatly enhanced the ability of Tth RuvB to hydrolyze ATP in the presence of DNA and to promote branch migration of a synthetic Holliday junction at 37°?C. These results indicate the conservation of the RuvA-RuvB interaction in different bacterial species, and suggest the existence of a ruvA homolog in T. thermophilus. Although GTP and dGTP were efficiently hydrolyzed by Tth RuvB, these nucleoside triphosphates could not be utilized for branch migration in vitro, implying that the conformational change in RuvB brought about by ATP hydrolysis, which is necessary for driving the Holliday junction branch migration, cannot be accomplished by the hydrolysis of these nucleoside triphosphates.     

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.     

The endonuclease Hje catalyses rapid, multiple turnover resolution of Holliday junctions

Holliday junction-resolving enzymes are ubiquitous, structure-specific endonucleases that resolve four-way DNA junctions by the introduction of paired nicks in opposing strands, and are required for homologous recombination, double-strand break repair, recombination-dependent restart of stalled or collapsed DNA replication forks, and phage DNA processing. Here, we present the first steady-state kinetic characterisation of a junction-resolving enzyme; the Hje endonuclease from Sulfolobus solfataricus. We demonstrate that substrate turnover by Hje is sequence-independent and limited largely by the rate of cleavage of the phosphodiester bonds of the bound Holliday junction substrate, rather than substrate association or product dissociation. Reaction rates under multiple turnover conditions compare favourably with type II restriction enzymes. These properties, coupled with a high level of specificity for four-way junctions over all other DNA substrates, make Hje a suitable enzyme for applications requiring the detection and cleavage of Holliday junctions in vitro.     

Novel properties of the Thermus thermophilus RuvB protein, which promotes branch migration of Holliday junctions

Branch migration of Holliday junctions, which are central DNA intermediates in homologous recombination, is promoted by the RuvA-RuvB protein complex, and the junctions are resolved by the action of the RuvC protein in Escherichia coli. We report here the cloning of the ruvB gene from a thermophilic eubacterium, Thermus thermophilus HB8 (Tth), and the biochemical characterization of the gene product expressed in E. coli. The Tth ruvB gene could not complement the UV sensitivity of an E. coli ruvB deletion mutant and made the wild-type strain more sensitive to UV. In contrast to E. coli RuvB, whose ATPase activity is strongly enhanced by supercoiled DNA but only weakly enhanced by linear duplex DNA, the ATPase activity of Tth RuvB was efficiently and equally enhanced by supercoiled and linear duplex DNA. Tth RuvB hydrolyzed a broader range of nucleoside triphosphates than E. coli RuvB. In addition, Tth RuvB, in the absence of RuvA protein, promoted branch migration of a synthetic Holliday junction at 60° C in an ATP-dependent manner. The protein, as judged by its ATPase activity, required ATP for thermostability. Since a RuvA protein has not yet been identified in T. thermophilus, we used E. coli RuvA to examine the effects of RuvA on the activities of Tth RuvB. E. coli RuvA greatly enhanced the ability of Tth RuvB to hydrolyze ATP in the presence of DNA and to promote branch migration of a synthetic Holliday junction at 37° C. These results indicate the conservation of the RuvA-RuvB interaction in different bacterial species, and suggest the existence of a ruvA homolog in T. thermophilus. Although GTP and dGTP were efficiently hydrolyzed by Tth RuvB, these nucleoside triphosphates could not be utilized for branch migration in vitro, implying that the conformational change in RuvB brought about by ATP hydrolysis, which is necessary for driving the Holliday junction branch migration, cannot be accomplished by the hydrolysis of these nucleoside triphosphates. Received: 26 November 1998 / Accepted: 19 April 1999     

Thermostable chemotaxis proteins from the hyperthermophilic bacterium Thermotoga maritima.

