Interactions of the RAD7 and RAD23 excision repair genes of Saccharomyces cerevisiae with DNA repair genes in different epistasis groups

Summary The RAD7 and RAD23 genes of S. cerevisiae affect the efficiency of excision repair of UV-damaged DNA. We have examined the UV survival of strains carrying the rad7 or rad23 deletion mutation in combination with deletion mutations in genes affecting different DNA repair pathways. As expected, the rad7 and rad23 mutations interact epistatically with the excision repair defective rad1 mutation, and synergistically with the rad6 and rad52 mutations that affect the postreplication repair and recombinational repair pathways, respectively. However, the rad7rad6 and the rad23rad6 mutants exhibit the same level of UV sensitivity as the radlrad6 mutant. This observation is of interest since, in contrast to the rad7 or the rad23 mutations, the rad1 mutant is very UV sensitive and highly excision defective. This observation suggests that RAD6 and RAD7 and RAD23 genes compete for the same substrate during DNA repair.     

The Saccharomyces cerevisiae RAD2 gene complements a Schizosaccharomyces pombe repair mutation

Summary Two Saccharomyces cerevisiae genes necessary for excision repair of UV damage in DNA, RAD1 and RAD2, were introduced individually, on a yeast shuttle vector, into seven Schizosaccharomyces pombe mutants — rads1, 2, 5, 13, 15,16 and 17. The presence of the cloned RAD1 gene did not affect survival of any of the S. pombe mutants. The RAD2 gene increased survival of S. pombe rad13 to near the wild-type level after UV irradiation and had no effect on any of the other mutants tested. S. pombe rad13 mutants are somewhat defective in removal of pyrimidine dimers so complementation by the S. cerevisiae RAD2 gene suggests that the genes may code for equivalent proteins in the two yeasts.     

The PSO4 gene of S. cerevisiae is important for sporulation and the meiotic DNA repair of photoactivated psoralen lesions

We have evaluated the effect of the Saccharomyces cerevisiae pso4-1 mutation in sporulation and DNA repair during meiosis. We have found that pso4-1 cells were arrested in an early step of meiosis, before premeiotic DNA synthesis, and hence did not produce spores. These results suggest that the PSO4 gene may act at the start point of the cell cycle, as do some SPO and CDC genes. The pso4-1 mutant cells are specifically sensitive to 8-MOP- and 3-CPs-photoinduced lesions, and are found to be severely affected in meiotic recombination as well as impaired in the mutagenic response, as previously described for mitosis. This means that the PSO4 gene is important for the repair 8-MOP-photoinduced lesions, mainly double-strand breaks, and the processing of these lesions into recombinogenic intermediates.     

DNA polymerase III is required for DNA repair in Saccharomyces cerevisiae

We have studied the role of DNA polymerase III, encoded in S. cerevisiae by the CDC2 gene, in the repair of yeast nuclear DNA. It was found that the repair of MMS-induced single-strand breaks is defective in the DNA polymerase III temperature-sensitive mutant cdc2-1 at the restrictive temperature (37 °C), but is not affected at the permissive temperature (23 °C). Under conditions where only a small number of lesions was introduced into DNA (80% survival), the repair of MMS-induced damage could also be observed in the mutant at the restrictive temperature, although with low efficiency. When the quantity of lesions increased (50% survival or less), the repair of single-strand breaks was blocked. At the same time we observed a high rate of reversion in the meth, his and trp loci of the cdc2-1 mutant under restrictive conditions. The results presented suggest that DNA polymerase III is involved in the repair of MMS-induced lesions in yeast DNA and that the cdc2-1 mutation affects the proofreading activity of this polymerase.     

RAD58 (XRS4)—A new gene in the RAD52 epistasis group

The RAD58 (XRS4) gene of Saccharomyces cerevisiae has been previously identified as a DNA repair gene. In this communication, we show that RAD58 also encodes an essential meiotic function. The spore inviability of rad58 strains is not rescued by a spo13 mutation. The rad50 mutation suppresses spore inviability of a spo13 rad58 strain suggesting that RAD58 acts after RAD50 in meiotic recombination. The rad58-4 mutation does not prevent mitotic recombination events. Haploid rad58 cells fail to carry out G₂-repair of gamma-induced lesions, whereas rad58/rad58 diploids are able to perform some diploid-specific repair of these lesions.     

