Resolution of Holliday junctions in genetic recombination: RuvC protein nicks DNA at the point of strand exchange

Canonical and novel non-canonical activities of the Holliday junction resolvase Yen1

Yen1 and GEN1 are members of the Rad2/XPG family of nucleases that were identified as the first canonical nuclear Holliday junction (HJ) resolvases in budding yeast and humans due to their ability to introduce two symmetric, coordinated incisions on opposite strands of the HJ, yielding nicked DNA products that could be readily ligated. While GEN1 has been extensively characterized in vitro, much less is known about the biochemistry of Yen1. Here, we have performed the first in-depth characterization of purified Yen1. We confirmed that Yen1 resembles GEN1 in many aspects, including range of substrates targeted, position of most incisions they produce or the increase in the first incision rate by assembly of a dimer on a HJ, despite minor differences. However, we demonstrate that Yen1 is endowed with additional nuclease activities, like a nick-specific 5′-3′ exonuclease or HJ arm-chopping that could apparently blur its classification as a canonical HJ resolvase. Despite this, we show that Yen1 fulfils the requirements of a canonical HJ resolvase and hypothesize that its wider array of nuclease activities might contribute to its function in the removal of persistent recombination or replication intermediates.

Single-Molecular Förster Resonance Energy Transfer Measurement on Structures and Interactions of Biomolecules

Single-molecule Förster resonance energy transfer (smFRET) inherits the strategy of measurement from the effective "spectroscopic ruler" FRET and can be utilized to observe molecular behaviors with relatively high throughput at nanometer scale. The simplicity in principle and configuration of smFRET make it easy to apply and couple with other technologies to comprehensively understand single-molecule dynamics in various application scenarios. Despite its widespread application, smFRET is continuously developing and novel studies based on the advanced platforms have been done. Here, we summarize some representative examples of smFRET research of recent years to exhibit the versatility and note typical strategies to further improve the performance of smFRET measurement on different biomolecules.

Single bacterial resolvases first exploit, then constrain intrinsic dynamics of the Holliday junction to direct recombination

Homologous recombination forms and resolves an entangled DNA Holliday Junction (HJ) crucial for achieving genetic reshuffling and genome repair. To maintain genomic integrity, specialized resolvase enzymes cleave the entangled DNA into two discrete DNA molecules. However, it is unclear how two similar stacking isomers are distinguished, and how a cognate sequence is found and recognized to achieve accurate recombination. We here use single-molecule fluorescence observation and cluster analysis to examine how prototypic bacterial resolvase RuvC singles out two of the four HJ strands and achieves sequence-specific cleavage. We find that RuvC first exploits, then constrains the dynamics of intrinsic HJ isomer exchange at a sampled branch position to direct cleavage toward the catalytically competent HJ conformation and sequence, thus controlling recombination output at minimal energetic cost. Our model of rapid DNA scanning followed by ‘snap-locking’ of a cognate sequence is strikingly consistent with the conformational proofreading of other DNA-modifying enzymes.

Resolution of single and double Holliday junction recombination intermediates by GEN1

Genetic recombination provides an important mechanism for the repair of DNA double-strand breaks. Homologous pairing and strand exchange lead to the formation of DNA intermediates, in which sister chromatids or homologous chromosomes are covalently linked by four-way Holliday junctions (HJs). Depending on the type of recombination reaction that takes place, intermediates may have single or double HJs, and their resolution is essential for proper chromosome segregation. In mitotic cells, double HJs are primarily dissolved by the BLM helicase-TopoisomeraseIIIα-RMI1-RMI2 (BTR) complex, whereas single HJs (and double HJs that have escaped the attention of BTR) are resolved by structure-selective endonucleases known as HJ resolvases. These enzymes are ubiquitous in nature, because they are present in bacteriophage, bacteria, archaea, and simple and complex eukaryotes. The human HJ resolvase GEN1 is a member of the XPG/Rad2 family of 5'-flap endonucleases. Biochemical studies of GEN1 revealed that it cleaves synthetic DNA substrates containing a single HJ by a mechanism similar to that shown by the prototypic HJ resolvase, Escherichia coli RuvC protein, but it is unclear whether these substrates fully recapitulate the properties of recombination intermediates that arise within a physiological context. Here, we show that GEN1 efficiently cleaves both single and double HJs contained within large recombination intermediates. Moreover, we find that GEN1 exhibits a weak sequence preference for incision between two G residues that reside in a T-rich region of DNA. These results contrast with those obtained with RuvC, which exhibits a strict requirement for the consensus sequence 5'-A/TTTG/C-3'.

