Genetic analysis of gamma-ray mutagenesis in yeast. III. Double-mutant strains

Homologous recombination and the repair of DNA double-strand breaks

Homologous recombination enables the cell to access and copy intact DNA sequence information in trans, particularly to repair DNA damage affecting both strands of the double helix. Here, we discuss the DNA transactions and enzymatic activities required for this elegantly orchestrated process in the context of the repair of DNA double-strand breaks in somatic cells. This includes homology search, DNA strand invasion, repair DNA synthesis, and restoration of intact chromosomes. Aspects of DNA topology affecting individual steps are highlighted. Overall, recombination is a dynamic pathway with multiple metastable and reversible intermediates designed to achieve DNA repair with high fidelity.

Ubiquitin signalling in DNA replication and repair

Post-translational modification by ubiquitin is best known for its role in targeting its substrates for regulated degradation. However, non-proteolytic functions of the ubiquitin system, often involving either monoubiquitylation or polyubiquitylation through Lys63-linked chains, have emerged in various cell signalling pathways. These two forms of the ubiquitin signal contribute to three different pathways related to the maintenance of genome integrity that are responsible for the processing of DNA double-strand breaks, the repair of interstrand cross links and the bypass of lesions during DNA replication.

Mating type influences chromosome loss and replicative senescence in telomerase-deficient budding yeast by Dnl4-dependent telomere fusion

As we age, the majority of our cells gradually lose the capacity to divide because of replicative senescence that results from the inability to replicate the ends of chromosomes. The timing of senescence is dependent on the length of telomeric DNA, which elicits a checkpoint signal when critically short. Critically short telomeres also become vulnerable to deleterious rearrangements, end-degradation and telomere-telomere fusions. Here we report a novel role of non-homologous end-joining (NHEJ), a pathway of double-strand break repair in influencing both the kinetics of replicative senescence and the rate of chromosome loss in telomerase-deficient Saccharomyces cerevisiae. In telomerase-deficient cells, the absence of NHEJ delays replicative senescence, decreases loss of viability during senescence, and suppresses senescence-associated chromosome loss and telomere-telomere fusion. Differences in mating-type gene expression in haploid and diploid cells affect NHEJ function, resulting in distinct kinetics of replicative senescence. These results suggest that the differences in the kinetics of replicative senescence in haploid and diploid telomerase-deficient yeast are determined by changes in NHEJ-dependent telomere fusion, perhaps through the initiation of the breakage-fusion-bridge cycle.

DNA damage checkpoints are involved in postreplication repair

Saccharomyces cerevisiae MMS2 encodes a ubiquitin-conjugating enzyme variant, belongs to the error-free branch of the RAD6 postreplication repair (PRR) pathway, and is parallel to the REV3-mediated mutagenesis branch. A mutation in genes of either the MMS2 or the REV3 branch does not result in extreme sensitivity to DNA-damaging agents; however, deletion of both subpathways of PRR results in a synergistic phenotype. Nevertheless, the double mutant is not as sensitive to DNA-damaging agents as a rad6 or rad18 mutant defective in the entire PRR pathway, suggesting the presence of an additional subpathway within PRR. A synthetic lethal screen was employed in the presence of a sublethal dose of a DNA-damaging agent to identify novel genes involved in PRR, which resulted in the isolation of RAD9 as a candidate PRR gene. Epistatic analysis showed that rad9 is synergistic to both mms2 and rev3 with respect to killing by methyl methanesulfonate (MMS), and the triple mutant is nearly as sensitive as the rad18 single mutant. In addition, rad9 rad18 is no more sensitive to MMS than the rad18 single mutant, suggesting that rad9 plays a role within the PRR pathway. Moreover, deletion of RAD9 reduces damage-induced mutagenesis and the mms2 spontaneous and induced mutagenesis is partially dependent on the RAD9 gene. We further demonstrated that the observed synergistic interactions apply to any two members between different branches of PRR and G1/S and G2/M checkpoint genes. These results suggest that a damage checkpoint is essential for tolerance mediated by both the error-free and error-prone branches of PRR.

