Inducible removal of UV-induced pyrimidine dimers from transcriptionally active and inactive genes of Saccharomyces cerevisiae

An epigenetically inherited UV hyper-resistance phenotype in Saccharomyces cerevisiae

Background

Epigenetics refers to inheritable phenotypic changes that occur in the absence of genetic alteration. Such adaptations can provide phenotypic plasticity in reaction to environmental cues. While prior studies suggest that epigenetics plays a role in the response to DNA damage, no direct demonstration of epigenetically inheritable processes have been described in this context.

Results

Here we report the identification of an epigenetic response to ultraviolet (UV) radiation in the baker’s yeast Saccharomyces cerevisiae. Cells that have been previously exposed to a low dosage of UV exhibit dramatically increased survival following subsequent UV exposure, which we refer to as UV hyper-resistance (UVHR). This phenotypic change persists for multiple mitotic generations, without any indication of an underlying genetic basis. Pre-exposed cells experience a notable reduction in the amount of DNA damage caused by the secondary UV exposure. While the mechanism for the protection is not fully characterized, our results suggest that UV-induced cell size increases and/or cell wall changes are contributing factors. In addition, we have identified two histone modifications, H3K56 acetylation and H3K4 methylation, that are important for UVHR, potentially serving as mediators of UV protective gene expression patterns, as well as epigenetic marks to propagate the phenotype across cell generations.

Conclusions

Exposure to UV radiation triggers an epigenetically inheritable protective response in baker’s yeast that increases the likelihood of survival in response to subsequent UV exposures. These studies provide the first demonstration of an epigenetically inheritable dimension of the cellular response to DNA damage.

Supplementary Information

The online version contains supplementary material available at 10.1186/s13072-022-00464-5.

Filling gaps in translesion DNA synthesis in human cells

During DNA replication, forks may encounter unrepaired lesions that hamper DNA synthesis. Cells have universal strategies to promote damage bypass allowing cells to survive. DNA damage tolerance can be performed upon template switch or by specialized DNA polymerases, known as translesion (TLS) polymerases. Human cells count on more than eleven TLS polymerases and this work reviews the functions of some of these enzymes: Rev1, Pol η, Pol ι, Pol κ, Pol θ and Pol ζ. The mechanisms of damage bypass vary according to the lesion, as well as to the TLS polymerases available, and may occur directly at the fork during replication. Alternatively, the lesion may be skipped, leaving a single-stranded DNA gap that will be replicated later. Details of the participation of these enzymes are revised for the replication of damaged template. TLS polymerases also have functions in other cellular processes. These include involvement in somatic hypermutation in immunoglobulin genes, direct participation in recombination and repair processes, and contributing to replicating noncanonical DNA structures. The importance of DNA damage replication to cell survival is supported by recent discoveries that certain genes encoding TLS polymerases are induced in response to DNA damaging agents, protecting cells from a subsequent challenge to DNA replication. We retrace the findings on these genotoxic (adaptive) responses of human cells and show the common aspects with the SOS responses in bacteria. Paradoxically, although TLS of DNA damage is normally an error prone mechanism, in general it protects from carcinogenesis, as evidenced by increased tumorigenesis in xeroderma pigmentosum variant patients, who are deficient in Pol η. As these TLS polymerases also promote cell survival, they constitute an important mechanism by which cancer cells acquire resistance to genotoxic chemotherapy. Therefore, the TLS polymerases are new potential targets for improving therapy against tumors.

