Molecular Mechanisms of Pyrimidine Dimer Excision in Saccharomyces cerevisiae: Incision of Ultraviolet-Irradiated Deoxyribonucleic Acid In Vivo

A group of genetically related ultraviolet (UV)-sensitive mutants of Saccharomyces cerevisiae has been examined in terms of their survival after exposure to UV radiation, their ability to carry out excision repair of pyrimidine dimers as measured by the loss of sites (pyrimidine dimers) sensitive to a dimer-specific enzyme probe, and in terms of their ability to effect incision of their deoxyribonucleic acid (DNA) during post-UV incubation in vivo (as measured by the detection of single-strand breaks in nuclear DNA). In addition to a haploid RAD⁺ strain (S288C), 11 different mutants representing six RAD loci (RAD1, RAD2, RAD3, RAD4, RAD14, and RAD18) were examined. Quantitative analysis of excision repair capacity, as determined by the loss of sites in DNA sensitive to an enzyme preparation from M. luteus which is specific for pyrimidine dimers, revealed a profound defect in this parameter in all but three of the strains examined. The rad14-1 mutant showed reduced but significant residual capacity to remove enzyme-sensitive sites as did the rad2-4 mutant. The latter was the only one of three different rad2 alleles examined which was leaky in this respect. The UV-sensitive strain carrying the mutant allele rad18-1 exhibited normal loss of enzyme-sensitive sites consistent with its assignment to the RAD6 rather than the RAD3 epistatic group. All strains having mutant alleles of the RAD1, RAD2, RAD3, RAD4, and RAD14 loci showed no detectable incubation-dependent strand breaks in nuclear DNA after exposure to UV radiation. These experiments suggest that the RAD1, RAD2, RAD3, RAD4 (and probably RAD14) genes are all required for the incision of UV-irradiated DNA during pyrimidine dimer excision in vivo.     

Decreased UV mutagenesis in cdc8, a DNA replication mutant of Saccharomyces cerevisiae.

Summary A DNA replication mutant of yeast, cdc8, was found to decrease UV-induced reversion of lys2-1, arg4-17, tyr1 and ura1. This effect was observed with all three alleles of cdc8 tested. Survival curves obtained following UV irradiation in cdc8 rad double mutants show that cdc8 is epistatic to rad6, as well as to rad1; cdc8 rad51 double mutants seem to be more sensitive than the single mutants. Since UV-induced reversion in cdc8 rad1 and cdc8 rad51 double mutants is like that of the cdc8 single mutants, we conclude that CDC8 plays a direct role in error-prone repair. To test whether CDC8 codes for a DNA polymerase, we have purified both DNA polymerase I and DNA polymerase II from cdc8 and CDC+ cells. The purified DNA polymerases from cdc8 were no more heat labile than those from CDC+, suggesting that CDC8 is not a structural gene for either enzyme.     

A role for histone H2B during repair of UV-induced DNA damage in Saccharomyces cerevisiae

To investigate the role of the nucleosome during repair of DNA damage in yeast, we screened for histone H2B mutants that were sensitive to UV irradiation. We have isolated a new mutant, htb1-3, that shows preferential sensitivity to UV-C. There is no detectable difference in bulk chromatin structure or in the number of UV-induced cis-syn cyclobutane pyrimidine dimers (CPD) between HTB1 and htb1-3 strains. These results suggest a specific effect of this histone H2B mutation in UV-induced DNA repair processes rather than a global effect on chromatin structure. We analyzed the UV sensitivity of double mutants that contained the htb1-3 mutation and mutations in genes from each of the three epistasis groups of RAD genes. The htb1-3 mutation enhanced UV-induced cell killing in rad1Delta and rad52Delta mutants but not in rad6Delta or rad18Delta mutants, which are defective in postreplicational DNA repair (PRR). When combined with other mutations that affect PRR, the histone mutation increased the UV sensitivity of strains with defects in either the error-prone (rev1Delta) or error-free (rad30Delta) branches of PRR, but did not enhance the UV sensitivity of a strain with a rad5Delta mutation. When combined with a ubc13Delta mutation, which is also epistatic with rad5Delta, the htb1-3 mutation enhanced UV-induced cell killing. These results suggest that histone H2B acts in a novel RAD5-dependent branch of PRR.     

