Genetic and Molecular Analysis of Recombination Events in Saccharomyces Cerevisiae Occurring in the Presence of the Hyper-Recombination Mutation Hpr1

The hyper-recombination mutation hpr1 specifically increases mitotic intrachromatid crossovers, with no effect on other mitotic recombination events such as unequal sister chromatid exchange and plasmid-chromosome recombination, and no effect on meiotic recombination and a lesser effect on intrachromosomal gene conversion. The excision repair RAD1 gene is partially required for the expression on the hpr1 phenotype. The simplest hypothesis to account for some of the hpr1 stimulated recombination events is that a heteroduplex DNA intermediate and localized gene conversion are involved. hpr1 stimulated crossover events are independent of intrachromosomal gene conversion events stimulated by the hyper-gene conversion mutation hpr5. This result suggests that different intrachromosomal recombination processes are affected in each mutant strain. We propose that HPR1 may function to inhibit intrachromatid crossovers.     

Isolation and Genetic Analysis of Extragenic Suppressors of the Hyper-Deletion Phenotype of the Saccharomyces Cerevisiae Hpr1δ Mutation

The HPR1 gene of Saccharomyces cerevisae is involved in maintaining low levels of deletions between DNA repeats. To understand how deletions initiate in the absence of the Hpr1 protein and the mechanisms of recombination leading to deletions in S. cerevisiae, we have isolated mutations as suppressors of the hyper-deletion phenotype of the hpr1δ mutation. The mutations defined five different genes called HRS for hyper-recombination suppression. They suppress the hyper-deletion phenotype of hpr1δ strains for three direct repeat systems tested. The mutations eliminated the hyper-deletion phenotype of hpr1δ strains either completely (hrs1-1 and hrs2-1) or significantly (hrs3-1, hrs4-1 and hrs5-1). None of the mutations has a clear effect on the levels of spontaneous and double-strand break-induced deletions. Among other characteristics we have found are the following: (1) one mutation, hrs1-1, reduces the frequency of deletions in rad52-1 strains 20-fold, suggesting that the HRS1 gene is involved in the formation of RAD52-independent deletions; (2) the hrs2-1 hpr1δ mutant is sensitive to methyl-methane-sulfonate and the single mutants hpr1δ and hrs2-1 are resistant, which suggests that the HPR1 and HRS2 proteins may have redundant DNA repair functions; (3) the hrs4-1 mutation confers a hyper-mutator phenotype and (4) the phenotype of lack of activation of gene expression observed in hpr1δ strains is only partially suppressed by the hrs2-1 mutation, which suggests that the possible functions of the Hpr1 protein in gene expression and recombination repair can be separated. We discuss the possible relationship between the HPR1 and the HRS genes and their involvement in initiation of the events responsible for deletion formation.     

HPR1, a novel yeast gene that prevents intrachromosomal excision recombination, shows carboxy-terminal homology to the Saccharomyces cerevisiae TOP1 gene.

The HPR1 gene has been cloned by complementation of the hyperrecombination phenotype of hpr1-1 strains by using a color assay system. HPR1 is a gene that is in single copy on chromosome IV of Saccharomyces cerevisiae, closely linked to ARO1, and it codes for a putative protein of 752 amino acids (molecular mass, 88 kilodaltons). Computer searches revealed homology (48.8% conserved homology; 24.8% identity) with the S. cerevisiae TOP1 gene in an alpha-helical stretch of 129 amino acids near the carboxy-terminal region of both proteins. The ethyl methanesulfonate-induced hpr1-1 mutation is a single-base change that produces a stop codon at amino acid 559 coding for a protein that lacks the carboxy-terminal TOP1 homologous region. Haploid strains carrying deletions of the HPR1 gene show a slightly reduced mitotic growth rate and extremely high rates of intrachromosomal excision recombination (frequency, 10 to 15%) but have a undetectable effect on rDNA recombination. Double-null mutants hpr1 top1 grow very poorly. We conclude that Hpr1 is a novel eucaryotic protein, mutation of which causes an increase in mitotic intrachromosomal excision recombination, and that it may be functionally related to an activity of the topoisomerase I protein.     

RAD10, an excision repair gene of Saccharomyces cerevisiae, is involved in the RAD1 pathway of mitotic recombination.

The RAD10 gene of Saccharomyces cerevisiae is required for the incision step of excision repair of UV-damaged DNA. We show that the RAD10 gene is also required for mitotic recombination. The rad10 delta mutation lowered the rate of intrachromosomal recombination of a his3 duplication in which one his3 allele has a deletion at the 3' end and the other his3 allele has a deletion at the 5' end (his3 delta 3' his3 delta 5'). The rate of formation of HIS3+ recombinants in the rad10 delta mutant was not affected by the rad1 delta mutation but decreased synergistically in the presence of the rad10 delta mutation in combination with the rad52 delta mutation. These observations indicate that the RAD1 and RAD10 genes function together in a mitotic recombination pathway that is distinct from the RAD52 recombination pathway. The rad10 delta mutation also lowered the efficiency of integration of linear DNA molecules and circular plasmids into homologous genomic sequences. We suggest that the RAD1 and RAD10 gene products act in recombination after the formation of the recombinogenic substrate. The rad1 delta and rad10 delta mutations did not affect meiotic intrachromosomal recombination of the his3 delta 3' his3 delta 5' duplication or mitotic and meiotic recombination of ade2 heteroalleles located on homologous chromosomes.     