Structure and Metal Binding Properties of a Poxvirus Resolvase

Poxviruses replicate their linear genomes by forming concatemers that must be resolved into monomeric units to produce new virions. A viral resolvase cleaves DNA four-way junctions extruded at the concatemer junctions to produce monomeric genomes. This cleavage reaction is required for viral replication, so the resolvase is an attractive target for small molecule inhibitors. To provide a platform for understanding resolvase mechanism and designing inhibitors, we have determined the crystal structure of the canarypox virus (CPV) resolvase. CPV resolvase is dimer of RNase H superfamily domains related to Escherichia coli RuvC, with an active site lined by highly conserved acidic residues that bind metal ions. There are several intriguing structural differences between resolvase and RuvC, and a model of the CPV resolvase·Holliday junction complex provides insights into the consequences of these differences, including a plausible explanation for the weak sequence specificity exhibited by the poxvirus enzymes. The model also explains why the poxvirus resolvases are more promiscuous than RuvC, cleaving a variety of branched, bulged, and flap-containing substrates. Based on the unique active site structure observed for CPV resolvase, we have carried out a series of experiments to test divalent ion usage and preferences. We find that the two resolvase metal binding sites have different preferences for Mg(2+) versus Mn(2+) Optimal resolvase activity is maintained with 5 μm Mn(2+) and 100 μm Mg(2+), concentrations that are well below those required for either metal alone. Together, our findings provide biochemical insights and structural models that will facilitate studying poxvirus replication and the search for efficient poxvirus inhibitors.

Characterization of biochemical properties of Bacillus subtilis RecQ helicase

RecQ family helicases function as safeguards of the genome. Unlike Escherichia coli, the Gram-positive Bacillus subtilis bacterium possesses two RecQ-like homologues, RecQ[Bs] and RecS, which are required for the repair of DNA double-strand breaks. RecQ[Bs] also binds to the forked DNA to ensure a smooth progression of the cell cycle. Here we present the first biochemical analysis of recombinant RecQ[Bs]. RecQ[Bs] binds weakly to single-stranded DNA (ssDNA) and blunt-ended double-stranded DNA (dsDNA) but strongly to forked dsDNA. The protein exhibits a DNA-stimulated ATPase activity and ATP- and Mg(2+)-dependent DNA helicase activity with a 3' → 5' polarity. Molecular modeling shows that RecQ[Bs] shares high sequence and structure similarity with E. coli RecQ. Surprisingly, RecQ[Bs] resembles the truncated Saccharomyces cerevisiae Sgs1 and human RecQ helicases more than RecQ[Ec] with regard to its enzymatic activities. Specifically, RecQ[Bs] unwinds forked dsDNA and DNA duplexes with a 3'-overhang but is inactive on blunt-ended dsDNA and 5'-overhung duplexes. Interestingly, RecQ[Bs] unwinds blunt-ended DNA with structural features, including nicks, gaps, 5'-flaps, Kappa joints, synthetic replication forks, and Holliday junctions. We discuss these findings in the context of RecQ[Bs]'s possible functions in preserving genomic stability.

