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

Prokaryotic DNA Crossroads: Holliday Junction Formation and Resolution

Cells are continually exposed to a multitude of internal and external stressors, which give rise to various types of DNA damage. To protect the integrity of their genetic material, cells are equipped with a repertoire of repair proteins that engage in various repair mechanisms, facilitated by intricate networks of protein-protein and protein-DNA interactions. Among these networks is the homologous recombination (HR) system, a molecular repair mechanism conserved in all three domains of life. On one hand, HR ensures high-fidelity, template-dependent DNA repair, while on the other hand, it results in the generation of combinatorial genetic variations through allelic exchange. Despite substantial progress in understanding this pathway in bacteria, yeast, and humans, several critical questions remain unanswered, including the molecular processes leading to the exchange of DNA segments, the coordination of protein binding, conformational switching during branch migration, and the resolution of Holliday Junctions (HJs). This Review delves into our current understanding of the HR pathway in bacteria, shedding light on the roles played by various proteins or their complexes at different stages of HR. In the first part of this Review, we provide a brief overview of the end resection processes and the strand-exchange reaction, offering a concise depiction of the mechanisms that culminate in the formation of HJs. In the latter half, we expound upon the alternative methods of branch migration and HJ resolution more comprehensively and holistically, considering the historical research timelines. Finally, when we consolidate our knowledge about HR within the broader context of genome replication and the emergence of resistant species, it becomes evident that the HR pathway is indispensable for the survival of bacteria in diverse ecological niches.

Recombinational repair in the absence of holliday junction resolvases in E. coli

Cells possess two major DNA damage tolerance pathways that allow them to duplicate their genomes despite the presence of replication blocking lesions: translesion synthesis (TLS) and daughter strand gap repair (DSGR). The TLS pathway involves specialized DNA polymerases that are able to synthesize past DNA lesions while DSGR relies on Recombinational Repair (RR). At least two mechanisms are associated with RR: Homologous Recombination (HR) and RecA Mediated Excision Repair (RAMER). While HR and RAMER both depend on RecFOR and RecA, only the HR mechanism should involve Holliday Junctions (HJs) resolvase reactions. In this study we investigated the role of HJ resolvases, RuvC, TopIII and RusA on the balance between RAMER and HR in E. coli MG1655 derivatives. Using UV survival measurements, we first clearly establish that, in this genetic background, topB and ruvC define two distinct pathways of HJ resolution. We observed that a recA mutant is much more sensitive to UV than the ruvC topB double mutant which is deficient in HR because of its failure to resolve HJs. This difference is independent of RAMER, the SOS system, RusA, and the three TLS DNA polymerases, and may be accounted for by Double Strand Break repair mechanisms such as Synthesis Dependent Strand Annealing, Single Strand Annealing, or Break Induced Replication, which are independent of HJ resolvases. We then used a plasmid-based assay, in which RR is triggered by a single blocking lesion present on a plasmid molecule, to establish that while HR requires topB, ruvC or rusA, RAMER is independent of these genes and, as expected, requires a functional UvrABC excinuclease. Surprisingly, analysis of the RR events in a strain devoid of HJ resolvases reveals that the UvrABC dependent repair of the single lesion present on the plasmid molecule can generate an excision track potentially extending to dozens of nucleotides.

The topoisomerase 3α zinc-finger domain T1 of Arabidopsis thaliana is required for targeting the enzyme activity to Holliday junction-like DNA repair intermediates

Topoisomerase 3α, a class I topoisomerase, consists of a TOPRIM domain, an active centre and a variable number of zinc-finger domains (ZFDs) at the C-terminus, in multicellular organisms. Whereas the functions of the TOPRIM domain and the active centre are known, the specific role of the ZFDs is still obscure. In contrast to mammals where a knockout of TOP3α leads to lethality, we found that CRISPR/Cas induced mutants in Arabidopsis are viable but show growth retardation and meiotic defects, which can be reversed by the expression of the complete protein. However, complementation with AtTOP3α missing either the TOPRIM-domain or carrying a mutation of the catalytic tyrosine of the active centre leads to embryo lethality. Surprisingly, this phenotype can be overcome by the simultaneous removal of the ZFDs from the protein. In combination with a mutation of the nuclease AtMUS81, the TOP3α knockout proved to be also embryo lethal. Here, expression of TOP3α without ZFDs, and in particular without the conserved ZFD T1, leads to only a partly complementation in root growth-in contrast to the complete protein, that restores root length to mus81-1 mutant level. Expressing the E. coli resolvase RusA in this background, which is able to process Holliday junction (HJ)-like recombination intermediates, we could rescue this root growth defect. Considering all these results, we conclude that the ZFD T1 is specifically required for targeting the topoisomerase activity to HJ like recombination intermediates to enable their processing. In the case of an inactivated enzyme, this leads to cell death due to the masking of these intermediates, hindering their resolution by MUS81.

