Effect of DNA sequence and nucleotide cofactors on hRad51 binding to ssDNA: role of hRad52 in recruitment

hRad51 binding to ssDNA is significantly lowered in the presence of a nucleotide cofactor ATP/ADP/ATPgammaS. In these conditions, presence of trace amounts of hRad52 protein restores hRad51 binding to DNA. In the absence of any nucleotide cofactor where intrinsic binding of hRad51 to ssDNA is higher, hRad52 brings about no improved binding. hRad51 binding to ssDNA is strongly influenced by the DNA sequence. The protein binding to repeat sequences is poor compared to that of mixed DNA sequence. Interestingly, presence of hRad52 restores the ability of hRad51 binding to such DNA targets as well. Moreover, all the cooperative effects of hRad52 on hRad51 binding are highly specific to the latter's binding to ssDNA and not to dsDNA. These results help us to model important mechanistic steps of hRad51 presynapsis on ssDNA templates.     

Interaction of hRad51 and hRad52 with MCM complex: a cross-talk between recombination and replication proteins

Human Rad51 and Rad52 are implicated in DNA repair during replication. Here we show, by pull-down assays, that purified hRad51 and hRad52 interact with each other as well as with Mini chromosome maintenance (MCM) proteins in HeLa cell extracts. Furthermore, immunoprecipitation experiments corroborate the same where hRad51 and hRad52 proteins not only cross-talk with each other but also pull down MCM3 and MCM2/3 proteins, respectively. The interaction scoring assays, performed reciprocally, demonstrate the same specificity, based on which, we speculate that MCM complex exhibits strong propensity to get physically recruited to the sites where hRad51 and hRad52-mediated homologously aligned ends need to be replicationally repaired.     

The hRad51 and RecA proteins show significant differences in cooperative binding to single-stranded DNA.

The human Rad51 protein (hRad51), like its bacterial homologue RecA, catalyzes genetic recombination between homologous single and double-stranded DNA substrates. Using IAsys biosensor technology, we have examined the critical first step in this process, the binding of hRad51 and RecA to ssDNA. We show that hRad51 binds cooperatively and with high affinity to an oligonucleotide substrate in both the absence and presence of nucleotide cofactors. In fact, both ATP and ATPgammaS have a slight inhibitory effect on hRad51 binding affinity. We show that this results from a decrease in the intrinsic affinity of a given monomer for ssDNA, which is counterbalanced by an increase in the cooperative assembly of protein onto DNA. In contrast, we show that the dramatic NTP-induced increase in ssDNA binding affinity of RecA is accounted for by a significant increase in cooperative filament assembly and not by an increase in the intrinsic DNA binding affinity of monomeric RecA. These results demonstrate that although the hRad51 and RecA proteins display many structural and functional similarities, they show profound inherent mechanistic differences.     

Reconstitution of the strand invasion step of double-strand break repair using human Rad51 Rad52 and RPA proteins

The human Rad51 recombinase is essential for the repair of double-strand breaks in DNA that occur in somatic cells after exposure to ionising irradiation, or in germ line cells undergoing meiotic recombination. The initiation of double-strand break repair is thought to involve resection of the double-strand break to produce 3'-ended single-stranded (ss) tails that invade homologous duplex DNA. Here, we have used purified proteins to set up a defined in vitro system for the initial strand invasion step of double-strand break repair. We show that (i) hRad51 binds to the ssDNA of tailed duplex DNA molecules, and (ii) hRad51 catalyses the invasion of tailed duplex DNA into homologous covalently closed DNA. Invasion is stimulated by the single-strand DNA binding protein RPA, and by the hRad52 protein. Strikingly, hRad51 forms terminal nucleoprotein filaments on either 3' or 5'-ssDNA tails and promotes strand invasion without regard for the polarity of the tail. Taken together, these results show that hRad51 is recruited to regions of ssDNA occurring at resected double-strand breaks, and that hRad51 shows no intrinsic polarity preference at the strand invasion step that initiates double-strand break repair.     