The RAD6/BRE1 histone modification pathway in Saccharomyces confers radiation resistance through a RAD51-dependent process that is independent of RAD18

We examine ionizing radiation (IR) sensitivity and epistasis relationships of several Saccharomyces mutants affecting post-translational modifications of histones H2B and H3. Mutants bre1Delta, lge1Delta, and rtf1Delta, defective in histone H2B lysine 123 ubiquitination, show IR sensitivity equivalent to that of the dot1Delta mutant that we reported on earlier, consistent with published findings that Dot1p requires H2B K123 ubiquitination to fully methylate histone H3 K79. This implicates progressive K79 methylation rather than mono-methylation in IR resistance. The set2Delta mutant, defective in H3 K36 methylation, shows mild IR sensitivity whereas mutants that abolish H3 K4 methylation resemble wild type. The dot1Delta, bre1Delta, and lge1Delta mutants show epistasis for IR sensitivity. The paf1Delta mutant, also reportedly defective in H2B K123 ubiquitination, confers no sensitivity. The rad6Delta, rad51null, rad50Delta, and rad9Delta mutations are epistatic to bre1Delta and dot1Delta, but rad18Delta and rad5Delta show additivity with bre1Delta, dot1Delta, and each other. The bre1Delta rad18Delta double mutant resembles rad6Delta in sensitivity; thus the role of Rad6p in ubiquitinating H2B accounts for its extra sensitivity compared to rad18Delta. We conclude that IR resistance conferred by BRE1 and DOT1 is mediated through homologous recombinational repair, not postreplication repair, and confirm findings of a G1 checkpoint role for the RAD6/BRE1/DOT1 pathway.

Loss of DNA polymerase zeta causes chromosomal instability in mammalian cells

Rev3L encodes the catalytic subunit of DNA polymerase zeta (pol zeta) in mammalian cells. In yeast, pol zeta helps cells bypass sites of DNA damage that can block replication enzymes. Targeted disruption of the mouse Rev3L gene causes lethality midway through embryonic gestation, and Rev3L-/- mouse embryonic fibroblasts (MEFs) remain in a quiescent state in culture. This suggests that pol zeta may be necessary for tolerance of endogenous DNA damage during normal cell growth. We report the generation of mitotically active Rev3L-/- MEFs on a p53-/- genetic background. Rev3L null MEFs exhibited striking chromosomal instability, with a large increase in translocation frequency. Many complex genetic aberrations were found only in Rev3L null cells. Rev3L null cells had increased chromosome numbers, most commonly near pentaploid, and double minute chromosomes were frequently found. This chromosomal instability associated with loss of a DNA polymerase activity in mammalian cells is similar to the instability associated with loss of homologous recombination capacity. Rev3L null MEFs were also moderately sensitive to mitomycin C, methyl methanesulfonate, and UV and gamma-radiation, indicating that mammalian pol zeta helps cells tolerate diverse types of DNA damage. The increased occurrence of chromosomal translocations in Rev3L-/- MEFs suggests that loss of Rev3L expression could contribute to genome instability during neoplastic transformation and progression.

Multiple roles of Rev3, the catalytic subunit of polzeta in maintaining genome stability in vertebrates

Translesion DNA synthesis (TLS) and homologous DNA recombination (HR) are two major postreplicational repair (PRR) pathways. The REV3 gene of Saccharomyces cerevisiae encodes the catalytic subunit of DNA polymerase zeta, which is involved in mutagenic TLS. To investigate the role of REV3 in vertebrates, we disruped the gene in chicken DT40 cells. REV3(-/-) cells are sensitive to various DNA-damaging agents, including UV, methyl methanesulphonate (MMS), cisplatin and ionizing radiation (IR), consistent with its role in TLS. Interestingly, REV3(-/-) cells showed reduced gene targeting efficiencies and significant increase in the level of chromosomal breaks in the subsequent M phase after IR in the G(2) phase, suggesting the involvement of Rev3 in HR-mediated double-strand break repair. REV3(-/-) cells showed significant increase in sister chromatid exchange events and chromosomal breaks even in the absence of exogenous genotoxic stress. Furthermore, double mutants of REV3 and RAD54, genes involved in HR, are synthetic lethal. In conclusion, Rev3 plays critical roles in PRR, which accounts for survival on naturally occurring endogenous as well as induced damages during replication.

