S. cerevisiae has three pathways for DNA interstrand crosslink repair.

Yeast mutants, snm1 (pso2-1), rev3 (pso1-1), and rad51, which display significant sensitivity to interstrand crosslinks (ICLs) have low relative sensitivity to other DNA damaging agents. SNM1, REV3, and RAD51 were disrupted in the same haploid strain, singly and in combination. The double mutants, snm1 Delta rev3 Delta, snm1 Delta rad51 Delta and rev3 Delta rad51 Delta were all more sensitive to ICLs than any of the single mutants, indicating that they are in separate epistasis groups for survival. A triple mutant displayed greater sensitivity to ICLs than any of the double mutants, with one ICL per genome being lethal. Therefore, Saccharomyces cerevisiae appears to have three separate ICL repair pathways, but no more. S-phase delay was not observed after ICL damage introduced by cisplatin (CDDP) or 8-methoxypsoralen (8-MOP) during the G1-phase, in any of the above mutants, or in an isogenic rad14 Delta mutant deficient in nucleotide excision repair. However, the psoralen analog angelicin (monoadduct damage) induced a significant S-phase delay in the rad14 Delta mutant. Thus, normal S-phase in the presence of ICLs does not seem to be due to rapid excision repair. The results also indicate that monoadduct formation by CDDP or 8-MOP at the doses used is not sufficient to delay S-phase in the rad14 Delta mutant. While the sensitivity of a rev3 Delta mutant indicates Pol zeta is needed for optimal ICL repair, isogenic cells deficient in Pol eta (rad30 Delta cells) were not significantly more sensitive to ICL agents than wild-type cells, and have no S-phase delay.     

Role of PSO genes in repair of DNA damage of Saccharomyces cerevisiae

Photoactivated psoralens used in treatment of skin diseases like Psoriasis and Vitiligo cause DNA damage, the repair of which may lead to mutations and thus to higher risk to have skin cancer. The simple eukaryote Saccharomyces cerevisiae was chosen to investigate the cells' genetic endowment with repair mechanisms for this type of DNA damage and to study the genetic consequences of such repair. Genetic studies on yeast mutants sensitive to photoactivated psoralens, named pso mutants, showed their allocation to 10 distinct loci. Cloning and molecular characterization allowed their grouping into three functional classes: (I) the largest group comprises seven PSO genes that are either generally or specifically involved in error-prone DNA repair and thus affect induced mutability and recombination; (II) one PSO gene that represents error-free excision repair, and (III) two PSO genes encoding proteins not influencing DNA repair but physiological processes unrelated to nucleic acid metabolism. Of the seven DNA repair genes involved in induced mutagenesis three PSO loci [PSO1/REV3, PSO8/RAD6, PSO9/MEC3] were allelic to already known repair genes, whereas three, PSO2/SNM1, PSO3/RNR4, and PSO4/PRP19 represent new genes involved in DNA repair and nucleic acid metabolism in S. cerevisiae. Gene PSO2 encodes a protein indispensable for repair of interstrand cross-link (ICL) that are produced in DNA by a variety of bi- and polyfunctional mutagens and that appears to be important for a likewise repair function in humans as well. In silico analysis predicts a putative endonucleolytic activity for Pso2p/Snm1p in removing hairpins generated as repair intermediates. The absence of induced mutation in pso3/rnr4 mutants indicates an important role of this subunit of ribonucleotide reductase (RNR) in regulation of translesion polymerase zeta in error-prone repair. Prp19p/Pso4p influences efficiency of DNA repair via splicing of pre-mRNAs of intron-containing repair genes but also may function in the stability of the nuclear scaffold that might influence DNA repair capacity. The seventh gene, PSO10 which controls an unknown step in induced mutagenesis is not yet cloned. Two genes, PSO6/ERG3 and PSO7/COX11, are responsible for structural elements of the membrane and for a functional respiratory chain (RC), respectively, and their function thus indirectly influences sensitivity to photoactivated psoralens.     

The pso mutants of Saccharomyces cerevisiae comprise two groups: one deficient in DNA repair and another with altered mutagen metabolism.

