RAD29 and RAD31--new genes from Saccharomyces cerevisiae yeasts, participating in control of DNA repair. II. Clarification of possible functions of these genes

Possible functions of previously described genes RAD29 and RAD31 involved in DNA repair were determined by analyzing the interaction between these genes and mutations in the genes of the three basic epistatic groups: RAD3 (nucleotide excision repair), RAD6 (error-prone mutagenic repair system), RAD52 (recombination repair pathway), and also the apn1 mutation that blocks the synthesis of major AP endonuclease (base excision repair). The results obtained in these studies and the estimation of the capability for excision repair of lesions induced by 8-metoxipsoralen and subsequent exposure to long-wavelength UV light in mutants for these genes led to the assumption that the RAD29 and RAD31 genes are involved in yeast DNA repair control.     

DNA repair defects channel interstrand DNA cross-links into alternate recombinational and error-prone repair pathways

The repair of psoralen interstrand cross-links in the yeast Saccharomyces cerevisiae involves the DNA repair groups nucleotide excision repair (NER), homologous recombination (HR), and post-replication repair (PRR). In repair-proficient yeast cells cross-links induce double-strand breaks, in an NER-dependent process; the double-strand breaks are then repaired by HR. An alternate error-prone repair pathway generates mutations at cross-link sites. We have characterized the repair of plasmid molecules carrying a single psoralen cross-link, psoralen monoadduct, or double-strand break in yeast cells with deficiencies in NER, HR, or PRR genes, measuring the repair efficiencies and the levels of gene conversions, crossing over, and mutations. Strains with deficiencies in the NER genes RAD1, RAD3, RAD4, and RAD10 had low levels of cross-link-induced recombination but higher mutation frequencies than repair-proficient cells. Deletion of the HR genes RAD51, RAD52, RAD54, RAD55, and RAD57 also decreased induced recombination and increased mutation frequencies above those of NER-deficient yeast. Strains lacking the PRR genes RAD5, RAD6, and RAD18 did not have any cross-link-induced mutations but showed increased levels of recombination; rad5 and rad6 cells also had altered patterns of cross-link-induced gene conversion in comparison with repair-proficient yeast. Our observations suggest that psoralen cross-links can be repaired by three pathways: an error-free recombinational pathway requiring NER and HR and two PRR-dependent error-prone pathways, one NER-dependent and one NER-independent.     

Excision repair of DNA in nuclear extracts from the yeast Saccharomyces cerevisiae.

Excision repair of DNA is an important cellular response to DNA damage caused by a broad spectrum of physical and chemical agents. We have established a cell-free system in which damage-specific DNA repair synthesis can be demonstrated in vitro with nuclear extracts from the yeast Saccharomyces cerevisiae. Repair synthesis of UV-irradiated plasmid DNA was observed in a radiation dose-dependent manner and was unaffected by mutations in the RAD1, RAD2, RAD3, RAD4, RAD10, or APN1 genes. DNA damaged with cis-platin was not recognized as a substrate for repair synthesis. Further examination of the repair synthesis observed with UV-irradiated DNA revealed that it is dependent on the presence of endonuclease III-sensitive lesions in DNA, but not pyrimidine dimers. These observations suggest that the repair synthesis observed in yeast nuclear extracts reflects base excision repair of DNA. Our data indicate that the patch size of this repair synthesis is at least seven nucleotides. This system is expected to facilitate the identification of specific gene products which participate in base excision repair in yeast.     

Cells expressing murine RAD52 splice variants favor sister chromatid repair

The RAD52 gene is essential for homologous recombination in the yeast Saccharomyces cerevisiae. RAD52 is the archetype in an epistasis group of genes essential for DNA damage repair. By catalyzing the replacement of replication protein A with Rad51 on single-stranded DNA, Rad52 likely promotes strand invasion of a double-stranded DNA molecule by single-stranded DNA. Although the sequence and in vitro functions of mammalian RAD52 are conserved with those of yeast, one difference is the presence of introns and consequent splicing of the mammalian RAD52 pre-mRNA. We identified two novel splice variants from the RAD52 gene that are expressed in adult mouse tissues. Expression of these splice variants in tissue culture cells elevates the frequency of recombination that uses a sister chromatid template. To characterize this dominant phenotype further, the RAD52 gene from the yeast Saccharomyces cerevisiae was truncated to model the mammalian splice variants. The same dominant sister chromatid recombination phenotype seen in mammalian cells was also observed in yeast. Furthermore, repair from a homologous chromatid is reduced in yeast, implying that the choice of alternative repair pathways may be controlled by these variants. In addition, a dominant DNA repair defect induced by one of the variants in yeast is suppressed by overexpression of RAD51, suggesting that the Rad51-Rad52 interaction is impaired.     

