Over-expression of the NUD1-coded endo-exonuclease in Saccharomyces cerevisiae enhances DNA recombination and repair

  The NUD1(=NUC2) gene of Saccharomyces cerevisiae has been subcloned and over-expressed in multi-copy plasmids. Enhanced expression of this nuclear endo-exonuclease gene was confirmed by Northern hybridization (>10-fold increase), and increased enzymatic activity (2.4-fold increase) was demonstrated by direct immunological assay using antibody raised against the purified Neurospora crassa endo-exonuclease. We found that increased expression of NUD1 was associated with an increase in cell surivival after irradiation treatment with gamma rays, and an increase in radiation-induced mitotic recombination frequencies between duplicated gene sequences. The results presented here are consistent with previous biochemical data and confirm a role for the NUD1 gene product in recombination/repair processes. Received: 10 November 1995 / 16 January 1996     

The use of a double-marker shuttle vector to study DNA double-strand break repair in wild-type and radiation-sensitive mutants of the yeast Saccharomyces cerevisiae

An episomal DNA vector (YpJA18), encoding two selectable recombinant yeast genes (TRP1, URA3), was constructed to assess the fidelity of DNA repair in haploid repair-competent (RAD) wild-type yeast and several radiation-sensitive mutants. Either a DNA double-strand break (DSB) or a double-strand gap of 169 bp (DSG) was introduced by restriction enzymes in-vitro within the coding sequence of the URA3 gene of this vector. To eliminate transfer artefacts, selection was first applied for the undamaged TRP1 gene followed by counter selection for URA3 gene activity, which indicated correct repair of the DSB and DSG. Correct repair of the damaged URA3 gene was found to be about 90% in RAD cells (normalized for the expression of undamaged URA3 in TRP ⁺ transformants). Plasmids isolated from the transformants (URA ⁺ TRP ⁺) carry both unique sites (ApaI and NcoI) within the URA3 gene indicating the precise restitution of the 169-bp gap. An excision-repair-defective rad4-4 mutant repaired these lesions as correctly as RAD cells, whereas the mutants rad50-1, rad51-1 and rad54-1, proven to be defective in DSB repair and mitotic recombination, showed less than 5% correct repair of such lesions. In contrast, a representative of the RAD6 epistasis group of genes, the rev2-1 mutant which is sensitive towards UV and ionizing radiation, had a significantly reduced ability (about 20%) for the correct repair of both DSBs and DSGs.     

A rapid method to monitor repair and mis-repair of DNA double-strand breaks by using cell extracts of the yeast Saccharomyces cerevisiae

We present a rapid in vitro method to scan the repair of DNA double-strand breaks (DSBs). A DSB was introduced at the EcoRI site within the lacZ gene of the plasmid pUC18 and the plasmid was exposed to cellular extracts from a wild-type repair-competent (RAD) and a mutant (rad52Δ) strain of the yeast Saccharomyces cerevisiae. The fidelity of rejoining was determined by the expression of the lacZ gene after bacterial transformation with the treated plasmid. A cellular extract from the yeast S. cerevisiae was found to be capable of rejoining DNA DSBs. Breaks at the EcoRI site were rejoined by extracts from both wild-type and mutant strains to form circular plasmids with almost equal efficiency. However, the fidelity of rejoining was lower for the rad52Δ extract than for normal wild-type. Received: 2 September /2 November 1997     

Genetic control of plasmid DNA double-strand gap repair in yeast,Saccharomyces cerevisiae

Summary The repair of double-strand gaps (DSGs) in the plasmid DNA of radiosensitive mutants of Saccharomyces cerevisiae has been analyzed. The proportion of repair events that resulted in complete plasmid DNA DSG recovery was close to 100% in Rad⁺ cells. Mutation rad55 does not influence the efficiency and preciseness of DSG repair. The mutant rad57, which is capable of recombinational DNA DSB repair, resulted in no DSG recovery. Mutation rad53 substantially inhibits the efficiency of DSG repair but does not influence the precision of repair. Plasmid DNA DSG repair is completely blocked by mutations rad50 and rad54.     

