A core activity associated with the N terminus of the yeast RAD52 protein is revealed by RAD51 overexpression suppression of C-terminal rad52 truncation alleles.

C-terminal rad52 truncation and internal deletion mutants were characterized for their ability to repair MMS-induced double-strand breaks and to produce viable spores during meiosis. The rad52-Delta251 allele, encoding the N-terminal 251 amino acids of the predicted 504-amino-acid polypeptide, supports partial activity for both functions. Furthermore, RAD51 overexpression completely suppresses the MMS sensitivity of a rad52-Delta251 mutant. The absence of the C terminus in the truncated protein makes it likely that suppression occurs by bypassing the C-terminal functions of Rad52p. RAD51 overexpression does not suppress the low level of spore viability that the rad52-Delta251 allele causes and only partially suppresses the defect in rad52 alleles encoding the N-terminal 292 or 327 amino acids. The results of this study also show that intragenic complementation between rad52 alleles is governed by a complex relationship that depends heavily on the two alleles involved and their relative dosage. In heteroallelic rad52 diploids, the rad52-Delta251 allele does not complement rad52 missense mutations altering residues 61 or 64 in the N terminus. However, complementation is achieved with each of these missense alleles when the rad52-Delta251 allele is overexpressed. Complementation also occurs between rad52-Delta327 and an internal deletion allele missing residues 210 through 327. We suggest that the first 251 amino acids of Rad52p constitute a core domain that provides critical RAD52 activities.     

Effects of controlled RAD52 expression on repair and recombination in Saccharomyces cerevisiae.

We have examined the effects of RAD52 overexpression on methyl methanesulfonate (MMS) sensitivity and spontaneous mitotic recombination rates. Cells expressing a 10-fold excess of RAD52 mRNA from the ENO1 promoter are no more resistant to MMS than are wild-type cells. Similarly, under the same conditions, the rate of mitotic recombination within a reporter plasmid does not exceed that measured in wild-type cells. This high level of expression is capable of correcting the defects of rad52 mutant cells in carrying out repair and recombination. From these observations, we conclude that wild-type amounts of Rad52 are not rate limiting for repair of MMS-induced lesions or plasmid recombination. By placing RAD52 under the control of the inducible GAL1 promoter, we find that induction results in a 12-fold increase in the fraction of recombinants within 4 h. After this time, the fraction increases less rapidly. When RAD52 expression is quickly repressed during induction, the amount of RAD52 mRNA decreases rapidly and no nascent recombinants are formed. This result suggests a short active half-life for the protein product. Induction of RAD52 in G1-arrested mutant cells also causes a rapid increase in recombinants, suggesting that replication is not necessary for plasmid recombination.     

Recovery of deficient homologous recombination in Brca2-depleted mouse cells by wild-type Rad51 expression

The BRCA2 tumor suppressor is important in maintaining genomic stability. BRCA2 is proposed to control the availability, cellular localization and DNA binding activity of the central homologous recombination protein, RAD51, with loss of BRCA2 resulting in defective homologous recombination. Nevertheless, the roles of BRCA2 in regulating RAD51 and how other proteins implicated in RAD51 regulation, such as RAD52 and RAD54 function relative to BRCA2 is not known. In this study, we tested whether defective homologous recombination in Brca2-depleted mouse hybridoma cells could be rectified by expression of mouse Rad51 or the Rad51-interacting mouse proteins, Rad52 and Rad54. In the Brca2-depleted cells, defective homologous recombination can be restored by over-expression of wild-type mouse Rad51, but not mouse Rad52 or Rad54. Correction of the homologous recombination defect requires Rad51 ATPase activity. A sizeable fraction ( approximately 50%) of over-expressed wild-type Rad51 is nuclear localized. The restoration of homologous recombination in the presence of a low (i.e., non-functional) level of Brca2 by wild-type Rad51 over-expression is unexpected. We suggest that Rad51 may access the nuclear compartment in a Brca2-independent manner and when Rad51 is over-expressed, the normal requirement for Brca2 control over Rad51 function in homologous recombination is dispensable. Our studies support loss of Rad51 function as a critical underlying factor in the homologous recombination defect in the Brca2-depleted cells.     

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.     