Sister chromatid-based DNA repair is mediated by RAD54, not by DMC1 or TID1

In the mitotic cell cycle of the yeast Saccharomyces cerevisiae, the sister chromatid is preferred over the homologous chromosome (non-sister chromatid) as a substrate for DNA double-strand break repair. However, no genes have yet been shown to be preferentially involved in sister chromatid-mediated repair. We developed a novel method to identify genes that are required for repair by the sister chromatid, using a haploid strain that can embark on meiosis. We show that the recombinational repair gene RAD54 is required primarily for sister chromatid-based repair, whereas TID1, a yeast RAD54 homologue, and the meiotic gene DMC1, are dispensable for this type of repair. Our observations suggest that the sister chromatid repair pathway, which involves RAD54, and the homologous chromosome repair pathway, which involves DMC1, can substitute for one another under some circumstances. Deletion of RAD54 in S.cerevisiae results in a phenotype similar to that found in mammalian cells, namely impaired DNA repair and reduced recombination during mitotic growth, with no apparent effect on meiosis. The principal role of RAD54 in sister chromatid-based repair may also be shared by mammalian and yeast cells.     

The role of homologous recombination processes in the repair of severe forms of DNA damage in mammalian cells

The role of homologous recombination processes in the repair of severe forms of DNA damage is reviewed, with particular attention to the functions of members of the recA/RAD51 family of genes. In the yeast Saccharomyces cerevisiae, several of the gene products involved in homologous recombination repair (HRR) have been studied in detail, and a picture is beginning to emerge of the repair mechanism for DNA double-strand breaks. Knowledge is fragmentary for other eukaryotic organisms and for other types of DNA damage. In mammalian cells, while it has been known for some years that HRR occurs, the relative importance of the process in repairing DNA damage is unknown and very few of the gene products involved have been identified. Very recently, a number of RAD51-like genes have been identified in mammals, either through cloning genes complementing cell lines sensitive to DNA-damaging agents (XRCC2, XRCC3), or through homology searches (RAD51L1, RAD51L2, RAD51L3). As yet the role of these genes and their possible functions are speculative, although the combination of sequence conservation and gene expression patterns suggest that they function in HRR pathways.     

Dual cell cycle checkpoints sensitive to chromosome replication and DNA damage in the budding yeast Saccharomyces cerevisiae.

In eucaryotic cells chromosomes must be fully replicated and repaired before mitosis begins. Genetic studies indicate that this dependence of mitosis on completion of DNA replication and DNA repair derives from a negative control called a checkpoint which somehow checks for replication and DNA damage and blocks cell entry into mitosis. Here we summarize our current understanding of the genetic components of the cell cycle checkpoint in budding yeast. Mutants were identified and their phase and signal specificity tested primarily through interactions of the arrest-defective mutants with cell division cycle mutants. The results indicate that dual checkpoint controls exist in budding yeast, one control sensitive to inhibition of DNA replication (S-phase checkpoint), and a distinct but overlapping control sensitive to DNA repair (G2 checkpoint). Six genes are required for arrest in G2 phase after DNA damage (RAD9, RAD17, RAD24, MEC1, MEC2, and MEC3), and two of these are also essential for arrest in S phase when DNA replication is blocked (MEC1 and MEC2).     

A new recombinational DNA repair gene from Schizosaccharomyces pombe with homology to Escherichia coli RecA.

A new DNA repair gene from Schizosaccharomyces pombe with homology to RecA was identified and characterized. Comparative analysis showed highest similarity to Saccharomyces cerevisiae Rad55p. rhp55(+) (rad homologue pombe 55) encodes a predicted 350-amino-acid protein with an M(r) of 38,000. The rhp55Delta mutant was highly sensitive to methyl methanesulfonate (MMS), ionizing radiation (IR), and, to a lesser degree, UV. These phenotypes were enhanced at low temperatures, similar to deletions in the S. cerevisiae RAD55 and RAD57 genes. Many rhp55Delta cells were elongated with aberrant nuclei and an increased DNA content. The rhp55 mutant showed minor deficiencies in meiotic intra- and intergenic recombination. Sporulation efficiency and spore viability were significantly reduced. Double-mutant analysis showed that rhp55(+) acts in one DNA repair pathway with rhp51(+) and rhp54(+), homologs of the budding yeast RAD51 and RAD54 genes, respectively. However, rhp55(+) is in a different epistasis group for repair of UV-, MMS-, or gamma-ray-induced DNA damage than is rad22(+), a putative RAD52 homolog of fission yeast. The structural and functional similarity suggests that rhp55(+) is a homolog of the S. cerevisiae RAD55 gene and we propose that the functional diversification of RecA-like genes in budding yeast is evolutionarily conserved.     