Yeast mutants that are sensitive to photoactivated psoralens, named pso mutants, were isolated and described more than 20 years ago. Nine genes responsible for the pso phenotypes were identified and seven of them cloned and molecularly characterized. Of the nine PSO genes of yeast seven apparently encode proteins involved in the repair of DNA lesions generated by photoinduced psoralens and by other mutagens, while two, PSO6 and PSO7, are responsible for structural elements of the membrane and for a functional respiratory chain, respectively. Of the seven proven or putative DNA repair genes six directly or indirectly control induced mutagenesis. Four of these PSO loci were found allelic to already known repair genes, whereas two, PSO2 and PSO4, represent new genes involved in DNA repair and in repair/pre-mRNA processing in S. cerevisiae. Gene PSO2 encodes a protein indispensable for repair of DNA interstrand cross-links that are produced by a variety of bi- and poly-functional mutagens and that appears to be important for a likewise repair function in humans as well.     

Mutagenesis induced by mono- and bi-functional alkylating agents in yeast mutants sensitive to photo-addition of furocoumarins (pso)

The inactivation and the induction of forward and reverse mutations by a mono- and a bifunctional nitrogen mustard in 3 pso mutants of Saccharomyces cerevisiae, initially selected for their sensitivity to psoralen photo-addition, were compared with that of the wild-type.The pso1-1 mutant was very sensitive to both alkylating agents, and the mutagenecity was abolished. This correlates with the defect in the error-prone repair capacity for lesions induced by psoralen photo-addition and radiations already observed for this mutant. Therefore it appears that the PSO1⁺ gene product acts on a spectrum of DNA lesions.The pso2-1 mutant was highly sensitive to the lethal effect of the bifunctional nitrogen mustard and was only slightly sensitive to the monofunctional one. For both agents a reduction in induced mutagenesis was seen. The same was true for mono- and bifunctional psoralen derivatives. The pso2-1 mutant having the same sensitivity as the wild-type to UV and ionizing radiations, it is suggested that the PSO2⁺ gene product is predominantly necessary for the repair of cross-links irrespective of their molecular nature.In contrast with psoralen photo-induced inactivation the pso3-1 mutant had the same sensitivity as the wild-type to alkylating agents. However, a reduction in induced mutagenesis was seen in both cases. This response was modulated according to dose and type of mutation. Consequently, it appeared that the PSO3⁺ gene product acts specifically on psoralen photo-induced sub-lethal lesions and on a fraction of premutagenic lesions independently of their structure.     

Human SNM1A suppresses the DNA repair defects of yeast pso2 mutants

Pso2/Snm1 plays a key role in the repair of DNA interstrand cross-links in yeast. Human cells possess three orthologues of Pso2; SNM1A, SNM1B/Apollo and SNM1C/Artemis. Studies using mammalian cells disrupted or depleted for these genes have yielded equivocal evidence that any of these is a true functional homologues of the yeast gene. Here we show that ectopic expression of only one of the three human orthologues, hSNM1A, effectively suppresses the sensitivity of yeast pso2 (snm1) disruptants to cross-linking agents. Two other phenotypes of the pso2 mutants are also partially rescued by ectopic expression of hSNM1A, namely the double-strand repair break defect observed during cross-link processing in pso2 cells, as well as the spontaneous intrachromatid recombination defect of pso2 msh2 double mutants. Finally, we show that recombinant hSNM1A is a 5'-exonuclease, as also recently reported for the yeast Pso2 protein. Together our data suggest that hSnm1A is a functional homologue of yeast Pso2/Snm1.     

Interaction of the yeast Pso5/Rad16 and Sgs1 proteins: influences on DNA repair and aging.

The interaction trap method was used to isolate putative binding partners of Rad16/Pso5, a protein responsible for repair of silent DNA. One of the interactors found was Sgs1, a DNA helicase influencing the life span of Saccharomyces cerevisiae, with homology to the human BLM, WRN and RECQL4 proteins. Using the same fusion proteins from the two-hybrid screening, we show evidence that both proteins also interact in vitro. We tested isogenic strains, containing mutant alleles of the two genes in single and double mutant combination, for phenotypic similarity. Life span in sgs1Delta single and sgs1Delta rad16Delta double mutants is about 40% of that of WT, and the rad16/pso5Delta single mutant also had its life span reduced to 75%. Sensitivity to different mutagens, whose lesions are poorly repaired in rad16/pso5Delta mutants, was tested in sgs1Delta mutants. The sgs1Delta conferred sensitivity to MMS, H2O2 and was moderately sensitive to UV(254nm) (UVC) and 4-NQO. An epistatic interaction between rad16 and sgs1 mutations after UVC, 4-NQO and H2O2 was observed. Moreover, we found that in a top3 background, functional Sgs1p and Rad16p apparently channel MMS, 4-NQO and H2O2 induced lesions into aberrant DNA repair. Our results demonstrate that Sgs1 is not only involved in genome stability, somatic recombination and aging, but is also implicated, together with Rad16/Pso5, in the repair of specific DNA damage.     