Molecular dissection of interactions between Rad51 and members of the recombination-repair group

Recombination is important for the repair of DNA damage and for chromosome segregation during meiosis; it has also been shown to participate in the regulation of cell proliferation. In the yeast Saccharomyces cerevisiae, recombination requires products of the RAD52 epistasis group. The Rad51 protein associates with the Rad51, Rad52, Rad54, and Rad55 proteins to form a dynamic complex. We describe a new strategy to screen for mutations which cause specific disruption of the interaction between certain proteins in the complex, leaving other interactions intact. This approach defines distinct protein interaction domains and protein relationships within the Rad51 complex. Alignment of the mutations onto the constructed three-dimensional model of the Rad51 protein reveal possible partially overlapping interfaces for the Rad51-Rad52 and the Rad51-Rad54 interactions. Rad51-Rad55 and Rad51-Rad51 interactions are affected by the same spectrum of mutations, indicating similarity between the two modes of binding. Finally, the detection of a subset of mutations within Rad51 which disrupt the interaction with mutant Rad52 protein but activate the interaction with Rad54 suggests that dynamic changes within the Rad51 protein may contribute to an ordered reaction process.     

The N-terminal DNA-binding domain of Rad52 promotes RAD51-independent recombination in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the Rad52 protein plays a role in both RAD51-dependent and RAD51-independent recombination pathways. We characterized a rad52 mutant, rad52-329, which lacks the C-terminal Rad51-interacting domain, and studied its role in RAD51-independent recombination. The rad52-329 mutant is completely defective in mating-type switching, but partially proficient in recombination between inverted repeats. We also analyzed the effect of the rad52-329 mutant on telomere recombination. Yeast cells lacking telomerase maintain telomere length by recombination. The rad52-329 mutant is deficient in RAD51-dependent telomere recombination, but is proficient in RAD51-independent telomere recombination. In addition, we examined the roles of other recombination genes in the telomere recombination. The RAD51-independent recombination in the rad52-329 mutant is promoted by a paralogue of Rad52, Rad59. All components of the Rad50-Mre11-Xrs2 complex are also important, but not essential, for RAD51-independent telomere recombination. Interestingly, RAD51 inhibits the RAD51-independent, RAD52-dependent telomere recombination. These findings indicate that Rad52 itself, and more precisely its N-terminal DNA-binding domain, promote an essential reaction in recombination in the absence of RAD51.     

Genetic re-engineering of Saccharomyces cerevisiae RAD51 leads to a significant increase in the frequency of gene repair in vivo

Oligonucleotides can be used to direct the alteration of single nucleotides in chromosomal genes in yeast. Rad51 protein appears to play a central role in catalyzing the reaction, most likely through its DNA pairing function. Here, we re-engineer the RAD51 gene in order to produce proteins bearing altered levels of known activities. Overexpression of wild-type ScRAD51 elevates the correction of an integrated, mutant hygromycin resistance gene ~3-fold. Overexpression of an altered RAD51 gene, which encodes a protein that has a higher affinity for ScRad54, enhances the targeting frequency nearly 100-fold. Another mutation which increases the affinity of Rad51 for DNA was also found to increase gene repair when overexpressed in the cell. Other mutations in the Rad51 protein, such as one that reduces interaction with Rad52, has little or no effect on the frequency of gene repair. These data provide the first evidence that the Rad51 protein can be modified so as to increase the frequency of gene repair in yeast.     

Accumulation of sumoylated Rad52 in checkpoint mutants perturbed in DNA replication

Checkpoints are cellular surveillance and signaling pathways that regulate responses to DNA damage and perturbations of DNA replication. Here we show that high levels of sumoylated Rad52 are present in the mec1 sml1 and rad53 sml1 checkpoint mutants exposed to DNA-damaging agents such as methyl methanesulfonate (MMS) or the DNA replication inhibitor hydroxyurea (HU). The kinase-defective mutant rad53-K227A also showed high levels of Rad52 sumoylation. Elevated levels of Rad52 sumoylation occur in checkpoint mutants proceeding S phase being exposed DNA-damaging agent. Interestingly, chromatin immunoprecipitation (ChIP) on chip analyses revealed non-canonical chromosomal localization of Rad52 in the HU-treated rad53-K227A cells arrested in early S phase: Rad52 localization at dormant and early DNA replication origins. However, such unusual localization was not dependent on the sumoylation of Rad52. In addition, we also found that Rad52 could be highly sumoylated in the absence of Rad51. Double mutation of RAD51 and RAD53 exhibited the similar levels of Rad52 sumoylation to RAD53 single mutation. The significance and regulation mechanism of Rad52 sumoylation by checkpoint pathways will be discussed.     