Two budding yeast RAD4 homologs in fission yeast play different roles in the repair of UV-induced DNA damage

We have identified two fission yeast homologs of budding yeast Rad4 and human xeroderma pigmentosum complementation group C (XP-C) correcting protein, designated Rhp4A and Rhp4B. Here we show that the rhp4 genes encode NER factors that are required for UV-induced DNA damage repair in fission yeast. The rhp4A-deficient cells but not the rhp4B-deficient cells are sensitive to UV irradiation. However, the disruption of both rhp4A and rhp4B resulted in UV sensitivity that was greater than that of the rhp4A-deficient cells, revealing that Rhp4B plays a role in DNA repair on its own. Fission yeast has two pathways to repair photolesions on DNA, namely, nucleotide excision repair (NER) and UV-damaged DNA endonuclease-dependent excision repair (UVER). Studies with the NER-deficient rad13 and the UVER-deficient (Delta)uvde mutants showed the two rhp4 genes are involved in NER and not UVER. Assessment of the ability of the various mutants to remove cyclobutane pyrimidine dimers (CPDs) from the rbp2 gene locus indicated that Rhp4A is involved in the preferential repair of lesions on the transcribed DNA strand and plays the major role in fission yeast NER. Rhp4B in contrast acts as an accessory protein in non-transcribed strand (NTS) repair.     

Repair of UV-irradiated plasmid DNA in a Saccharomyces cerevisiae rad3 mutant deficient in excision-repair of pyrimidine dimers

Summary The repair of UV-irradiated DNA of plasmid pBB29 was studied in an incision-defective rad3-2 strain of Saccharomyces cerevisiae and in a uvrA6 strain of Escherichia coli by the measurement of cell transformation. Plasmid pBB29 used in these experiments contained as markers the DNA of nuclear yeast gene LEU-2 and DNA of the bacterial plasmid pBR327 with resistance to Tet and Amp enabling simultaneous screening of transformant cells in both microorganisms.We found that the yeast rad3-2 mutant, deficient in incision of UV-induced pyrimidine dimers in nuclear DNA, was fully capable of repairing such lessions in plasmid DNA. The repair efficiency was comparable to that of the wild-type cells. The E. coli uvrA6 mutant, deficient in a specific nuclease for pyrimidine dimer excision from chromosomal DNA, was unable to repair UV-damaged plasmid DNA. The difference in repair capacity between the uvrA6 mutant strain and the wild-type strain was of several thousand-fold.It seems that the rad3 mutation, which confers deficiency in the DNA excision-repair system in yeast, is limited only to the nuclear DNA.     

Genetic analysis of the Neurospora crassa RAD14 homolog mus-43 and the RAD10 homolog mus-44 reveals that they belong to the mus-38 pathway of two nucleotide excision repair systems

Saccharomyces cerevisiae Rad14 and Rad10 proteins are essential for nucleotide excision repair (NER). Rad14 is a UV-damaged DNA binding protein and Rad10 is a structure-specific endonuclease that functions in a complex with Rad1. In this study, we identified and characterized the RAD14 and RAD10 homolog genes in Neurospora crassa, which we named mus-43 and mus-44, respectively. Disruption of mus-43 and mus-44 conferred sensitivity to UV and 4-nitroquinoline 1-oxide, but not to methyl methanesulfonate, N-methyl-N'-nitro-N-nitrosoguanidine, camptothecin, hydroxyurea, or bleomycin. The mus-44 mutant was more sensitive to UV than the mus-43 mutant. Genetic analysis indicated that mus-43 and mus-44 are epistatic to mus-38 which is a homolog of the S. cerevisiae RAD1, but not to mus-18 which belongs to a second excision repair pathway. Immunological assays demonstrated that both mus-43 and mus-44 retained the ability to excise UV-induced cyclobutane pyrimidine dimers and 6-4 photoproducts, but that excision ability was completely abolished in the mus-43 mus-18 and mus-44 mus-18 double mutants. These double mutants exhibited extremely high sensitivity to UV. In mus-43 and mus-44 mutants, the UV-induced mutation frequency increased compared to that of the wild-type. The mus-44 mutants also exhibited a partial photoreactivation defect phenotype similar to mus-38. These results suggest that both mus-43 and mus-44 function in the mus-38 NER pathway, but not in the mus-18 excision repair pathway.     