The regulation of mitochondrial DNA levels in Saccharomyces cerevisiae

Summary Mitochondrial DNA (mtDNA) synthesis can continue under conditions which block cell division and nuclear DNA (nDNA) synthesis, producing cells with several times the normal level of mtDNA. We have examined mtDNA synthesis in cultures recovering from such cell cycle blocks. Our results show that the rate of mtDNA synthesis is not affected either during a block of the cell cycle with -factor or during recovery from a perturbation in the amount of mtDNA/cell induced by blocking the cell cycle with -factor or cdc4. The normal mtDNA content was restored a period of several generations when permissive conditions were restored. These results suggest that mtDNA synthesis is coupled to cell growth.     

Cloning and integrative deletion of the RAD6 gene of Saccharomyces cerevisiae

Summary Three overlapping plasmids were isolated from a YEp24 library, which restore Rad+ functions to rad6-1 and rad6-3 mutants. Different subclones were made and shown to integrate by homologous recombination at the RAD6 site on chromosome VII, thus verifying the cloned DNA segments to be the RAD6 gene and not a suppressor. The gene resides in a 1.15 kb fragment, which restores Rad⁺ levels of resistance to U.V., MMS and -rays to both rad6-1 and rad6-3 strains. It also restores sporulation ability to rad6-1 diploids.Integrative deletion of the RAD6 gene was shown not to be completely lethal to the yeast. Our results suggest that the RAD6 gene has some cell cycle-specific function(s), probably during late S phase.     

The CDC8 gene product is required for transformation with episomal and integrative plasmids in Saccharomyces cerevisiae

Summary The product of the yeast CDC8 gene (thymidylate kinase), which is required for chromosomal, mitochondrial and 2 plasmid replication, also participates in plasmid transformation processes in S. cerevisiae. The thermosensitive cdc8-1 mutant strain was transformed with episomal pDQ9 and integrative pDQ9-1 plasmids both of which carry the CDC8 gene. The results suggest that thymidylate kinase is essential for the expression of genes carried on transforming episomal plasmid DNA (probably through its replication) and is also essential for homologous recombination between chromosomal and linearized integrative plasmid DNA.     

Inhibition of DNA replication in Saccharomyces cerevisiae by araCMP

Summary Cytosine arabinoside (araC), a potent inhibitor of DNA replication in mammalian cells, was found to be completely ineffective in Saccharomyces cerevisiae. The 5 monophosphate derivative, araCMP, is toxic and effectively inhibits both nuclear and mitochondrial DNA synthesis in this organism. Although wild-type strains can be inhibited by araCMP, dTMP permeable (tup ^-) strains were found to be much more sensitive to the analogue. In vivo labelling experiments indicate that araC enters yeast cells; however, it is extensively catabolized by deamination and breakage of the glycosidic bond. In addition, the analogue is not efficiently phosphorylated in S. cerevisiae owing to an apparent lack of deoxynucleoside kinase activity. These results provide further evidence that deoxyribonucleotides can be synthesized only through de novo pathways in this organism. Finally, araCMP was found to be recombinagenic in S. cerevisiae which suggests, together with other previous studies, that, in general, inhibition of DNA synthesis in yeast promotes mitotic recombination events.     

The UV excision-repair system of Saccharomyces cerevisiae is involved in the removal of methylcytosines formed in vivo by a cloned prokaryotic DNA methyltransferase

Summary DNA methyltransferase activity is not normally found in yeast. To investigate the response of Saccharomyces cerevisiae to the presence of methylated bases, we introduced the Bacillus subtilis SPR phage DNA-[cytosine-5] methyltransferase gene on the shuttle vector, YEp51. The methyltransferase gene was functionally expressed in yeast under the control of the inducible yeast GAL10 promoter. Following induction we observed a time-dependent methylation of yeast DNA in RAD ⁺ and rad2 mutant strains; the rad2 mutant is defective in excision-repair of UV-induced DNA damage. Analysis of restriction endonuclease digestion patterns revealed that the relative amount of methylated DNA was greater in the excision defective rad2 mutant than in the RAD ⁺ strain. These data indicate that the yeast excision-repair system is capable of recognizing and removing m⁵C residues.     