The Rad52-Rad59 complex interacts with Rad51 and replication protein A

The RAD52 gene is essential for homology-dependent repair of double-strand breaks in Saccharomyces cerevisiae. Rad52 forms complexes with Rad51, replication protein A (RPA) or Rad59 and its presence is essential for the formation of Rad51-Rad52-Rad59 and RPA-Rad52-Rad59 complexes. The N-terminal region of Rad52, which is required for self-interaction to form a ring structure, is required for interaction with Rad59. Rad59 also shows self-interaction suggesting the formation of heteromeric and homomeric rings of Rad52 and Rad59. In wild-type cells, we propose the Rad51-Rad52-Rad59 complex is involved in conservative recombination events, including gene conversion and reciprocal recombination, whereas the Rad52-Rad59 complex participates in single-strand annealing.     

Analysis of the essential and excision repair functions of the RAD3 gene of Saccharomyces cerevisiae by mutagenesis.

The RAD3 gene of Saccharomyces cerevisiae, which is involved in excision repair of DNA and is essential for cell viability, was mutagenized by site-specific and random mutagenesis. Site-specific mutagenesis was targeted to two regions near the 5' and 3' ends of the coding region, selected on the basis of amino acid sequence homology with known nucleotide binding and with known specific DNA-binding proteins, respectively. Two mutations in the putative nucleotide-binding region and one in the putative DNA-binding region inactivate the excision repair function of the gene, but not the essential function. A gene encoding two tandem mutations in the putative DNA-binding region is defective in both excision repair and essential functions of RAD3. Seven plasmids were isolated following random mutagenesis with hydroxylamine. Mutations in six of these plasmids were identified by gap repair of mutant plasmids from the chromosome of strains with previously mapped rad3 mutations, followed by DNA sequencing. Three of these contain missense mutations which inactivate only the excision repair function. The other three carry nonsense mutations which inactivate both the excision repair and essential functions. Collectively our results indicate that the RAD3 excision repair function is more sensitive to inactivation than is the essential function. Overexpression of wild-type Rad3 protein and a number of rad3 mutant proteins did not affect the UV resistance of wild-type yeast cells. However, overexpression of Rad3-2 protein rendered wild-type cells partially UV sensitive, indicating that excess Rad3-2 protein is dominant to the wild-type form. These and other results suggest that Rad3-2 protein retains its affinity for damaged DNA or other substrates, but is not catalytically active in excision repair.     

Differential effects of Rad52p overexpression on gene targeting and extrachromosomal homologous recombination in a human cell line

Overexpression of the RAD52 epistasis group of gene products is a convenient way to investigate their in vivo roles in homologous recombination (HR) and DNA repair. Overexpression has the further attraction that any associated stimulation of HR may facilitate gene-targeting applications. Rad51p or Rad52p overexpression in mammalian cells have previously been shown to enhance some forms of HR and resistance to ionising radiation, but the effects of Rad52p overexpression on gene targeting have not been tested. Here we show that Rad52p overexpression inhibits gene targeting while stimulating extrachromosomal HR. We also find that Rad52p overexpression affects cell-cycle distribution, impairs cell survival and is lost during extensive passaging. Therefore, we suggest that excess Rad52p can inhibit the essential RAD51-dependent pathways of HR most likely to be responsible for gene targeting, while at the same time stimulating the RAD51-independent pathway thought to be responsible for extrachromosomal HR. The data also argue against Rad52p overexpression as a means of promoting gene targeting, and highlight the limitations of using a single HR assay to assess the overall status of HR.     