An expressed sequence tag homologous to cheA was previously isolated by random sequencing of Thermotoga maritima cDNA clones (C. W. Kim, P. Markiewicz, J. J. Lee, C. F. Schierle, and J. H. Miller, J. Mol. Biol. 231: 960-981, 1993). Oligonucleotides complementary to this sequence tag were synthesized and used to identify a clone from a T. maritima lambda library by using PCR. Two partially overlapping restriction fragments were subcloned from the lambda clone and sequenced. The resulting 5,251-bp sequence contained five open reading frames, including cheA, cheW, and cheY. In addition to the chemotaxis genes, the fragment also encodes a putative protein isoaspartyl methyltransferase and an open reading frame of unknown function. Both the cheW and cheY genes were individually cloned into inducible Escherichia coli expression vectors. Upon induction, both proteins were synthesized at high levels. T. maritima CheW and CheY were both soluble and were easily purified from the bulk of the endogenous E. coli protein by heat treatment at 80 degrees C for 10 min. CheY prepared in this way was shown to be active by the demonstration of Mg(2+)-dependent autophosphorylation with [32P]acetyl phosphate. In E. coli, CheW mediates the physical coupling of the receptors to the kinase CheA. The availability of a thermostable homolog of CheW opens the possibility of structural characterization of this small coupling protein, which is among the least well characterized proteins in the bacterial chemotaxis signal transduction pathway.     

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.     

The isomeric preference of Holliday junctions influences resolution bias by lambda integrase.

Lambda site-specific recombination proceeds by a pair of sequential strand exchanges that first generate and then resolve a Holliday junction intermediate. A family of synthetic Holliday junctions with the branch point constrained to the center of the 7 bp overlap region was used to show that resolution of the top strands and resolution of the bottom strands are symmetrical but stereochemically distinct processes. Lambda integrase is sensitive to isomeric structure, preferentially resolving the pair of strands that are crossed in the protein-free Holliday junction. At the branch point of stacked immobile Holliday junctions, the number of purines is preferentially maximized in the crossed (versus continuous) strands if there is an inequality of purines between strands of opposite polarity. This stacking preference was used to anticipate the resolution bias of freely mobile junctions and thereby to reinforce the conclusions with monomobile junctions. The results provide a strong indication that in the complete recombination reaction a restacking of helices occurs between the top and bottom strand exchanges.     

Structure and mechanism of the RuvB Holliday junction branch migration motor

The RuvB hexamer is the chemomechanical motor of the RuvAB complex that migrates Holliday junction branch-points in DNA recombination and the rescue of stalled DNA replication forks. The 1.6 A crystal structure of Thermotoga maritima RuvB together with five mutant structures reveal that RuvB is an ATPase-associated with diverse cellular activities (AAA+-class ATPase) with a winged-helix DNA-binding domain. The RuvB-ADP complex structure and mutagenesis suggest how AAA+-class ATPases couple nucleotide binding and hydrolysis to interdomain conformational changes and asymmetry within the RuvB hexamer implied by the crystallographic packing and small-angle X-ray scattering in solution. ATP-driven domain motion is positioned to move double-stranded DNA through the hexamer and drive conformational changes between subunits by altering the complementary hydrophilic protein- protein interfaces. Structural and biochemical analysis of five motifs in the protein suggest that ATP binding is a strained conformation recognized both by sensors and the Walker motifs and that intersubunit activation occurs by an arginine finger motif reminiscent of the GTPase-activating proteins. Taken together, these results provide insights into how RuvB functions as a motor for branch migration of Holliday junctions.     

A mutation in helicase motif III of E. coli RecG protein abolishes branch migration of Holliday junctions.

The RecG protein of Escherichia coli catalyses branch migration of Holliday junctions made by RecA and dissociates synthetic X junctions into duplex products in reactions that require hydrolysis of ATP. To investigate the mode of action of this enzyme a chromosomal mutation that inactivates recG (recG162) was cloned and sequenced. The recG162 mutation is a G:C to A:T transition, which produces an Ala428 to Val substitution in the protein. This change affects a motif (motif III) in the protein that is highly conserved in DNA and RNA helicases. RecG162 protein was purified and shown to retain the ability to bind synthetic X and Y junctions. However, it does not dissociate these junctions and fails to catalyse branch migration of Holliday junction intermediates purified from a RecA strand exchange reaction. RecG162 retains a DNA-dependent ATPase activity, but this is much reduced relative to the wild-type protein, especially with single-stranded DNA as a co-factor. These results suggest that branch migration by RecG is related to a junction-targeted DNA helicase activity.