The Schizosaccharomyces pombe rhp3+ gene required for DNA repair and cell viability is functionally interchangeable with the RAD3 gene of Saccharomyces cerevisiae.

The RAD3 gene of Saccharomyces cerevisiae is required for excision repair and is essential for cell viability. RAD3 encoded protein possesses a single stranded DNA-dependent ATPase and DNA and DNA.RNA helicase activities. Mutational studies have indicated a requirement for the RAD3 helicase activities in excision repair. To examine the extent of conservation of structure and function of RAD3 during eukaryotic evolution, we have cloned the RAD3 homolog, rhp3+, from the distantly related yeast Schizosaccharomyces pombe. RAD3 and rhp3+ encoded proteins are highly similar, sharing 67% identical amino acids. We show that like RAD3, rhp3+ is indispensable for excision repair and cell viability, and our studies indicate a requirement of the putative rhp3+ DNA helicase activity in DNA repair. We find that the RAD3 and rhp3+ genes can functionally substitute for one another. The level of complementation provided by the rhp3+ gene in S.cerevisiae rad3 mutants or by the RAD3 gene in S.pombe rhp3 mutants is remarkable in that both the excision repair and viability defects in both yeasts are restored to wild type levels. These observations suggest a parallel evolutionary conservation of other protein components with which RAD3 interacts in mediating its DNA repair and viability functions.     

The rhp6+ gene of Schizosaccharomyces pombe: a structural and functional homolog of the RAD6 gene from the distantly related yeast Saccharomyces cerevisiae.

The RAD6 gene of Saccharomyces cerevisiae encodes a ubiquitin conjugating enzyme and is required for DNA repair, DNA-damage-induced mutagenesis and sporulation. Here, we show that RAD6 and the rhp6+ gene from the distantly related yeast Schizosaccharomyces pombe share a high degree of structural and functional homology. The predominantly acidic carboxyl-terminal 21 amino acids present in the RAD6 protein are absent in the rhp6(+)-encoded protein; otherwise, the two proteins are very similar, with 77% identical residues. Like rad6, null mutations of the rhp6+ gene confer a defect in DNA repair, UV mutagenesis and sporulation, and the RAD6 and rhp6+ genes can functionally substitute for one another. These observations suggest that functional interactions between RAD6 (rhp6+) protein and other components of the DNA repair complex have been conserved among eukaryotes.     

Repair of exogenous (plasmid) DNA damaged by photoaddition of 8-methoxypsoralen in the yeast Saccharomyces cerevisiae

The contribution of different repair pathways to the repair of 8-methoxypsoralen (8-MOP) plus UVA induced lesions on a centromeric plasmid (YCp50) was investigated in the yeast Saccharomyces cerevisiae using the lithium acetate transformation method. The pathways of excision-resynthesis (RAD1) and recombination (RAD52) were found to be involved in the repair of exogenous as well as of genomic DNA. Mutants in RAD6 and PSO2 genes showed the same transformation efficiency with 8-MOP plus UVA treated plasmid as wild-type cells suggesting that these latter pathways involved in mutagenesis are not operating on plasmid DNA although required for the repair of 8-MOP photoadducts induced in genomic DNA. These results indicate that DNA-repair gene products may be differently involved in the repair of exogenous and endogenous DNA depending on the repair system and the nature of the DNA damage considered.     

Genetic analysis of homologous DNA recombination in vertebrate somatic cells

The maintenance of genomic stability and the ability to repair induced DNA damage in vertebrate cells require homologues of the yeast RAD52 epistasis group genes. The homologous recombination carried out by the products of these genes is essential and appears to be closely linked to DNA replication. Defects in recombination and associated activities are implicated in human cancer. This review summarises recent biochemical and genetic findings on the roles played by the vertebrate RAD52 group gene products in recombination. We describe the phenotypic analysis of genetically engineered mammalian and chicken mutants of homologous recombination genes.     

