Resolution of Joint Molecules by RuvABC and RecG Following Cleavage of the Escherichia coli Chromosome by EcoKI

DNA double-strand breaks can be repaired by homologous recombination involving the formation and resolution of Holliday junctions. In Escherichia coli, the RuvABC resolvasome and the RecG branch-migration enzyme have been proposed to act in alternative pathways for the resolution of Holliday junctions. Here, we have studied the requirements for RuvABC and RecG in DNA double-strand break repair after cleavage of the E. coli chromosome by the EcoKI restriction enzyme. We show an asymmetry in the ability of RuvABC and RecG to deal with joint molecules in vivo. We detect linear DNA products compatible with the cleavage-ligation of Holliday junctions by the RuvABC pathway but not by the RecG pathway. Nevertheless we show that the XerCD-mediated pathway of chromosome dimer resolution is required for survival regardless of whether the RuvABC or the RecG pathway is active, suggesting that crossing-over is a common outcome irrespective of the pathway utilised. This poses a problem. How can cells resolve joint molecules, such as Holliday junctions, to generate crossover products without cleavage-ligation? We suggest that the mechanism of bacterial DNA replication provides an answer to this question and that RecG can facilitate replication through Holliday junctions.     

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.     

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.     

Rapid analysis of protein-nucleic acid complexes using MALDI TOF mass spectrometry and ion pair reverse phase liquid chromatography

The RuvABC resolvasome of Escherichia coli typifies nucleoprotein complexes involved in genetic transactions. This molecular assembly 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 used matrix-assisted laser desorption/ionisation time of flight mass spectrometry (MALDI-TOF MS) to rapidly identify the binding of RuvA to an immobilised synthetic Holliday junction; unambiguous identification was verified using tryptic digest of the bound protein. In conjunction with a novel fluorescent-based technique incorporating ion pair reverse phase liquid chromatography, a "footprint" of the RuvA:Holliday complex was obtained. These two complementary techniques offer a generic approach to the analysis of nucleoprotein complexes.     

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.     

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

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

DNA double strand break repair and crossing over mediated by RuvABC resolvase and RecG translocase

DNA double-strand breaks threaten the stability of the genome, and yet are induced deliberately during meiosis in order to provoke homologous recombination and generate the crossovers needed to promote faithful chromosome transmission. Crossovers are secured via biased resolution of the double Holliday junction intermediates formed when both ends of the broken chromosome engage an intact homologue. To investigate whether the enzymes catalysing branch migration and resolution of Holliday junctions are directed to favour production of either crossover or noncrossover products, we engineered a genetic system based on DNA breakage induced by the I-SceI endonuclease to detect analogous exchanges in Escherichia coli where the enzymology of recombination is more fully understood. Analysis of the recombinants generated revealed approximately equal numbers of crossover and noncrossover products, regardless of whether repair is mediated via RecG, RuvABC, or the RusA resolvase. We conclude that there little or no control of crossing over at the level of Holliday junction resolution. Thus, if similar resolvases function during meiosis, additional factors must act to bias recombination in favour of crossover progeny.     

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.     

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".     

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.     

Repair and antirepair DNA helicases in Helicobacter pylori

Orthologs of RecG and RuvABC are highly conserved among prokaryotes; in Escherichia coli, they participate in independent pathways that branch migrate Holliday junctions during recombinational DNA repair. RecG also has been shown to directly convert stalled replication forks into Holliday junctions. The bacterium Helicobacter pylori, with remarkably high levels of recombination, possesses RecG and RuvABC homologs, but in contrast to E. coli, H. pylori RecG limits recombinational repair. We now show that the RuvABC pathway plays the prominent, if not exclusive, repair role. By introducing an E. coli resolvase (RusA) into H. pylori, the repair and recombination phenotypes of the ruvB mutant but not the recG mutant were improved. Our results indicate that RecG and RuvB compete for Holliday junction structures in recombinational repair, but since a classic RecG resolvase is absent from H. pylori, deployment of the RecG pathway is lethal. We propose that evolutionary loss of the H. pylori RecG resolvase provides an "antirepair" pathway allowing for selection of varied strains. Such competition between repair and antirepair provides a novel mechanism to maximize fitness at a bacterial population level.     