Chromium resistant mutants of the yeast Saccharomyces cerevisiae

Summary Many strains of Saccharomyces cerevisiae do not grow on YPD agar containing 750 g/ml CrO₃. Mutants able to grow in the presence of 850 g/ml CrO₃ were obtained from such strains after UV mutagenesis. All of the mutants grew even in the presence of 1,000 /ml CrO₃. Chromium resistance was dominant or partial dominant over normal response, therefore it was impossible to determine the number of genetic loci by complementation analysis. However, the segregation of representative mutants strongly indicated that resistance was determined by single mutations. In addition, a limited analysis of recombination suggested that the chromium resistant mutations were located on a certain region of the yeast genome. Although it was determined that the mutants had slightly reduced rates of Cr⁶⁺ uptake, the exact mechanism of resistance was not discovered. According to the studies of interactions between resistant mutations and sensitive mutations, however, we have proposed a preliminary pathway of Cr⁶⁺ detoxification.     

Cloning and characterization of the SKI3 gene of Saccharomyces cerevisiae demonstrates allelism to SKI5

Summary We have identified a mutant strain of the yeast Saccharomyces cerevisiae which overproduces killer toxin. This strain contains a single mutation which fails to complement defects in both the SKI3 and SKI5 genes, while a cloned copy of this gene complements both the ski3 and ski5 defects. The level of secreted toxin from a cDNA based plasmid is not increased in a ski3 strain, showing that the overproduction phenotype is dependent upon an increased level of M1 dsRNA.     

Resistance to cadmium is under the control of the CAD2 gene in the yeast Saccharomyces cerevisiae

Summary A cadmium-resistant strain, X3382-3A, which is able to grow in a medium containing 0.2 mM cadmium sulfate, was picked out from our laboratory stock strains of Saccharomyces cerevisiae. The cadmium resistance of this strain is controlled by a single dominant nuclear gene, denoted as CAD2. The locus of CAD2 was mapped by gene linkage to a site 15.5 centimorgans to the right of the his7 locus on the right arm of chromosome II. The cadmium resistance of the strain carrying CAD2 was evaluated for its properties of cadmium uptake, cadmium distribution and cadmium-metallothionein formation, in comparison with those of some other strains. The results suggest that the novel type of cadmium resistance controlled by CAD2 does not involve production of a cadmiumm-metallothionein.     

Inhibition of thymidylate biosynthesis induces mitotic unequal sister chromatid recombination in Saccharomyces cerevisiae

Summary Inhibition of thymidylate biosynthesis has been found to induce deletion of a LEU2 insert from the ribosomal DNA gene cluster of haploid strains of Saccharomyces cerevisiae. Loss of the insert was detected phenotypically by the enhanced production of both sectored (leu⁺/leu^–) and non-sectored (leu^–) colonies. Hybridization patterns obtained by Southern blot analysis of DNA from the leu⁺ and leu^– sectors were consistent with the occurrence of unequal sister chromatid recombination. The induction of sectored colonies was prevented by the rad52-1 mutation but not by defects in RAD6. However, the formation of non-sectored leu^– colonies was induced by thymidylate depletion in both rad52-1 and rad6 strains.     

Cloning and mapping of CDC40, a Saccharomyces cerevisiae gene with a role in DNA repair

Summary The cdc40 mutation has been previously shown to be a heat-sensitive cell-division-cycle mutation. At the restrictive temperature, cdc40 cells arrest at the end of DNA replication, but retain sensitivity to hydroxyurea (Kassir and Simchen 1978). The mutation has also been shown to affect commitment to meiotic recombination and its realization. Here we show that mutant cells are extremely sensitive to Methyl-Methane Sulfonate (MMS) when the treatment is carried out at restrictive temperature. Incubation at 37 °C prior to, or after MMS treatment at 23 °C, does not result in lower survival. It is concluded that the CDC40 gene product has a role in DNA repair, possibly holding together or protecting the DNA during the early stages of repair.The CDC40 gene was cloned on a 2.65 kb DNA fragment. A 2 plasmid carrying the gene was integrated and mapped to chromosome IV, between trp4 and ade8, by the method of marker loss. Conventional tetrad analysis has shown cdc40 to map 1.7 cM from trp4.     