Delineating the requirements for spontaneous DNA damage resistance pathways in genome maintenance and viability in Saccharomyces cerevisiae

Cellular metabolic processes constantly generate reactive species that damage DNA. To counteract this relentless assault, cells have developed multiple pathways to resist damage. The base excision repair (BER) and nucleotide excision repair (NER) pathways remove damage whereas the recombination (REC) and postreplication repair (PRR) pathways bypass the damage, allowing deferred removal. Genetic studies in yeast indicate that these pathways can process a common spontaneous lesion(s), with mutational inactivation of any pathway increasing the burden on the remaining pathways. In this study, we examine the consequences of simultaneously compromising three or more of these pathways. Although the presence of a functional BER pathway alone is able to support haploid growth, retention of the NER, REC, or PRR pathway alone is not, indicating that BER is the key damage resistance pathway in yeast and may be responsible for the removal of the majority of either spontaneous DNA damage or specifically those lesions that are potentially lethal. In the diploid state, functional BER, NER, or REC alone can support growth, while PRR alone is insufficient for growth. In diploids, the presence of PRR alone may confer a lethal mutation load or, alternatively, PRR alone may be insufficient to deal with potentially lethal, replication-blocking lesions.

RAD18 and RAD54 cooperatively contribute to maintenance of genomic stability in vertebrate cells

Translesion DNA synthesis (TLS) and homologous DNA recombination (HR) are two major pathways that account for survival after post-replicational DNA damage. TLS functions by filling gaps on a daughter strand that remain after DNA replication caused by damage on the mother strand, while HR can repair gaps and breaks using the intact sister chromatid as a template. The RAD18 gene, which is conserved from lower eukaryotes to vertebrates, is essential for TLS in Saccharomyces cerevisiae. To investigate the role of RAD18, we disrupted RAD18 by gene targeting in the chicken B-lymphocyte line DT40. RAD18(-/-) cells are sensitive to various DNA-damaging agents including ultraviolet light and the cross-linking agent cisplatin, consistent with its role in TLS. Interestingly, elevated sister chromatid exchange, which reflects HR- mediated post-replicational repair, was observed in RAD18(-/-) cells during the cell cycle. Strikingly, double mutants of RAD18 and RAD54, a gene involved in HR, are synthetic lethal, although the single mutant in either gene can proliferate with nearly normal kinetics. These data suggest that RAD18 plays an essential role in maintaining chromosomal DNA in cooperation with the RAD54-dependent DNA repair pathway.

BRCA2: a genetic risk factor for breast cancer

The identification of the breast cancer susceptibility genes BRCA1 and BRCA2 a few years ago has been greeted with great excitement and has raised hopes that they might illuminate the common mechanisms of this disease. Today we have to recognize that these expectations remain unfulfilled. Mutations in BRCA1 and BRCA2 account only for a relatively small proportion of breast cancers, even within the group of familiar clusters, they seem to be virtually non-existing in sporadic breast cancers. A substantial proportion of familiar breast cancer clusters has failed to provide evidence for an association with mutations in either BRCA1 or BRCA2, thus we have to look forward to the identification of additional breast cancer susceptibility genes. What has been most disappointing is that the mutation status of BRCA1/2 can provide only limited information for cancer risk. Initial assessments had indicated a risk of close to 90% for mutation carriers to develop breast cancer until age 75 - a value that turned out to be restricted to high-risk families in which the BRCA1 and BRCA2 genes had been genomically mapped. In unselected clusters the risk appears much lower, some estimates suggest less than 40%. Both BRCA1 and BRCA2 large encode proteins that appear to have a plethora of functions, with a conspicuous association to DNA repair and DNA recombination, and probably transcription activation. Defects in DNA repair can result in cancer predisposition syndromes and are recognized as being instrumental in cancer progression. Central questions have remained unanswered: What is the function of damaged BRCA1 and BRCA2 genes in breast cancer risk? What is the basis of large variations of risk conferred to the patients by identical mutations? How can the predictive value of mutation surveys be increased?

