INO80-dependent chromatin remodeling regulates early and late stages of mitotic homologous recombination

Chromatin remodeling is emerging as a critical regulator of DNA repair factor access to DNA damage, and optimum accessibility of these factors is a major determinant of DNA repair outcome. Hence, chromatin remodeling is likely to play a key role in genome stabilization and tumor suppression. We previously showed that nucleosome eviction near double-strand breaks (DSBs) in yeast is regulated by the INO80 nucleosome remodeling complex and is defective in mutants lacking the Arp8 subunit of INO80. In the absence of homologous donor sequences, RPA recruitment to a DSB appeared normal in arp8Δ, but Rad51 recruitment was defective. We now show that the early strand invasion step of homologous recombination (HR) is markedly delayed in an arp8Δ haploid, but there is only a minor defect in haploid HR efficiency (MAT switching). In an arp8Δ diploid, interhomolog DSB repair by HR shows a modest defect that is partially suppressed by overexpression of Rad51 or its mediator, Rad52. In wild type cells, DSB repair typically results in gene conversion, and most gene conversion tracts are continuous, reflecting efficient mismatch repair of heteroduplex DNA. In contrast, arp8Δ gene conversion tracts are longer and frequently discontinuous, indicating defects in late stages of HR. Interestingly, when a homologous donor sequence is present, Rad51 is recruited normally to a DSB in arp8Δ, but its transfer to the donor is delayed, and this correlates with defective displacement of donor nucleosomes. We propose that retained nucleosomes at donors destabilize heteroduplex DNA or impair mismatch recognition, reflected in delayed strand invasion and altered conversion tracts.     

A genetic screen for DNA double-strand break repair mutations in Drosophila

The study of DNA double-strand break (DSB) repair has been greatly facilitated by the use of rare-cutting endonucleases, which induce a break precisely at their cut sites that can be strategically placed in the genome. We previously established such a system in Drosophila and showed that the yeast I-SceI enzyme cuts efficiently in Drosophila cells and those breaks are effectively repaired by conserved mechanisms. In this study, we determined the genetic requirements for the repair of this I-SceI-induced DSB in the germline. We show that Drosophila Rad51 and Rad54 are both required for homologous repair by gene conversion, but are dispensable for single-strand annealing repair. We provided evidence suggesting that Rad51 is more stringently required than Rad54 for intersister gene conversion. We uncovered a significant role of DNA ligase IV in nonhomologous end joining. We conducted a screen for candidate mutations affecting DSB repair and discovered novel mutations in genes that include mutagen sensitive 206, single-strand annealing reducer, and others. In addition, we demonstrated an intricate balance among different repair pathways in which the cell differentially utilizes repair mechanisms in response to both changes in the genomic environment surrounding the break and deficiencies in one or the other repair pathways.     

Spontaneous and double-strand break-induced recombination,and gene conversion tract lengths,are differentially affected by overexpression of wild-type or ATPase-defective yeast Rad54

Rad54 plays key roles in homologous recombination (HR) and double-strand break (DSB) repair in yeast, along with Rad51, Rad52, Rad55 and Rad57. Rad54 belongs to the Swi2/Snf2 family of DNA-stimulated ATPases. Rad51 nucleoprotein filaments catalyze DNA strand exchange and Rad54 augments this activity of Rad51. Mutations in the Rad54 ATPase domain (ATPase^–) impair Rad54 function in vitro, sensitize yeast to killing by methylmethane sulfonate and reduce spontaneous gene conversion. We found that overexpression of ATPase^– Rad54 reduced spontaneous direct repeat gene conversion and increased both spontaneous direct repeat deletion and spontaneous allelic conversion. Overexpression of ATPase^– Rad54 decreased DSB-induced allelic conversion, but increased chromosome loss and DSB-dependent lethality. Thus, ATP hydrolysis by Rad54 contributes to genome stability by promoting high-fidelity DSB repair and suppressing spontaneous deletions. Overexpression of wild-type Rad54 did not alter DSB-induced HR levels, but conversion tract lengths were reduced. Interestingly, ATPase^– Rad54 decreased overall HR levels and increased tract lengths. These tract length changes provide new in vivo evidence that Rad54 functions in the post-synaptic phase during recombinational repair of DSBs.     