Crystal structure of RuvC resolvase in complex with Holliday junction substrate

The key intermediate in genetic recombination is the Holliday junction (HJ), a four-way DNA structure. At the end of recombination, HJs are cleaved by specific nucleases called resolvases. In Gram-negative bacteria, this cleavage is performed by RuvC, a dimeric endonuclease that belongs to the retroviral integrase superfamily. Here, we report the first crystal structure of RuvC in complex with a synthetic HJ solved at 3.75 Å resolution. The junction in the complex is in an unfolded 2-fold symmetrical conformation, in which the four arms point toward the vertices of a tetrahedron. The two scissile phosphates are located one nucleotide from the strand exchange point, and RuvC approaches them from the minor groove side. The key protein-DNA contacts observed in the structure were verified using a thiol-based site-specific cross-linking approach. Compared with known complex structures of the phage resolvases endonuclease I and endonuclease VII, the RuvC structure exhibits striking differences in the mode of substrate binding and location of the cleavage site.

Characterization of the Holliday junction resolving enzyme encoded by the Bacillus subtilis bacteriophage SPP1

Recombination-dependent DNA replication, which is a central component of viral replication restart, is poorly understood in Firmicutes bacteriophages. Phage SPP1 initiates unidirectional theta DNA replication from a discrete replication origin (oriL), and when replication progresses, the fork might stall by the binding of the origin binding protein G38P to the late replication origin (oriR). Replication restart is dependent on viral recombination proteins to synthesize a linear head-to-tail concatemer, which is the substrate for viral DNA packaging. To identify new functions involved in this process, uncharacterized genes from phage SPP1 were analyzed. Immediately after infection, SPP1 transcribes a number of genes involved in recombination and replication from P_E2 and P_E3 promoters. Resequencing the region corresponding to the last two hypothetical genes transcribed from the P_E2 operon (genes 44 and 45) showed that they are in fact a single gene, re-annotated here as gene 44, that encodes a single polypeptide, named gene 44 product (G44P, 27.5 kDa). G44P shares a low but significant degree of identity in its C-terminal region with virus-encoded RusA-like resolvases. The data presented here demonstrate that G44P, which is a dimer in solution, binds with high affinity but without sequence specificity to several double-stranded DNA recombination intermediates. G44P preferentially cleaves Holliday junctions, but also, with lower efficiency, replicated D-loops. It also partially complemented the loss of RecU resolvase activity in B. subtilis cells. These in vitro and in vivo data suggest a role for G44P in replication restart during the transition to concatemeric viral replication.

In silico identification of a multi-functional regulatory protein involved in Holliday junction resolution in bacteria

BACKGROUND

Homologous recombination is a fundamental cellular process that is most widely used by cells to rearrange genes and accurately repair DNA double-strand breaks. It may result in the formation of a critical intermediate named Holliday junction, which is a four-way DNA junction and needs to be resolved to allow chromosome segregation. Different Holliday junction resolution systems and enzymes have been characterized from all three domains of life. In bacteria, the RuvABC complex is the most important resolution system.

RESULTS

In this study, we conducted comparative genomics studies to identify a novel DNA-binding protein, YebC, which may serve as a key transcriptional regulator that mainly regulates the gene expression of RuvABC resolvasome in bacteria. On the other hand, the presence of YebC orthologs in some organisms lacking RuvC implied that it might participate in other biological processes. Further phylogenetic analysis of YebC protein sequences revealed two functionally different subtypes: YebC_I and YebC_II. Distribution of YebC_I is much wider than YebC_II. Only YebC_I proteins may play an important role in regulating RuvABC gene expression in bacteria. Investigation of YebC-like proteins in eukaryotes suggested that they may have originated from YebC_II proteins and evolved a new function as a specific translational activator in mitochondria. Finally, additional phylum-specific genes associated with Holliday junction resolution were predicted.