The RAD9-dependent gene trans-activation is required for excision repair of active genes but not for repair of non-transcribed DNA

The Saccharomyces cerevisiae RAD9 and RAD24 are two cell cycle checkpoint genes required for UV-dependent up-regulation of a battery of genes involved in different metabolic pathways. RAD9 is also implicated in nucleotide excision repair (NER); however, its precise role is still unclear. For the present study, we made use of the high-resolution primer extension technique to show that the RAD9-deleted cells are deficient in the repair of both strands of the URA3 gene. Interestingly, this defect was suppressed by over-expressing the RAD24 gene, suggesting that the role of RAD9 in NER is indirect probably through the UV-dependent trans-activation of some NER factors. Accordingly, we present evidence that the inhibition of UV-related de novo protein synthesis by cycloheximide has no effect on the rad9Delta mutant while it suppresses the correcting effect of RAD24 over-expression. Importantly, we have also shown that RAD9 has no role in repair of transcriptionally inactive DNA sequences (URA3 promoter and transcriptionally silent GAL10 gene). Furthermore, de novo protein synthesis was not required for NER in the absence of transcription-coupled NER. This implies that RAD9-dependent gene up-regulation is required for NER only when this process is coupled to transcription.

Functionally distinct nucleosome-free regions in yeast require Rad7 and Rad16 for nucleotide excision repair

In yeast, Rad7 and Rad16 are two proteins required for nucleotide excision repair (NER) of non-transcribed chromatin. They have roles in damage recognition, in the postincision steps of NER, and in ultraviolet-light-dependent histone H3 acetylation. Moreover, Rad16 is an ATP-ase of the SNF2 superfamily and therefore might facilitate chromatin repair by nucleosome remodelling. Here, we used yeast rad7 Delta rad16 Delta mutants and show that Rad7-Rad16 is also required for NER of UV-lesions in three functionally distinct nucleosome-free regions (NFRs), the promoter and 3'-end of the URA3 gene and the ARS1 origin of replication. Moreover, rapid repair of UV-lesions by photolyase confirmed that nucleosomes were absent and that neither UV-damage formation nor rad7 Delta rad16 Delta mutations altered chromatin accessibility in NFRs. The data are consistent with a role of Rad7-Rad16 in damage recognition and processing in absence of nucleosomes. An additional role in nucleosome remodelling is discussed.

Distinct functions of the ubiquitin-proteasome pathway influence nucleotide excision repair

The Rad23/Rad4 nucleotide excision repair (NER) protein complex functions at an early stage of the NER reaction, possibly promoting the recognition of damaged DNA. Here we show that Rad4 protein is ubiquitinated and degraded in response to ultraviolet (UV) radiation, and identify a novel cullin-based E3 ubiquitin ligase required for this process. We also show that this novel ubiquitin ligase is required for optimal NER. Our results demonstrate that optimal NER correlates with the ubiquitination of Rad4 following UV radiation, but not its subsequent degradation. Furthermore, we show that the ubiquitin-proteasome pathway (UPP) regulates NER via two distinct mechanisms. The first occurs independently of de novo protein synthesis, and requires Rad23 and a nonproteolytic function of the 19S regulatory complex of the 26S proteasome. The second requires de novo protein synthesis, and relies on the activity of the newly identified E3 ubiquitin ligase. These studies reveal that, following UV radiation, NER is mediated by nonproteolytic activities of the UPP, via the ubiquitin-like domain of Rad23 and UV radiation-induced ubiquitination of Rad4.

Mutation induction in haploid yeast after split-dose radiation exposure. II. Combination of UV-irradiation and X-rays

Split-dose protocols can be used to investigate the kinetics of recovery from radiation damage and to elucidate the mechanisms of cell inactivation and mutation induction. In this study, a haploid strain of the yeast, Saccharomyces cerevisiae, wild-type with regard to radiation sensitivity, was irradiated with 254-nm ultraviolet (UV) light and then exposed to X-rays after incubation for 0-6 hr. The cells were incubated either on nutrient medium or salt agar between the treatments. Loss of reproductive ability and mutation to canavanine resistance were measured. When the X-ray exposure immediately followed UV-irradiation, the X-ray survival curves had the same slope irrespective of the pretreatment, while the X-ray mutation induction curves were changed from linear to linear quadratic with increasing UV fluence. Incubations up to about 3 hr on nutrient medium between the treatments led to synergism with respect to cell inactivation and antagonism with respect to mutation, but after 4-6 hr the two treatments acted independently. Incubation on salt agar did not cause any change in the survival curves, but there was a strong suppression of X-ray-induced mutation with increasing UV fluence. On the basis of these results, we suggest that mutation after combined UV and X-ray exposure is affected not only by the induction and suppression of DNA repair processes, but also by radiation-induced modifications of cell-cycle progression and changes in the expression of the mutant phenotype.