Human Rad54 protein stimulates DNA strand exchange activity of hRad51 protein in the presence of Ca2+

Rad51 and Rad54 proteins play a key role in homologous recombination in eukaryotes. Recently, we reported that Ca2+ is required in vitro for human Rad51 protein to form an active nucleoprotein filament that is important for the search of homologous DNA and for DNA strand exchange, two critical steps of homologous recombination. Here we find that Ca2+ is also required for hRad54 protein to effectively stimulate DNA strand exchange activity of hRad51 protein. This finding identifies Ca2+ as a universal cofactor of DNA strand exchange promoted by mammalian homologous recombination proteins in vitro. We further investigated the hRad54-dependent stimulation of DNA strand exchange. The mechanism of stimulation appeared to include specific interaction of hRad54 protein with the hRad51 nucleoprotein filament. Our results show that hRad54 protein significantly stimulates homology-independent coaggregation of dsDNA with the filament, which represents an essential step of the search for homologous DNA. The results obtained indicate that hRad54 protein serves as a dsDNA gateway for the hRad51-ssDNA filament, promoting binding and an ATP hydrolysis-dependent translocation of dsDNA during the search for homologous sequences.     

Heteroduplex formation by human Rad51 protein: effects of DNA end-structure, hRP-A and hRad52.

Purified human Rad51 protein (hRad51) catalyses ATP-dependent homologous pairing and strand transfer reactions, characteristic of a central role in homologous recombination and double-strand break repair. Using single-stranded circular and partially homologous linear duplex DNA, we found that the length of heteroduplex DNA formed by hRad51 was limited to approximately 1.3 kb, significantly less than that observed with Escherichia coli RecA and Saccharomyces cerevisiae Rad51 protein. Joint molecule formation required the presence of a 3' or 5'-overhang on the duplex DNA substrate and initiated preferentially at the 5'-end of the complementaryx strand. These results are consistent with a preference for strand transfer in the 3'-5' direction relative to the single-stranded DNA. The human single-strand DNA-binding protein, hRP-A, stimulated hRad51-mediated joint molecule formation by removing secondary structures from single-stranded DNA, a role similar to that played by E. coli single-strand DNA-binding protein in RecA-mediated strand exchange reactions. Indeed, E. coli single-strand DNA-binding protein could substitute for hRP-A in hRad51-mediated reactions. Joint molecule formation by hRad51 was stimulated or inhibited by hRad52, dependent upon the reaction conditions. The inhibitory effect could be overcome by the presence of hRP-A or excess heterologous DNA.     

The human Rad51 protein: polarity of strand transfer and stimulation by hRP-A.

The human Rad51 protein is homologous to the RecA protein and catalyses homologous pairing and strand transfer reactions in vitro. Using single-stranded circular and homologous linear duplex DNA, we show that hRad51 forms stable joint molecules by transfer of the 5' end of the complementary strand of the linear duplex to the ssDNA. The polarity of strand transfer is therefore 3' to 5', defined relative to the ssDNA on which hRad51 initiates filament formation. This polarity is opposite to that observed with RecA. Homologous pairing and strand transfer require stoichiometric amounts of hRad51, corresponding to one hRad51 monomer per three nucleotides of ssDNA. Joint molecules are not observed when the protein is present in limiting or excessive amounts. The human ssDNA binding-protein, hRP-A, stimulates hRad51-mediated reactions. Its effect is consistent with a role in the removal of secondary structures from ssDNA, thereby facilitating the formation of continuous Rad51 filaments.     