Holliday junction resolvases

Four-way DNA intermediates, called Holliday junctions (HJs), can form during meiotic and mitotic recombination, and their removal is crucial for chromosome segregation. A group of ubiquitous and highly specialized structure-selective endonucleases catalyze the cleavage of HJs into two disconnected DNA duplexes in a reaction called HJ resolution. These enzymes, called HJ resolvases, have been identified in bacteria and their bacteriophages, archaea, and eukaryotes. In this review, we discuss fundamental aspects of the HJ structure and their interaction with junction-resolving enzymes. This is followed by a brief discussion of the eubacterial RuvABC enzymes, which provide the paradigm for HJ resolvases in other organisms. Finally, we review the biochemical and structural properties of some well-characterized resolvases from archaea, bacteriophage, and eukaryotes.

AtGEN1 and AtSEND1, two paralogs in Arabidopsis, possess holliday junction resolvase activity

Holliday junctions (HJs) are physical links between homologous DNA molecules that arise as central intermediary structures during homologous recombination and repair in meiotic and somatic cells. It is necessary for these structures to be resolved to ensure correct chromosome segregation and other functions. In eukaryotes, including plants, homologs of a gene called XPG-like endonuclease1 (GEN1) have been identified that process HJs in a manner analogous to the HJ resolvases of phages, archaea, and bacteria. Here, we report that Arabidopsis (Arabidopsis thaliana), a eukaryotic organism, has two functional GEN1 homologs instead of one. Like all known eukaryotic resolvases, AtGEN1 and Arabidopsis single-strand DNA endonuclease1 both belong to class IV of the Rad2/XPG family of nucleases. Their resolvase activity shares the characteristics of the Escherichia coli radiation and UV sensitive C paradigm for resolvases, which involves resolving HJs by symmetrically oriented incisions in two opposing strands. This leads to ligatable products without the need for further processing. The observation that the sequence context influences the cleavage by the enzymes can be interpreted as a hint for the existence of sequence specificity. The two Arabidopsis paralogs differ in their preferred sequences. The precise cleavage positions observed for the resolution of mobile nicked HJs suggest that these cleavage positions are determined by both the substrate structure and the sequence context at the junction point.

Characterization of the ATPase activity of RecG and RuvAB proteins on model fork structures reveals insight into stalled DNA replication fork repair

RecG and RuvAB are proposed to act at stalled DNA replication forks to facilitate replication restart. To clarify the roles of these proteins in fork regression, we used a coupled spectrophotometric ATPase assay to determine how these helicases act on two groups of model fork substrates: the first group mimics nascent stalled forks, whereas the second mimics regressed fork structures. The results show that RecG is active on the substrates in group 1, whereas these are poor substrates for RuvAB. In addition, in the presence of group 1 forks, the single-stranded DNA-binding protein (SSB) enhances the activity of RecG and enables it to compete with excess RuvA. In contrast, SSB inhibits the activity of RuvAB on these substrates. Results also show that the preferred regressed fork substrate for RuvAB is a Holliday junction, not a forked DNA. The active form of the enzyme on the Holliday junction contains a single RuvA tetramer. In contrast, although the enzyme is active on a regressed fork structure, RuvB loading by a single RuvA tetramer is impaired, and full activity requires the cooperative binding of two forked DNA substrate molecules. Collectively, the data support a model where RecG is responsible for stalled DNA replication fork regression. SSB ensures that if the nascent fork has single-stranded DNA character RuvAB is inhibited, whereas the activity of RecG is preferentially enhanced. Only once the fork has been regressed and the DNA is relaxed can RuvAB bind to a RecG-extruded Holliday junction.

