The PSO4 gene is responsible for an error-prone recombinational DNA repair pathway in Saccharomyces cerevisiae

Summary The induction of mitotic gene conversion and crossing-over inSaccharomyces cerevisiae diploid cells homozygous for thepso4-1 mutation was examined in comparison to the corresponding wild-type strain. Thepso4-1 mutant strain was found to be completely blocked in mitotic recombination induced by photoaddition of mono- and bifunctional psoralen derivatives as well as by mono- (HN1) and bifunctional (HN2) nitrogen mustards or 254 nm UV radiation in both stationary and exponential phases of growth. Concerning the lethal effect, diploids homozygous for thepso4-1 mutation are more sensitive to all agents tested in any growth phase. However, this effect is more pronounced in the G2 phase of the cell cycle. These results imply that the ploidy effect and the resistance of budding cells are under the control of thePSO4 gene. On the other hand, thepso4-1 mutant is mutationally defective for all agents used. Therefore, thepso4-1 mutant has a generalized block in both recombination and mutation ability. This indicates that thePSO4 gene is involved in an error-prone repair pathway which relies on a recombinational mechanism, strongly suggesting an analogy between thepso4-1 mutation and theRecA orLexA mutation ofEscherichia coli.     

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.     

The PSO3 gene is involved in error-prone intragenic recombinational DNA repair in Saccharomyces cerevisiae

Summary The induction of gene conversion and mitotic crossing-over by photoaddition of psoralens, 254 nm ultraviolet radiation, and nitrogen mustards was determined in diploid cells homozygous for the pso3-1 mutation and in the corresponding wild type of Saccharomyces cerevisiae. For these different agents, the frequency of non-reciprocal events (conversion) is reduced in the pso3-1 mutant compared to the wild type. In contrast, the frequency of reciprocal events (crossing-over) is increased at a range of doses. These observations, together with the block in induced mutagenesis for both reverse and forward mutations previously reported for the pso3-1 mutant, suggest that the PS03 gene product plays a role in mismatch repair of short patch regions. The block in gene conversion in the pso3 homozygous diploid leads, in the case of nitrogen mustards, to specific repair intermediates which are lethal to the cells.     

Interactions of PRP2 protein with pre-mRNA splicing complexes in Saccharomyces cerevisiae.

PRP2 protein of Saccharomyces cerevisiae is required for the pre-mRNA splicing reaction but not for the early stages of spliceosome assembly. Using anti-PRP2 antibodies we demonstrate that PRP2 protein is associated with spliceosomes prior to, and throughout step 1 of the splicing reaction. Heat-inactivated prp2 protein, by contrast, does not seem to associate with spliceosomes. By elution of electrophoretically distinct spliceosomal complexes from non-denaturing gels we identify the specific complex with which PRP2 initially interacts in the pathway of spliceosome assembly.     

Differential repair and recombination of psoralen damaged plasmid DNA in Saccharomyces cerevisiae.

Summary Psoralen photoreaction with DNA produces interstrand crosslinks, which require the activity of excision and recombinational pathways for repair. Yeast replicating plasmids, carrying the HIS3, TRP1, and URA3 genes, were photoreacted with psoralen in vitro and transfected into Saccharomyces cerevisiae cells. Repair was assayed as the relative transformation efficiency. A recombination-deficient rad52 strain was the least efficient in the repair of psoralen-damaged plasmids; excision repair-deficient rad1 and rad3 strains had repair efficiencies intermediate between those of rad52 and RAD cells. The level of repair also depended on the conditions of transformant selection; repair was more efficient in medium lacking tryptophan than in medium from which either histidine or uracil was omitted. The plasmid repair differential between these selective media was greatest in rad1 cells, and depended on RAD52. Plasmid-chromosome recombination was stimulated by psoralen damage, and required RAD52 function. Chromosome to plasmid gene conversion was seen most frequently at the HIS3 locus. In RAD and rad3 cells, the majority of the conversions were associated with plasmid integration, while in rad1 cells most were non-crossover events. Plasmid to chromosome gene conversion was observed most frequently at the TRP1 locus, and was accompanied by plasmid loss.     

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.     

Saccharomyces cerevisiae Ku70 potentiates illegitimate DNA double-strand break repair and serves as a barrier to error-prone DNA repair pathways.