The meiosis-specific recombinase hDmc1 forms ring structures and interacts with hRad51

Eukaryotic cells encode two homologs of Escherichia coli RecA protein, Rad51 and Dmc1, which are required for meiotic recombination. Rad51, like E.coli RecA, forms helical nucleoprotein filaments that promote joint molecule and heteroduplex DNA formation. Electron microscopy reveals that the human meiosis-specific recombinase Dmc1 forms ring structures that bind single-stranded (ss) and double-stranded (ds) DNA. The protein binds preferentially to ssDNA tails and gaps in duplex DNA. hDmc1-ssDNA complexes exhibit an irregular, often compacted structure, and promote strand-transfer reactions with homologous duplex DNA. hDmc1 binds duplex DNA with reduced affinity to form nucleoprotein complexes. In contrast to helical RecA/Rad51 filaments, however, Dmc1 filaments are composed of a linear array of stacked protein rings. Consistent with the requirement for two recombinases in meiotic recombination, hDmc1 interacts directly with hRad51.     

Human Rad52 facilitates a three-stranded pairing that follows no strand exchange: a novel pairing function of the protein

Human Rad52 protein, by analogy with the genetics of yeast Rad52, is believed to mediate a pathway of homologous recombination even independent of Rad51. Current study is focused on unraveling the molecular properties of hRad52 that endow the protein such an ability. We show here that the hRad52 protein binds single-stranded DNA (ssDNA) as well as 3'- and 5'-tailed duplexes severalfold better than blunt-ended duplexes, altering the sensitivity of the bound DNA to the action of DNase I. Protein binding is sensitive to the length of the ssDNA: targets as short as a 33mer poorly bind the protein, whereas that of a 61mer and above bind the protein stably well. Such stable ssDNA-hRad52 complexes are highly competent in mediating not only the annealing of two complementary strands but also three-stranded pairing. The latter involves homologous recognition of linear duplex DNA by the ssDNA-hRad52 complex. We show that the hRad52 protein facilitates homologous recognition between ssDNA and duplex-DNA through a process that involves unwinding or transient unpairing of the interacting duplex via a novel three-stranded intermediate that does not lead to strand exchange. The results enable us to visualize a novel role for hRad52 that may model its function in a pathway requiring no hRad51.     

Rad51 protein controls Rad52-mediated DNA annealing

In Saccharomyces cerevisiae, Rad52 protein plays an essential role in the repair of DNA double-stranded breaks (DSBs). Rad52 and its orthologs possess the unique capacity to anneal single-stranded DNA (ssDNA) complexed with its cognate ssDNA-binding protein, RPA. This annealing activity is used in multiple mechanisms of DSB repair: single-stranded annealing, synthesis-dependent strand annealing, and cross-over formation. Here we report that the S. cerevisiae DNA strand exchange protein, Rad51, prevents Rad52-mediated annealing of complementary ssDNA. Efficient inhibition is ATP-dependent and involves a specific interaction between Rad51 and Rad52. Free Rad51 can limit DNA annealing by Rad52, but the Rad51 nucleoprotein filament is even more effective. We also discovered that the budding yeast Rad52 paralog, Rad59 protein, partially restores Rad52-dependent DNA annealing in the presence of Rad51, suggesting that Rad52 and Rad59 function coordinately to enhance recombinational DNA repair either by directing the processed DSBs to repair by DNA strand annealing or by promoting second end capture to form a double Holliday junction. This regulation of Rad52-mediated annealing suggests a control function for Rad51 in deciding the recombination path taken for a processed DNA break; the ssDNA can be directed to either Rad51-mediated DNA strand invasion or to Rad52-mediated DNA annealing. This channeling determines the nature of the subsequent repair process and is consistent with the observed competition between these pathways in vivo.     