In vitro activation of inactive nitrogenase component I with molybdate.

The mode of interaction in haploid Saccharomyces cerevisiae of two pso mutations with each other and with rad mutations affected in their excision-resynthesis (rad3), error-prone (rad6), and deoxyribonucleic acid double-strand break (rad52) repair pathways was determined for various double mutant combinations. Survival data for 8-methoxypsoralen photoaddition, 254-nm ultraviolet light and gamma rays are presented. For 8-methoxypsoralen photoaddition, which induces both deoxyribonucleic acid interstrand cross-links and monoadditions, the pso1 mutation is epistatic to the rad6, rad52, and pso2 mutations, whereas it is synergistic to rad3. The pso2 mutation, which is specifically sensitive to photoaddition of psoralens, is epistatic to rad3 and demonstrates a nonepistatic interaction with rad6 and rad52. rad3 and rad6, as well as rad 6 and rad52, show synergistic interactions with each other, whereas rad 3 is epistatic to rad52. Consequently, it is proposed that PSO1 and RAD3 genes govern steps in the independent pathways. The PSO1 activity leading to an intermediate which is repaired via the three incidence pathways controlled by RAD6, RAD52, and PSO2 genes. Since pso1 interacts synergistically with rad3 and rad52 and epistatically with rad6 after UV radiation, the PSO1 gene appears to belong to the RAD6 group. For gamma ray sensitivity, pso1 is epistatic to rad6 and rad52, which suggests that this gene controls a step which is common to the two other independent pathways.     

Allelism of PSO4 and PRP19 links pre-mRNA processing with recombination and error-prone DNA repair in Saccharomyces cerevisiae.

The radiation-sensitive mutant pso4-1 of Saccharomyces cerevisiae shows a pleiotropic phenotype, including sensitivity to DNA cross-linking agents, nearly blocked sporulation and reduced mutability. We have cloned the putative yeast DNA repair gene PSO4 from a genomic library by complementation of the blocked UV-induced mutagenesis and of sporulation in diploids homozygous for pso4-1. Sequence analysis revealed that gene PSO4 consists of 1512 bp located upstream of UBI4 on chromosome XII and encodes a putative protein of 56.7 kDa. PSO4 is allelic to PRP19, a gene encoding a spliceosome-associated protein, but shares no significant homology with other yeast genes. Gene disruption with a destroyed reading frame of our PSO4 clone resulted in death of haploid cells, confirming the finding that PSO4/PRP19 is an essential gene. Thus, PSO4 is the third essential DNA repair gene found in the yeast S.cerevisiae.     

Unique and overlapping functions of the Exo1, Mre11 and Pso2 nucleases in DNA repair

The Mre11 and Pso2 nucleases function in homologous recombination and interstrand cross-link (ICL) repair pathways, respectively, while the Exo1 nuclease is involved in homologous recombination and mismatch repair. Characterization of the sensitivity of single, double and triple mutants for these nucleases in Saccharomyces cerevisiae to various DNA damaging agents reveals complex interactions that depend on the type of DNA damage. The pso2 mutant is uniquely sensitive to agents that generate ICLs and mre11-H125N shows the highest sensitivity of the single mutants for ionizing radiation and methyl methane sulfonate. However, elimination of all three nucleases confers higher sensitivity to IR than any of the single or double mutant combinations indicating a high degree of redundancy and versatility in the response to DNA damage. In response to ICL agents, double-strand breaks are still formed in the triple nuclease mutant indicating that none of these nucleases are responsible for unhooking cross-links.     