Molecular strategy for survival at a critical high temperature in Eschierichia coli

The molecular mechanism supporting survival at a critical high temperature (CHT) in Escherichia coli was investigated. Genome-wide screening with a single-gene knockout library provided a list of genes indispensable for growth at 47°C, called thermotolerant genes. Genes for which expression was affected by exposure to CHT were identified by DNA chip analysis. Unexpectedly, the former contents did not overlap with the latter except for dnaJ and dnaK, indicating that a specific set of non-heat shock genes is required for the organism to survive under such a severe condition. More than half of the mutants of the thermotolerant genes were found to be sensitive to H₂O₂ at 30°C, suggesting that the mechanism of thermotolerance partially overlaps with that of oxidative stress resistance. Their encoded enzymes or proteins are related to outer membrane organization, DNA double-strand break repair, tRNA modification, protein quality control, translation control or cell division. DNA chip analyses of essential genes suggest that many of the genes encoding ribosomal proteins are down-regulated at CHT. Bioinformatics analysis and comparison with the genomic information of other microbes suggest that E. coli possesses several systems for survival at CHT. This analysis allows us to speculate that a lipopolysaccharide biosynthesis system for outer membrane organization and a sulfur-relay system for tRNA modification have been acquired by horizontal gene transfer.

DNA Helicases

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

Crystallographic and modelling studies on Mycobacterium tuberculosis RuvA Additional role of RuvB-binding domain and inter species variability

RuvA, along with RuvB, is involved in branch migration of heteroduplex DNA in homologous recombination. The structures of three new crystal forms of RuvA from Mycobacterium tuberculosis (MtRuvA) have been determined. The RuvB-binding domain is cleaved off in one of them. Detailed models of the complexes of octameric RuvA from different species with the Holliday junction have also been constructed. A thorough examination of the structures presented here and those reported earlier brings to light the hitherto unappreciated role of the RuvB-binding domain in determining inter-domain orientation and oligomerization. These structures also permit an exploration of the interspecies variability of structural features such as oligomerization and the conformation of the loop that carries the acidic pin, in terms of amino acid substitutions. These models emphasize the additional role of the RuvB-binding domain in Holliday junction binding. This role along with its role in oligomerization could have important biological implications.

RecG interacts directly with SSB: implications for stalled replication fork regression

RecG and RuvAB are proposed to act at stalled DNA replication forks to facilitate replication restart. To define the roles of these proteins in fork regression, we used a combination of assays to determine whether RecG, RuvAB or both are capable of acting at a stalled fork. The results show that RecG binds to the C-terminus of single-stranded DNA binding protein (SSB) forming a stoichiometric complex of 2 RecG monomers per SSB tetramer. This binding occurs in solution and to SSB protein bound to single stranded DNA (ssDNA). The result of this binding is stabilization of the interaction of RecG with ssDNA. In contrast, RuvAB does not bind to SSB. Side-by-side analysis of the catalytic efficiency of the ATPase activity of each enzyme revealed that (-)scDNA and ssDNA are potent stimulators of the ATPase activity of RecG but not for RuvAB, whereas relaxed circular DNA is a poor cofactor for RecG but an excellent one for RuvAB. Collectively, these data suggest that the timing of repair protein access to the DNA at stalled forks is determined by the nature of the DNA available at the fork. We propose that RecG acts first, with RuvAB acting either after RecG or in a separate pathway following protein-independent fork regression.

Impact of mutS inactivation on foreign DNA acquisition by natural transformation in Pseudomonas stutzeri