Dynamic Regulatory Interactions of Rad51, Rad52, and Replication Protein-A in Recombination Intermediates

Rad51, Rad52, and replication protein-A (RPA) play crucial roles in the repair of DNA double-strand breaks in Saccharomyces cerevisiae. Rad51 mediates DNA strand exchange, a key reaction in DNA recombination. Rad52 recruits Rad51 into single-stranded DNAs (ssDNAs) that are saturated with RPA. Rad52 also promotes annealing of ssDNA strands that are complexed with RPA. Specific protein-protein interactions are involved in these reactions. Here we report new biochemical characteristics of these protein interactions. First, Rad52-RPA interaction requires multiple molecules of RPA to be associated with ssDNA, suggesting that multiple contacts between the Rad52 ring and RPA-ssDNA filament are needed for stable binding. Second, RPA-t11, which is a recombination-deficient mutant of RPA, displays a defect in interacting with Rad52 in the presence of salt above 50 mM, explaining the defect in Rad52-mediated ssDNA annealing in the presence of this mutation. Third, ssDNA annealing promoted by Rad52 is preceded by aggregation of multiple RPA-ssDNA complexes with Rad52, and Rad51 inhibits this aggregation. These results suggest a regulatory role for Rad51 that suppresses ssDNA annealing and facilitates DNA strand invasion. Finally, the Rad51-double-stranded DNA complex disrupts Rad52-RPA interaction in ssDNA and titrates Rad52 from RPA. This suggests an additional regulatory role for Rad51 following DNA strand invasion, where Rad51-double-stranded DNA may inhibit illegitimate second-end capture to ensure the error-free repair of a DNA double-strand break.     

Rad52-mediated DNA annealing after Rad51-mediated DNA strand exchange promotes second ssDNA capture

Rad51, Rad52, and RPA play central roles in homologous DNA recombination. Rad51 mediates DNA strand exchange, a key reaction in DNA recombination. Rad52 has two distinct activities: to recruit Rad51 onto single-strand (ss)DNA that is complexed with the ssDNA-binding protein, RPA, and to anneal complementary ssDNA complexed with RPA. Here, we report that Rad52 promotes annealing of the ssDNA strand that is displaced by DNA strand exchange by Rad51 and RPA, to a second ssDNA strand. An RPA that is recombination-deficient (RPA(rfa1-t11)) failed to support annealing, explaining its in vivo phenotype. Escherichia coli RecO and SSB proteins, which are functional homologues of Rad52 and RPA, also facilitated the same reaction, demonstrating its conserved nature. We also demonstrate that the two activities of Rad52, recruiting Rad51 and annealing DNA, are coordinated in DNA strand exchange and second ssDNA capture.     

Interaction with Rad51 is indispensable for recombination mediator function of Rad52

In the yeast Saccharomyces cerevisiae, the RAD52 gene is indispensable for homologous recombination and DNA repair. Rad52 protein binds DNA, anneals complementary ssDNA strands, and self-associates to form multimeric complexes. Moreover, Rad52 physically interacts with the Rad51 recombinase and serves as a mediator in the Rad51-catalyzed DNA strand exchange reaction. Here, we examine the functional significance of the Rad51/Rad52 interaction. Through a series of deletions, we have identified residues 409-420 of Rad52 as being indispensable and likely sufficient for its interaction with Rad51. We have constructed a four-amino acid deletion mutation within this region of Rad52 to ablate its interaction with Rad51. We show that the rad52delta409-412 mutant protein is defective in the mediator function in vitro even though none of the other Rad52 activities, namely, DNA binding, ssDNA annealing, and protein oligomerization, are affected. We also show that the sensitivity of the rad52delta409-412 mutant to ionizing radiation can be complemented by overexpression of Rad51. These results thus demonstrate the significance of the Rad51-Rad52 interaction in homologous recombination.     

Homologous DNA pairing by human recombination factors Rad51 and Rad54

Human Rad51 (hRad51) and Rad54 proteins are key members of the RAD52 group required for homologous recombination. We show an ability of hRad54 to promote transient separation of the strands in duplex DNA via its ATP hydrolysis-driven DNA supercoiling function. The ATPase, DNA supercoiling, and DNA strand opening activities of hRad54 are greatly stimulated through an interaction with hRad51. Importantly, we demonstrate that hRad51 and hRad54 functionally cooperate in the homologous DNA pairing reaction that forms recombination DNA intermediates. Our results should provide a biochemical model for dissecting the role of hRad51 and hRad54 in recombination reactions in human cells.     

