Purification of Rad1 protein from Saccharomyces cerevisiae and further characterization of the Rad1/Rad10 endonuclease complex

DNA repair mechanisms and the bypass of DNA damage in Saccharomyces cerevisiae

DNA repair mechanisms are critical for maintaining the integrity of genomic DNA, and their loss is associated with cancer predisposition syndromes. Studies in Saccharomyces cerevisiae have played a central role in elucidating the highly conserved mechanisms that promote eukaryotic genome stability. This review will focus on repair mechanisms that involve excision of a single strand from duplex DNA with the intact, complementary strand serving as a template to fill the resulting gap. These mechanisms are of two general types: those that remove damage from DNA and those that repair errors made during DNA synthesis. The major DNA-damage repair pathways are base excision repair and nucleotide excision repair, which, in the most simple terms, are distinguished by the extent of single-strand DNA removed together with the lesion. Mistakes made by DNA polymerases are corrected by the mismatch repair pathway, which also corrects mismatches generated when single strands of non-identical duplexes are exchanged during homologous recombination. In addition to the true repair pathways, the postreplication repair pathway allows lesions or structural aberrations that block replicative DNA polymerases to be tolerated. There are two bypass mechanisms: an error-free mechanism that involves a switch to an undamaged template for synthesis past the lesion and an error-prone mechanism that utilizes specialized translesion synthesis DNA polymerases to directly synthesize DNA across the lesion. A high level of functional redundancy exists among the pathways that deal with lesions, which minimizes the detrimental effects of endogenous and exogenous DNA damage.

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.

Msh2 blocks an alternative mechanism for non-homologous tail removal during single-strand annealing in Saccharomyces cerevisiae

Chromosomal translocations are frequently observed in cells exposed to agents that cause DNA double-strand breaks (DSBs), such as ionizing radiation and chemotherapeutic drugs, and are often associated with tumors in mammals. Recently, translocation formation in the budding yeast, Saccharomyces cerevisiae, has been found to occur at high frequencies following the creation of multiple DSBs adjacent to repetitive sequences on non-homologous chromosomes. The genetic control of translocation formation and the chromosome complements of the clones that contain translocations suggest that translocation formation occurs by single-strand annealing (SSA). Among the factors important for translocation formation by SSA is the central mismatch repair (MMR) and homologous recombination (HR) factor, Msh2. Here we describe the effects of several msh2 missense mutations on translocation formation that suggest that Msh2 has separable functions in stabilizing annealed single strands, and removing non-homologous sequences from their ends. Additionally, interactions between the msh2 alleles and a null allele of RAD1, which encodes a subunit of a nuclease critical for the removal of non-homologous tails suggest that Msh2 blocks an alternative mechanism for removing these sequences. These results suggest that Msh2 plays multiple roles in the formation of chromosomal translocations following acute levels of DNA damage.

Multiple pathways of recombination induced by double-strand breaks in Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae has been the principal organism used in experiments to examine genetic recombination in eukaryotes. Studies over the past decade have shown that meiotic recombination and probably most mitotic recombination arise from the repair of double-strand breaks (DSBs). There are multiple pathways by which such DSBs can be repaired, including several homologous recombination pathways and still other nonhomologous mechanisms. Our understanding has also been greatly enriched by the characterization of many proteins involved in recombination and by insights that link aspects of DNA repair to chromosome replication. New molecular models of DSB-induced gene conversion are presented. This review encompasses these different aspects of DSB-induced recombination in Saccharomyces and attempts to relate genetic, molecular biological, and biochemical studies of the processes of DNA repair and recombination.

Pokeweed antiviral protein cleaves double-stranded supercoiled DNA using the same active site required to depurinate rRNA

Ribosome-inactivating proteins (RIPs) are N-glycosylases that remove a specific adenine from the sarcin/ricin loop of the large rRNA in a manner analogous to N-glycosylases that are involved in DNA repair. Some RIPs have been reported to remove adenines from single-stranded DNA and cleave double-stranded supercoiled DNA. The molecular basis for the activity of RIPs on double-stranded DNA is not known. Pokeweed antiviral protein (PAP), a single-chain RIP from Phytolacca americana, cleaves supercoiled DNA into relaxed and linear forms. Double-stranded DNA treated with PAP contains apurinic/apyrimidinic (AP) sites due to the removal of adenine. Using an active-site mutant of PAP (PAPx) which does not depurinate rRNA, we present evidence that double-stranded DNA treated with PAPx does not contain AP sites and is not cleaved. These results demonstrate for the first time that PAP cleaves supercoiled double-stranded DNA using the same active site that is required for depurination of rRNA.