Regulation of RAD54- and RAD52-lacZ gene fusions in Saccharomyces cerevisiae in response to DNA damage.

The RAD52 and RAD54 genes in the yeast Saccharomyces cerevisiae are involved in both DNA repair and DNA recombination. RAD54 has recently been shown to be inducible by X-rays, while RAD52 is not. To further investigate the regulation of these genes, we constructed gene fusions using 5' regions upstream of the RAD52 and RAD54 genes and a 3'-terminal fragment of the Escherichia coli beta-galactosidase gene. Yeast transformants with either an integrated or an autonomously replicating plasmid containing these fusions expressed beta-galactosidase activity constitutively. In addition, the RAD54 gene fusion was inducible in both haploid and diploid cells in response to the DNA-damaging agents X-rays, UV light, and methyl methanesulfonate, but not in response to heat shock. The RAD52-lacZ gene fusion showed little or no induction in response to X-ray or UV radiation nor methyl methanesulfonate. Typical induction levels for RAD54 in cells exposed to such agents were from 3- to 12-fold, in good agreement with previous mRNA analyses. When MATa cells were arrested in G1 with alpha-factor, RAD54 was still inducible after DNA damage, indicating that the observed induction is independent of the cell cycle. Using a yeast vector containing the EcoRI structural gene fused to the GAL1 promoter, we showed that double-strand breaks alone are sufficient in vivo for induction of RAD54.     

A complex pattern of sensitivity to simple monofunctional alkylating agents exists amongst the rad mutants of Saccharomyces cerevisiae

Summary The radiation-sensitive rad mutants of the yeast Saccharomyces cerevisiae exhibit a complex pattern of sensitivity to simple monofunctional alkylating agents. The RAD1, RAD2, RAD4 and RAD14 genes of the RAD3 epistasis group are implicated in the repair of ethylations to DNA. The RAD3, RAD10 and RAD16 genes of this group are not involved. The RAD4 and RAD14 genes have a particular role in repair following exposure to those ethylating agents that preferentially alkylate oxygen, but not to those that preferentially ethylate nitrogen. The RAD1 and RAD2 genes are involved in the repair of damage induced by all the ethylating agents used except EMS. The mutants in this group that are sensitive to ENU were not sensitive to MNU, suggesting that nucleotide excision operates on ethylations but not on methylations.In the RAD6 group, the RAD6 and RAD18 genes are involved in DNA repair after exposure to all the alkylating agents tested, whereas RAD8 appears to have a role in the repair of O-alkylations but not N-alkylations. RAD9 operates in the repair of methylations and ethylations, but does not influence events after exposure to EMS. In the RAD52 group, the mutants tested were sensitive to ENU and DES. Thus some members of all three epistasis groups are involved in the repair of alkylations to DNA.Abbreviations DES diethylsulphate - EMS ethylmethanesulphonate - ENNG N-ethyl-N-nitro-N-nitrosoguanidine - ENU N-ethylnitrosourea - MNU N-methylnitrosourea - DMSO dimethylsulphoxide - MMS methylmethanesulphonate     

A homologue of the Rad18 postreplication repair gene is required for DNA damage responses throughout the fission yeast cell cycle

Cells activate DNA repair pathways and cell cycle checkpoints when they suffer damage to their genome. They also activate tolerance pathways that facilitate survival. In Escherichia coli, a mechanism known as postreplication repair (PRR) is used to bypass lesions that would otherwise present a physical block to DNA polymerase. PRR has also been proposed to occur in eukaryotic cells, although the partitioning of DNA synthesis to a discrete S-phase would suggest that it is only operative within a defined period of the cell cycle. Eukaryotic PRR has been most extensively studied in the budding yeast Saccharomyces cerevisiae. Two important genes for components of this repair pathway are RAD6, which encodes an ubiquitin-conjugating enzyme, and RAD18, which encodes a RING-finger protein and forms a heterodimer with Rad6p. Rad18p can also bind to DNA. We report here the identification of the Schizosaccharomyces pombe homologue of RAD18, which we have denoted rhp18. rhp18 mutants are hypersensitive to DNA-damaging agents, but show this hypersensitivity throughout the cell cycle. rhp18 mutants are characterised by a longer than usual DNA damage checkpoint arrest that is required for their residual viability following irradiation. Genetic analyses show that rhp18 controls a unique DNA damage repair/tolerance pathway that extends beyond the requirement to tolerate damage during S-phase, suggesting a broader definition of the function of this eukaryotic PRR protein.