Rad51 protein stimulates the branch migration activity of Rad54 protein

The Rad51 and Rad54 proteins play important roles during homologous recombination in eukaryotes. Rad51 forms a nucleoprotein filament on single-stranded DNA and performs the initial steps of double strand break repair. Rad54 belongs to the Swi2/Snf2 family of ATP-dependent DNA translocases. We previously showed that Rad54 promotes branch migration of Holliday junctions. Here we find that human Rad51 (hRad51) significantly stimulates the branch migration activity of hRad54. The stimulation appears to be evolutionarily conserved, as yeast Rad51 also stimulates the branch migration activity of yeast Rad54. We further investigated the mechanism of this stimulation. Our results demonstrate that the stimulation of hRad54-promoted branch migration by hRad51 is driven by specific protein-protein interactions, and the active form of the hRad51 filament is more stimulatory than the inactive one. The current results support the hypothesis that the hRad51 conformation state has a strong effect on interaction with hRad54 and ultimately on the function of hRad54 in homologous recombination.     

Real-time measurements of the nucleation, growth and dissociation of single Rad51-DNA nucleoprotein filaments

Human Rad51 (hRad51), the protein central to DNA pairing and strand exchange during homologous recombination, polymerizes on DNA to form nucleoprotein filaments. By making use of magnetic tweezers to manipulate individual DNA molecules, we measured the nucleation and growth of hRad51 nucleoprotein filaments, and their subsequent disassembly in real time. The dependence of the initial polymerization rate upon the concentration of hRad51 suggests that the rate-limiting step is the formation of a nucleus involving 5.5 ± 1.5 hRad51 monomers, corresponding to one helical turn of the hRad51 nucleoprotein filament. Polymerization is highly cooperative (i.e. a nucleation-limited reaction) at low concentrations and less cooperative (a growth-limited reaction) at high concentrations of the protein. We show that the observed preference of hRad51 to form nucleoprotein filaments on double-stranded DNA rather than on single-stranded DNA is due to the fact that it depolymerizes much faster from ssDNA than from dsDNA: indeed, hRad51 polymerizes faster on ssDNA than on dsDNA. Hydrolysis of ATP by hRad51 does not correlate with its dissociation from dsDNA. This suggests that hRad51 does not depolymerize rapidly from dsDNA after strand exchange but stays bound to the heteroduplex, highlighting the importance of partner proteins to facilitate hRad51 depolymerization from dsDNA.     

Molecular anatomy of the recombination mediator function of Saccharomyces cerevisiae Rad52

A helical filament of Rad51 on single-strand DNA (ssDNA), called the presynaptic filament, catalyzes DNA joint formation during homologous recombination. Rad52 facilitates presynaptic filament assembly, and this recombination mediator activity is thought to rely on the interactions of Rad52 with Rad51, the ssDNA-binding protein RPA, and ssDNA. The N-terminal region of Rad52, which has DNA binding activity and an oligomeric structure, is thought to be crucial for mediator activity and recombination. Unexpectedly, we find that the C-terminal region of Rad52 also harbors a DNA binding function. Importantly, the Rad52 C-terminal portion alone can promote Rad51 presynaptic filament assembly. The middle portion of Rad52 associates with DNA-bound RPA and contributes to the recombination mediator activity. Accordingly, expression of a protein species that harbors the middle and C-terminal regions of Rad52 in the rad52 Delta327 background enhances the association of Rad51 protein with a HO-made DNA double-strand break and partially complements the methylmethane sulfonate sensitivity of the mutant cells. Our results provide a mechanistic framework for rationalizing the multi-faceted role of Rad52 in recombination and DNA repair.     