In prokaryotic mismatch repair the MutS protein and its homologs recognize the mismatches. The mutS gene of naturally transformable Pseudomonas stutzeri ATCC 17587 (genomovar 2) was identified and characterized. The deduced amino acid sequence (859 amino acids; 95.6 kDa) displayed protein domains I to IV and a mismatch-binding motif similar to those in MutS of Escherichia coli. A mutS::aac mutant showed 20- to 163-fold-greater spontaneous mutability. Transformation experiments with DNA fragments of rpoB containing single nucleotide changes (providing rifampin resistance) indicated that mismatches resulting from both transitions and transversions were eliminated with about 90% efficiency in mutS+. The mutS+ gene of strain ATCC 17587 did not complement an E. coli mutant but partially complemented a P. stutzeri JM300 mutant (genomovar 4). The declining heterogamic transformation by DNA with 0.1 to 14.6% sequence divergence was partially alleviated by mutS::aac, indicating that there was a 14 to 16% contribution of mismatch repair to sexual isolation. Expression of mutS+ from a multicopy plasmid eliminated autogamic transformation and greatly decreased heterogamic transformation, suggesting that there is strong limitation of MutS in the wild type for marker rejection. Remarkably, mutS::aac altered foreign DNA acquisition by homology-facilitated illegitimate recombination (HFIR) during transformation, as follows: (i) the mean length of acquired DNA was increased in transformants having a net gain of DNA, (ii) the HFIR events became clustered (hot spots) and less dependent on microhomologies, which may have been due to topoisomerase action, and (iii) a novel type of transformants (14%) had integrated foreign DNA with no loss of resident DNA. We concluded that in P. stutzeri upregulation of MutS could enforce sexual isolation and downregulation could increase foreign DNA acquisition and that MutS affects mechanisms of HFIR.

Host processing of branched DNA intermediates is involved in targeted transposition of IS911

A simplified system using bacterial insertion sequence IS911 has been developed to investigate targeted insertion next to DNA sequences resembling IS ends. We show here that these IR-targeted events occur by an unusual mechanism. In the circular IS911 transposition intermediate the two IRs are abutted to form an IR/IR junction. IR-targeted insertion involves transfer of a single end of the junction to the target IR to generate a branched DNA structure. The single-end transfer (SET) intermediate, but not the final insertion product, can be detected in an in vitro reaction. SET intermediates must be processed by the bacterial host to obtain the final insertion products. Sequence analysis of these IR-targeted insertion products and of those obtained in vivo revealed high levels of DNA sequence conversion in which mutations from one IR were transferred to another. These sequence changes cannot be explained by the classic transposition pathway. A model is presented in which the four-way Holliday-like junction created by SET is processed by host-mediated branch migration, resolution, repair and replication. This pathway resembles those described for processing other branched DNA structures such as stalled replication forks.

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.

Binding specificity determines polarity of DNA unwinding by the Sgs1 protein of S. cerevisiae

Saccharomyces cerevisiae Sgs1 protein is a member of the RecQ DNA helicase family which also includes the products of the human Bloom's syndrome and Werner's syndrome genes. We have studied the substrate specificity of a recombinant Sgs1 helicase (amino acid residues 400-1268 of the Sgs1 protein). Sgs1 shows a strong preference for binding branched DNA substrates, including duplex structures with a 3' single-stranded overhang and DNA junctions with multiple branches. Duplex DNA with a 5' rather than a 3' single-stranded tail is not recognized or unwound by Sgs1. DNase I and hydroxyl radical footprinting of the Sgs1-DNA complex shows that the protein binds specifically to the junction of a double-stranded DNA and its 3' overhang. Binding and unwinding of duplex DNA with a 3' overhang are much reduced if the backbone polarity of the 3' overhang is reversed in the junction region, but are unaffected if polarity reversal occurs four nucleotides away from the junction. These results indicate that the 3' to 5' polarity of unwinding by the recombinant Sgs1 protein is a direct consequence of the binding of the helicase to the single-stranded/double-stranded DNA junction and its recognition of the polarity of the single-stranded DNA at the junction. The recombinant Sgs1 also unwinds four-way junctions (synthetic Holliday junctions), a result that may be significant in terms of its role in suppressing DNA recombination in vivo.

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.

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.