Removal of one nonhomologous DNA end during gene conversion by a RAD1- and MSH2-independent pathway

Repair of a double-strand break (DSB) by homologous recombination depends on the invasion of a 3'-ended strand into an intact template sequence to initiate new DNA synthesis. When the end of the invading DNA is not homologous to the donor, the nonhomologous sequences must be removed before new synthesis can begin. In Saccharomyces cerevisiae, the removal of these ends depends on both the nucleotide excision repair endonuclease Rad1p/Rad10p and the mismatch repair proteins Msh2p/Msh3p. In rad1 or msh2 mutants, when both ends of the DSB have nonhomologous ends, repair is reduced approximately 90-fold compared to a plasmid with perfect ends; however, with only one nonhomologous end, repair is reduced on average only 5-fold. These results suggest that yeast has an alternative, but less efficient, way to remove a nonhomologous tail from the second end participating in gene conversion. When the removal of one nonhomologous end is impaired in rad1 and msh2 mutants, there is also a 1-hr delay in the appearance of crossover products of gene conversion, compared to noncrossovers. We interpret these results in terms of the formation and resolution of alternative intermediates of a synthesis-dependent strand annealing mechanism.

Affinity purification and partial characterization of a yeast multiprotein complex for nucleotide excision repair using histidine-tagged Rad14 protein

The nucleotide excision repair (NER) pathway of eukaryotes involves approximately 30 polypeptides. Reconstitution of this pathway with purified components is consistent with the sequential assembly of NER proteins at the DNA lesion. However, recent studies have suggested that NER proteins may be pre-assembled in a high molecular weight complex in the absence of DNA damage. To examine this model further, we have constructed a histidine-tagged version of the yeast DNA damage recognition protein Rad14. Affinity purification of this protein from yeast nuclear extracts resulted in the co-purification of Rad1, Rad7, Rad10, Rad16, Rad23, RPA, RPB1, and TFIIH proteins, whereas none of these proteins bound to the affinity resin in the absence of recombinant Rad14. Furthermore, many of the co-purifying proteins were present in approximately equimolar amounts. Co-elution of these proteins was also observed when the nuclear extract was fractionated by gel filtration, indicating that the NER proteins were associated in a complex with a molecular mass of >1000 kDa prior to affinity chromatography. The affinity purified NER complex catalyzed the incision of UV-irradiated DNA in an ATP-dependent reaction. We conclude that active high molecular weight complexes of NER proteins exist in undamaged yeast cells.

Two distinct DNA ligase activities in mitotic extracts of the yeast Saccharomyces cerevisiae

Four biochemically distinct DNA ligases have been identified in mammalian cells. One of these enzymes, DNA ligase I, is functionally homologous to the DNA ligase encoded by the Saccharomyces cerevisiae CDC9 gene. Cdc9 DNA ligase has been assumed to be the only species of DNA ligase in this organism. In the present study we have identified a second DNA ligase activity in mitotic extracts of S. cerevisiae with chromatographic properties different from Cdc9 DNA ligase, which is the major DNA joining activity. This minor DNA joining activity, which contributes 5-10% of the total cellular DNA joining activity, forms a 90 kDa enzyme-adenylate intermediate which, unlike the Cdc9 enzyme-adenylate intermediate, reacts with an oligo (pdT)/poly (rA) substrate. The levels of the minor DNA joining activity are not altered by mutation or by overexpression of the CDC9 gene. Furthermore, the 90 kDa polypeptide is not recognized by a Cdc9 antiserum. Since this minor species does not appear to be a modified form of Cdc9 DNA ligase, it has been designated as S. cerevisiae DNA ligase II. Based on the similarities in polynucleotide substrate specificity, this enzyme may be the functional homolog of mammalian DNA ligase III or IV.