DNA annealing mediated by Rad52 and Rad59 proteins

In the budding yeast Saccharomyces cerevisiae, the RAD52 gene is essential for all homologous recombination events and its homologue, the RAD59 gene, is important for those that occur independently of RAD51. Both Rad52 and Rad59 proteins can anneal complementary single-stranded (ss) DNA. We quantitatively examined the ssDNA annealing activity of Rad52 and Rad59 proteins and found significant differences in their biochemical properties. First, and most importantly, they differ in their ability to anneal ssDNA that is complexed with replication protein A (RPA). Rad52 can anneal an RPA-ssDNA complex, but Rad59 cannot. Second, Rad59-promoted DNA annealing follows first-order reaction kinetics, whereas Rad52-promoted annealing follows second-order reaction kinetics. Last, Rad59 enhances Rad52-mediated DNA annealing at increased NaCl concentrations, both in the absence and presence of RPA. These results suggest that Rad59 performs different functions in the recombination process, and should be more accurately viewed as a Rad52 paralogue.     

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.     

Rad51p and Rad54p,but not Rad52p,elevate gene repair in Saccharomyces cerevisiae directed by modified single-stranded oligonucleotide vectors

Synthetic single-stranded DNA vectors have been used to correct point and frameshift mutations in episomal or chromosomal targets in the yeast Saccharomyces cerevisiae. Certain parameters, such as the length of the vector and the genetic background of the organism, have a significant impact on the process of targeted gene repair, and point mutations are corrected at a higher frequency than frameshift mutations. Genetic analyses reveal that expression levels of the recombination/repair genes RAD51, RAD52 and RAD54 can affect the frequency of gene repair. Overexpression of RAD51 enhances the frequency 4-fold for correction of an episomal target and 5-fold for correction of a chromosomal target; overexpression of RAD54 is also effective in stimulating gene repair, to the same extent as RAD51 in the chromosomal target. In sharp contrast, RAD52 gene expression serves to reduce gene repair activity in rescue experiments and in experiments where RAD52 is overexpressed in a wild-type strain. This may suggest an antagonist role for Rad52p. Consistent with this notion, the highest level of targeted repair occurs when the RAD51 gene is overexpressed in a strain of yeast deficient in RAD52 gene function.     

Studies of the Interaction between Rad52 Protein and the Yeast Single-Stranded DNA Binding Protein RPA

The RFA1 gene encodes the large subunit of the yeast trimeric single-stranded DNA binding protein replication protein A (RPA), which is known to play a critical role in DNA replication. A Saccharomyces cerevisiae strain carrying the rfa1-44 allele displays a number of impaired recombination and repair phenotypes, all of which are suppressible by overexpression of RAD52. We demonstrate that a rad52 mutation is epistatic to the rfa1-44 mutation, placing RFA1 and RAD52 in the same genetic pathway. Furthermore, two-hybrid analysis indicates the existence of interactions between Rad52 and all three subunits of RPA. The nature of this Rad52-RPA interaction was further explored by using two different mutant alleles of rad52. Both mutations lie in the amino terminus of Rad52, a region previously defined as being responsible for its DNA binding ability (U. H. Mortenson, C. Beudixen, I. Sunjeuaric, and R. Rothstein, Proc. Natl. Acad. Sci. USA 93:10729–10734, 1996). The yeast two-hybrid system was used to monitor the protein-protein interactions of the mutant Rad52 proteins. Both of the mutant proteins are capable of self-interaction but are unable to interact with Rad51. The mutant proteins also lack the ability to interact with the large subunit of RPA, Rfa1. Interestingly, they retain their ability to interact with the medium-sized subunit, Rfa2. Given the location of the mutations in the DNA binding domain of Rad52, a model incorporating the role of DNA in the protein-protein interactions involved in the repair of DNA double-strand breaks is presented.     

Ionizing radiation-induced foci formation of mammalian Rad51 and Rad54 depends on the Rad51 paralogs, but not on Rad52

Homologous recombination is of major importance for the prevention of genomic instability during chromosome duplication and repair of DNA damage, especially double-strand breaks. Biochemical experiments have revealed that during the process of homologous recombination the RAD52 group proteins, including Rad51, Rad52 and Rad54, are involved in an essential step: formation of a joint molecule between the broken DNA and the intact repair template. Accessory proteins for this reaction include the Rad51 paralogs and BRCA2. The significance of homologous recombination for the cell is underscored by the evolutionary conservation of the Rad51, Rad52 and Rad54 proteins from yeast to humans. Upon treatment of cells with ionizing radiation, the RAD52 group proteins accumulate at the sites of DNA damage into so-called foci. For the yeast Saccharomyces cerevisiae, foci formation of Rad51 and Rad54 is abrogated in the absence of Rad52, while Rad51 foci formation does occur in the absence of the Rad51 paralog Rad55. By contrast, we show here that in mammalian cells, Rad52 is not required for foci formation of Rad51 and Rad54. Furthermore, radiation-induced foci formation of Rad51 and Rad54 is impaired in all Rad51 paralog and BRCA2 mutant cell lines tested, while Rad52 foci formation is not influenced by a mutation in any of these recombination proteins. Despite their evolutionary conservation and biochemical similarities, S. cerevisiae and mammalian Rad52 appear to differentially contribute to the DNA-damage response.     