Repair of UV-irradiated plasmid DNA in mutants of Saccharomyces cerevisiae and Escherichia coli deficient in repair of pyrimidine dimers

The repair of in vitro UV-irradiated DNA of plasmid pBB29 was studied in excision defective yeast mutants rad1, rad2, rad3, rad4, rad10 and in Escherichia coli mutants uvr- and recA-, by measuring the cell transformation frequency. Rad2, rad3, rad4, and rad10 mutants could repair plasmid DNA despite their inability to repair nuclear DNA, whereas the reduced ability of rad1 mutant for plasmid DNA repair demonstrated alone the same dependence on the host functions that are needed for nuclear DNA repair. In E. coli the repair of UV-irradiated plasmid DNA is carried out only by the excision-repair system dependent on uvr genes. Treatment of UV-irradiated plasmid DNA with UV endonuclease from Micrococcus luteus greatly enhances the efficiency of transformation of E. coli uvr- mutants. Similar treatment with cell-free extracts of yeast rad1 mutant or wild-type strains as well as with nuclease BaL31, despite their ability for preferential cutting of UV damaged DNA, showed no influence on cell transformation.     

Defective thymine dimer excision in radiation-sensitive mutants rad10 and rad16 of Saccharomyces cerevisiae

Summary Two rad mutants of yeast, rad10 and rad16, are shown to be defective in the removal of UV-induced pyrimidine dimers since DNAs obtained from irradiated cells following a post-irradiation incubation in the dark still retain UV-endonuclease-sensitive sites. Both rad10 and rad16 mutants are in the same pathway of excision-repair as the rad1, rad2, rad3 and rad4 mutants.     

Epistatic interactions between four rad loci in yeast

Haploid yeast strains carrying mutations in two or more of four ad genes were contrusted by tetrad dissection, and the UV survival of these strains was measured. It was found that (with one exception) double mutant strains were not significantly more sensitive than the most sensitive single mutants, for strains involving mutant loci rad 1, rad 3 and rad 4. The exception was the double mutant rad 1–5 rad 4-4, but another double mutant involving different alleles of the the same loci did not show an enhanced UV sensitivity. Triple and quadruple mutants also failed to show a significantly increased UV sensitivity with respect to the single mutants. The results indicate that all these four mutant loci confer UV sensitivity by the same mechanism, and it is suggested that the wild-type alleles mediate excision-repair of UV-induced DNA lesions. Enhanced sensitivity of the genotype rad 1–5 rad 4-4 is attributed to leakiness of these alleles.     

A similar defect in UV-induced mutagenesis conferred by the rad6 and rad18 mutations of Saccharomyces cerevisiae

The single rad6 and rad18 yeast mutants share a number of physiological and biochemical properties related to DNA repair, suggesting that they affect closely related steps. However, it has been reported that UV-induced mutagenesis is considerably more depressed in rad6 than it is in rad18 cells. In an attempt to better understand the role of these genes, a genetic system believed to differentiate between targeted and untargeted events was used. The data are interpreted to mean that both mutations prevent the occurrence of targeted events, as if they prevent error-prone replication in front of pyrimidine dimers. The number of non-targeted mutants per survivor in each mutant was increased by UV irradiation. This may correspond to a stimulation of the error-prone replication.     

Repair of pyrimidine dimers in radiation-sensitive mutants rad3, rad4, rad6 and rad9 of Saccharomyces cerevisiae.

The ability to remove ultraviolet (UV)-induced pyrimidine dimers was examined in four radiation-sensitive mutants of Saccharomyces cerevisiae. The susceptibility of DNA from irradiated cells to nicking by either the T4 UV-endonuclease or an endonuclease activity found in crude extracts of Micrococcus luteus was used to measure the presence of dimers in DNA. The rad3 and rad4 mutants are shown to be defective in dimer excision whereas the rad6 and rad9 mutants are proficient in dimer excision.     

Characterization of postreplication repair in Saccharomyces cerevisiae and effects of rad6, rad18, rev3 and rad52 mutations

Summary Postreplication repair of nuclear DNA was examined in an excision defective haploid strain of yeast lacking mitochondrial DNA (ral ⁰). The size of the DNA synthesized in cells exposed to various fluences of ultraviolet light (UV) corresponds approximately to the average interdimer distance in the parental DNA. Upon further incubation of cells following exposure to 2.5 J/m², the DNA increases in size; by 4 h, it corresponds to DNA from uniformly labeled cells. The alkaline sucrose sedimentation pattern of DNA pulse labeled at various times after UV irradiation, for up to 4 h, does not change substantially, indicating that dimers continue to block DNA replication. A significant amount of postreplication repair requires de novo protein synthesis, as determined by its inhibition by cycloheximide. The rad6 mutant does not carry out postreplication repair, the rad18 and rad52 mutants show great inhibition while the rev3 mutation does not affect postreplication repair. Both recombinational and nonrecombinational repair mechanisms may function in postreplication repair and most of postreplication repair is error free.     