Ku, a heterodimer of polypeptides of approximately 70 kDa and 80 kDa (Ku70 and Ku80, respectively), binds avidly to DNA double-strand breaks (DSBs). Mammalian cells defective in Ku are hypersensitive to ionizing radiation due to a deficiency in DSB repair. Here, we show that the simple inactivation of the Saccharomyces cerevisiae Ku70 homologue (Yku70p), does not lead to increased radiosensitivity. However, yku70 mutations enhance the radiosensitivity of rad52 strains, which are deficient in homologous recombination. Through establishing a rapid and reproducible in vivo plasmid rejoining assay, we show that Yku70p plays a crucial role in the repair of DSBs bearing cohesive termini. Whereas this damage is repaired accurately in YKU70 backgrounds, in yku70 mutant strains terminal deletions of up to several hundred bp occur before ligation ensues. Interestingly, this error-prone DNA repair pathway utilizes short homologies between the two recombining molecules and is thus highly reminiscent of a predominant form of DSB repair that operates in vertebrates. These data therefore provide evidence for two distinct and evolutionarily conserved illegitimate recombination pathways. One of these is accurate and Yku70p-dependent, whereas the other is error-prone and Yku70-independent. Furthermore, our studies suggest that Yku70 promotes genomic stability both by promoting accurate DNA repair and by serving as a barrier to error-prone repair processes.     

The PRP31 gene encodes a novel protein required for pre-mRNA splicing in Saccharomyces cerevisiae.

The pre-mRNA splicing factor Prp31p was identified in a screen of temperature-sensitive yeast strains for those exhibiting a splicing defect upon shift to the non- permissive temperature. The wild-type PRP31 gene was cloned and shown to be essential for cell viability. The PRP31 gene is predicted to encode a 60 kDa polypeptide. No similarities with other known splicing factors or motifs indicative of protein-protein or RNA-protein interaction domains are discernible in the predicted amino acid sequence. A PRP31 allele bearing a triple repeat of the hemagglutinin epitope has been generated. The tagged protein is functional in vivo and a single polypeptide species of the predicted size was detected by Western analysis with proteins from yeast cell extracts. Functional Prp31p is required for the processing of pre-mRNA species both in vivo and in vitro, indicating that the protein is directly involved in the splicing pathway.     

DNA postreplication repair and mutagenesis in Saccharomyces cerevisiae.

DNA postreplication repair (PRR) is defined as an activity to convert DNA damage-induced single-stranded gaps into large molecular weight DNA without actually removing the replication-blocking lesions. In bacteria such as Escherichia coli, this activity requires RecA and the RecA-mediated SOS response and is accomplished by recombination and mutagenic translesion DNA synthesis. Eukaryotic cells appear to share similar DNA damage tolerance pathways; however, some enzymes required for PRR in eukaryotes are rather different from those of prokaryotes. In the yeast Saccharomyces cerevisiae, PRR is centrally controlled by RAD6 and RAD18, whose products form a stable complex with single-stranded DNA-binding, ATPase and ubiquitin-conjugating activities. PRR can be further divided into translesion DNA synthesis and error-free modes, the exact molecular events of which are largely unknown. This error-free PRR is analogous to DNA damage-avoidance as defined in mammalian cells, which relies on recombination processes. Two possible mechanisms by which recombination participate in PRR to resolve the stalled replication folk are discussed. Recombination and PRR are also genetically regulated by a DNA helicase and are coupled to the cell-cycle. The PRR processes appear to be highly conserved within eukaryotes, from yeast to human.     

Allelism of pleiotropic drug resistance in Saccharomyces cerevisiae

Allelism of pleiotropic drug resistant (pdr) mutants was evaluated by complementation tests, linkage to chromosome-VII centromere markers and response to a partial suppressor (sur). Complementation tests were confounded by incomplete dominance and somatic segregation. Phenotypic suppression by sur was observed for all mutant and wild type alleles and thus could not be used to distinguish alleles. Five different alleles were tentatively identified by their close linkage to leul; 88 tetrads from three factor crosses produced the following linkages--leul (4.7) pdrl (17.0) trp5. Resistance of DRI 9/T7, a [cir o] strain of French origin, was not inherited as an allele of pdr but was controlled by a different pleiotropic centromere linked gene. An evaluation of published data suggest that antl, AMYl, till, cyh3, BOR2, and axe1 may be alleles of pdr. Thus pdr appears to be an allele that influences permeability to many inhibitors.     