Evidence that an endo-exonuclease controlled by the NUC2 gene functions in the induction of ‘petite’ mutations in Saccharomyces cerevisiae

Summary Defects in the RAD52 gene of the yeast Saccharomyces cerevisiae reduce the levels of the NUC2 endo-exonuclease by approximately 90% compared to the levels in wild-type strains. To examine the potential role of this nuclease in the induction of mitochondrial petite mutations, congenic RAD52 and rad52-1 haploids were subjected to treatment with ethidium bromide, a well-known inducer of these mutations. The rad52 strain showed a much higher resistance to ethidium bromide-induced petite formation than the corresponding wild-type strain. Two approaches were taken to confirm that this finding reflected the nuclease deficiency, and not some other effect attributable to the rad52-1 mutation. First, a multicopy plasmid (YEp213-10) carrying NUC2 was transformed into a RAD52 strain. This resulted in an increased fraction of spontaneous petite mutations relative to that seen for the same strain without the plasmid and sensitized the strain carrying the plasmid to peptite induction by ethidium bromide treatment. Second, a strain having a nuc2 allele that encodes a temperaturesensitive nuclease was treated with ethidium bromide at the restrictive and permissive temperatures. Petite induction was reduced under restrictive conditions. Enzyme assays revealed that the RAD52 (YEp213-10) strain had the highest level of antibody-precipitable NUC2 endo-exonuclease whereas the nuc2 and rad52 mutants had the lowest levels. Furthermore, addition of ethidium bromide to the reaction mixture stimulated the activity of the nuclease on double-stranded DNA. Peptite induction by antifolate-mediated thymine nucleotide depletion was also inhibited by inactivation of RAD52 indicating that the effect of reduced NUC2 endo-exonuclease was not restricted to ethidium bromide treatment. Taken collectively, these results indicate that the NUC2 gene product functions in the production of mitochondrial petite mutations.     

Mating-type suppression of the DNA-repair defect of the yeast rad6Δ mutation requires the activity of genes in the RAD52 epistasis group

The RAD6 gene of Saccharomyces cerevisiae is required for post-replication repair of UV-damaged DNA, UV mutagenesis, and sporulation. Here, we show that the radiation sensitivity of a MAT a rad6 strain can be suppressed by the MAT2 gene carried on a multicopy plasmid. The a1-2 suppression is specific to the RAD6 pathway, as mutations in genes required for nucleotide excision repair or for recombinational repair do not show such mating-type suppression. The a1-2 suppression of the rad6 mutation requires the activity of the RAD52 group of genes, suggesting that suppression occurs by channelling of post-replication gaps present in the rad6 mutant into the RAD52 recombinational repair pathway. The a1-2 repressor could mediate this suppression via an enhancement in the expression, or the activity, of recombination genes.     

Repair of gamma ray-induced S1 nuclease hypersensitive sites in yeast depends on homologous mitotic recombination and a RAD18-dependent function

Summary Repair under non-growth conditions of DNA double-strand breaks (DSB) and chromatin sites sensitive to S1 endonuclease (SSS) induced by ⁶⁰Cobalt-gamma rays were monitored in repair-competent and deficient strains of Saccharomyces cerevisiae by pulsed field gelelectrophoresis. In stationary-phase cells of a repair-competent RAD diploid, and an excision-deficient rad3-2 diploid, SSS are repaired as efficiently as DSB, whereas in a repair-competent RAD haploid, and a rad 50-1 diploid, neither SSS nor DSB are repaired. The rad18-2 diploid repairs DSB well but is defective in SSS repair. Obviously, SSS repair in yeast chromatin, like DSB repair, depends on recombination, but unlike DSB repair depends additionally on RAD18 function.     