CONCLUSIONS

Overall, our data provide new insights into the basic mechanism of Holliday junction resolution and homologous recombination in bacteria.

Holliday junction-containing DNA structures persist in cells lacking Sgs1 or Top3 following exposure to DNA damage

The Sgs1-Rmi1-Top3 "dissolvasome" is required for the maintenance of genome stability and has been implicated in the processing of various types of DNA structures arising during DNA replication. Previous investigations have revealed that unprocessed (X-shaped) homologous recombination repair (HRR) intermediates persist when S-phase is perturbed by using methyl methanesulfonate (MMS) in Saccharomyces cerevisiae cells with impaired Sgs1 or Top3. However, the precise nature of these persistent DNA structures remains poorly characterized. Here, we report that ectopic expression of either of two heterologous and structurally unrelated Holliday junction (HJ) resolvases, Escherichia coli RusA or human GEN1(1-527), promotes the removal of these X-structures in vivo. Moreover, other types of DNA replication intermediates, including stalled replication forks and non-HRR-dependent X-structures, are refractory to RusA or GEN1(1-527), demonstrating specificity of these HJ resolvases for MMS-induced X-structures in vivo. These data suggest that the X-structures persisting in cells with impaired Sgs1 or Top3 contain HJs. Furthermore, we demonstrate that Sgs1 directly promotes X-structure removal, because the persistent structures arising in Sgs1-deficient strains are eliminated when Sgs1 is reactivated in vivo. We propose that HJ resolvases and Sgs1-Top3-Rmi1 comprise two independent processes to deal with HJ-containing DNA intermediates arising during HRR in S-phase.

Is RecG a general guardian of the bacterial genome?

The RecG protein of Escherichia coli is a double-stranded DNA translocase that unwinds a variety of branched DNAs in vitro, including Holliday junctions, replication forks, D-loops and R-loops. Coupled with the reported pleiotropy of recG mutations, this broad range of potential targets has made it hard to pin down what the protein does in vivo, though roles in recombination and replication fork repair have been suggested. However, recent studies suggest that RecG provides a more general defence against pathological DNA replication. We have postulated that this is achieved through the ability of RecG to eliminate substrates that the replication restart protein, PriA, could otherwise exploit to re-replicate the chromosome. Without RecG, PriA triggers a cascade of events that interfere with the duplication and segregation of chromosomes. Here we review the studies that led us to this idea and to conclude that RecG may be both a specialist activity and a general guardian of the genome.

New insight into the recognition of branched DNA structure by junction-resolving enzymes

Junction-resolving enzymes are nucleases that exhibit structural selectivity for the four-way (Holliday) junction in DNA. In general, these enzymes both recognize and distort the structure of the junction. New insight into the molecular recognition processes has been provided by two recent co-crystal structures of resolving enzymes bound to four-way DNA junctions in highly contrasting ways. T4 endonuclease VII binds the junction in an open conformation to an approximately flat binding surface whereas T7 endonuclease I envelops the junction, which retains a much more three-dimensional structure. Both proteins make contacts with the DNA backbone over an extensive area in order to generate structural specificity. The comparison highlights the versatility of Holliday junction resolution, and extracts some general principles of recognition.

RusA Holliday junction resolvase: DNA complex structure--insights into selectivity and specificity

We have determined the structure of a catalytically inactive D70N variant of the Escherichia coli RusA resolvase bound to a duplex DNA substrate that reveals critical protein-DNA interactions and permits a much clearer understanding of the interaction of the enzyme with a Holliday junction (HJ). The RusA enzyme cleaves HJs, the fourway DNA branchpoints formed by homologous recombination, by introducing symmetrical cuts in the phosphodiester backbone in a Mg2+ dependent reaction. Although, RusA shows a high level of selectivity for DNA junctions, preferring to bind fourway junctions over other substrates in vitro, it has also been shown to have appreciable affinity for duplex DNA. However, RusA does not show DNA cleavage activity with duplex substrates. Our structure suggests the possible basis for structural selectivity as well as sources of the sequence specificity observed for DNA cleavage by RusA.