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.     

Functional differences and interactions among the putative RecA homologs Rad51, Rad55, and Rad57.

The genes of the Saccharomyces cerevisiae RAD52 epistasis group are required for the repair of ionizing radiation-induced DNA damage. Three of these genes, RAD51, RAD55, and RAD57, have been identified as putative RecA homologs. An important feature of RecA is its ability to bind and hydrolyze ATP. RAD55 and RAD57 contain putative nucleotide binding motifs, and the importance of these motifs was determined by constructing site-directed mutations of the conserved lysine residue within the Walker A-box. Changing the lysine residue to arginine or alanine resulted in a mutant phenotype in DNA repair and sporulation for Rad55 but not for Rad57. Protein-protein interactions among Rad51, Rad55, and Rad57 were tested for by the two-hybrid system. Rad55 was shown to interact with Rad51 and Rad57 but not with itself. Additionally, no interaction between Rad57 and Rad51 or between Rad57 and itself was detected. Consistent with the hypothesis that Rad55 and Rad57 may function within, or stabilize, a protein complex, we found that RAD51 expressed from a high-copy-number plasmid suppresses the DNA repair defect of strains carrying rad55 and rad57 mutations. These data, in conjunction with other reports, demonstrate the importance of protein-protein interactions in the process of DNA repair.     

Regulation of ionizing radiation-induced Rad52 nuclear foci formation by c-Abl-mediated phosphorylation

The RAD52 epistasis group of proteins, including Rad51, Rad52, and Rad54, plays an important role in the homologous recombination repair of double strand breaks. A well characterized feature associated with the ability of these proteins to repair double strand breaks is inducible nuclear foci formation at the sites of damage. How the process is functionally regulated in response to DNA damage, however, remains elusive. We show here that c-Abl tyrosine kinase associates with and phosphorylates Rad52 on tyrosine 104. Importantly, the very same site of Rad52 is phosphorylated on exposure of cells to ionizing radiation (IR). The functional significance of c-Abl-dependent phosphorylation of Rad52 is underscored by our findings that cells that express the phosphorylation-resistant Rad52 mutant, in which tyrosine 104 is replaced by phenylalanine, exhibit compromised nuclear foci formation in response to IR. Furthermore, IR-induced Rad52 nuclear foci formation is markedly suppressed by the expression of dominant-negative c-Abl. Together our data support a mode of post-translational regulation of Rad52 mediated by the c-Abl tyrosine kinase.     

Requirement of RAD52 group genes for postreplication repair of UV-damaged DNA in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, replication through DNA lesions is promoted by Rad6-Rad18-dependent processes that include translesion synthesis by DNA polymerases eta and zeta and a Rad5-Mms2-Ubc13-controlled postreplicational repair (PRR) pathway which repairs the discontinuities in the newly synthesized DNA that form opposite from DNA lesions on the template strand. Here, we examine the contributions of the RAD51, RAD52, and RAD54 genes and of the RAD50 and XRS2 genes to the PRR of UV-damaged DNA. We find that deletions of the RAD51, RAD52, and RAD54 genes impair the efficiency of PRR and that almost all of the PRR is inhibited in the absence of both Rad5 and Rad52. We suggest a role for the Rad5 pathway when the lesion is located on the leading strand template and for the Rad52 pathway when the lesion is located on the lagging strand template. We surmise that both of these pathways operate in a nonrecombinational manner, Rad5 by mediating replication fork regression and template switching via its DNA helicase activity and Rad52 via a synthesis-dependent strand annealing mode. In addition, our results suggest a role for the Rad50 and Xrs2 proteins and thereby for the MRX complex in promoting PRR via both the Rad5 and Rad52 pathways.