The repair of DNA methylation damage in Saccharomyces cerevisiae

 The major genotoxicity of methyl methanesulfonate (MMS) is due to the production of a lethal 3-methyladenine (3MeA) lesion. An alkylation-specific base-excision repair pathway in yeast is initiated by a Mag1 3MeA DNA glycosylase that removes the damaged base, followed by an Apn1 apurinic/ apyrimidinic endonuclease that cleaves the DNA strand at the abasic site for subsequent repair. MMS is also regarded as a radiomimetic agent, since a number of DNA radiation-repair mutants are also sensitive to MMS. To understand how these radiation-repair genes are involved in DNA methylation repair, we performed an epistatic analysis by combining yeast mag1 and apn1 mutations with mutations involved in each of the RAD3, RAD6 and RAD52 groups. We found that cells carrying rad6, rad18, rad50 and rad52 single mutations are far more sensitive to killing by MMS than the mag1 mutant, that double mutants were much more sensitive than either of the corresponding single mutants, and that the effects of the double mutants were either additive or synergistic, suggesting that post-replication and recombination-repair pathways recognize either the same lesions as MAG1 and APN1, or else some differ- ent lesions produced by MMS treatment. Lesions handled by recombination and post replication repair are not simply 3MeA, since over-expression of the MAG1 gene does not offset the loss of these pathways. Based on the above analyses, we discuss possible mechanisms for the repair of methylation damage by various pathways. Received: 13 June/24 July 1996     

Synergism between yeast nucleotide and base excision repair pathways in the protection against DNA methylation damage

The treatment of cells with simple DNA methylating agents such as methyl methanesulfonate (MMS) results in genotoxic lesions, including 3-methyladenine which blocks DNA replication. All the organisms studied to date contain an alkylation-specific base excision repair pathway. In the yeast Saccharomyces cerevisiae, the base excision repair pathway is initiated by a Mag1 3-methyladenine DNA glycosylase that removes the damaged base, followed by the Apn1 apurinic/apyrimidinic endonuclease which cleaves the DNA strand at the abasic site for subsequent repair and synthesis. Several nucleotide excision repair pathway mutants display only slightly increased sensitivity to killing by MMS, indicating that nucleotide excision repair per se does not play a major role in the repair of DNA methylation damage. However, mag1 and apn1 mutants that are also defective in nucleotide excision repair are extremely sensitive to MMS-induced killing and the effects are synergistic. These observations suggest that nucleotide excision repair and alkylation-specific base excision repair provide alternative pathways for the repair of DNA methylation damage. In addition to their role in nucleotide excision repair, Rad1 and Rad10 form a complex that is involved in recombination repair. It was found that the apn1 rad1 and apn1 rad10 double mutants have a growth defect and are significantly more sensitive to MMS killing than apn1 rad2 and apn1 rad4 double mutants in a gradient plate assay. Furthermore, the apn1 rad1 double mutant increased both the spontaneous and MMS-induced mutation frequency. Thus, the recombination repair defects of rad1 and rad10 may confer an additional synergistic effect when combined with the apn1 mutation. Received: 8 September 1997 / 13 November 1997     

Further characterization of the yeastpso4-1 mutant: interaction withrad51 andrad52 mutants after photoinduced psoralen lesions

Thepso4-1 mutant was characterized as deficient in some types of recombination, including gene conversion, crossing over, and intrachromosomal recombination. The mode of interaction betweenpso4-1 andrad51 and betweenpso4-1 andrad52 mutants indicated that thePSO4 gene belongs to theRAD52 epistasis group for strand-break repair. Moreover, the presence of thepso4-1 mutation decreased 8-MOP-photoinduced mutagenesis of therad51 andrad52 mutants. Complementation tests using heterozygous diploid strains showed that thePso4 protein might interact with theRad52 protein during repair of 8-MOP photolesions. Thepso4-1 mutant, even though defective in inter- and intea-chromosomal recombination, conserves the ability for plasmid integration of circular and linear plasmid DNA. On the other hand, similar to therad51 mutant,pso4-1 was able to incise but did not restore high-molecular-weight DNA during the repair of cross links induced by 8-MOP plus UVA. These results, together with those of previous reports, indicate that thePSO4 gene belongs to theRAD52 DNA repair group and its product participates in the DNA rejoining step of the repair of cross-link lesions, which are crucial for induced mutagenesis and recombinogenesis.     