Unravelling the role of SNM1 in the DNA repair system of Trypanosoma brucei

All living cells are subject to agents that promote DNA damage. A particularly lethal lesion are interstrand cross‐links (ICL), a property exploited by several anti‐cancer chemotherapies. In yeast and humans, an enzyme that plays a key role in repairing such damage are the PSO2/SNM1 nucleases. Here, we report that Trypanosoma brucei, the causative agent of African trypanosomiasis, possesses a bona fide member of this family (called TbSNM1) with expression of the parasite enzyme able to suppress the sensitivity yeast pso2Δ mutants display towards mechlorethamine, an ICL‐inducing compound. By disrupting the Tbsnm1 gene, we demonstrate that TbSNM1 activity is non‐essential to the medically relevant T. brucei life cycle stage. However, trypanosomes lacking this enzyme are more susceptible to bi‐ and tri‐functional DNA alkylating agents with this phenotype readily complemented by ectopic expression of Tbsnm1. Genetically modified variants of the null mutant line were subsequently used to establish the anti‐parasitic mechanism of action of nitrobenzylphosphoramide mustard and aziridinyl nitrobenzamide prodrugs, compounds previously shown to possess potent trypanocidal properties while exhibiting limited toxicity to mammalian cells. This established that these agents, following activation by a parasite specific type I nitroreductase, produce metabolites that promote formation of ICLs leading to inhibition of trypanosomal growth.     

Psoralen-sensitive mutant pso9-1 of Saccharomyces cerevisiae contains a mutant allele of the DNA damage checkpoint gene MEC3

Complementation analysis of the pso9-1 yeast mutant strain sensitive to photoactivated mono- and bifunctional psoralens, UV-light 254 nm, and nitrosoguanidine, with pso1 to pso8 mutants, confirmed that it contains a novel pso mutation. Molecular cloning via the reverse genetics complementation approach using a yeast genomic library suggested pso9-1 to be a mutant allele of the DNA damage checkpoint control gene MEC3. Non-complementation of several sensitivity phenotypes in pso9-1/mec3Delta diploids confirmed allelism. The pso9-1 mutant allele contains a -1 frameshift mutation (deletion of one A) at nucleotide position 802 (802delA), resulting in nine different amino acid residues from that point and a premature termination. This mutation affected the binding properties of Pso9-1p, abolishing its interactions with both Rad17p and Ddc1p. Further interaction assays employing mec3 constructions lacking the last 25 and 75 amino acid carboxyl termini were also not able to maintain stable interactions. Moreover, the pso9-1 mutant strain could no longer sense DNA damage since it continued in the cell cycle after 8-MOP + UVA treatment. Taken together, these observations allowed us to propose a model for checkpoint activation generated by photo-induced adducts.     

PSO4: a novel gene involved in error-prone repair in Saccharomyces cerevisiae

The haploid xs9 mutant, originally selected for on the basis of a slight sensitivity to the lethal effect of X-rays, was found to be extremely sensitive to inactivation by 8-methoxypsoralen (8MOP) photoaddition, especially when cells are treated in the G2 phase of the cell cycle. As the xs9 mutation showed no allelism with any of the 3 known pso mutations, it was now given the name of pso4-1. Regarding inactivation, the pso4-1 mutant is also sensitive to mono- (HN1) or bi-functional (HN2) nitrogen mustards, it is slightly sensitive to 254 nm UV radiation (UV), and shows nearly normal sensitivity to 3-carbethoxypsoralen (3-CPs) photoaddition or methyl methanesulfonate (MMS). Regarding mutagenesis, the pso4-1 mutation completely blocks reverse and forward mutations induced by either 8MOP or 3CPs photoaddition, or by gamma-rays. In the cases of UV, HN1, HN2 or MMS treatments, while reversion induction is still completely abolished, forward mutagenesis is only partially inhibited for UV, HN1, or MMS, and it is unaffected for HN2. Besides severely inhibiting induced mutagenesis, the pso4-1 mutation was found to be semi-dominant, to block sporulation, to abolish the diploid resistance effect, and to block induced mitotic recombination, which indicates that the PSO4 gene is involved in a recombinational pathway of error-prone repair, comparable to the E. coli SOS repair pathway.     

Saccharomyces cerevisiae RAD53 (CHK2) but not CHK1 is required for double-strand break-initiated SCE and DNA damage-associated SCE after exposure to X rays and chemical agents