RuvAB acts at arrested replication forks

Replication arrest leads to the occurrence of DNA double-stranded breaks (DSB). We studied the mechanism of DSB formation by direct measure of the amount of in vivo linear DNA in Escherichia coli cells that lack the RecBCD recombination complex and by genetic means. The RuvABC proteins, which catalyze migration and cleavage of Holliday junctions, are responsible for the occurrence of DSBs at arrested replication forks. In cells proficient for RecBC, RuvAB is uncoupled from RuvC and DSBs may be prevented. This may be explained if a Holliday junction forms upon replication fork arrest, by annealing of the two nascent strands. RecBCD may act on the double-stranded tail prior to the cleavage of the RuvAB-bound junction by RuvC to rescue the blocked replication fork without breakage.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Mutational analysis on structure-function relationship of a holliday junction specific endonuclease RuvC

BACKGROUND

Escherichia coli RuvC protein is a specific endonuclease that resolves Holliday junctions during homologous recombination. For junction resolution, RuvC undergoes distinct steps such as dimerization, junction-specific binding and endonucleolytic cleavage. The crystal structure of RuvC has been revealed.

RESULTS

To identify functionally important residues, we isolated a large number of mutant ruvC genes created by random mutagenesis and characterized their properties in vivo and in vitro. The mutations which were isolated most frequently were mapped to the four acidic residues constituting the catalytic centre. Amongst the several mutant proteins affected in the dimer interface, only one could not form a dimer. The others were able to form a dimer but were defective in cleavage. F69L and K118R mutant proteins could not cleave the junction, but they were able to form a dimer and bind the junction DNA.

CONCLUSIONS

Random mutagenesis highlighted many structurally and functionally important residues of RuvC, most of which are highly conserved among RuvC homologues. Dimer formation and also conservation of intact interface interactions between the subunits are important for junction binding and subsequent cleavage. Phe-69 and Lys-118 are critically important for the interactions which lead to junction cleavage.

Coordinated actions of RuvABC in Holliday junction processing

The RuvA, RuvB and RuvC proteins of Escherichia coli process Holliday junctions during genetic recombination and DNA repair. Biochemical studies have shown that RuvA and RuvB promote branch migration whereas RuvC resolves junctions by endonucleolytic cleavage. Here we show that RuvAB stimulate Holliday junction resolution by RuvC. Elevated RuvC activity was dependent upon RuvAB-mediated ATP-hydrolysis. These results show that the three Ruv proteins work in a coordinated manner to promote Holliday junction resolution, and account for the resolvase-defective phenotype exhibited by ruvA, ruvB or ruvC mutant strains.

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.

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.

Processing of recombination intermediates by the RuvABC proteins

The RuvA, RuvB, and RuvC proteins in Escherichia coli play important roles in the late stages of homologous genetic recombination and the recombinational repair of damaged DNA. Two proteins, RuvA and RuvB, form a complex that promotes ATP-dependent branch migration of Holliday junctions, a process that is important for the formation of heteroduplex DNA. Individual roles for each protein have been defined, with RuvA acting as a specificity factor that targets RuvB, the branch migration motor to the junction. Structural studies indicate that two RuvA tetramers sandwich the junction and hold it in an unfolded square-planar configuration. Hexameric rings of RuvB face each other across the junction and promote a novel dual helicase action that "pumps" DNA through the RuvAB complex, using the free energy provided by ATP hydrolysis. The third protein, RuvC endonuclease, resolves the Holliday junction by introducing nicks into two DNA strands. Genetic and biochemical studies indicate that branch migration and resolution are coupled by direct interactions between the three proteins, possibly by the formation of a RuvABC complex.

Characterization of a Holliday junction-resolving enzyme from Schizosaccharomyces pombe

The rearrangement and repair of DNA by homologous recombination involves the creation of Holliday junctions, which are cleaved by a class of junction-specific endonucleases to generate recombinant duplex DNA products. Only two cellular junction-resolving enzymes have been identified to date: RuvC in eubacteria and CCE1 from Saccharomyces cerevisiae mitochondria. We have identified a protein from Schizosaccharomyces pombe which has 28% sequence identity to CCE1. The YDC2 protein has been cloned and overexpressed in Escherichia coli, and the purified recombinant protein has been shown to be a Holliday junction-resolving enzyme. YDC2 has a high degree of specificity for the structure of the four-way junction, to which it binds as a dimer. The enzyme exhibits a sequence specificity for junction cleavage that differs from both CCE1 and RuvC, and it cleaves fixed junctions at the point of strand exchange. The conservation of the mechanism of Holliday junction cleavage between two organisms as diverse as S. cerevisiae and S. pombe suggests that there may be a common pathway for mitochondrial homologous recombination in fungi, plants, protists, and possibly higher eukaryotes.