Selective binding of meiosis-specific yeast Hop1 protein to the holliday junctions distorts the DNA structure and its implications for junction migration and resolution

Saccharomyces cerevisiae HOP1, which encodes a component of synaptonemal complex (SC), plays an important role in both gene conversion and crossing over between homologs, as well as enforces meiotic recombination checkpoint control over the progression of recombination intermediates. In hop1Delta mutants, meiosis-specific double-strand breaks (DSBs) are reduced to 10% of the wild-type level, and at aberrantly late times, these DSBs are processed into inter-sister recombination intermediates. However, the underlying mechanism by which Hop1 protein regulates these nuclear events remains obscure. Here we show that Hop1 protein interacts selectively with the Holliday junction, changes its global conformation and blocks the dissolution of the junction by a RecQ helicase. The Holliday junction-Hop1 protein complexes are significantly more stable at higher ionic strengths and molar excess of unlabeled competitor DNA than complexes containing other recombination intermediates. Structural analysis of the Holliday junction using 2-aminopurine fluorescence emission, DNase I footprinting and KMnO4 probing provide compelling evidence that Hop1 protein binding induces significant distortion at the center of the Holliday junction. We propose that Hop1 protein might coordinate the physical monitoring of meiotic recombination intermediates with the process of branch migration of Holliday junction.

Evolution of a phage RuvC endonuclease for resolution of both Holliday and branched DNA junctions

Resolution of Holliday junction recombination intermediates in most Gram-negative bacteria is accomplished by the RuvC endonuclease acting in concert with the RuvAB branch migration machinery. Gram-positive species, however, lack RuvC, with the exception of distantly related orthologues from bacteriophages infecting Lactococci and Streptococci. We have purified one of these proteins, 67RuvC, from Lactococcus lactis phage bIL67 and demonstrated that it functions as a Holliday structure resolvase. Differences in the sequence selectivity of resolution between 67RuvC and Escherichia coli RuvC were noted, although both enzymes prefer to cleave 3' of thymidine residues. However, unlike its cellular counterpart, 67RuvC readily binds and cleaves a variety of branched DNA substrates in addition to Holliday junctions. Plasmids expressing 67RuvC induce chromosomal breaks, probably as a consequence of replication fork cleavage, and cannot be recovered from recombination-defective E. coli strains. Despite these deleterious effects, 67RuvC constructs suppress the UV light sensitivity of ruvA, ruvAB and ruvABC mutant strains confirming that the phage protein mediates Holliday junction resolution in vivo. The characterization of 67RuvC offers a unique insight into how a Holliday junction-specific resolvase can evolve into a debranching endonuclease tailored to the requirements of phage recombination.

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.

Electrostatic Interactions and the Folding of the Four-way DNA Junction: Analysis by Selective Methyl Phosphonate Substitution

The structure and dynamics of the four-way (Holliday) junction are strongly dependent on the presence of metal ions. In this study, the importance of phosphate charge in and around the point of strand exchange has been explored by selective replacement with electrically neutral methyl phosphonate groups, guided by crystal structures of the junction in the folded, stacked X conformation. Junction conformation has been analysed by comparative gel electrophoresis and fluorescence resonance energy transfer (FRET). Three of sets of phosphate groups on the exchanging strands have been analysed; those at the point of strand exchange and those to their 3' and 5' sides. The exchanging and 3' phosphate groups form a box of negatively charged groups on the minor groove face of the junction, while the 5' phosphate groups face each other on the major groove side, with their proR oxygen atoms directed at one another. The largest effects are observed on substitution of the exchanging phosphate groups; replacement of both groups leads to the loss of the requirement for addition of metal ions to allow junction folding. When the equivalent phosphate groups on the continuous strands were substituted, a proportion of the junction folded into the alternative conformer so as to bring these phosphate groups onto the exchanging strands. These species did not interconvert, and thus this is likely to result from the alternative diasteromeric forms of the methyl phosphonate group. This shows that some of the conformational effects result from more than purely electrostatic interactions. Smaller but significant effects were observed on substitution of the flanking phosphate groups. All methyl phosphonate substitutions at these positions allowed folding to proceed at a reduced concentration of magnesium ions, with double substitutions more effective than single substitutions. Substitution of 5' phosphates resulted in a greater degree of folding at a given ionic concentration compared to the corresponding 3' phosphate substitutions. These results show that the phosphate groups at the point of strand exchange exert the largest electrostatic effect on junction folding, but a number of phosphate groups in the vicinity of the exchange region contribute to the overall effects.