Rad54 dissociates homologous recombination intermediates by branch migration

Double-strand DNA breaks (DSBs) cause cell death and genome instability. Homologous recombination is a major DSB repair pathway that operates by forming joint molecules with homologous DNA sequences, which are used as templates to achieve accurate repair. In eukaryotes, Rad51 protein (RecA homolog) searches for homologous sequences and catalyzes the formation of joint molecules (D-loops). Once joint molecules have been formed, DNA polymerase extends the 3' single-stranded DNA tails of the broken chromosome, restoring the lost information. How joint molecules subsequently dissociate is unknown. We reconstituted DSB repair in vitro using purified human homologous recombination proteins and DNA polymerase eta. We found that Rad54 protein, owing to its ATP-dependent branch-migration activity, can cause dissociation of joint molecules. These results suggest a previously uncharacterized mechanism of DSB repair in which Rad54 branch-migration activity plays an important role.     

Caffeine inhibits gene conversion by displacing Rad51 from ssDNA

Efficient repair of chromosomal double-strand breaks (DSBs) by homologous recombination relies on the formation of a Rad51 recombinase filament that forms on single-stranded DNA (ssDNA) created at DSB ends. This filament facilitates the search for a homologous donor sequence and promotes strand invasion. Recently caffeine treatment has been shown to prevent gene targeting in mammalian cells by increasing non-productive Rad51 interactions between the DSB and random regions of the genome. Here we show that caffeine treatment prevents gene conversion in yeast, independently of its inhibition of the Mec1^ATR/Tel1^ATM-dependent DNA damage response or caffeine''s inhibition of 5′ to 3′ resection of DSB ends. Caffeine treatment results in a dosage-dependent eviction of Rad51 from ssDNA. Gene conversion is impaired even at low concentrations of caffeine, where there is no discernible dismantling of the Rad51 filament. Loss of the Rad51 filament integrity is independent of Srs2''s Rad51 filament dismantling activity or Rad51''s ATPase activity and does not depend on non-specific Rad51 binding to undamaged double-stranded DNA. Caffeine treatment had similar effects on irradiated HeLa cells, promoting loss of previously assembled Rad51 foci. We conclude that caffeine treatment can disrupt gene conversion by disrupting Rad51 filaments.     

Rad51 Inhibits Translocation Formation by Non-Conservative Homologous Recombination in Saccharomyces cerevisiae

Chromosomal translocations are a primary biological response to ionizing radiation (IR) exposure, and are likely to result from the inappropriate repair of the DNA double-strand breaks (DSBs) that are created. An abundance of repetitive sequences in eukaryotic genomes provides ample opportunity for such breaks to be repaired by homologous recombination (HR) between non-allelic repeats. Interestingly, in the budding yeast, Saccharomyces cerevisiae the central strand exchange protein, Rad51 that is required for DSB repair by gene conversion between unlinked repeats that conserves genomic structure also suppresses translocation formation by several HR mechanisms. In particular, Rad51 suppresses translocation formation by single-strand annealing (SSA), perhaps the most efficient mechanism for translocation formation by HR in both yeast and mammalian cells. Further, the enhanced translocation formation that emerges in the absence of Rad51 displays a distinct pattern of genetic control, suggesting that this occurs by a separate mechanism. Since hypomorphic mutations in RAD51 in mammalian cells also reduce DSB repair by conservative gene conversion and stimulate non-conservative repair by SSA, this mechanism may also operate in humans and, perhaps contribute to the genome instability that propels the development of cancer.     

Rad51-independent interchromosomal double-strand break repair by gene conversion requires Rad52 but not Rad55, Rad57, or Dmc1

Homologous recombination (HR) is critical for DNA double-strand break (DSB) repair and genome stabilization. In yeast, HR is catalyzed by the Rad51 strand transferase and its “mediators,” including the Rad52 single-strand DNA-annealing protein, two Rad51 paralogs (Rad55 and Rad57), and Rad54. A Rad51 homolog, Dmc1, is important for meiotic HR. In wild-type cells, most DSB repair results in gene conversion, a conservative HR outcome. Because Rad51 plays a central role in the homology search and strand invasion steps, DSBs either are not repaired or are repaired by nonconservative single-strand annealing or break-induced replication mechanisms in rad51Δ mutants. Although DSB repair by gene conversion in the absence of Rad51 has been reported for ectopic HR events (e.g., inverted repeats or between plasmids), Rad51 has been thought to be essential for DSB repair by conservative interchromosomal (allelic) gene conversion. Here, we demonstrate that DSBs stimulate gene conversion between homologous chromosomes (allelic conversion) by >30-fold in a rad51Δ mutant. We show that Rad51-independent allelic conversion and break-induced replication occur independently of Rad55, Rad57, and Dmc1 but require Rad52. Unlike DSB-induced events, spontaneous allelic conversion was detected in both rad51Δ and rad52Δ mutants, but not in a rad51Δ rad52Δ double mutant. The frequencies of crossovers associated with DSB-induced gene conversion were similar in the wild type and the rad51Δ mutant, but discontinuous conversion tracts were fivefold more frequent and tract lengths were more widely distributed in the rad51Δ mutant, indicating that heteroduplex DNA has an altered structure, or is processed differently, in the absence of Rad51.     