NMR study of the exchange rate between two stacked conformers of a model Holliday junction

Our investigations into the folding behavior of a series of small model Holliday junctions in the presence of magnesium ions revealed a sequence (junction J9a) displaying a 71/29 population ratio between the two differently folded stacked X-conformers in slow exchange on the NMR chemical shift time scale. For the first time we report the rates of interconversion between two stacked X-conformers and their lifetimes as measured by chemical exchange (EXSY) NMR spectroscopy: k1 5.6 (+/-0.5) s-1, k-1 2.3 (+/-0.2) s-1. The corresponding lifetimes (tau=1/k) are: tau1 430 ms, tau2 180 ms and the conformational transition barrier amounts to DeltaGdouble dagger294 68 kJ/mol (16.2 kcal/mol). It is argued that this free-energy barrier reflects the maximum barrier that separates stacked X-conformers in junction 9a from the unfolded structure.

A new Holliday junction resolving enzyme from Schizosaccharomyces pombe that is homologous to CCE1 from Saccharomyces cerevisiae

The resolution of Holliday junctions is a critical stage in recombination. We describe the identification and initial biochemical characterisation of a new Holliday junction resolvase from Schizosaccharomyces pombe. Resolvase activity was initially detected in partially purified cell-free extracts of S. pombe. Resolution of X-junction DNA occurred by the introduction of symmetrical cuts in strands of the same polarity. All cuts occurred 3' of thymine nucleotides with a possible preference for cleavage one nucleotide 3' from the point of strand crossover. During the course of these studies, a potential S. pombe homologue of the Saccharomyces cerevisiae Cruciform Cutting Endonuclease I was identified in the database (SpCCE1). The gene was cloned by PCR, overexpressed in Escherichia coli and its product purified as a His-tagged fusion protein. Purified SpCCE1 binds to X-junctions in a structure-specific manner and resolves them to nicked linear duplex products that are repairable by DNA ligase. SpCCE1 cuts X-junctions in precisely the same way as the resolvase activity from partially purified extracts of S. pombe, indicating that they are probably the same. Finally, we show that SpCCE1 can function as a Holliday junction resolvase in vivo by its ability to complement a resolvase-deficient strain of E. coli.

Effect of DNA topology on Holliday junction resolution by Escherichia coli RuvC and bacteriophage T7 endonuclease I

Holliday junctions are key intermediates in homologous genetic recombination. Their resolution requires specialised nucleases that nick pairs of strands at the junction point, leading to the separation of mature recombinants. Resolution occurs in either of two orientations, according to which DNA strands are cut. We show that DNA topology can determine the efficiency and outcome of a recombination reaction. Using two Holliday junction resolvases, Escherichia coli RuvC protein and T7 endonuclease I, we observed that supercoiled figure-8 DNA molecules containing Holliday junctions were resolved with a specific orientation bias, and that this bias was reversed by the presence of a topological tether (catenation). In contrast, when all topological constraints were removed by restriction digestion, the recombination intermediates were resolved equally in the two orientations. These results show that topological constraints affecting Holliday junction structure influence the orientation of resolution by cellular resolvases.