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.

Bacillus subtilis RecU protein cleaves Holliday junctions and anneals single-stranded DNA

Bacillus subtilis RecU protein is involved in homologous recombination, DNA repair, and chromosome segregation. Purified RecU binds preferentially to three- and four-strand junctions when compared to single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA) ( approximately 10- and approximately 40-fold lower efficiency, respectively). RecU cleaves mobile four-way junctions but fails to cleave a linear dsDNA with a putative cognate site, a finding consistent with a similar genetic defect observed for genes classified within the epsilon epistatic group (namely ruvA, recD, and recU). In the presence of Mg(2+), RecU also anneals a circular ssDNA and a homologous linear dsDNA with a ssDNA tail and a linear ssDNA and a homologous supercoiled dsDNA substrate. These results suggest that RecU, which cleaves recombination intermediates with high specificity, might also help in their assembly.

Holliday junctions in the eukaryotic nucleus: resolution in sight?

The Holliday junction is a key recombination intermediate whose resolution generates crossovers. Interplay between recombination, repair and replication has moved the Holliday junction to the center stage of nuclear DNA metabolism. Holliday junction resolvases in the eukaryotic nucleus have long eluded identification. The endonucleases Mus81/Mms4-Eme1 and XPF-MEI-9/MUS312 are structurally related to the archaeal resolvase Hjc and were found to be involved in crossover formation in budding yeast and flies, respectively. Although these endonucleases might represent one class of eukaryotic resolvases, their substrate preference opens up the possibility that junctions other than classical Holliday junctions might contribute to crossovers. Holliday junction resolution to non-crossover products can also be achieved topologically, for example, by the action of RecQ-like DNA helicases combined with topoisomerase III.

The Structure of Escherichia coli RusA Endonuclease Reveals a New Holliday Junction DNA Binding Fold

Holliday junction resolution performed by a variety of structure-specific endonucleases is a key step in DNA recombination and repair. It is believed that all resolvases carry out their reaction chemistries in a similar fashion, utilizing a divalent cation to facilitate the hydrolysis of the phosphodiester backbone of the DNA, but their architecture varies. To date, with the exception of bacteriophage T4 endonuclease VII, each of the known resolvase enzyme structures has been categorized into one of two families: the integrases and the nucleases. We have now determined the structure of the Escherichia coli RusA Holliday junction resolvase, which reveals a fourth structural class for these enzymes. The structure suggests that dimer formation is essential for Mg(2+) cation binding and hence catalysis and that like the other resolvases, RusA distorts its Holliday junction target upon binding. Key residues identified by mutagenesis experiments are well positioned to interact with the DNA.

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.

Mus81-Eme1 and Rqh1 involvement in processing stalled and collapsed replication forks

The processing of stalled replication forks and the repair of collapsed replication forks are essential functions in all organisms. In fission yeast DNA junctions at stalled replication forks appear to be processed by either the Rqh1 DNA helicase or Mus81-Eme1 endonuclease. Accordingly, we show that the hypersensitivity to agents that cause replication fork stalling of mus81, eme1, and rqh1 mutants is suppressed by a Holliday junction resolvase (RusA), as is the synthetic lethality of a mus81(-) rqh1(-) double mutant. Recombinant Mus81-Eme1, purified from Escherichia coli, readily cleaves replication fork structures but cleaves synthetic Holliday junctions relatively poorly in vitro. From these data we propose that Mus81-Eme1 can process stalled replication forks before they have regressed to form a Holliday junction. We also implicate Mus81-Eme1 and Rqh1 in the repair of collapsed replication forks. Here Mus81-Eme1 and Rqh1 seem to function on different substrates because RusA can substitute for Mus81-Eme1 but not Rqh1.

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.