Members of the RAD52 Epistasis Group Contribute to Mitochondrial Homologous Recombination and Double-Strand Break Repair in Saccharomyces cerevisiae

Mitochondria contain an independently maintained genome that encodes several proteins required for cellular respiration. Deletions in the mitochondrial genome have been identified that cause several maternally inherited diseases and are associated with certain cancers and neurological disorders. The majority of these deletions in human cells are flanked by short, repetitive sequences, suggesting that these deletions may result from recombination events. Our current understanding of the maintenance and repair of mtDNA is quite limited compared to our understanding of similar events in the nucleus. Many nuclear DNA repair proteins are now known to also localize to mitochondria, but their function and the mechanism of their action remain largely unknown. This study investigated the contribution of the nuclear double-strand break repair (DSBR) proteins Rad51p, Rad52p and Rad59p in mtDNA repair. We have determined that both Rad51p and Rad59p are localized to the matrix of the mitochondria and that Rad51p binds directly to mitochondrial DNA. In addition, a mitochondrially-targeted restriction endonuclease (mtLS-KpnI) was used to produce a unique double-strand break (DSB) in the mitochondrial genome, which allowed direct analysis of DSB repair in vivo in Saccharomyces cerevisiae. We find that loss of these three proteins significantly decreases the rate of spontaneous deletion events and the loss of Rad51p and Rad59p impairs the repair of induced mtDNA DSBs.     

Ago2 facilitates Rad51 recruitment and DNA double-strand break repair by homologous recombination

DNA double-strand breaks (DSBs) are highly cytotoxic lesions and pose a major threat to genome stability if not properly repaired. We and others have previously shown that a class of DSB-induced small RNAs (diRNAs) is produced from sequences around DSB sites. DiRNAs are associated with Argonaute (Ago) proteins and play an important role in DSB repair, though the mechanism through which they act remains unclear. Here, we report that the role of diRNAs in DSB repair is restricted to repair by homologous recombination (HR) and that it specifically relies on the effector protein Ago2 in mammalian cells. Interestingly, we show that Ago2 forms a complex with Rad51 and that the interaction is enhanced in cells treated with ionizing radiation. We demonstrate that Rad51 accumulation at DSB sites and HR repair depend on catalytic activity and small RNA-binding capability of Ago2. In contrast, DSB resection as well as RPA and Mre11 loading is unaffected by Ago2 or Dicer depletion, suggesting that Ago2 very likely functions directly in mediating Rad51 accumulation at DSBs. Taken together, our findings suggest that guided by diRNAs, Ago2 can promote Rad51 recruitment and/or retention at DSBs to facilitate repair by HR.     

Phosphorylation of Ago2 is required for its role in DNA double-strand break repair

Repair of DNA double-strand break(DSB) is critical for the maintenance of genome integrity. A class of DSB-induced small RNAs(di RNAs) has been shown to play an important role in DSB repair. In humans,di RNAs are associated with Ago2 and guide the recruitment of Rad51 to DSB sites to facilitate repair by homologous recombination(HR). Ago2 activity has been reported to be regulated by phosphorylation under normal and hypoxic conditions. However, the role of Ago2 phosphorylation in DNA damage repair is unexplored. Here, we show that S672, S828, T830, and S831 of human Ago2 are phosphorylated in response to ionizing radiation(IR). S672 A mutation of Ago2 leads to significant reduction in Rad51 foci formation and HR efficiency. We further show that defective association of Ago2 S672 A variant with DSB sites, instead of defects in di RNA and Rad51 binding, may account for decreased Rad51 foci formation and HR efficiency.Our study reveals a novel regulatory mechanism for the function of Ago2 in DNA repair.     