In-vitro recombination in rad and rnc mutants of Saccharomyces cerevisiae

Summary Extracts of S. cerevisiae cells can catalyze homologous recombination between plasmids in vitro. Extracts prepared from rad50, rad52 or rad54 disruption mutants all have reduced recombinational activity compared to wild-type. The rad52 and rad54 extracts are more impaired in the recombination of plasmids containing double-strand breaks than of intact plasmids, whereas rad50 extracts are deficient equally for both types of substrate. The nuclease RhoNuc (previously designated yNucR), encoded by the RNC1 (previously designated NUC2) gene and regulated by the RAD52 gene, is not required for recombination when one substrate is single-stranded but is essential for the majority of recombination events when both substrates are double-stranded. Furthermore, elimination of this nuclease restores recombination in rad52 extracts to levels comparable to those in wild-type extracts.     

A DNA sequence in Saccharomyces exiguus is homologous with the HO gene of Saccharomyces cerevisiae

Summary The DNA of Saccharomyces exiguus was analyzed by Southern hybridization using cloned MATa, MAT, and HO genes of Saccharomyces cerevisiae as probes. It was shown that S. exiguus has a DNA sequence homologous with the HO gene of S. cerevisiae and that this DNA sequence is on a chromosome of about 940 kb of DNA in S. exiguus. However, there is no DNA sequence in S. exiguus that is homologous with the MAT genes of S. cerevisiae.     

Mechanism of resistance to sulphite in Saccharomyces cerevisiae

Growth inhibition and cell killing caused by sulphite were reduced in seven Saccharomyces cerevisiae sulphite-resistant independent mutants, compared to their parental strains. Genetic analysis showed that in the seven mutants resistance was inherited as a single-gene dominant mutation and that all the analyzed mutations were allelic, thus identifying a major gene responsible for sulphite resistance in S. cerevisiae. Two of the mutants, MBS20-9 and MBS30, were further characterized. ³⁵S-sulphite uptake experiments showed that the ability to accumulate sulphite was markedly reduced in the two resistant strains. No difference between resistant and sensitive strains with respect to glyceraldehyde-3-phosphate dehydrogenase sensitivity to sulphite, or to intracellular glutathione content, were revealed. In contrast, the extracellular acetaldehyde concentration was higher in the resistant mutants, both in the presence and in the absence of sulphite.     

Hyperresistance to formaldehyde of Saccharomyces cerevisiae seems not to be correlated with the formation and removal of DNA protein cross-links

Summary The formation and removal of formaldehyde-mediated DNA protein cross-linking was measured by CsCI density gradient analysis in yeast strains of differing resistance to formaldehyde. Wild-type cells and transformants made hyperresistant to formaldehyde by a multi-copy vector containing the yeast SFA gene were specifically labeled in their DNA and incubated in the presence of formaldehyde. Treatment with formaldehyde lead to the formation of equal amounts of DNA protein cross-links; subsequent liquid holding of cells for 24 h resulted in the removal of nearly all DNA protein crosslinks regardless of the original formaldehyde resistance status of the strains.     

Gene PSO5 of Saccharomyces cerevisiae,involved in repair of oxidative DNA damage,is allelic to RAD16

The pos5-1 mutation renders Saccharomyces cerevisiae cells sensitive to DNA-damaging agents. We have isolated plasmids from a S. cerevisiae genomic library capable of restoring wild-type levels of 254-nm ultraviolet light sensitivity of the pso5-1 mutant. DNA sequence analysis revealed that the complementing activity resides in RAD16, a gene involved in excision repair. Tetrad analysis showed that PSO5, like RAD16, is tightly linked to LYS2 on chromosome II. Moreover, allelism between the pso5-1 and rad16 mutants was demonstrated by the comparison of mutagen sensitivity phenotypes, complementation tests, and by meiotic analysis. The cloned RAD16 gene was capable of restoring wild-type resistance of the pso5-1 mutant to H₂O₂ and photoactivated 3-carbethoxypsoralen, both treatments generating oxidative stress-related DNA damage. This indicates that RAD16/PSO5 might also participate in the repair of oxidative base damage.