The human checkpoint protein hRad17 interacts with the PCNA-like proteins hRad1, hHus1, and hRad9

DNA damage activates cell cycle checkpoints that prevent progression through the cell cycle. In yeast, the DNA damage checkpoint response is regulated by a series of genes that have mammalian homologs, including rad1, rad9, hus1, and rad17. On the basis of sequence homology, yeast and human Rad1, Rad9, and Hus1 protein homologs are predicted to structurally resemble the sliding clamp PCNA. Likewise, Rad17 homologs have extensive homology with replication factor C (RFC) subunits (p36, p37, p38, p40, and p140), which form a clamp loader for PCNA. These observations predict that Rad1, Hus1, and Rad9 might interact with Rad17 as a clamp-clamp loader pair during the DNA damage response. In this report, we demonstrate that endogenous human Rad17 (hRad17) interacts with the PCNA-related checkpoint proteins hRad1, hRad9, and hHus1. Mutational analysis of hRad1 and hRad17 demonstrates that this interaction has properties similar to the interaction between RFC and PCNA, a well characterized clamp-clamp loader pair. Moreover, we show that DNA damage affects the association of hRad17 with the clamp-like checkpoint proteins. Collectively, these data provide the first experimental evidence that hRad17 interacts with the PCNA-like proteins hRad1, hHus1, and hRad9 in manner similar to the interaction between RFC and PCNA.     

Yeast Rad52 and Rad51 recombination proteins define a second pathway of DNA damage assessment in response to a single double-strand break

Saccharomyces cells with a single unrepaired double-strand break adapt after checkpoint-mediated G(2)/M arrest. We have found that both Rad51 and Rad52 recombination proteins play key roles in adaptation. Cells lacking Rad51p fail to adapt, but deleting RAD52 suppresses rad51Delta. rad52Delta also suppresses adaptation defects of srs2Delta mutants but not those of yku70Delta or tid1Delta mutants. Neither rad54Delta nor rad55Delta affects adaptation. A Rad51 mutant that fails to interact with Rad52p is adaptation defective; conversely, a C-terminal truncation mutant of Rad52p, impaired in interaction with Rad51p, is also adaptation defective. In contrast, rad51-K191A, a mutation that abolishes recombination and results in a protein that does not bind to single-stranded DNA (ssDNA), supports adaptation, as do Rad51 mutants impaired in interaction with Rad54p or Rad55p. An rfa1-t11 mutation in the ssDNA binding complex RPA partially restores adaptation in rad51Delta mutants and fully restores adaptation in yku70Delta and tid1Delta mutants. Surprisingly, although neither rfa1-t11 nor rad52Delta mutants are adaptation defective, the rad52Delta rfa1-t11 double mutant fails to adapt and exhibits the persistent hyperphosphorylation of the DNA damage checkpoint protein Rad53 after HO induction. We suggest that monitoring of the extent of DNA damage depends on independent binding of RPA and Rad52p to ssDNA, with Rad52p's activity modulated by Rad51p whereas RPA's action depends on Tid1p.     

In vivo assembly and disassembly of Rad51 and Rad52 complexes during double-strand break repair

Assembly and disassembly of Rad51 and Rad52 complexes were monitored by immunofluorescence during homologous recombination initiated by an HO endonuclease-induced double-strand break (DSB) at the MAT locus. DSB-induced Rad51 and Rad52 foci colocalize with a TetR-GFP focus at tetO sequences adjacent to MAT. In strains in which HO cleaves three sites on chromosome III, we observe three distinct foci that colocalize with adjacent GFP chromosome marks. We compared the kinetics of focus formation with recombination intermediates and products when HO-cleaved MATalpha recombines with the donor, MATa. Rad51 assembly occurs 1 h after HO cleavage. Rad51 disassembly occurs at the same time that new DNA synthesis is initiated after single-stranded (ss) MAT DNA invades MATa. We present evidence for three distinct roles for Rad52 in recombination: a presynaptic role necessary for Rad51 assembly, a synaptic role with Rad51 filaments, and a postsynaptic role after Rad51 dissociates. Additional biochemical studies suggest the presence of an ssDNA complex containing both Rad51 and Rad52.