Intrachromatid excision of telomeric DNA as a mechanism for telomere size control in Saccharomyces cerevisiae

We have previously identified a process in the yeast Saccharomyces cerevisiae that results in the contraction of elongated telomeres to wild-type length within a few generations. We have termed this process telomeric rapid deletion (TRD). In this study, we use a combination of physical and genetic assays to investigate the mechanism of TRD. First, to distinguish among several recombinational and nucleolytic pathways, we developed a novel physical assay in which HaeIII restriction sites are positioned within the telomeric tract. Specific telomeres were subsequently tested for HaeIII site movement between telomeres and for HaeIII site retention during TRD. Second, genetic analyses have demonstrated that mutations in RAD50 and MRE11 inhibit TRD. TRD, however, is independent of the Rap1p C-terminal domain, a central regulator of telomere size control. Our results provide evidence that TRD is an intrachromatid deletion process in which sequences near the extreme terminus invade end-distal sequences and excise the intervening sequences. We propose that the Mre11p-Rad50p-Xrs2p complex prepares the invading telomeric overhang for strand invasion, possibly through end processing or through alterations in chromatin structure.

Lessons learned from BRCA1 and BRCA2

BRCA1 and BRCA2 are breast cancer susceptibility genes. Mutations within BRCA1 and BRCA1 are responsible for most familial breast cancer cases. Targeted deletion of Brca1 or Brca2 in mice has revealed an essential function for their encoded products, BRCA1 and BRCA2, in cell proliferation during embryogenesis. Mouse models established from conditional expression of mutant Brca1 alleles develop mammary gland tumors, providing compelling evidence that BRCA1 functions as a breast cancer suppressor. Human cancer cells and mouse cells deficient in BRCA1 or BRCA2 exhibit radiation hypersensitivity and chromosomal abnormalities, thus revealing a potential role for both BRCA1 and BRCA2 in the maintenance of genetic stability through participation in the cellular response to DNA damage. Functional analyses of the BRCA1 and BRCA2 gene products have established their dual participation in transcription regulation and DNA damage repair. Potential insight into the molecular basis for these functions of BRCA1 and BRCA2 has been provided by studies that implicate these two tumor suppressors in both the maintenance of genetic stability and the regulation of cell growth and differentiation.

A double-strand break repair component is essential for S phase completion in fission yeast cell cycling

Fission yeast rad22(+), a homologue of budding yeast RAD52, encodes a double-strand break repair component, which is dispensable for proliferation. We, however, have recently obtained a cell division cycle mutant with a temperature-sensitive allele of rad22(+), designated rad22-H6, which resulted from a point mutation in the conserved coding sequence leading to one amino acid alteration. We have subsequently isolated rad22(+) and its novel homologue rti1(+) as multicopy suppressors of this mutant. rti1(+) suppresses all the defects of cells lacking rad22(+). Mating type switch-inactive heterothallic cells lacking either rad22(+) or rti1(+) are viable, but those lacking both genes are inviable and arrest proliferation with a cell division cycle phenotype. At the nonpermissive temperature, a synchronous culture of rad22-H6 cells performs DNA synthesis without delay and arrests with chromosomes seemingly intact and replication completed and with a high level of tyrosine-phosphorylated Cdc2. However, rad22-H6 cells show a typical S phase arrest phenotype if combined with the rad1-1 checkpoint mutation. rad22(+) genetically interacts with rad11(+), which encodes the large subunit of replication protein A. Deletion of rad22(+)/rti1(+) or the presence of rad22-H6 mutation decreases the restriction temperature of rad11-A1 cells by 4-6 degrees C and leads to cell cycle arrest with chromosomes incompletely replicated. Thus, in fission yeast a double-strand break repair component is required for a certain step of chromosome replication unlinked to repair, partly via interacting with replication protein A.