Recognition and manipulation of branched DNA structure by junction-resolving enzymes

The junction-resolving enzymes are a class of nucleases that introduce paired cleavages into four-way DNA junctions. They are important in DNA recombination and repair, and are found throughout nature, from eubacteria and their bacteriophages through to higher eukaryotes and their viruses. These enzymes exhibit structure-selective binding to DNA junctions; although cleavage may be more or less sequence-dependent, binding affinity is purely related to the branched structure of the DNA. Binding and cleavage events can be separated for a number of the enzymes by mutagenesis, and mutant proteins that are defective in cleavage while retaining normal junction-selective binding have been isolated. Critical acidic residues have been identified in several resolving enzymes, suggesting a role in the coordination of metal ions that probably deliver the hydrolytic water molecule. The resolving enzymes all bind to junctions in dimeric form, and the subunits introduce independent cleavages within the lifetime of the enzyme-junction complex to ensure resolution of the four-way junction. In addition to recognising the structure of the junction, recent data from four different junction-resolving enzymes indicate that they also manipulate the global structure. In some cases this results in severe distortion of the folded structure of the junction. Understanding the recognition and manipulation of DNA structure by these enzymes is a fascinating challenge in molecular recognition.

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.

Sequence specificity and biochemical characterization of the RusA Holliday junction resolvase of Escherichia coli

The RusA protein of Escherichia coli is an endonuclease that resolves Holliday intermediates in recombination and DNA repair. Analysis of its subunit structure revealed that the native protein is a dimer. Its resolution activity was investigated using synthetic X-junctions with homologous cores. Resolution occurs by dual strand incision predominantly 5' of CC dinucleotides located symmetrically. A junction lacking homology is not resolved. The efficiency of resolution is related inversely to the number of base pairs in the homologous core, which suggests that branch migration is rate-limiting. Inhibition of resolution at high ratios of protein to DNA suggests that binding of RusA may immobilize the junction point at non-cleavable sites. Resolution is stimulated by alkaline pH and by Mn2+. The protein is unstable in the absence of substrate DNA and loses approximately 80% of its activity within 1 min under standard reaction conditions. DNA binding stabilizes the activity. Junction resolution is inhibited in the presence of RuvA. This observation probably explains why RusA is unable to promote efficient recombination and DNA repair in ruvA+ strains unless it is expressed at a high level.

In vitro reconstitution of the late steps of genetic recombination in E. coli

Purified proteins have been used to reconstitute an in vitro system for the medial-to-late stages of recombination in E. coli. In this system, RecA protein formed recombination intermediates that were processed by the actions of the RuvA, RuvB, and RuvC proteins. RuvAB was found to promote branch migration, to dissociate the RecA filament, and to modulate the orientation of cleavage of Holliday junction resolution by RuvC. Monoclonal antibodies directed against RuvA, RuvB, or RuvC inhibited resolution in the reconstituted system. Specific protein-protein interactions between the branch migration motor (RuvB) and the resolvase (RuvC) were also observed. These results provide evidence for coordinated action during the late stages of recombination, possibly involving the assembly of a RuvABC branch migration/resolution complex.

The RuvC protein dimer resolves Holliday junctions by a dual incision mechanism that involves base-specific contacts

The Escherichia coli RuvC protein resolves DNA intermediates produced during genetic recombination. In vitro, RuvC binds specifically to Holliday junctions and resolves them by the introduction of nicks into two strands of like polarity. In contrast to junction recognition, which occurs without regard for DNA sequence, resolution occurs preferentially at sequences that exhibit the consensus 5'-(A/T)TT/(G/C)-3' (where / indicates the site of incision). Synthetic Holliday junctions containing modified cleavage sequences have been used to investigate the mechanism of cleavage. The results indicate that specific DNA sequences are required for the correct docking of DNA into the two active sites of the RuvC dimer. In addition, using chemically modified oligonucleotides to introduce a hydrolysis-resistant 3'-S-phosphorothiolate linkage at the cleavage site, it was found that, as long as the sequence requirements are fulfilled, the two incisions could be uncoupled from each other. These results indicate that RuvC protein resolves Holliday junctions by a mechanism similar to that exhibited by certain restriction enzymes.