RusA proteins from the extreme thermophile Aquifex aeolicus and lactococcal phage r1t resolve Holliday junctions

The RusA protein of Escherichia coli is a DNA structure-specific endonuclease that resolves Holliday junction intermediates formed during DNA replication, recombination and repair by introducing symmetrically paired incisions 5' to CC dinucleotides. It is encoded by the defective prophage DLP12, which raises the possibility that it may be of bacteriophage origin. We show that rusA-like sequences are indeed often associated with prophage sequences in the genomes of several bacterial species. They are also found in many bacteriophages, including Lactococcus lactis phage r1t. However, rusA is also present in the chromosome of the hyperthermophilic bacterium Aquifex aeolicus. In this case, there is no obvious association of rusA with prophage-like sequences. Given the ancient lineage of Aquifex aeolicus, this observation provides the first indication that RusA may be of bacterial origin. The RusA proteins of A. aeolicus and bacteriophage r1t were purified and shown to resolve Holliday junctions. The r1t enzyme also promotes DNA repair in strains lacking the RuvABC resolvase. Both enzymes cleave junctions in a sequence-dependent manner, but the A. aeolicus RusA shows a different sequence preference (3' to TG) from the E. coli protein (5' to CC), and the r1t RusA has relaxed sequence dependence, requiring only a single cytosine.

Recombinational DNA repair of damaged replication forks in Escherichia coli: questions

It has recently become clear that the recombinational repair of stalled replication forks is the primary function of homologous recombination systems in bacteria. In spite of the rapid progress in many related lines of inquiry that have converged to support this view, much remains to be done. This review focuses on several key gaps in understanding. Insufficient data currently exists on: (a) the levels and types of DNA damage present as a function of growth conditions, (b) which types of damage and other barriers actually halt replication, (c) the structures of the stalled/collapsed replication forks, (d) the number of recombinational repair paths available and their mechanistic details, (e) the enzymology of some of the key reactions required for repair, (f) the role of certain recombination proteins that have not yet been studied, and (g) the molecular origin of certain in vivo observations associated with recombinational DNA repair during the SOS response. The current status of each of these topics is reviewed.

Dissection of the regional roles of the archaeal Holliday junction resolvase Hjc by structural and mutational analyses

Hjc is an archaeal DNA endonuclease, which resolves the Holliday junction in the presence of divalent metals. Combined with mutational analyses, the x-ray structure of the Pyrococcus furiosus Hjc crystal grown in the presence of ammonium sulfate revealed a positively charged interface, rich in conserved basic residues, and the catalytic center (Nishino, T., Komori, K., Tsuchiya, D., Ishino, Y., and Morikawa, K. (2001) Structure 9, 197-T204). This structural study also suggested that the N-terminal segment and some loops of Hjc play crucial roles in the cleavage of DNA. However, a structural view of the interaction between these regions and DNA remains elusive. To clarify the regional roles of Hjc in the recognition of the Holliday junction, further structural and biochemical analyses were carried out. A new crystal form of Hjc was obtained from a polyethylene glycol solution in the absence of ammonium sulfate, and its structure has been determined at 2.16-A resolution. A comparison of the two crystal structures has revealed that the N-terminal segment undergoes a serious conformational change. The site-directed mutagenesis of the sulfate-binding site within the segment caused a dramatic decrease in the junction binding, but the mutant was still capable of cleaving DNA with a 20-fold lower efficiency. The kinetic analysis of Hjc-Holliday junction interaction indicated that mutations in the N-terminal segment greatly increased the dissociation rate constants of the Hjc-Holliday junction complex, explaining the decreased stability of the complex. This segment is also responsible for the disruption of base pairs near the junction center, through specific interactions with them. Taken together, these results imply that, in addition to the secondary effects of two basic loops, the flexible N-terminal segment plays predominant roles in the recognition of DNA conformation near the crossover and in correct positioning of the cleavage site to the catalytic center of the Hjc resolvase.

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.