Repair of endonuclease-induced double-strand breaks in Saccharomyces cerevisiae: essential role for genes associated with nonhomologous end-joining

Repair of double-strand breaks (DSBs) in chromosomal DNA by nonhomologous end-joining (NHEJ) is not well characterized in the yeast Saccharomyces cerevisiae. Here we demonstrate that several genes associated with NHEJ perform essential functions in the repair of endonuclease-induced DSBs in vivo. Galactose-induced expression of EcoRI endonuclease in rad50, mre11, or xrs2 mutants, which are deficient in plasmid DSB end-joining and some forms of recombination, resulted in G2 arrest and rapid cell killing. Endonuclease synthesis also produced moderate cell killing in sir4 strains. In contrast, EcoRI caused prolonged cell-cycle arrest of recombination-defective rad51, rad52, rad54, rad55, and rad57 mutants, but cells remained viable. Cell-cycle progression was inhibited in excision repair-defective rad1 mutants, but not in rad2 cells, indicating a role for Rad1 processing of the DSB ends. Phenotypic responses of additional mutants, including exo1, srs2, rad5, and rdh54 strains, suggest roles in recombinational repair, but not in NHEJ. Interestingly, the rapid cell killing in haploid rad50 and mre11 strains was largely eliminated in diploids, suggesting that the cohesive-ended DSBs could be efficiently repaired by homologous recombination throughout the cell cycle in the diploid mutants. These results demonstrate essential but separable roles for NHEJ pathway genes in the repair of chromosomal DSBs that are structurally similar to those occurring during cellular development.

Mutations of the CDC28 gene and the radiation sensitivity of Saccharomyces cerevisiae

cdc28-srm, a non-temperature-sensitive (ts) mutation in the CDC28 gene of Saccharomyces cerevisiae that affects fidelity of mitotic transmission of both mitochondrial and nuclear genetic structures (Devin et al., 1990), also affected cell growth and sensitivity to lethal effects of ionizing radiation. At 30 degrees C cdc28-13, a ts mutation, was without appreciable effects on spontaneous mitochondrial rho(-)-mutagenesis, cell growth and radiation sensitivity, whereas all three cell characteristics mentioned were affected (although to a lesser degree than by cdc28-srm) by cdc28-1, another ts mutation. cdc28-srm was without any significant effect on the rates of spontaneous nuclear gene mutations and gamma-ray-induced mitotic recombination. An analysis of double mutants as regards their radiation sensitivity has revealed additive or even synergistic interactions between the cdc28-srm mutation and every one of the rad6-1 and rad52-1 mutations. The rad9 delta allele was found to be epistatic to cdc28-srm. These data suggest that the p34CDC28 protein is involved in the RAD9-dependent feedback control of DNA integrity operating at the cell cycle checkpoints.

Radiosensitivity of haplont yeast cells irradiated with sparsely and densely ionizing radiations

Five haploid and three diploid yeast strains of various species (Yarrowia lipolytica, Pichia pinus and Pichia guilliermondii) were irradiated with alpha-particles from 239Pu and gamma-rays from 137Cs or 60Co in the stationary phase of growth. A common feature of these species is that they exhibit a haploid state as a normal vegetative state in natural conditions. It was shown that the transition from the haploid to the diploid state is not accompanied by increased radioresistance, and diploid strains were unable to perform liquid-holding recovery. The absence of diploid-specific recovery in diploid strains was also supported by the fact that the RBE of alpha-particles was almost identical for haploid and the corresponding diploid strains being much smaller than that observed in typical wild-type diploid strains capable of diploid-specific recovery. The results suggest that haplont yeast may have evolved to diplont yeast via the development of a specific repair system conferring specific resistance in the diploid state.

Mutations in XRS2 and RAD50 delay but do not prevent mating-type switching in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, a large number of genes in the RAD52 epistasis group has been implicated in the repair of chromosomal double-strand breaks and in both mitotic and meiotic homologous recombination. While most of these genes are essential for yeast mating-type (MAT) gene switching, neither RAD50 nor XRS2 is required to complete this specialized mitotic gene conversion process. Using a galactose-inducible HO endonuclease gene to initiate MAT switching, we have examined the effect of null mutations of RAD50 and of XRS2 on intermediate steps of this recombination event. Both rad50 and xrs2 mutants exhibit a marked delay in the completion of switching. Both mutations reduce the extent of 5'-to-3' degradation from the end of the HO-created double-strand break. The steps of initial strand invasion and new DNA synthesis are delayed by approximately 30 min in mutant cells. However, later events are still further delayed, suggesting that XRS2 and RAD50 affect more than one step in the process. In the rad50 xrs2 double mutant, the completion of MAT switching is delayed more than in either single mutant, without reducing the overall efficiency of the process. The XRS2 gene encodes an 854-amino-acid protein with no obvious similarity to the Rad50 protein or to any other protein in the database. Overexpression of RAD50 does not complement the defects in xrs2 or vice versa.