Repair of UV lesions in silenced chromatin provides in vivo evidence for a compact chromatin structure

Genes positioned close to telomeres in yeast are silenced by a heterochromatin-like structure containing Sir proteins. To investigate whether silencing also affects DNA repair, we studied removal of UV lesions by photolyase and nucleotide excision repair (NER) in strains containing the URA3 gene inserted 2 kilobases from a telomere. URA3 was transcriptionally active in sir3delta mutants, partially silenced in SIR3 cells, or completely silenced by overexpression of SIR3 or deletion of RPD3. The active URA3 showed efficient repair by both pathways. Fast repair of the promoter and 3' end by photolyase reflected a non-nucleosomal structure. Partial silencing had no remarkable effect on photolyase but reduced repair by NER, indicating differential accessibility for the two repair reactions. Complete silencing inhibits NER and photolyase in the coding region as well as in the promoter and the 3'-end. Conventional nuclease footprinting analyses revealed subtle changes in the promoter proximal nucleosome under partially silenced conditions but a pronounced reorganization of chromatin extending over the whole gene in silenced chromatin. Thus, both repair systems are sensitive to chromatin changes associated with silencing and provide direct evidence for a compact structure of heterochromatin.

Defective nucleotide excision repair in yeast hpr1 and tho2 mutants

Nucleotide excision repair (NER) and transcription are intimately related. First, TFIIH has a dual role in transcription initiation and NER and, secondly, transcription leads to more efficient repair of damage present in transcribed sequences. It is thought that elongating RNAPII, stalled at a DNA lesion, is used for the loading of the NER machinery in a process termed transcription-coupled repair (TCR). Non-transcribed regions are repaired by the so-called global genome repair (GGR). We have previously defined a number of yeast genes, whose deletions confer transcription-dependent hyper-recombination phenotypes. As these mutations cause impairment of transcription elongation we have assayed whether they also affect DNA repair. We show that null mutations of the HPR1 and THO2 genes, encoding two prominent proteins of the THO complex, increase UV sensitivity of yeast cells lacking GGR. Consistent with this result, molecular analyses of DNA repair of the RPB2 transcribed strand using T4 endo V show that hpr1 and tho2 do indeed impair TCR. However, this effect is not confined to TCR alone because the mutants are slightly affected in GGR. These results indicate that THO affects both transcription and NER. We discuss different alternatives to explain the effect of the THO complex on DNA repair.

The Saccharomyces cerevisiae RAD9 cell cycle checkpoint gene is required for optimal repair of UV-induced pyrimidine dimers in both G(1) and G(2)/M phases of the cell cycle

Cells respond to DNA damage by activating both cellular growth arrest and DNA repair processes. In Saccharomyces cerevesiae the RAD9 gene controls DNA damage-mediated cell cycle arrest that is known to allow efficient repair. To ascertain whether RAD9 plays a role in DNA repair per se, the removal of UV-induced photolesions was assessed in synchronized isogenic normal and rad9 cells using the high resolution primer extension technique. The results show that RAD9 is indeed involved in the removal of photolesions from both the transcribed and the non-transcribed strands of the reporter GAL10 gene, in G(1)- as well as G(2)/M-arrested cells. Interestingly, these data also reveal that in both normal and rad9 mutant, the repair strand bias towards the transcribed stand is more pronounced in G(2)/M- than in G(1)-arrested cells. These data indicate that RAD9 coordinate the cellular response to DNA damage by activating both cell cycle checkpoint and excision repair.