The importance of the ERCC1/ERCC4[XPF] complex for hypoxic-cell radioresistance does not appear to derive from its participation in the nucleotide excision repair pathway

The repair-deficient mutant rodent cell lines UV20 and UV41, which are defective in the ERCC1/ERCC4[XPF]-mediated 5'-endonuclease activity, are unusually sensitive to gamma-irradiation under hypoxic (but not oxic) conditions. Because this 5'-endonuclease appears to be involved in two distinct (but overlapping) DNA-repair pathways-the nucleotide excision repair pathway and the recombination-dependent pathway for the removal of DNA interstrand cross-links-it is unclear which of these defective activities is responsible for the hypoxic radiosensitivity of UV20 and UV41 cells. Accordingly, we have extended these measurements to the UV5 and UV24 lines which carry mutations in the ERCC2[XPD] and ERCC3[XPB] genes, respectively; both of these genes encode DNA helicases. These two mutants display a sensitivity to ultraviolet light that is similar to that of UV20 and UV41 cells, reflecting their defect in the incision step of the nucleotide excision repair pathway. However, neither UV5 nor UV24 cells are especially cross-sensitive to agents that produce DNA interstrand cross-links, suggesting that the ERCC2 and ERCC3 activities are not crucial for the repair of these lesions. We show that neither UV5 nor UV24 cells exhibit the unusual hypoxic radiosensitivity that characterizes UV20 and UV41 cells. Based on these data and on a comparison of the patterns of cross-sensitivity of these various mutants to other DNA-damaging agents, we conclude that the increased hypoxic radiosensitivity observed in the UV20 and UV41 mutants is due to a defect in the ERCC1/ERCC4-dependent pathway for the repair of DNA cross-links and not in the nucleotide excision repair pathway. The evidence suggests that this sensitivity may be mediated by some type of radiation-induced cross-links, possibly DNA-protein cross-links.

Xeroderma pigmentosum group F caused by a defect in a structure-specific DNA repair endonuclease

Nucleotide excision repair, which is defective in xeroderma pigmentosum (XP), involves incision of a DNA strand on each side of a lesion. We isolated a human gene homologous to yeast Rad1 and found that it corrects the repair defects of XP group F as well as rodent groups 4 and 11. Causative mutations and strongly reduced levels of encoded protein were identified in XP-F patients. The XPF protein was purified from mammalian cells in a tight complex with ERCC1. This complex is a structure-specific endonuclease responsible for the 5' incision during repair. These results demonstrate that the XPF, ERCC4, and ERCC11 genes are equivalent, complete the isolation of the XP genes that form the core nucleotide excision repair system, and solve the catalytic function of the XPF-containing complex.

Mutational analysis of the human nucleotide excision repair gene ERCC1

The human DNA repair protein ERCC1 resides in a complex together with the ERCC4, ERCC11 and XP-F correcting activities, thought to perform the 5' strand incision during nucleotide excision repair (NER). Its yeast counterpart, RAD1-RAD10, has an additional engagement in a mitotic recombination pathway, probably required for repair of DNA cross-links. Mutational analysis revealed that the poorly conserved N-terminal 91 amino acids of ERCC1 are dispensable for both repair functions, in contrast to a deletion of only four residues from the C-terminus. A database search revealed a strongly conserved motif in this C-terminus sharing sequence homology with many DNA break processing proteins, indicating that this part is primarily required for the presumed structure-specific endonuclease activity of ERCC1. Most missense mutations in the central region give rise to an unstable protein (complex). Accordingly, we found that free ERCC1 is very rapidly degraded, suggesting that protein-protein interactions provide stability. Survival experiments show that the removal of cross-links requires less ERCC1 than UV repair. This suggests that the ERCC1-dependent step in cross-link repair occurs outside the context of NER and provides an explanation for the phenotype of the human repair syndrome xeroderma pigmentosum group F.

Identification of functional domains within the RAD1.RAD10 repair and recombination endonuclease of Saccharomyces cerevisiae

Saccharomyces cerevisiae rad1 and rad10 mutants are unable to carry out nucleotide excision repair and are also defective in a mitotic intrachromosomal recombination pathway. The products of these genes are subunits of an endonuclease which recognizes DNA duplex/single-strand junctions and specifically cleaves the 3' single-strand extension at or near the junction. It has been suggested that such junctions arise as a consequence of DNA lesion processing during nucleotide excision repair and the processing of double-strand breaks during intrachromosomal recombination. In this study we show that the RAD1 RAD10 complex also cleaves a more complex junction structure consisting of a duplex with a protruding 3' single-strand branch that resembles putative recombination intermediates in the RAD1 RAD10-mediated single-strand annealing pathway of mitotic recombination. Using monoclonal antibodies, we have identified two regions of RAD1 that are required for the cleavage of duplex/single-strand junctions. These reagents also inhibit nucleotide excision repair in vitro, confirming the essential role of the RAD1 RAD10 endonuclease in this pathway.