Saccharomyces cerevisiae RAD53 (CHK2) and CHK1 control two parallel branches of the RAD9-mediated pathway for DNA damage-induced G(2) arrest. Previous studies indicate that RAD9 is required for X-ray-associated sister chromatid exchange (SCE), suppresses homology-directed translocations, and is involved in pathways for double-strand break repair (DSB) repair that are different than those controlled by PDS1. We measured DNA damage-associated SCE in strains containing two tandem fragments of his3, his3-Delta5' and his3-Delta3'::HOcs, and rates of spontaneous translocations in diploids containing GAL1::his3-Delta5' and trp1::his3-Delta3'::HOcs. DNA damage-associated SCE was measured after log phase cells were exposed to methyl methanesulfonate (MMS), 4-nitroquinoline 1-oxide (4-NQO), UV, X rays and HO-induced DSBs. We observed that rad53 mutants were defective in MMS-, 4-NQO, X-ray-associated and HO-induced SCE but not in UV-associated SCE. Similar to rad9 pds1 double mutants, rad53 pds1 double mutants exhibited more X-ray sensitivity than the single mutants. rad53 sml1 diploid mutants exhibited a 10-fold higher rate of spontaneous translocations compared to the sml1 diploid mutants. chk1 mutants were not deficient in DNA damage-associated SCE after exposure to DNA damaging agents or after DSBs were generated at trp1::his3-Delta5'his3-Delta3'::HOcs. These data indicate that RAD53, not CHK1, is required for DSB-initiated SCE, and DNA damage-associated SCE after exposure to X-ray-mimetic and UV-mimetic chemicals.     

Isolation and Characterization of pso Mutants Sensitive to Photo-Addition of Psoralen Derivatives in SACCHAROMYCES CEREVISIAE

We have isolated mutants sensitive to photo-addition of bi-functional and mono-functional derivatives of psoralen in Saccharomyces cerevisiae. Three of these pso mutants were analyzed in detail. They segregate in meiosis like Mendelian genes and complement each other, as well as existing radiation-sensitive (rad and rev) mutants. The study of heterozygous diploid strains (PSO⁺/pso) indicates that the three pso genes are recessive. The mutant pso1–1 demonstrates a cross-sensitivity to UV and γ-rays, whereas mutants pso2–1 and pso3–1 are specifically sensitive to photo-addition of psoralen derivatives. The comparison of exponentially growing cells to stationary-phase cells demonstrates that for the three mutants the defect in repair capacity of DNA cross-links and monoadducts concerns G1 and early S-phase cells. The pso2–1 mutant is, however, also defective in G2 repair and loses diploid resistance when it is in the homozygous state.—The block in repair capacity in these novel mutants is discussed in relation to the three other repair pathways known to be involved in the repair of furocoumarins photo-induced lesions in yeast DNA.     

Increased DNA double strand breakage is responsible for sensitivity of the pso3-1 mutant of Saccharomyces cerevisiae to hydrogen peroxide

Escherichia coli endonuclease III (endo III) is the key repair enzyme essential for removal of oxidized pyrimidines and abasic sites. Although two homologues of endo III, Ntgl and Ntg2, were found in Saccharomyces cerevisiae, they do not significantly contribute to repair of oxidative DNA damage in vivo. This suggests that an additional activity(ies) or a regulatory pathway(s) involved in cellular response to oxidative DNA damage may exist in yeast. The pso3-1 mutant of S. cerevisiae was previously shown to be specifically sensitive to toxic effects of hydrogen peroxide (H2O2) and paraquat. Here, we show that increased DNA double strand breakage is very likely the basis of sensitivity of the pso3-1 mutant cells to H2O2. Our results, thus, indicate an involvement of the Pso3 protein in protection of yeast cells from oxidative stress presumably through its ability to prevent DNA double strand breakage. Furthermore, complementation of the repair defects of the pso3-1 mutant cells by E. coli endo III has been examined. It has been found that expression of the nth gene in the pso3-1 mutant cells recovers survival, decreases mutability and protects yeast genomic DNA from breakage following H2O2 treatment. This might suggest some degree of functional similarity between Pso3 and Nth.     

Saccharomyces cerevisiae lacking Snm1, Rev3 or Rad51 have a normal S-phase but arrest permanently in G2 after cisplatin treatment

The role of Snm1, Rev3 and Rad51 in S-phase after cisplatin (CDDP) DNA treatment has been examined. When isogenic deletion mutants snm1 delta, rev3 delta and rad51 delta were arrested in G1 and treated with doses of CDDP causing significant lethality (<20% survival in the mutant strains), they progressed through S-phase with normal kinetics. The mutants arrested in G2 like wild-type cells, however they did not exit the arrest and reenter the cell cycle. This finding demonstrates that these genes are not required to allow DNA replication in the presence of damage. Therefore, Snm1, Rev3 and Rad51 may act after S to allow repair. At high levels of damage (<40% survival in wild-type cells) S-phase was slowed in a MEC1-dependent fashion. The cross-link incision kinetics of snm1 delta and rev3 delta mutants were also examined; both showed no deficiencies in incision of cross-linked DNA.     