RAD9, RAD24, RAD16 and RAD26 are required for the inducible nucleotide excision repair of UV-induced cyclobutane pyrimidine dimers from the transcribed and non-transcribed regions of the Saccharomyces cerevisiae MFA2 gene

In this study, the effect of a prior UV irradiation on the removal of cyclobutane pyrimidine dimers (CPDs) from the transcribed strand (TS) and non-transcribed strand (NTS) of the MFA2 gene in haploid Saccharomyces cerevisiae (S. cerevisiae) cells was investigated. In NER competent cells, the pre-irradiation with a dose of 20J/m2 enhances the removal of CPDs induced by a second UV dose of 100J/m2 in the TS and the NTS of MFA2 gene except for the CPDs in the region +258 to +298 in the NTS, where the enhanced repair was absent. No inducible repair was observed in rad9, rad24, rad16 and rad26 cells, indicating two checkpoint genes RAD9 and RAD24, the global repair gene RAD16 and the transcription coupled repair gene RAD26 are essential for inducible NER.

Transcription-coupled repair is inducible in hamster cells

In mammalian cells, the rate of nucleotide excision repair of UV dimers is heterogeneous throughout the genome, with repair occurring more rapidly in the transcribed strand of active genes than in the genome overall. This repair pathway is termed transcription-coupled repair (TCR) and is thought to permit the rapid resumption of RNA synthesis following UV irradiation. To evaluate the inducibility of the TCR process, we examined the repair of UV-induced cyclobutane pyrimidine dimers (CPDs) at the level of the gene following exposure of hamster cells to a sub-lethal UV fluence, 3 h prior to a higher dose. Repair was detected by a well-established technique allowing quantification of CPDs at the level of a specific strand by Southern blot hybridization. Here, we show that prior low-dose irradiation clearly enhanced the early rate of CPD removal in the transcribed strand of the active DHFR gene. Furthermore, the RNA synthesis recovery following UV exposure was stimulated by the priming UV dose. Thus, we provide evidence for an inducible TCR response to CPDs in hamster cells. This pathway is independent of the p53 activation, since the hamster cell line that we used expresses high levels of mutant p53 protein.

Mitotic viability and metabolic competence in UV-irradiated yeast cells

Colony formation is the classic method for measuring survival of yeast cells. This method measures mitotic viability and can underestimate the fraction of cells capable of carrying out other DNA processing events. Here, we report an alternative method, based on cell metabolism, to determine the fraction of surviving cells after ultraviolet (UV) irradiation. The reduction of 2,3,5-triphenyl tetrazolium chloride (or TTC) to formazan in mitochondria was compared with cell colony formation and DNA repair capacity in wt cells and two repair-deficient strains (rad1Delta and rad7Delta). Both TTC reduction and cell colony formation gave a linear response with different ratios of mitotically viable cells and heat-inactivated cells. However, monitoring the formation of formazan in non-dividing yeast cells that are partially (rad7Delta) or totally (wt) proficient at DNA repair is a more accurate measure of cell survival after UV irradiation. Before repair of UV photoproducts (cis-syn cyclobutane pyrimidine dimers or CPDs) is complete, these two assays give very different results, implying that many damaged cells are metabolically competent but cannot replicate. For example, only 25% of the rad7Delta cells are mitotically viable after a UV dose of 12 J/m(2)75% of these cells are metabolically competent and remove over 55% of the CPDs from their genomic DNA. Moreover, repair of CPDs in wt cells dramatically decreases after the first few hours of liquid holding (L.H.; incubation in water) and correlates with a substantial decrease in cell metabolism over the same time period. In contrast, cell colony formation may be the more accurate indicator of cell survival after UV irradiation of rad1Delta cells (i.e., cells with little DNA repair activity). These results indicate that the metabolic competence of UV-irradiated, non-dividing yeast cells is a much better indicator of cell survival than mitotic viability in partially (or totally) repair proficient yeast cultures.