The HMG-domain protein Ixr1 blocks excision repair of cisplatin-DNA adducts in yeast

Ixr1 is a yeast HMG-domain protein which binds the major DNA adducts of the antitumor drug cisplatin. Previous work demonstrated that Saccharomyces cerevisiae cells lacking the IXR1 gene were two-fold less sensitive to cisplatin treatment than wild-type cells, and the present investigation reveals a six-fold difference in yeast having a different background. The possibility that the lower cytotoxicity of cisplatin in the ixr1 strain is the result of enhanced repair was investigated in rad1, rad2, rad4, rad6, rad9, rad10, rad14 and rad52 backgrounds. In three of the excision repair mutants, rad2, rad4 and rad14, the differential sensitivity caused by removing the Ixr1 protein was nearly abolished. This result demonstrates that the greater cisplatin resistance in the ixr1 strain is most likely a consequence of excision repair, supporting the theory that Ixr1 and other HMG-domain proteins can block repair of the major cisplatin-DNA adducts in vivo. The differential sensitivity of wild-type cells and those lacking Ixr1 persisted in the rad1 and rad10 strains, however, indicating that these two proteins act at a stage in the excision repair pathway where damage recognition is less critical. A model is proposed to account for these results, which is strongly supported recently identified functional roles for the rad excision repair gene products. A rad52 mutant was more sensitive to cisplatin than the RAD52 parental strain, which reveals that Rad52, a double-strand break repair protein, repairs cisplatin-DNA adducts, probably interstrand cross-links. A rad52 ixr1 strain was less sensitive to cisplatin than the rad52 IXR1 strain, consistent with Ixr1 not blocking repair of cisplatin adducts removed by Rad52 rad6 strains behaved similarly, except they were both substantially more sensitive to cisplatin. Interruption of the RAD9 gene, which is involved in DNA-damage-induced cell cycle arrest, had no affect on cisplatin cytotoxicity.

Role of the Rad1 and Rad10 proteins in nucleotide excision repair and recombination

In Saccharomyces cerevisiae, the RAD1 and RAD10 genes are involved in DNA nucleotide excision repair (NER) and in a pathway of mitotic recombination that occurs between direct repeat DNA sequences. In this paper, we show that purified Rad1 and Rad10 interact with a synthetic bubble structure and incise the DNA at the 5'-side of the centrally unpaired region. When Rad1-Rad10 and purified XPG protein (the human homolog of yeast Rad2 protein) were co-incubated with the DNA substrate, we observed incisions at both ends of the bubble. This reaction mimics the dual incision step in nucleotide excision repair in vivo. In addition, the recent suggestion that Rad1 can act to resolve Holliday junctions (Habraken, Y., Sung, P., Prakash, L., and Prakash, S. (1994) Nature 371, 531-534), explaining the recombination defect observed in rad1 mutants, has been further investigated. However, using proteins purified in two different laboratories we were unable to show any interaction between Rad1 and synthetic Holliday junctions. The role that Rad1-Rad10 plays in recombination is likely to resemble its activity in NER by acting upon partially unpaired DNA intermediates such as those formed by recombination mechanisms involving single-strand DNA annealing.

Partial characterization of the DNA repair protein complex, containing the ERCC1, ERCC4, ERCC11 and XPF correcting activities

The nucleotide excision repair (NER) protein ERCC1 is part of a functional complex, which harbors in addition the repair correcting activities of ERCC4, ERCC11 and human XPF. ERCC1 is not associated with a defect in any of the known human NER disorders: xeroderma pigmentosum, Cockayne's syndrome or trichothiodystrophy. Here we report the partial purification and characterization of the ERCC1 complex. Immunoprecipitation studies tentatively identified a subunit in the complex with an apparent MW of approximately 120 kDa. The complex has affinity for DNA, but no clear preference for ss, ds or UV-damaged DNA substrates. The size of the entire complex determined by non-denaturing gradient gels (approximately 280 kDa) is considerably larger than previously found using size separation on glycerol gradients (approximately 120 kDa). Stable associations of the ERCC1 complex with other known repair factors (XPA, XPC, XPG and TFIIH complex) could not be detected.