DNA interstrand cross-link repair in Saccharomyces cerevisiae

DNA interstrand cross-links (ICL) present a formidable challenge to the cellular DNA repair apparatus. For Escherichia coli, a pathway which combines nucleotide excision repair (NER) and homologous recombination repair (HRR) to eliminate ICL has been characterized in detail, both genetically and biochemically. Mechanisms of ICL repair in eukaryotes have proved more difficult to define, primarily as a result of the fact that several pathways appear compete for ICL repair intermediates, and also because these competing activities are regulated in the cell cycle. The budding yeast Saccharomyces cerevisiae has proven a powerful tool for dissecting ICL repair. Important roles for NER, HRR and postreplication/translesion synthesis pathways have all been identified. Here we review, with reference to similarities and differences in higher eukaryotes, what has been discovered to date concerning ICL repair in this simple eukaryote.     

A role for MMS4 in the processing of recombination intermediates during meiosis in Saccharomyces cerevisiae.

The MMS4 gene of Saccharomyces cerevisiae was originally identified due to its sensitivity to MMS in vegetative cells. Subsequent studies have confirmed a role for MMS4 in DNA metabolism of vegetative cells. In addition, mms4 diploids were observed to sporulate poorly. This work demonstrates that the mms4 sporulation defect is due to triggering of the meiotic recombination checkpoint. Genetic, physical, and cytological analyses suggest that MMS4 functions after the single end invasion step of meiotic recombination. In spo13 diploids, red1, but not mek1, is epistatic to mms4 for sporulation and spore viability, suggesting that MMS4 may be required only when homologs are capable of undergoing synapsis. MMS4 and MUS81 are in the same epistasis group for spore viability, consistent with biochemical data that show that the two proteins function in a complex. In contrast, MMS4 functions independently of MSH5 in the production of viable spores. We propose that MMS4 is required for the processing of specific recombination intermediates during meiosis.     

Homologous recombination between single-stranded DNA and chromosomal genes in Saccharomyces cerevisiae.

Transformation of Saccharomyces cerevisiae strains was examined by using the URA3 and TRP1 genes cloned into M13 vectors in the absence of sequences capable of promoting autonomous replication. These constructs transform S. cerevisiae cells to prototrophy by homologous recombination with the resident mutant gene. Single-stranded DNA was found to transform S. cerevisiae cells at efficiencies greater than that of double-stranded DNA. No conversion of single-stranded transforming DNA into duplex forms could be detected during the transformation process, and we conclude that single-stranded DNA may participate directly in recombination with chromosomal sequences. Transformation with single-stranded DNA gave rise to both gene conversion and reciprocal exchange events. Cotransformation with competing heterologous single-stranded DNA specifically inhibited transformation by single-stranded DNA, suggesting that one of the components in the transformation-recombination process has a preferential affinity for single-stranded DNA.     

Double-strand-break repair and recombination catalyzed by a nuclear extract of Saccharomyces cerevisiae.

An in vitro system for double-strand-break repair and recombination of plasmid substrates catalyzed by extracts prepared from yeast nuclei has been developed. Recombination events that generate crossover products were detected amongst reaction products by Southern blot hybridization, or by the polymerase chain reaction (PCR). The recombination reaction was found to be stimulated by a double-strand break within homologous sequences and proceeded by a mechanism that involved branched DNA intermediates. In addition to pairing events that generate crossovers, the formation of inverted repeats (head-to-head and tail-to-tail joined products) was also detected. Two models are presented which propose that the formation of crossover products and inverted repeats occur by similar mechanisms.     

Effects of controlled RAD52 expression on repair and recombination in Saccharomyces cerevisiae.

We have examined the effects of RAD52 overexpression on methyl methanesulfonate (MMS) sensitivity and spontaneous mitotic recombination rates. Cells expressing a 10-fold excess of RAD52 mRNA from the ENO1 promoter are no more resistant to MMS than are wild-type cells. Similarly, under the same conditions, the rate of mitotic recombination within a reporter plasmid does not exceed that measured in wild-type cells. This high level of expression is capable of correcting the defects of rad52 mutant cells in carrying out repair and recombination. From these observations, we conclude that wild-type amounts of Rad52 are not rate limiting for repair of MMS-induced lesions or plasmid recombination. By placing RAD52 under the control of the inducible GAL1 promoter, we find that induction results in a 12-fold increase in the fraction of recombinants within 4 h. After this time, the fraction increases less rapidly. When RAD52 expression is quickly repressed during induction, the amount of RAD52 mRNA decreases rapidly and no nascent recombinants are formed. This result suggests a short active half-life for the protein product. Induction of RAD52 in G1-arrested mutant cells also causes a rapid increase in recombinants, suggesting that replication is not necessary for plasmid recombination.