Adaptive enhancement and kinetics of nucleotide excision repair in humans

An adaptive response, low doses of a mutagen rendering cells more able to subsequently cope with higher doses of that or a related challenging mutagen, enhances nucleotide excision repair in human fibroblasts. After fibroblasts were flashed with 20 J/m2 of UVC, the cyclopyrimidine dimer frequency at any single dinucleotide position remained unchanged for several hours before abruptly displaying first order kinetics of repair. These kinetics were determined by ligation-mediated PCR along exon 9 of the human p53 gene. When a chronic dose of quinacrine mustard (QM) preceded the UVC challenge, the duration of the cyclobutane pyrimidine dimer (CPD) repair lags were reduced by a factor of three and the kinetic half-lives for CPD repair were reduced by a factor of three. The observed repair kinetics are consistent with the following model. The UVC dose required (K(m)) to generate a substrate concentration which half-saturates the cell's repair capacity is 3 J/m2 for the high affinity (6-4) photoproducts and greater than 100 J/m2 for the low affinity cyclobutane dimers. After 20 J/m2 of UVC, the repair enzyme is saturated with (6-4) photoproducts; these competitively inhibit CPD repair by binding all available repair enzyme. After the (6-4)s are repaired, the CPD concentration is less than K(m)(CPD) and so CPD repair kinetics initiate with first order kinetics. QM-induced enhancement, by increasing the concentration, Vmax, of repair enzyme, shortens the duration of (6-4) saturation and increases the rate constant for cyclobutane dimer repair. The data exactly fit the expectations from Michaelis kinetics. Transcription coupled repair is less amenable to Michaelis interpretations and enhanced global repair was almost as rapid as the slightly enhanced transcription coupled repair. We infer that repair enhancement is unable to proportionally increase the number of matrix attachment sites necessary for transcription coupled repair. Understanding competitive inhibition between adduct classes and adaptive enhancement of Vmax is important to understanding the effects of high doses of mutagen mixtures.

Radiation inducible DNA repair processes in eukaryotes

Eukaryotic cells respond to radiation-induced damage in DNA and other cellular components by turning on cascades of regulatory events which constitute a complex network of pathways of cell cycle checkpoints, DNA repair and damage tolerance mechanisms, recombination and delayed cell death (apoptosis). By virtue of the high homology in structure and function of yeast and mammalian proteins several DNA repair pathways that may be upregulated in response to radiation, and some of their regulatory factors involved in sensing of damage, signal transduction by protein kinase cascades and transcription have been identified. In yeast, genes for DNA synthesis and replicative damage bypass, for base and nucleotide excision repair, in particular global genome repair, and for crucial steps in DNA double strand break repair by homologous recombination show enhanced expression in response to radiation. In mammalian cells, the identification of homologous genes and upregulated homologous DNA repair pathways makes fast progress. It is, however, evident that the regulatory network is considerably more complex than in yeast. The improved understanding on the molecular level of the radiation-inducible cellular responses to radiation is of high public interest. Especially, the response to very low doses may have relevance for the risk estimation for ionising radiation and, possibly as well, ultraviolet light (UV-B), and for the design of suitable dose fractionation schemes for radiotherapy.

Induction of the SOS response increases the efficiency of global nucleotide excision repair of cyclobutane pyrimidine dimers, but not 6-4 photoproducts, in UV-irradiated Escherichia coli

Nucleotide excision repair (NER) is responsible for the removal of a variety of lesions from damaged DNA and proceeds through two subpathways, global repair and transcription-coupled repair. In Escherichia coli, both subpathways require UvrA and UvrB, which are induced following DNA damage as part of the SOS response. We found that elimination of the SOS response either genetically or by treatment with the transcription inhibitor rifampin reduced the efficiency of global repair of the major UV-induced lesion, the cyclobutane pyrimidine dimer (CPD), but had no effect on the global repair of 6-4 photoproducts. Mutants in which the SOS response was constitutively derepressed repaired CPDs more rapidly than did wild-type cells, and this rate was not affected by rifampin. Transcription-coupled repair of CPDs occurred in the absence of SOS induction but was undetectable when the response was expressed constitutively. These results suggest that damage-inducible synthesis of UvrA and UvrB is necessary for efficient repair of CPDs and that the levels of these proteins determine the rate of NER of UV photoproducts. We compare our findings with recent data from eukaryotic systems and suggest that damage-inducible stress responses are generally critical for efficient global repair of certain types of genomic damage.