Characterization of Rad51 from Apicomplexan Parasite Toxoplasma gondii: An Implication for Inefficient Gene Targeting

Repairing double strand breaks (DSBs) is absolutely essential for the survival of obligate intracellular parasite Toxoplasma gondii. Thus, DSB repair mechanisms could be excellent targets for chemotherapeutic interventions. Recent genetic and bioinformatics analyses confirm the presence of both homologous recombination (HR) as well as non homologous end joining (NHEJ) proteins in this lower eukaryote. In order to get mechanistic insights into the HR mediated DSB repair pathway in this parasite, we have characterized the key protein involved in homologous recombination, namely TgRad51, at the biochemical and genetic levels. We have purified recombinant TgRad51 protein to 99% homogeneity and have characterized it biochemically. The ATP hydrolysis activity of TgRad51 shows a higher K(M) and much lower k(cat) compared to bacterial RecA or Rad51 from other related protozoan parasites. Taking yeast as a surrogate model system we have shown that TgRad51 is less efficient in gene conversion mechanism. Further, we have found that TgRad51 mediated gene integration is more prone towards random genetic loci rather than targeted locus. We hypothesize that compromised ATPase activity of TgRad51 is responsible for inefficient gene targeting and poor gene conversion efficiency in this protozoan parasite. With increase in homologous flanking regions almost three fold increments in targeted gene integration is observed, which is similar to the trend found with ScRad51. Our findings not only help us in understanding the reason behind inefficient gene targeting in T. gondii but also could be exploited to facilitate high throughput knockout as well as epitope tagging of Toxoplasma genes.     

Mouse RAD54 affects DNA double-strand break repair and sister chromatid exchange

Cells can achieve error-free repair of DNA double-strand breaks (DSBs) by homologous recombination through gene conversion with or without crossover. In contrast, an alternative homology-dependent DSB repair pathway, single-strand annealing (SSA), results in deletions. In this study, we analyzed the effect of mRAD54, a gene involved in homologous recombination, on the repair of a site-specific I-SceI-induced DSB located in a repeated DNA sequence in the genome of mouse embryonic stem cells. We used six isogenic cell lines differing solely in the orientation of the repeats. The combination of the three recombination-test substrates used discriminated among SSA, intrachromatid gene conversion, and sister chromatid gene conversion. DSB repair was most efficient for the substrate that allowed recovery of SSA events. Gene conversion with crossover, indistinguishable from long tract gene conversion, preferentially involved the sister chromatid rather than the repeat on the same chromatid. Comparing DSB repair in mRAD54 wild-type and knockout cells revealed direct evidence for a role of mRAD54 in DSB repair. The substrate measuring SSA showed an increased efficiency of DSB repair in the absence of mRAD54. The substrate measuring sister chromatid gene conversion showed a decrease in gene conversion with and without crossover. Consistent with this observation, DNA damage-induced sister chromatid exchange was reduced in mRAD54-deficient cells. Our results suggest that mRAD54 promotes gene conversion with predominant use of the sister chromatid as the repair template at the expense of error-prone SSA.     

Recruitment of the recombinational repair machinery to a DNA double-strand break in yeast

Repair of DNA double-strand breaks (DSBs) by homologous recombination requires members of the RAD52 epistasis group. Here we use chromatin immunoprecipitation (ChIP) to examine the temporal order of recruitment of Rad51p, Rad52p, Rad54p, Rad55p, and RPA to a single, induced DSB in yeast. Our results suggest a sequential, interdependent assembly of Rad proteins adjacent to the DSB initiated by binding of Rad51p. ChIP time courses from various mutant strains and additional biochemical studies suggest that Rad52p, Rad55p, and Rad54p each help promote the formation and/or stabilization of the Rad51p nucleoprotein filament. We also find that all four Rad proteins associate with homologous donor sequences during strand invasion. These studies provide a near comprehensive view of the molecular events required for the in vivo assembly of a functional Rad51p presynaptic filament.     

Functional analysis of the Drosophila Rad51 gene (spn-A) in repair of DNA damage and meiotic chromosome segregation