Mutations in XRS2 and RAD50 delay but do not prevent mating-type switching in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, a large number of genes in the RAD52 epistasis group has been implicated in the repair of chromosomal double-strand breaks and in both mitotic and meiotic homologous recombination. While most of these genes are essential for yeast mating-type (MAT) gene switching, neither RAD50 nor XRS2 is required to complete this specialized mitotic gene conversion process. Using a galactose-inducible HO endonuclease gene to initiate MAT switching, we have examined the effect of null mutations of RAD50 and of XRS2 on intermediate steps of this recombination event. Both rad50 and xrs2 mutants exhibit a marked delay in the completion of switching. Both mutations reduce the extent of 5'-to-3' degradation from the end of the HO-created double-strand break. The steps of initial strand invasion and new DNA synthesis are delayed by approximately 30 min in mutant cells. However, later events are still further delayed, suggesting that XRS2 and RAD50 affect more than one step in the process. In the rad50 xrs2 double mutant, the completion of MAT switching is delayed more than in either single mutant, without reducing the overall efficiency of the process. The XRS2 gene encodes an 854-amino-acid protein with no obvious similarity to the Rad50 protein or to any other protein in the database. Overexpression of RAD50 does not complement the defects in xrs2 or vice versa.

Modification of radiation-induced damage by hyperthermia--role of repair processes

The role of repair inhibition in hyperthermic sensitization has been investigated by carrying out interaction studies (non-lethal heat plus radiation) using three radiosensitive mutant strains rad 9-4, rad 51, rad 52 of diploid yeast. The radiosensitization observed in these mutants is compared with that obtained in a wild type strain X2180. Stationary phase cells were heat treated at 51 degrees C for 30 min and log-phase cells at 49 degrees C for 5 min such that the heat treatment per se was non-lethal. Thermal enhancement ratios (TER) were calculated as the ratio of D0 values as well as D10 values, for radiation alone and for combination of heat and radiation. In stationary phase cells TER values ranged from 1.25 to 2 in different strains. There was no significant difference in the degree of sensitization in wild type and mutant strains. However in log-phase cells TER calculated as the ratio of D10 values was 1.84 for wild type strain; whereas the same was 1.2, 1.18 and 1.50 for rad 9-4, rad 51 and rad 52 strains. TER value obtained from ratio of D0 values was also significantly higher for wild type cells in log-phase cultures. These results suggest that the radiosensitization by heat occurs prominently in radioresistant log-phase cells and reflects as a reduction in the shoulder width of survival response curves. Prompt sensitization as seen by the increase in slope of survival curve also contributes to the TER. Inhibition of recovery from sublethal damage by heat appears to be an important mechanism of radiosensitization in log-phase cells.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Characterization of double-strand break-induced recombination: homology requirements and single-stranded DNA formation

In the yeast Saccharomyces cerevisiae, a double-strand chromosome break created by the HO endonuclease is frequently repaired in mitotically growing cells by recombination between flanking homologous regions, producing a deletion. We showed that single-stranded regions were formed on both sides of the double-strand break prior to the formation of the product. The kinetics of the single-stranded DNA were monitored in strains with the recombination-deficient mutations rad52 and rad50 as well as in the wild-type strain. In rad50 mutants, single-stranded DNA was generated at a slower rate than in the wild type, whereas rad52 mutants generated single-stranded DNA at a faster rate. Product formation was largely blocked in the rad52 mutant. In the rad50 rad52 double mutant, the effects were superimposed in that the exonucleolytic activity was slowed but product formation was blocked. rad50 appears to act before or at the same stage as rad52. We constructed strains containing two ura3 segments on one side of the HO cut site and one ura3 region on the other side to characterize how flanking repeats find each other. Deletions formed preterentially between the homologous regions closest to the double-strand break. By varying the size of the middle ura3 segment, we determined that recombination initiated by a double-strand break requires a minimum homologous length between 63 and 89 bp. In these competition experiments, the frequency of recombination was dependent on the length of homology in an approximately linear manner.