Role of PSO genes in the repair of photoinduced interstrand cross-links and photooxidative damage in the DNA of the yeast Saccharomyces cerevisiae

Recent progress in elucidating the molecular structure of the PSSO genes PSO2 to PSO7 is presented. Their role in DNA repair and mutagenesis is discussed in the light of the putative proteins encoded in the respective ORFs and with the knowledge of recent progress in biological and biochemical experimentation. The role of the RecA protein in some steps of DNA repair in Saccharomyces cerevisiae is presented and discussed.

Excision repair at the level of the nucleotide in the Saccharomyces cerevisiae MFA2 gene: mapping of where enhanced repair in the transcribed strand begins or ends and identification of only a partial rad16 requisite for repairing upstream control sequences

We wished to determine where transcription enhanced nucleotide excision repair begins and ends for a Saccharomyces cerevisiae gene transcribed by RNA polymerase II, and to examine the role of the RAD16 gene in repairing upstream, non-transcribed control sequences of such a gene. To do so, we developed a method to study the repair of UV induced cyclobutane pyrimidine dimers (CPDs) at the level of the nucleotide in the control and coding sequences of the MFA2 gene. This gene is active in haploid a mating type cells but inactive in alpha cells: its regulation is mediated by changes in chromatin structure. DNA from UV irradiated cells was cut with a CPD-specific endonuclease, restricted and selected strands of the MFA2 gene separated from genomic DNA prior to end-labelling and resolution on a sequencing gel. We confirmed repair trends seen using Southern blotting to examine kilobase size fragments, but were additionally able to elucidate subtle differences in repairing portions of the transcribed strand (TS) of MFA2. Enhanced repair of the TS when the gene is active, began well before the start of transcription. Clearly, enhanced repair in this region cannot be due to mRNA synthesis. The repair of CPDs is even further enhanced in the transcribed portion of the TS, and returns to a basal level after the termination of transcription. The approach also revealed that RAD16 has a role in the repair of the TS when MFA2 is active. Removal of CPDs from the TS control region was impaired but not totally defective in a rad16 a mutant. Repair from the TS coding sequence also has a Rad16 component, but a lesser one than for the upstream control sequences, and this was more marked for the sequences towards the end of the transcribed region. The system developed permits further dissection of the relationships between DNA repair, chromatin structure and transcription at the MFA2 locus.

The RAD7, RAD16, and RAD23 genes of Saccharomyces cerevisiae: requirement for transcription-independent nucleotide excision repair in vitro and interactions between the gene products

Nucleotide excision repair (NER) is a biochemical process required for the repair of many different types of DNA lesions. In the yeast Saccharomyces cerevisiae, the RAD7, RAD16, and RAD23 genes have been specifically implicated in NER of certain transcriptionally repressed loci and in the nontranscribed strand of transcriptionally active genes. We have used a cell-free system to study the roles of the Rad7, Rad16, and Rad23 proteins in NER. Transcription-independent NER of a plasmid substrate was defective in rad7, rad16, and rad23 mutant extracts. Complementation studies with a previously purified NER protein complex (nucleotide excision repairosome) indicate that Rad23 is a component of the repairosome, whereas Rad7 and Rad16 proteins were not found in this complex. Complementation studies with rad4, rad7, rad16, and rad23 mutant extracts suggest physical interactions among these proteins. This conclusion was confirmed by experiments using the yeast two-hybrid assay, which demonstrated the following pairwise interactions: Rad4 with Rad23, Rad4 with Rad7, and Rad7 with Rad16. Additionally, interaction between the Rad7 and Rad16 proteins was demonstrated in vitro. Our results show that Rad7, Rad16, and Rad23 are required for transcription-independent NER in vitro. This process may involve a unique protein complex which is distinct from the repairosome and which contains at least the Rad4, Rad7, and Rad16 proteins.