Rad51 is a crucial enzyme in DNA repair, mediating the strand invasion and strand exchange steps of homologous recombination (HR). Mutations in the Drosophila Rad51 gene (spn-A) disrupt somatic as well as meiotic double-strand break (DSB) repair, similar to fungal Rad51 genes. However, the sterility of spn-A mutant females prevented a thorough analysis of the role of Rad51 in meiosis. In this study, we generated transgenic animals that express spn-A dsRNA under control of an inducible promoter, and examined the effects of inhibiting expression of spn-A on DNA repair, meiotic recombination and meiotic chromosome pairing and segregation. We found that depletion of spn-A mRNA had no effect on the viability of non-mutagen-treated transgenic animals but greatly reduced the survival of larvae that were exposed to the radiomimetic drug MMS, in agreement with the MMS and X-ray sensitivity of spn-A mutant animals. We also found that increases in dose of spn-A gene enhanced larval resistance to MMS exposure, suggesting that at high damage levels, Rad51 protein levels may be limiting for DNA repair. spn-A RNAi strongly stimulated X-X nondisjunction and decreased recombination along the X in female meiosis, consistent with a requirement of Rad51 in meiotic recombination. However, neither RNAi directed against the spn-A mRNA nor homozygosity for a spn-A null mutation had any effect on male fertility or on X-Y segregation in male meiosis, indicating that Rad51 likely plays no role in male meiotic chromosome pairing. Our results support a central role for Rad51 in HR in both somatic and meiotic DSB repair, but indicate that Rad51 in Drosophila is dispensable for meiotic chromosome pairing. Our results also provide the first demonstration that RNAi can be used to inhibit the functions of meiotic genes in Drosophila.     

Overexpression of Rad51 inhibits double-strand break-induced homologous recombination but does not affect gene conversion tract lengths

DNA double-strand breaks (DSBs) in yeast are repaired by homologous recombination (HR) and non-homologous end-joining (NHEJ). Rad51 forms nucleoprotein filaments at processed broken ends that effect strand exchange, forming heteroduplex DNA (hDNA) that gives rise to a gene conversion tract. We hypothesized that excess Rad51 would increase gene conversion tract lengths. We found that excess Rad51 reduced DSB-induced HR but did not alter tract lengths or other outcomes including rates of crossovers, break-induced replication, or chromosome loss. Thus, excess Rad51 appears to influence DSB-induced HR at an early stage. MAT heterozygosity largely mitigated the inhibitory effect of excess Rad51 on allelic HR, but not direct repeat HR. Excess Rad52 had no effect on DSB-induced HR efficiency or outcome, nor did it mitigate the dominant negative effects of excess Rad51. Excess Rad51 had little effect on DSB-induced lethality in wild-type cells, but it did enhance lethality in yku70Delta mutants. Interestingly, dnl4Delta showed marked DSB-induced lethality but this was not further enhanced by excess Rad51. The differential effects of yku70Delta and dnl4Delta indicate that the enhanced killing with excess Rad51 in yku70Delta is not due to its NHEJ defect, but may reflect its defect in end-protection and/or its inability to escape from checkpoint arrest. Srs2 displaces Rad51 from nucleoprotein filaments in vitro, suggesting that excess Rad51 might antagonize Srs2. We show that excess Rad51 does not reduce survival of wild-type cells treated with methylmethane sulfonate (MMS), or cells suffering a single DSB. In contrast, excess Rad51 sensitized srs2Delta cells to both MMS and a single DSB. These results support the idea that excess Rad51 antagonizes Srs2, and underscores the importance of displacing Rad51 from nucleoprotein filaments to achieve optimum repair efficiency.     

A tale of tails: insights into the coordination of 3′ end processing during homologous recombination

Eukaryotic genomes harbor a large number of homologous repeat sequences that are capable of recombining. Their potential to disrupt genome stability highlights the need to understand how homologous recombination processes are coordinated. The Saccharomyces cerevisiae Rad1–Rad10 endonuclease performs an essential role in recombination between repeated sequences, by processing 3′ single‐stranded intermediates formed during single‐strand annealing and gene conversion events. Several recent studies have focused on factors involved in Rad1–Rad10‐dependent removal of 3′ nonhomologous tails during homologous recombination, including Msh2–Msh3, Slx4, and the newly identified Saw1 protein. Together, this new work provides a model for how Rad1–Rad10‐dependent end processing is coordinated: Msh2–Msh3 stabilizes and prepares double‐strand/single‐strand junctions for Rad1–Rad10 cleavage, Saw1 recruits Rad1–Rad10 to 3′ tails, and Slx4 mediates crosstalk between the DNA damage checkpoint machinery and Rad1–Rad10.     