Interaction between checkpoint genes RAD9, RAD17, RAD24, and RAD53 involved in the determination of yeast Saccharomyces cerevisiae sensitivity to ionizing radiation

Mechanisms for genetic control of cell division cycle (checkpoint control) have been studied in most detail in yeast Saccharomyces cerevisiae. To clarify the role of checkpoint genes RAD9, RAD17, RAD24, and RAD53 in cell radioresistance, double mutants were analyzed for cell sensitivity to ionizing radiation. Double mutants carrying mutations in combination with mutation rad9Delta were shown to manifest the epistatic type of interaction. Our results suggest that checkpoint genes RAD9, RAD17, RAD24, and RAD53 belong to a single epistatic group designated RAD9 and govern the same pathway. Genes RAD9 and RAD53 have a positive effect on sensitivity to gamma-radiation, whereas RAD17 and RAD24 have a negative effect. Interactions between mutations may differ when considering their sensitivity to gamma-radiation and UV light; mutations rad9Delta and rad24Delta were shown to manifest the additive effect in the first case and epistatic effect in the second.     

Interaction between checkpoint genes RAD9, RAD17, RAD24, and RAD53 involved in the determination of yeast Saccharomyces cerevisiae sensitivity to ionizing radiation

Mechanisms for genetic control of cell division cycle (checkpoint control) have been studied in most detail in yeast Saccharomyces cerevisiae. To clarify the role of checkpoint genes RAD9, RAD17, RAD24, and RAD53 in cell radioresistance, double mutants were analyzed for cell sensitivity to ionizing radiation. Double mutants carrying mutations in combination with mutation rad9delta were shown to manifest the epistatic type of interaction. Our results suggest that checkpoint genes RAD9, RAD17, RAD24, and RAD53 belong to a single epistatic group designated RAD9 and govern the same pathway. Genes RAD9 and RAD53 have a positive effect on sensitivity to gamma-radiation, whereas RAD17 and RAD24 have a negative effect. Interactions between mutations may differ when considering their sensitivity to gamma-radiation and UV light; mutations rad9delta and rad24delta were shown to manifest the additive effect in the first case and epistatic effect in the second.     

Molecular cloning of eucaryotic genes required for excision repair of UV-irradiated DNA: isolation and partial characterization of the RAD3 gene of Saccharomyces cerevisiae.

We describe the molecular cloning of a 6-kilobase (kb) fragment of yeast chromosomal DNA containing the RAD3 gene of Saccharomyces cerevisiae. When present in the autonomously replicating yeast cloning vector YEp24, this fragment transformed two different UV-sensitive, excision repair-defective rad3 mutants of S. cerevisiae to UV resistance. The same result was obtained with a variety of other plasmids containing a 4.5-kb subclone of the 6-kb fragment. The UV sensitivity of mutants defective in the RAD1, RAD2, RAD4, and RAD14 loci was not affected by transformation with these plasmids. The 4.5-kb fragment was subcloned into the integrating yeast vector YIp5, and the resultant plasmid was used to transform the rad3-1 mutant to UV resistance. Both genetic and physical studies showed that this plasmid integrated by homologous recombination into the rad3 site uniquely. We conclude from these studies that the cloned DNA that transforms the rad3-1 mutant to UV resistance contains the yeast chromosomal RAD3 gene. The 4.5-kb fragment was mapped by restriction analysis, and studies on some of the subclones generated from this fragment indicate that the RAD3 gene is at least 1.5 kb in size.     

The RAD7 and RAD16 genes, which are essential for pyrimidine dimer removal from the silent mating type loci, are also required for repair of the nontranscribed strand of an active gene in Saccharomyces cerevisiae.