A large-scale screen for mutagen-sensitive loci in Drosophila

In a screen for new DNA repair mutants, we tested 6275 Drosophila strains bearing homozygous mutagenized autosomes (obtained from C. Zuker) for hypersensitivity to methyl methanesulfonate (MMS) and nitrogen mustard (HN2). Testing of 2585 second-chromosome lines resulted in the recovery of 18 mutants, 8 of which were alleles of known genes. The remaining 10 second-chromosome mutants were solely sensitive to MMS and define 8 new mutagen-sensitive genes (mus212-mus219). Testing of 3690 third chromosomes led to the identification of 60 third-chromosome mutants, 44 of which were alleles of known genes. The remaining 16 mutants define 14 new mutagen-sensitive genes (mus314-mus327). We have initiated efforts to identify these genes at the molecular level and report here the first two identified. The HN2-sensitive mus322 mutant defines the Drosophila ortholog of the yeast snm1 gene, and the MMS- and HN2-sensitive mus301 mutant defines the Drosophila ortholog of the human HEL308 gene. We have also identified a second-chromosome mutant, mus215(ZIII-2059), that uniformly reduces the frequency of meiotic recombination to <3% of that observed in wild type and thus defines a function required for both DNA repair and meiotic recombination. At least one allele of each new gene identified in this study is available at the Bloomington Stock Center.     

DNA interstrand cross-link repair in the Saccharomyces cerevisiae cell cycle: overlapping roles for PSO2 (SNM1) with MutS factors and EXO1 during S phase

Pso2/Snm1 is a member of the beta-CASP metallo-beta-lactamase family of proteins that include the V(D)J recombination factor Artemis. Saccharomyces cerevisiae pso2 mutants are specifically sensitive to agents that induce DNA interstrand cross-links (ICLs). Here we establish a novel overlapping function for PSO2 with MutS mismatch repair factors and the 5'-3' exonuclease Exo1 in the repair of DNA ICLs, which is confined to S phase. Our data demonstrate a requirement for NER and Pso2, or Exo1 and MutS factors, in the processing of ICLs, and this is required prior to the repair of ICL-induced DNA double-strand breaks (DSBs) that form during replication. Using a chromosomally integrated inverted-repeat substrate, we also show that loss of both pso2 and exo1/msh2 reduces spontaneous homologous recombination rates. Therefore, PSO2, EXO1, and MSH2 also appear to have overlapping roles in the processing of some forms of endogenous DNA damage that occur at an irreversibly collapsed replication fork. Significantly, our analysis of ICL repair in cells synchronized for each cell cycle phase has revealed that homologous recombination does not play a major role in the direct repair of ICLs, even in G2, when a suitable template is readily available. Rather, we propose that recombination is primarily involved in the repair of DSBs that arise from the collapse of replication forks at ICLs. These findings have led to considerable clarification of the complex genetic relationship between various ICL repair pathways.     

Thermoconditional modulation of the pleiotropic sensitivity phenotype by the Saccharomyces cerevisiae PRP19 mutant allele pso4-1

The conditionally-lethal pso4-1 mutant allele of the spliceosomal-associated PRP19 gene allowed us to study this gene’s influence on pre-mRNA processing, DNA repair and sporulation. Phenotypes related to intron-containing genes were correlated to temperature. Splicing reporter systems and RT–PCR showed splicing efficiency in pso4-1 to be inversely correlated to growth temperature. A single amino acid substitution, replacing leucine with serine, was identified within the N-terminal region of the pso4-1 allele and was shown to affect the interacting properties of Pso4-1p. Amongst 24 interacting clones isolated in a two-hybrid screening, seven could be identified as parts of the RAD2, RLF2 and DBR1 genes. RAD2 encodes an endonuclease indispensable for nucleotide excision repair (NER), RLF2 encodes the major subunit of the chromatin assembly factor I, whose deletion results in sensitivity to UVC radiation, while DBR1 encodes the lariat RNA splicing debranching enzyme, which degrades intron lariat structures during splicing. Characterization of mutagen-sensitive phenotypes of rad2Δ, rlf2Δ and pso4-1 single and double mutant strains showed enhanced sensitivity for the rad2Δ pso4-1 and rlf2Δ pso4-1 double mutants, suggesting a functional interference of these proteins in DNA repair processes in Saccharomyces cerevisiae.