The RuvABC resolvase is indispensable for recombinational repair in sbcB15 mutants of Escherichia coli

The RuvABC proteins of Escherichia coli play an important role in the processing of Holliday junctions during homologous recombination and recombinational repair. Mutations in the ruv genes have a moderate effect on recombination and repair in wild-type strains but confer pronounced recombination deficiency and extreme sensitivity to DNA-damaging agents in a recBC sbcBC background. Genetic analysis presented in this work revealed that the (Delta)ruvABC mutation causes an identical DNA repair defect in UV-irradiated recBC sbcBC, sbcBC, and sbcB strains, indicating that the sbcB mutation alone is responsible for the extreme UV sensitivity of recBC sbcBC ruv derivatives. In experiments with gamma irradiation and in conjugational crosses, however, sbcBC (Delta)ruvABC and sbcB (Delta)ruvABC mutants displayed higher recombination proficiency than the recBC sbcBC (Delta)ruvABC strain. The frequency of conjugational recombination observed with the sbcB (Delta)ruvABC strain was quite similar to that of the (Delta)ruvABC single mutant, indicating that the sbcB mutation does not increase the requirement for RuvABC in a recombinational process starting from preexisting DNA ends. The differences between the results obtained in three experimental systems used suggest that in UV-irradiated cells, the RuvABC complex might act in an early stage of recombinational repair. The results of this work are discussed in the context of recent recombination models which propose the participation of RuvABC proteins in the processing of Holliday junctions made from stalled replication forks. We suggest that the mutant SbcB protein stabilizes these junctions and makes their processing highly dependent on RuvABC resolvase.     

Recombinations occurring in the process of DNA replication in Escherichia coli

In a number of works dealing with the relationship between replication and recombination in bacteria, it is assumed that recombinations permit the replication forks to resume moving after having stopped at the damage sites of the template DNA. As an evidence for recombination occurring during DNA replication, the involvement in this process of proteins RuvABC and RecG, providing processing of the Holliday junctions after recombination, is considered. However, it has been shown that these proteins are not essential for resuming DNA synthesis after an exposure of bacteria to UV light. These data cast doubt on the necessity of recombination for reactivation of replication initiated in the oriC region. Studying recombination in tandem duplications in Escherichia coli showed that during replication, unequal crossing over occurs between direct DNA repeats of sister chromosomes. In wild strains, this crossing over results in tandem duplications, thereby enhancing the expression of certain genes. Thus, recombination of two types occurs during DNA replication: unequal crossing over leading to duplications and homologous exchange, responsible for post-replication DNA repair. The unequal exchange constitutes a component of SOS response of the cell to deterioration of the environment.     

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

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

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.     

Resolution of holliday junctions by RuvABC prevents dimer formation in rep mutants and UV-irradiated cells

In this work, we present evidence that indicates that RuvABC proteins resolve Holliday junctions in a way that prevents dimer formation in vivo. First, although arrested replication forks are rescued by recombinational repair in cells deficient for the Rep helicase, rep mutants do not require the XerCD proteins or the dif site for viability. This shows that the recombination events at arrested replication forks are generally not accompanied by the formation of chromosome dimers. Secondly, resolution of dimers into monomers is essential in the rep ruv strain because of an increased frequency of RecFOR recombination events in the chromosome of this mutant. This suggests that, in the absence of the Ruv proteins, chromosomal recombination leads to frequent dimerization. Thirdly, dif or xerC mutations increase the UV sensitivity of ruv-deficient cells 100-fold, whereas they do not confer UV sensitivity to ruv+ cells. This shows that recombinational repair of UV lesions is not accompanied by dimer formation provided that the RuvABC proteins are active. The requirement for dimer resolution in ruv strains is suppressed by the expression of the RusA Holliday junction resolvase; therefore, RusA also prevents dimer formation. We conclude that the inviability arising from a high frequency of dimer formation in rep or UV-irradiated cells is only observed in the absence of known enzymes that resolve Holliday junctions.     

The function of recombinations occurring in the process of DNA replication in Escherichia coli

In a number of works dealing with the relationship between replication and recombination in bacteria, it is assumed that recombinations permit the replication forks to resume moving after having stopped at the damage sites of the template DNA. As an evidence for recombination occurring during DNA replication, the involvement in this process of proteins RuvABC and RecG, providing processing of the Holliday junctions after recombination, is considered. However, it has been shown that these proteins are not essential for resuming DNA synthesis after an exposure of bacteria to UV light. These data cast doubt on the necessity of recombination for reactivation of replication initiated in the oriC region. Studying recombination in tandem duplications in Escherichia coli showed that during replication, unequal crossing over occurs between direct DNA repeats of sister chromosomes. In wild strains, this crossing over results in tandem duplications, thereby enhancing the expression of certain genes. Thus, recombination of two types occurs during DNA replication: unequal crossing over leading to duplications and homologous exchange, responsible for post-replication DNA repair. The unequal exchange constitutes a component of SOS response of the cell to deterioration of the environment.     

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

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

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.