Characterization of double-strand break-induced recombination: homology requirements and single-stranded DNA formation

In the yeast Saccharomyces cerevisiae, a double-strand chromosome break created by the HO endonuclease is frequently repaired in mitotically growing cells by recombination between flanking homologous regions, producing a deletion. We showed that single-stranded regions were formed on both sides of the double-strand break prior to the formation of the product. The kinetics of the single-stranded DNA were monitored in strains with the recombination-deficient mutations rad52 and rad50 as well as in the wild-type strain. In rad50 mutants, single-stranded DNA was generated at a slower rate than in the wild type, whereas rad52 mutants generated single-stranded DNA at a faster rate. Product formation was largely blocked in the rad52 mutant. In the rad50 rad52 double mutant, the effects were superimposed in that the exonucleolytic activity was slowed but product formation was blocked. rad50 appears to act before or at the same stage as rad52. We constructed strains containing two ura3 segments on one side of the HO cut site and one ura3 region on the other side to characterize how flanking repeats find each other. Deletions formed preterentially between the homologous regions closest to the double-strand break. By varying the size of the middle ura3 segment, we determined that recombination initiated by a double-strand break requires a minimum homologous length between 63 and 89 bp. In these competition experiments, the frequency of recombination was dependent on the length of homology in an approximately linear manner.

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

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 gel-electrophoresis. 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.

Failure to induce a DNA repair gene, RAD54, in Saccharomyces cerevisiae does not affect DNA repair or recombination phenotypes

The Saccharomyces cerevisiae RAD54 gene is transcriptionally regulated by a broad spectrum of DNA-damaging agents. Induction of RAD54 by DNA-damaging agents is under positive control. Sequences responsible for DNA damage induction (the DRS element) lie within a 29-base-pair region from -99 to -70 from the most proximal transcription start site. This inducible promoter element is functionally separable from a poly(dA-dT) region immediately downstream which is required for constitutive expression. Deletions which eliminate induction of RAD54 transcription by DNA damage but do not affect constitutive expression have no effect on growth or survival of noninducible strains relative to wild-type strains in the presence of DNA-damaging agents. The DRS element is also not required for homothallic mating type switching, transcriptional induction of RAD54 during meiosis, meiotic recombination, or spontaneous or X-ray-induced mitotic recombination. We find no phenotype for a lack of induction of RAD54 message via the damage-inducible DRS, which raises significant questions about the physiology of DNA damage induction in S. cerevisiae.

REV3, a Saccharomyces cerevisiae gene whose function is required for induced mutagenesis, is predicted to encode a nonessential DNA polymerase

We have cloned the REV3 gene of Saccharomyces cerevisiae by complementation of the rev3 defect in UV-induced mutagenesis. The nucleotide sequence of this gene encodes a predicted protein of Mr 172,956 showing significant sequence similarity to Epstein-Barr virus DNA polymerase and to other members of a class of DNA polymerases including human DNA polymerase alpha and yeast DNA polymerase I. REV3 protein shows less sequence identity, and presumably a more distant evolutionary relationship, to the latter two enzymes than they do to each other. Haploids carrying a complete deletion of REV3 are viable. We suggest that induced mutagenesis in S. cerevisiae depends on a specialized DNA polymerase that is not required for other replicative processes. REV3 is located 2.8 centimorgans from CDC60, on chromosome XVI.

Failure to induce a DNA repair gene, RAD54, in Saccharomyces cerevisiae does not affect DNA repair or recombination phenotypes

The Saccharomyces cerevisiae RAD54 gene is transcriptionally regulated by a broad spectrum of DNA-damaging agents. Induction of RAD54 by DNA-damaging agents is under positive control. Sequences responsible for DNA damage induction (the DRS element) lie within a 29-base-pair region from -99 to -70 from the most proximal transcription start site. This inducible promoter element is functionally separable from a poly(dA-dT) region immediately downstream which is required for constitutive expression. Deletions which eliminate induction of RAD54 transcription by DNA damage but do not affect constitutive expression have no effect on growth or survival of noninducible strains relative to wild-type strains in the presence of DNA-damaging agents. The DRS element is also not required for homothallic mating type switching, transcriptional induction of RAD54 during meiosis, meiotic recombination, or spontaneous or X-ray-induced mitotic recombination. We find no phenotype for a lack of induction of RAD54 message via the damage-inducible DRS, which raises significant questions about the physiology of DNA damage induction in S. cerevisiae.