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 ixrl 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 ixrl 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 ixrl 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.     

An in vitro system for measuring genotoxicity mediated by human CYP3A4 in Saccharomyces cerevisiae

P450 activity is required to metabolically activate many chemical carcinogens, rendering them highly genotoxic. CYP3A4 is the most abundantly expressed P450 enzyme in the liver, accounting for most drug metabolism and constituting 50% of all hepatic P450 activity. CYP3A4 is also expressed in extrahepatic tissues, including the intestine. However, the role of CYP3A4 in activating chemical carcinogens into potent genotoxins is unclear. To facilitate efforts to determine whether CYP3A4, per se, can activate carcinogens into potent genotoxins, we expressed human CYP3A4 in the DNA‐repair mutant (rad4 rad51) strain of budding yeast Saccharomyces cerevisiae and tested the novel, recombinant yeast strain for ability to report CYP3A4‐mediated genotoxicity of a well‐known genotoxin, aflatoxin B1 (AFB₁). Yeast microsomes containing human CYP3A4, but not those that do not contain CYP3A4, were active in hydroxylation of diclofenac, a known CYP3A4 substrate drug, a result confirming CYP3A4 activity in the recombinant yeast strain. In cells exposed to AFB₁, the expression of CYP3A4 supported DNA adduct formation, chromosome rearrangements, cell death, and expression of the large subunit of ribonucleotide reductase, Rnr3, a marker of DNA damage. Expression of CYP3A4 also conferred sensitivity in rad4 rad51 mutants exposed to colon carcinogen, 2‐amino‐3,8‐dimethylimidazo[4,5‐f]quinoxaline (MeIQx). These data confirm the ability of human CYP3A4 to mediate the genotoxicity of AFB₁, and illustrate the usefulness of the CYP3A4‐expressing, DNA‐repair mutant yeast strain for screening other chemical compounds that are CYP3A4 substrates, for potential genotoxicity. Environ. Mol. Mutagen. 58:217–227, 2017. © 2017 Wiley Periodicals, Inc.     

Cisplatin-modification of DNA repair and ionizing radiation lethality in yeast,Saccharomyces cerevisiae

Cis-diamminedichloroplatinum II (cisplatin) is a DNA inter- and intrastrand crosslinking agent which can sensitize prokaryotic and eukaryotic cells to killing by ionizing radiation. The mechanism of radiosensitization is unknown but may involve cisplatin inhibition of repair of DNA damage caused by radiation. Repair proficient wild type and repair deficient (rad52, recombinational repair or rad3, excision repair) strains of the yeast Saccharomyces cerevisiae were used to determine whether defects in DNA repair mechanisms would modify the radiosensitizing effect of cisplatin. We report that cisplatin exposure could sensitize yeast cells with a competent recombinational repair mechanism (wild type or rad3), but could not sensitize cells defective in recombinational repair (rad52), indicating that the radiosensitizing effect of cisplatin was due to inhibition of DNA repair processes involving error free RAD52-dependent recombinational repair. The presence or absence of oxygen during irradiation did not alter this radiosensitization. Consistent with this result, cisplatin did not sensitize cells to mutation that results from lesion processing by an error prone DNA repair system. However, under certain circumstances, cisplatin exposure did not cause radiosensitization to killing by radiation in repair competent wild type cells. Within 2 h after a sublethal cisplatin treatment, wild type yeast cells became both thermally tolerant and radiation resistant. Cisplatin pretreatment also suppressed mutations caused by exposure to N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), a response previously shown in wild type yeast cells following radiation pretreatment. Like radiation, the cisplatin-induced stress response did not confer radiation resistance or suppress MNNG mutations in a recombinational repair deficient mutant (rad52), although thermal tolerance was still induced. These results support the idea that cisplatin adducts in DNA interfere with RAD52-dependent recombinational repair and thereby sensitize cells to killing by radiation. However, the lesions can subsequently induce a general stress response, part of which is induction of RAD52-dependent error free recombinational repair. This stress response confers radiation resistance, thermal tolerance, and mutation resistance in yeast.     