Escherichia coli responses to a single DNA adduct

To study the mechanisms by which Escherichia coli modulates the genotoxic effects of DNA damage, a novel system has been developed which permits quantitative measurements of various E. coli pathways involved in mutagenesis and DNA repair. Events measured include fidelity and efficiency of translesion DNA synthesis, excision repair, and recombination repair. Our strategy involves heteroduplex plasmid DNA bearing a single site-specific DNA adduct and several mismatched regions. The plasmid replicates in a mismatch repair-deficient host with the mismatches serving as strand-specific markers. Analysis of progeny plasmid DNA for linkage of the strand-specific markers identifies the pathway from which the plasmid is derived. Using this approach, a single 1, N(6)-ethenodeoxyadenosine adduct was shown to be repaired inefficiently by excision repair, to inhibit DNA synthesis by approximately 80 to 90%, and to direct the incorporation of correct dTMP opposite this adduct. This approach is especially useful in analyzing the damage avoidance-tolerance mechanisms. Our results also show that (i) progeny derived from the damage avoidance-tolerance pathway(s) accounts for more than 15% of all progeny; (ii) this pathway(s) requires functional recA, recF, recO, and recR genes, suggesting the mechanism to be daughter strand gap repair; (iii) the ruvABC genes or the recG gene is also required; and (iv) the RecG pathway appears to be more active than the RuvABC pathway. Based on these results, the mechanism of the damage avoidance-tolerance pathway is discussed.

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.

Modulation of RNA polymerase by (p)ppGpp reveals a RecG-dependent mechanism for replication fork progression

We have discovered a correlation between the ability of Escherichia coli cells to survive damage to DNA and their ability to modulate RNA polymerase via the stringent response regulators, (p)ppGpp. Elevation of (p)ppGpp, or certain mutations in the beta subunit of RNA polymerase, dramatically improve survival of UV-irradiated strains lacking the RuvABC Holliday junction resolvase. Increased survival depends on excision and recombination proteins and relies on the ability of RecG helicase to form Holliday junctions from replication forks stalled at lesions in the DNA and of PriA to initiate replication restart. The role of RecG provides novel insights into the interplay between transcription, replication, and recombination, and suggests a general model in which recombination underpins genome duplication in the face of frequent obstacles to replication fork progression.

A phylogenomic study of DNA repair genes, proteins, and processes

The ability to recognize and repair abnormal DNA structures is common to all forms of life. Studies in a variety of species have identified an incredible diversity of DNA repair pathways. Documenting and characterizing the similarities and differences in repair between species has important value for understanding the origin and evolution of repair pathways as well as for improving our understanding of phenotypes affected by repair (e.g., mutation rates, lifespan, tumorigenesis, survival in extreme environments). Unfortunately, while repair processes have been studied in quite a few species, the ecological and evolutionary diversity of such studies has been limited. Complete genome sequences can provide potential sources of new information about repair in different species. In this paper, we present a global comparative analysis of DNA repair proteins and processes based upon the analysis of available complete genome sequences. We use a new form of analysis that combines genome sequence information and phylogenetic studies into a composite analysis we refer to as phylogenomics. We use this phylogenomic analysis to study the evolution of repair proteins and processes and to predict the repair phenotypes of those species for which we now know the complete genome sequence.

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.

Recombinational DNA repair in bacteria and the RecA protein

In bacteria, the major function of homologous genetic recombination is recombinational DNA repair. This is not a process reserved only for rare double-strand breaks caused by ionizing radiation, nor is it limited to situations in which the SOS response has been induced. Recombinational DNA repair in bacteria is closely tied to the cellular replication systems, and it functions to repair damage at stalled replication forks, Studies with a variety of rec mutants, carried out under normal aerobic growth conditions, consistently suggest that at least 10-30% of all replication forks originating at the bacterial origin of replication are halted by DNA damage and must undergo recombinational DNA repair. The actual frequency may be much higher. Recombinational DNA repair is both the most complex and the least understood of bacterial DNA repair processes. When replication forks encounter a DNA lesion or strand break, repair is mediated by an adaptable set of pathways encompassing most of the enzymes involved in DNA metabolism. There are five separate enzymatic processes involved in these repair events: (1) The replication fork assembled at OriC stalls and/or collapses when encountering DNA damage. (2) Recombination enzymes provide a complementary strand for a lesion isolated in a single-strand gap, or reconstruct a branched DNA at the site of a double-strand break. (3) The phi X174-type primosome (or repair primosome) functions in the origin-independent reassembly of the replication fork. (4) The XerCD site-specific recombination system resolves the dimeric chromosomes that are the inevitable by-product of frequent recombination associated with recombinational DNA repair. (5) DNA excision repair and other repair systems eliminate lesions left behind in double-stranded DNA. The RecA protein plays a central role in the recombination phase of the process. Among its many activities, RecA protein is a motor protein, coupling the hydrolysis of ATP to the movement of DNA branches.