Molecular dosimetry of chemical mutagens. Relationship between DNA adduct formation and genetic changes analyzed at the molecular level

This is a review of the work carried out by 16 collaborating institutes within a project which was part of the European Programme: Science and Technology for Environmental Protection (STEP). The purpose of the project was to investigate the relationship between the exposure to genotoxic chemicals and the induction of DNA damage and genetic effects as determined in in vitro and in vivo assays under laboratory conditions. Two types of investigation were performed: (i) determination of the relationship between the extent of exposure to a genotoxic chemical and the frequency of DNA adducts formed in the test organism and (ii) identification of those DNA adducts which are responsible for the biological effects of genotoxic chemicals. The research was carried out with a series of alkylating agents which all induce similar types of DNA damage but for which the proportions of the different types of adducts vary. The frequency of this type of DNA damage was also modulated by base excision repair processes. In addition, a number of genotoxic agents which cause DNA damage recognized by nucleotide excision repair were investigated. The consequences of DNA adduct formation, i.e., the induction of gene mutations, were analyzed at the DNA sequence level, generating mutational spectra. These investigations of the mutational specificities of carcinogens contributed to our understanding of the molecular mechanisms which are involved in cancer induction by genotoxins.

Rad23 is required for transcription-coupled repair and efficient overrall repair in Saccharomyces cerevisiae

The repair of UV-induced photoproducts (cyclobutane pyrimidine dimers) in a well-characterized minichromosome, genomic DNA, and a transcribed genomic gene (RPB2) of a rad23delta mutant of Saccharomyces care was examined. Isogenic wild-type cells show a strong bias for the repair of the transcribed strands in both the plasmid and genomic genes and efficient overall repair of both DNAs (>80% of the dimers were removed in 6 h). However, the rad23delta mutant shows (i) no strand bias for repair in these genes and decreased repair of both strands, (ii) partial repair of genomic DNA (approximately 45% in 6 h), and (iii) very poor repair of the plasmid overall approximately 15% in 6 h). These features, coupled with the decreased UV survival of rad23delta cells, indicate that Rad23 is required for both transcription-coupled repair and efficient overall repair in S. cerevisiae.

Repair of plasmid and genomic DNA in a rad7 delta mutant of yeast

Repair of UV-induced cyclobutane pyrimidine dimers (CPDs) was examined in a yeast plasmid of known chromatin structure and in genomic DNA in a radiation-sensitive deletion mutant of yeast, rad7 delta, and its isogenic wild-type strain. A whole plasmid repair assay revealed that only approximately 50% of the CPDs in plasmid DNA are repaired after 6 h in this mutant, compared with almost 90% repaired in wild-type. Using a site-specific repair assay on 44 individual CPD sites within the plasmid we found that repair in the rad7 delta mutant occurred primarily in the transcribed regions of each strand of the plasmid, however, the rate of repair at nearly all sites measured was less than in the wild-type. There was no apparent correlation between repair rate and nucleosome position. In addition, approximately 55% of the CPDs in genomic DNA of the mutant are repaired during the 6 h period, compared with > 80% in the wild-type.

Regulation of the Saccharomyces cerevisiae DNA repair gene RAD16

The RAD16 gene product has been shown to be essential for the repair of the silenced mating type loci [Bang et al. (1992) Nucleic Acids Res. 20, 3925-3931]. More recently we demonstrated that the RAD16 and RAD7 proteins are also required for repair of non-transcribed strands of active genes in Saccharomyces cerevisiae [Waters et al. (1993) Mol. Gen. Genet. 239, 28-32]. We have studied the regulation of the RAD16 gene and found that the RAD16 transcript levels increased up to 7-fold upon UV irradiation. Heat shock at 42 degrees C also results in elevated levels of RAD16 mRNA. In sporulating MAT alpha/MATa diploid cells RAD16 mRNA is also induced. The basal level of the RAD16 transcript is constant during the mitotic cell cycle. G1-arrested cells show normal induction of RAD16 mRNA upon UV irradiation demonstrating that the induction is not a secondary consequence of G2 cell cycle arrest following UV irradiation. However, in cells arrested in G1 the induction of RAD16 mRNA after UV irradiation is not followed by a rapid decline as occurs in normal growing cells suggesting that the down regulation of RAD16 transcription is dependent on progression into the cell cycle.