��3, a transposable element that promotes host sexual reproduction

Theoretical models predict that selfish DNA elements require host sex to persist in a population. Therefore, a transposon that induces sex would strongly favor its own spread. We demonstrate that a protein homologous to transposases, called α3, was essential for mating type switch in Kluyveromyces lactis. Mutational analysis showed that amino acids conserved among transposases were essential for its function. During switching, sequences in the 5′ and 3′ flanking regions of the α3 gene were joined, forming a DNA circle, showing that α3 mobilized from the genome. The sequences encompassing the α3 gene circle junctions in the mating type α (MATα) locus were essential for switching from MATα to MATa, suggesting that α3 mobilization was a coupled event. Switching also required a DNA-binding protein, Mating type switch 1 (Mts1), whose binding sites in MATα were important. Expression of Mts1 was repressed in MATa/MATα diploids and by nutrients, limiting switching to haploids in low-nutrient conditions. A hairpin-capped DNA double-strand break (DSB) was observed in the MATa locus in mre11 mutant strains, indicating that mating type switch was induced by MAT-specific DSBs. This study provides empirical evidence for selfish DNA promoting host sexual reproduction by mediating mating type switch.     

Characterization of the role played by the RAD59 gene of Saccharomyces cerevisiae in ectopic recombination

The RAD52 group of genes in the yeast Saccharomyces cerevisiae controls the repair of DNA damage by a recombinational mechanism. Despite the growing evidence for physical and biochemical interactions between the proteins of this repair group, mutations in individual genes show very different effects on various types of recombination. The RAD59 gene encodes a protein with similarity to Rad52p which plays a role in the repair of damage caused by ionizing radiation. In the present study we have examined the role played by the Rad59 protein in mitotic ectopic recombination and analyzed the genetic interactions with other members of the repair group. We found that Rad59p plays a role in ectopic gene conversion that depends on the presence of Rad52p but is independent of the function of the RecA homologue Rad51p and of the Rad57 protein. The RAD59 gene product also participates in the RAD1-dependent pathway of recombination between direct repeats. We propose that Rad59p may act in a salvage mechanism that operates when the Rad51 filament is not functional. Received: 3 February / 22 April 1999     

Identification of the heterothallic mutation in HO-endonuclease of S. cerevisiae using HO/ho chimeric genes

HO-endonuclease initiates a mating-type switch in the yeast S. cerevisiae by making a doublestrand cleavage in the DNA of the mating-type gene, MAT. Heterothallic strains of yeast have a stable mating type and contain a recessive ho allele. Here we report the sequence of the ho allele; ho has four point mutations all of which encode for substitute amino acids. The fourth mutation is a leucine to histidine substitution within a presumptive zinc finger. Chimeric HO/ho genes were constructed in vivo by converting different parts of the sequence of the genomic ho allele to the HO sequence by gene conversion. HO activity was assessed by three bioassays: a mating-type switch, extinction of expression of an a-specific reporter gene, and the appearance of Can^r Ade^- papillae resulting from excision of an engineered Ty element containing the HO-endonuclease target site and a SUP4 ^o gene. We found that the replacement of the fourth point mutation in ho to the HO sequence restored HO activity to the chimeric endonuclease.     