Conditional deletion of Nbs1 in murine cells reveals its role in branching repair pathways of DNA double-strand breaks

NBS1 forms a complex with MRE11 and RAD50 (MRN) that is proposed to act on the upstream of two repair pathways of DNA double-strand break (DSB), homologous repair (HR) and non-homologous end joining (NHEJ). However, the function of Nbs1 in these processes has not fully been elucidated in mammals due to the lethal phenotype of cells and mice lacking Nbs1. Here, we have constructed mouse Nbs1-null embryonic fibroblasts and embryonic stem cells, through the Cre-loxP and sequential gene targeting techniques. We show that cells lacking Nbs1 display reduced HR of the single DSB in chromosomally integrated substrate, affecting both homology-directed repair (HDR) and single-stranded annealing pathways, and, surprisingly, increased NHEJ-mediated sequence deletion. Moreover, focus formation at DSBs and chromatin recruitment of the Nbs1 partners Rad50 and Mre11 as well as Rad51 and Brca1 are attenuated in these cells, whereas the NHEJ molecule Ku70 binding to chromatin is not affected. These data provide a novel insight into the function of MRN in the branching of DSB repair pathways.     

DNA length dependence of the single-strand annealing pathway and the role of Saccharomyces cerevisiae RAD59 in double-strand break repair

A DNA double-strand break (DSB) created by the HO endonuclease in Saccharomyces cerevisiae will stimulate recombination between flanking repeats by the single-strand annealing (SSA) pathway, producing a deletion. Previously the efficiency of SSA, using homologous sequences of different lengths, was measured in competition with that of a larger repeat further from the DSB, which ensured that nearly all cells would survive the DSB if the smaller region was not used (N. Sugawara and J. E. Haber, Mol. Cell. Biol. 12:563-575, 1992). Without competition, the efficiency with which homologous segments of 63 to 205 bp engaged in SSA was significantly increased. A sequence as small as 29 bp was used 0.2% of the time, and homology dependence was approximately linear up to 415 bp, at which size almost all cells survived. A mutant with a deletion of RAD59, a homologue of RAD52, was defective for SSA, especially when the homologous-sequence length was short; however, even with 1.17-kb substrates, SSA was reduced fourfold. DSB-induced gene conversion also showed a partial dependence on Rad59p, again being greatest when the homologous-sequence length was short. We found that Rad59p plays a role in removing nonhomologous sequences from the ends of single-stranded DNA when it invades a homologous DNA template, in a manner similar to that previously seen with srs2 mutants. Deltarad59 affected DSB-induced gene conversion differently from msh3 and msh2, which are also defective in removing nonhomologous ends in both DSB-induced gene conversion and SSA. A msh3 rad59 double mutant was more severely defective in SSA than either single mutant.     

Rad52 promotes postinvasion steps of meiotic double-strand-break repair

During DNA double-strand-break (DSB) repair by recombination, the broken chromosome uses a homologous chromosome as a repair template. Early steps of recombination are well characterized: DSB ends assemble filaments of RecA-family proteins that catalyze homologous pairing and strand-invasion reactions. By contrast, the postinvasion steps of recombination are poorly characterized. Rad52 plays an essential role during early steps of recombination by mediating assembly of a RecA homolog, Rad51, into nucleoprotein filaments. The meiosis-specific RecA-homolog Dmc1 does not show this dependence, however. By exploiting the Rad52 independence of Dmc1, we reveal that Rad52 promotes postinvasion steps of both crossover and noncrossover pathways of meiotic recombination in Saccharomyces cerevisiae. This activity resides in the N-terminal region of Rad52, which can anneal complementary DNA strands, and is independent of its Rad51-assembly function. Our findings show that Rad52 functions in temporally and biochemically distinct reactions and suggest a general annealing mechanism for reuniting DSB ends during recombination.     

Mutation in Brca2 stimulates error-prone homology-directed repair of DNA double-strand breaks occurring between repeated sequences

Mutation of BRCA2 causes familial early onset breast and ovarian cancer. BRCA2 has been suggested to be important for the maintenance of genome integrity and to have a role in DNA repair by homology- directed double-strand break (DSB) repair. By studying the repair of a specific induced chromosomal DSB we show that loss of Brca2 leads to a substantial increase in error-prone repair by homology-directed single-strand annealing and a reduction in DSB repair by conservative gene conversion. These data demonstrate that loss of Brca2 causes misrepair of chromosomal DSBs occurring between repeated sequences by stimulating use of an error-prone homologous recombination pathway. Furthermore, loss of Brca2 causes a large increase in genome-wide error-prone repair of both spontaneous DNA damage and mitomycin C-induced DNA cross-links at the expense of error-free repair by sister chromatid recombination. This provides insight into the mechanisms that induce genome instability in tumour cells lacking BRCA2.