The rad16 mutant of Saccharomyces cerevisiae was previously shown to be impaired in removal of UV-induced pyrimidine dimers from the silent mating-type loci (D. D. Bang, R. A. Verhage, N. Goosen, J. Brouwer, and P. van de Putte, Nucleic Acids Res. 20:3925-3931, 1992). Here we show that rad7 as well as rad7 rad16 double mutants have the same repair phenotype, indicating that the RAD7 and RAD16 gene products might operate in the same nucleotide excision repair subpathway. Dimer removal from the genome overall is essentially incomplete in these mutants, leaving about 20 to 30% of the DNA unrepaired. Repair analysis of the transcribed RPB2 gene shows that the nontranscribed strand is not repaired at all in rad7 and rad16 mutants, whereas the transcribed strand is repaired in these mutants at a fast rate similar to that in RAD+ cells. When the results obtained with the RPB2 gene can be generalized, the RAD7 and RAD16 proteins not only are essential for repair of silenced regions but also function in repair of nontranscribed strands of active genes in S. cerevisiae. The phenotype of rad7 and rad16 mutants closely resembles that of human xeroderma pigmentosum complementation group C (XP-C) cells, suggesting that RAD7 and RAD16 in S. cerevisiae function in the same pathway as the XPC gene in human cells. RAD4, which on the basis of sequence homology has been proposed to be the yeast XPC counterpart, seems to be involved in repair of both inactive and active yeast DNA, challenging the hypothesis that RAD4 and XPC are functional homologs.     

DNA-repair characterization of cdc40-1, a cell-cycle mutant of Saccharomyces cerevisiae

The cell-cycle specific mutation cdc40-1, which has been previously shown to be sensitive to MMS at the restrictive temperature, was further characterized as a DNA-repair-deficient mutation. cdc40-1 mutants shown only slight sensitivity to UV irradiation. Double mutant studies shown that rad6-l is epistatic to cdc40-1 with respect to sensitivity to UV irradiation and MMS. rad50-1 is epistatic to cdc40-1 with respect to MMS sensitivity in G1 stationary cells, but not in logarithmic cultures. An additive effect is seen between cdc40-1 and rad50-1 with respect to UV irradiation. cdc40-1 mutants are defective in UV-induced mutagenesis at the restrictive temperature. UV-induced levels of recombination are normal at both temperatures, while MMS-induced recombination is enhanced at the restrictive temperature.     

Repair of Pyrimidine Dimer Damage Induced in Yeast by Ultraviolet Light

Crude extracts from ultraviolet (UV)-irradiated yeast cells compete with UV-irradiated transforming deoxyribonucleic acid (DNA) for photoreactivating enzyme. The amount of competition is taken as a measure of the level of cyclobutyl pyrimidine dimers in the yeast DNA. A calibration of the competition using UV-irradiated calf thymus DNA indicates that an incident UV dose (1,500 ergs/mm(2)) yielding 1% survivors of wild-type cells produces between 2.5 x 10(4) to 5 x 10(4) dimers per cell. Wild-type cells irradiated in the exponential phase of growth remove or alter more than 90% of the dimers within 220 min after irradiation. Pyrimidine dimers induced in stationary-phase wild-type cells appear to remain in the DNA; however, with incubation, they become less photoreactivable in vivo, although remaining photoreactivable in vitro. In contrast, exponentially growing or stationary-phase UV-sensitive cells (rad2-17) show almost no detectable alteration of dimers. We conclude that the UV-sensitive cells lack an early step in the repair of UV-induced pyrimidine dimers.     

Meiotic DNA Metabolism in Wild-Type and Excision-Deficient Yeast following Uv Exposure

The effects of UV irradiation on DNA metabolism during meiosis have been examined in wild-type (RAD⁺) and mitotically defined excision-defective (rad1-1) strains of Saccharomyces cerevisiae that exhibit high levels of sporulation. The rad1-1 gene product is not required for normal meiosis: DNA synthesis, RNA synthesis, size of parental and newly synthesized DNA and sporulation are comparable in RAD⁺ and rad1-1 strains. Cells were UV irradiated at the beginning of meiosis, and the fate of UV-induced pyrimidine dimers as well as changes in DNA and DNA synthesis were followed during meiosis. Excision repair of pyrimidine dimers can occur during meiosis and the RAD1 gene product is required; alternate excision pathways do not exist. Although the rate of elongation is decreased, the presence of pyrimidine dimers during meiosis in the rad1-1 strain does not block meiotic DNA synthesis suggesting a bypass mechanism. The final size of DNA is about five times the distance between pyrimidine dimers after exposure to 4 J/m². Since pyrimidine dimers induced in parental strands of rad1-1 prior to premeiotic DNA synthesis do not become associated with newly synthesized DNA, the mechanism for replicational bypass does not appear to involve a recombinational process. The absence of such association indicates that normal meiotic recombination is also suppressed by UV-induced damage in DNA; this result at the molecular level is supported by observations at the genetic level.