Detection and partial purification of a cruciform-resolving activity (X-solvase) from nuclear extracts of mouse B-cells

We have identified a cruciform-resolving enzyme (X-solvase) in nuclear extracts from mouse B-cells, called EMX1, by using an exonuclease-resistant cruciform DNA as a substrate. The cruciform was a 104-nt oligonucleotide that spontaneously adopted a branched conformation with four arms, each arm protected by a terminal loop of five T residues. A ligatable nick was left in one arm. After ligation, the covalently closed substrate was used to follow an 1800-fold purification of the mouse X-solvase (EMX1) from crude nuclear extracts by chromatography on DEAE-cellulose, MonoQ and heparin-Sepharose. The purest fractions containing EMX1 show high specificity for cruciform DNA. The cleavage pattern is indistinguishable from that found in the same substrates after treatment with endonuclease VII from phage T4 or endonuclease X3 from the yeast Saccharomyces cerevisiae. EMX1 and yeast endonuclease X3 were also found to be sensitive to anti-(endonuclease VII) antibodies which inhibited their reactions with cruciform DNAs in vitro.

RAD1 and RAD10, but not other excision repair genes, are required for double-strand break-induced recombination in Saccharomyces cerevisiae

HO endonuclease-induced double-strand breaks (DSBs) in the yeast Saccharomyces cerevisiae can be repaired by the process of gap repair or, alternatively, by single-strand annealing if the site of the break is flanked by directly repeated homologous sequences. We have shown previously (J. Fishman-Lobell and J. E. Haber, Science 258:480-484, 1992) that during the repair of an HO-induced DSB, the excision repair gene RAD1 is needed to remove regions of nonhomology from the DSB ends. In this report, we present evidence that among nine genes involved in nucleotide excision repair, only RAD1 and RAD10 are required for removal of nonhomologous sequences from the DSB ends. rad1 delta and rad10 delta mutants displayed a 20-fold reduction in the ability to execute both gap repair and single-strand annealing pathways of HO-induced recombination. Mutations in RAD2, RAD3, and RAD14 reduced HO-induced recombination by about twofold. We also show that RAD7 and RAD16, which are required to remove UV photodamage from the silent HML, locus, are not required for MAT switching with HML or HMR as a donor. Our results provide a molecular basis for understanding the role of yeast nucleotide excision repair gene and their human homologs in DSB-induced recombination and repair.

Nucleotide excision repair in the yeast Saccharomyces cerevisiae: its relationship to specialized mitotic recombination and RNA polymerase II basal transcription

Nucleotide excision repair (NER) in eukaryotes is a biochemically complex process involving multiple gene products. The budding yeast Saccharomyces cerevisiae is an informative model for this process. Multiple genes and in some cases gene products that are indispensable for NER have been isolated from this organism. Homologues of many of these yeast genes are structurally and functionally conserved in higher organisms, including humans. The yeast Rad1/Rad10 heterodimeric protein complex is an endonuclease that is believed to participate in damage-specific incision of DNA during NER. This endonuclease is also required for specialized types of recombination. The products of the RAD3, SSL2(RAD25) SSL1 and TFB1 genes have dual roles in NER and in RNA polymerase II-dependent basal transcription.

Specific cleavage of model recombination and repair intermediates by the yeast Rad1-Rad10 DNA endonuclease

The RAD1 and RAD10 genes of Saccharomyces cerevisiae are required for both nucleotide excision repair and certain mitotic recombination events. Here, model recombination and repair intermediates were used to show that Rad1-Rad10-mediated cleavage occurs at duplex-single-strand junctions. Moreover, cleavage occurs only on the strand containing the 3' single-stranded tail. Thus, both biochemical and genetic evidence indicate a role for the Rad1-Rad10 complex in the cleavage of specific recombination intermediates. Furthermore, these data suggest that Rad1-Rad10 endonuclease incises DNA 5' to damaged bases during nucleotide excision repair.