Recombination initiated by double-strand breaks

The HO endonuclease was used to introduce a site-specific double-strand break (DSB) in an interval designed to monitor mitotic recombination. The interval included the trp1 and his3 genes inserted into chromosome III of S. cerevisiae between the CRY1 and MAT loci. Mitotic recombination was monitored in a diploid carrying heteroalleles of trp1 and his3. The normal recognition sites for the HO endonuclease were mutated at the MAT alleles and a synthetic recognition site for HO endonuclease was placed between trp1 and his3 on one of the chromosomes. HO-induced cleavage resulted in efficient recombination in this interval. Most of the data can be explained by double-strand gap repair in which the cut chromosome acts as the recipient. However, analysis of some of the recombinants indicates that regions of heteroduplex were generated flanking the site of the cut, and that some recombinants were the result of the cut chromosome acting as the genetic donor.By acceptance of this article, the publisher or recipient acknowledges the right of the U.S. Government and its agents and contractors to retain a nonexclusive, royalty-free license in and to any copyright covering the article     

Genetic analysis reveals different roles of Schizosaccharomyces pombe sfr1/dds20 in meiotic and mitotic DNA recombination and repair

DNA double-strand break (DSB) repair mediated by the Rad51 pathway of homologous recombination is conserved in eukaryotes. In yeast, Rad51 paralogs, Saccharomyces cerevisiae Rad55-Rad57 and Schizosaccharomyces pombe Rhp55-Rhp57, are mediators of Rad51 nucleoprotein formation. The recently discovered S. pombe Sfr1/Dds20 protein has been shown to interact with Rad51 and to operate in the Rad51-dependent DSB repair pathway in parallel to the paralog-mediated pathway. Here we show that Sfr1 is a nuclear protein and acts downstream of Rad50 in DSB processing. sfr1Delta is epistatic to rad18 (-) and rad60 (-), and Sfr1 is a high-copy suppressor of the replication and repair defects of a rad60 mutant. Sfr1 functions in a Cds1-independent UV damage tolerance mechanism. In contrast to mitotic recombination, meiotic recombination is significantly reduced in sfr1Delta strains. Our data indicate that Sfr1 acts in DSB repair mainly outside of S-phase, and is required for wild-type levels of meiotic recombination. We suggest that Sfr1 acts early in recombination and has a specific role in Rad51 filament assembly, distinct from that of the Rad51 paralogs.     

Repair of ultraviolet light damage in Saccharomyces cerevisiae as studied with double- and single-stranded incoming DNAs

Summary Purified double- and single-stranded DNAs of the autonomously replicating vector M13RK9-T were irradiated with ultraviolet light (UV) in vitro and introduced into competent whole cells of Saccharomyces cerevisiae. Incoming double-stranded DNA was more sensitive to UV in excision repair-deficient rad2-1 cells than in proficient repair RAD ⁺ cells, while single-stranded DNA exhibited high sensitivity in both host cells. The results indicate that in yeast there is no effective rescue of UV-incoming single-stranded DNA by excision repair or other constitutive dark repair processes.     

Robust immunoglobulin class switch recombination and end joining in Parp9‐deficient mice

To mount highly specific and adapted immune responses, B lymphocytes assemble and diversify their antibody repertoire through mechanisms involving the formation of programmed DNA damage. Immunoglobulin class switch recombination (CSR) is triggered by DNA lesions induced by activation‐induced cytidine deaminase, which are processed to double‐stranded DNA break (DSB) intermediates. These DSBs activate the cellular DNA damage response and enroll numerous DNA repair factors, involving poly(ADP‐ribose) polymerases Parp1, Parp2, and Parp3 to promote appropriate DNA repair and efficient long‐range recombination. The macroParp Parp9, which is overexpressed in certain lymphomas, has been recently implicated in DSB repair, acting together with Parp1. Here, we examine the contribution of Parp9 to the resolution of physiological DSBs incurred during V(D)J recombination and CSR by generating Parp9^?/? mice. We find that Parp9‐ deficient mice are viable, fertile, and do not show any overt phenotype. Moreover, we find that Parp9 is dispensable for B‐cell development. Finally, we show that CSR and DNA end‐joining are robust in the absence of Parp9, indicating that Parp9 is not essential in vivo to achieve physiological DSB repair, or that strong compensatory mechanisms exist.