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.

Catalytic and binding mutants of the junction-resolving enzyme endonuclease I of bacteriophage t7: role of acidic residues

Endonuclease I is a 149 amino acid protein of bacteriophage T7 that is a Holliday junction-resolving enzyme, i.e. a four-way junction-selective nuclease. We have performed a systematic mutagenesis study of this protein, whereby all acidic amino acids have been individually replaced by other residues, mainly alanine. Out of 21 acidic residues, five (Glu20, Glu35, Glu65, Asp55 and Asp74) are essential. Replacement of these residues by other amino acids leads to a protein that is inactive in the cleavage of DNA junctions, but which nevertheless binds selectively to DNA junctions. The remaining 16 acidic residues can be replaced without loss of activity. The five critical amino acids are located within one section of the primary sequence. It is rather likely that their function is to bind one or more metal ions that coordinate the water molecule that brings about hydrolysis of the phosphodiester bond. We have also constructed a mutant of endonuclease I that lacks nine amino acids (six of which are arginine or lysine) at the C-terminus. Unlike the acidic point mutants, the C-terminal truncation is unable to bind to DNA junctions. It is therefore likely that the basic C-terminus is an important element in binding to the DNA junction.

Substrate specificity of the SpCCE1 holliday junction resolvase of Schizosaccharomyces pombe

SpCCE1 from Schizosaccharomyces pombe is an endonuclease that resolves Holliday junctions in vitro. SpCCE1 also binds and cleaves a range of other DNAs (Y-junction; flap; and flayed, nicked, and partial duplexes) with varying efficiency. Cleavage sites are always 3' of thymine nucleotides positioned at or close to the branch point or strand interruption. SpCCE1's favored substrate is the X-junction. Up to two dimers of SpCCE1 can bind concurrently to the same X-junction at its crossover point. From mixing experiments of SpCCE1 and the Escherichia coli RuvA protein, we show that each dimer of SpCCE1 binds to a different face of the X-junction and that both are seemingly competent for strand cleavage. We propose that this provides a mechanism whereby SpCCE1 can scrutinize all four junction strands simultaneously for cleavable thymine nucleotides. SpCCE1 appears to resolve X-junctions by a nick and counter-nick mechanism. Therefore, to ensure a high probability of bilateral strand cleavage, SpCCE1 has a relatively long lifetime on X-junctions. This mechanism has the drawback of limiting dissociation from noncleavable junctions. We discuss why this might not be a problem in vivo.

Sequence-specificity of Holliday junction resolution: identification of RuvC mutants defective in metal binding and target site recognition

The RuvC protein of Escherichia coli resolves Holliday intermediates in recombination and DNA repair by a dual strand incision mechanism targeted to specific DNA sequences located symmetrically at the crossover. Two classes of amino acid substitutions are described that provide new insights into the sequence-specificity of the resolution reaction. The first includes D7N and G14S, which modify or eliminate metal binding and prevent catalysis. The second, defined by G114D, G114N, and A116T, interfere with the ability of RuvC to cleave at preferred sequences, but allow resolution at non-consensus target sites. All five mutant proteins bind junction DNA and impose an open conformation. D7N and G14S fail to induce hypersensitivity to hydroxyl radicals, a property of RuvC previously thought to reflect junction opening. A different mechanism is proposed whereby ferrous ions are co-ordinated in the complex to induce a high local concentration of radicals. The open structure imposed by wild-type RuvC in Mg2+ is similar to that observed previously using a junction with a different stacking preference. G114D and A116T impose slightly altered structures. This subtle change may be sufficient to explain the failure of these proteins to cleave the sequences normally preferred. Gly114 and Ala116 residues link two alpha-helices lining the wall of the catalytic cleft in each subunit of RuvC. We suggest that substitutions at these positions realign these helices and interfere with the ability to establish base-specific contacts at resolution hotspots.