Influence of misonidazole on survival of wild-type and radiosensitive mutants of yeast

Survival curves were obtained for haploid and diploid yeasts, Saccharomyces cerevisiae, of a wild-type strain and radiosensitive mutants exposed to gamma-rays in oxygenated and hypoxic conditions both in the absence and in the presence of misonidazole. Misonidazole enhanced the radiosensitivity only of hypoxic cells. A correlation between oxygen and misonidazole sensitization was observed. The data confirm that misonidazole mimics the sensitizing effect of oxygen. The degree of liquid-holding recovery of yeast cells was greater when the cells were irradiated in hypoxic conditions with than without misonidazole. Possible reasons for the observed radiation responses are discussed.

Repair of gamma-ray induced DNA strand breaks in the radiation-sensitive mutant rad18-2 of Saccharomyces cerevisiae

The repair of gamma-ray induced DNA single and double-strand breaks was looked at in wild type and rad18-2 strains of the yeast Saccharomyces cerevisiae using sucrose gradient centrifugation. It was found that rad18-2 diploid cells could repair single and double-strand breaks induced by gamma-rays. It was also found that rad18-2 cells experienced a breakup of their DNA during post-irradiation incubation to a size smaller than seen in cells just receiving irradiation. This breakup of DNA in rad18-2 cells is not degradation due to cell death since wild type cells irradiated to similar low survival levels do not show this breakup of DNA with 8 h incubation. The breakup of DNA in rad18-2 cells is not due to replication gaps being formed by synthesis on a damaged template since treatment of rad18-2 a mating type cells with alpha factor, to prevent initiation of DNA synthesis, does not prevent breakup of the DNA.

Genetic control of budding-cell resistance in the diploid yeast Saccharomyces cerevisiae exposed to gamma-radiation

The gamma-radiation response of stationary and budding cells of wild-type diploid strains (RAD) and radiation-sensitive strains rad2, 6, 9, 18, 50-55, 57 and rec4 was studied. As compared with the wild-type strains, mutants generally showed enhanced sensitivity in both stages of the cell cycle. Budding-cell resistance was totally absent from rad50-55 strains. Mutants rad6, 9 and 18 showed some degree of budding-cell resistance. The response of rad2 and rec4 strains was identical with that of the corresponding wild-type strains. These results suggest that the pathway dependent upon the expression of RAD50-55 loci functions more efficiently in budding cells compared with the pathway dependent on RAD2 and RAD6, 9 and 18 loci. Recombination between sister chromatids appears to play an important role in budding-cell resistance, and this process is under the control of the RAD52 repair pathway. The relationship between the repair pathways associated with budding-cell resistance and post-irradiation cellular recovery (LHR) is discussed.

The oxygen effect in haploid and diploid yeast strains of different sensitivities

The extent of the oxygen effect for cell survival was studied in diploid and haploid wild-type yeast and in mutants belonging to the rad2, rad6 and rad50 epistatic group. In haploids, reduced oxygen enhancement ratios were found in rad52, rad6 and rad18. The latter two also showed some influence of the mating type. In diploids the oxygen effect was decreased in rad2, rad52 and rad18.

Radioprotecting action of chemical compounds on gamma-irradiated yeast cells of various genotypes

The radioprotective efficiency of cysteamine and cysteine has been studied on haploid and diploid, Saccharomyces cerevisiae, wild-type and various X-ray repair deficient rad mutants. The correlation between the radioprotecting action of cysteamine and cell repair capacity was demonstrated for diploid yeasts; such a correlation was not expressed for wild-type and rad mutant haploid yeast cells. It was concluded that the radioprotective action may involve cellular recovery processes, which may be mediated by a recombination-like mechanism, for which the diploid state is required. Liquid holding recovery was shown not to participate in radioprotection, judged by the absence of the influence of cysteine on the delay of the first postradiation budding as well as by the additive action of cysteine and liquid holding recovery.