Genetic Control of Intrachromosomal Recombination in Saccharomyces Cerevisiae. I. Isolation and Genetic Characterization of Hyper-Recombination Mutations

Eight complementation groups have been defined for recessive mutations conferring an increased mitotic intrachromosomal recombination phenotype (hpr genes) in Saccharomyces cerevisiae. Some of the mutations preferentially increase intrachromosomal gene conversion (hpr4, hpr5 and hpr8) between repeated sequences, some increase loss of a marker between duplicated genes (hpr1 and hpr6), and some increase both types of events (hpr2, hpr3 and hpr7). New alleles of the CDC2 and CDC17 genes were recovered among these mutants. The mutants were also characterized for sensitivity to DNA damaging agents and for mutator activity. Among the more interesting mutants are hpr5, which shows a biased gene conversion in a leu2-112::URA3::leu2-k duplication; and hpr1, which has a much weaker effect on interchromosomal mitotic recombination than on intrachromosomal mitotic recombination. These analyses suggest that gene conversion and reciprocal exchange can be separated mutationally. Further studies are required to show whether different recombination pathways or different outcomes of the same recombination pathway are controlled by the genes identified in this study.     

RAD1, an excision repair gene of Saccharomyces cerevisiae, is also involved in recombination.

The RAD1 gene of Saccharomyces cerevisiae is required for the incision step of excision repair of damaged DNA. In this paper, we report our observations on the effect of the RAD1 gene on genetic recombination. Mitotic intrachromosomal and interchromosomal recombination in RAD+, rad1, rad52, and other rad mutant strains was examined. The rad1 deletion mutation and some rad1 point mutations reduced the frequency of intrachromosomal recombination of a his3 duplication, in which one his3 allele is deleted at the 3' end while the other his3 allele is deleted at the 5' end. Mutations in the other excision repair genes, RAD2, RAD3, and RAD4, did not lower recombination frequencies in the his3 duplication. As expected, recombination between the his3 deletion alleles in the duplication was reduced in the rad52 mutant. The frequency of HIS3+ recombinants fell synergistically in the rad1 rad52 double mutant, indicating that the RAD1 and RAD52 genes affect this recombination via different pathways. In contrast to the effect of mutations in the RAD52 gene, mutations in the RAD1 gene did not lower intrachromosomal and interchromosomal recombination between heteroalleles that carry point mutations rather than partial deletions; however, the rad1 delta mutation did lower the frequency of integration of linear plasmids and DNA fragments into homologous genomic sequences. We suggest that RAD1 plays a role in recombination after the formation of the recombinogenic substrate.     

Characterization of Mutations That Suppress the Temperature-Sensitive Growth of the Hpr1Δ Mutant of Saccharomyces Cerevisiae

The hpr1Δ3 mutant of Saccharomyces cerevisiae is temperature-sensitive for growth at 37° and has a 1000-fold increase in deletion of tandem direct repeats. The hyperrecombination phenotype, measured by deletion of a leu2 direct repeat, is partially dependent on the RAD1 and RAD52 gene products, but mutations in these RAD genes do not suppress the temperature-sensitive growth phenotype. Extragenic suppressors of the temperature-sensitive growth have been isolated and characterized. The 14 soh (suppressor of hpr1) mutants recovered represent eight complementation groups, with both dominant and recessive soh alleles. Some of the soh mutants suppress hpr1 hyperrecombination and are distinct from the rad mutants that suppress hpr1 hyperrecombination. Comparisons between the SOH genes and the RAD genes are presented as well as the requirement of RAD genes for the Soh phenotypes. Double soh mutants have been analyzed and reveal three classes of interactions: epistatic suppression of hpr1 hyperrecombination, synergistic suppression of hpr1 hyperrecombination and synthetic lethality. The SOH1 gene has been cloned and sequenced. The null allele is 10-fold increased for recombination as measured by deletion of a leu2 direct repeat.     

Cloning and characterisation of the Schizosaccharomyces pombe rad32 gene: a gene required for repair of double strand breaks and recombination.

A new Schizosaccharomyces pombe mutant (rad32) which is sensitive to gamma and UV irradiation is described. Pulsed field gel electrophoresis of DNA from irradiated cells indicates that the rad32 mutant, in comparison to wild type cells, has decreased ability to repair DNA double strand breaks. The mutant also undergoes decreased meiotic recombination and displays reduced stability of minichromosomes. The rad32 gene has been cloned by complementation of the UV sensitive phenotype. The gene, which is not essential for cell viability and is expressed at a moderate level in mitotically dividing cells, has significant homology to the meiotic recombination gene MRE11 of Saccharomyces cerevisiae. Epistasis analysis indicates that rad32 functions in a pathway which includes the rhp51 gene (the S.pombe homologue to S.cerevisiae RAD51) and that cells deleted for the rad32 gene in conjunction with either the rad3 deletion (a G2 checkpoint mutation) or the rad2 deletion (a chromosome stability and potential nucleotide excision repair mutation) are not viable.     

Rsp5, a ubiquitin-protein ligase, is involved in degradation of the single-stranded-DNA binding protein rfa1 in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, RAD1 and RAD52 are required for alternate pathways of mitotic recombination. Double-mutant strains exhibit a synergistic interaction that decreases direct repeat recombination rates dramatically. A mutation in RFA1, the largest subunit of a single-stranded DNA-binding protein complex (RP-A), suppresses the recombination deficiency of rad1 rad52 strains (J. Smith and R. Rothstein, Mol. Cell. Biol. 15:1632-1641, 1995). Previously, we hypothesized that this mutation, rfa1-D228Y, causes an increase in recombinogenic lesions as well as the activation of a RAD52-independent recombination pathway. To identify gene(s) acting in this pathway, temperature-sensitive (ts) mutations were screened for those that decrease recombination levels in a rad1 rad52 rfa1-D228Y strain. Three mutants were isolated. Each segregates as a single recessive gene. Two are allelic to RSP5, which encodes an essential ubiquitin-protein ligase. One allele, rsp5-25, contains two mutations within its open reading frame. The first mutation does not alter the amino acid sequence of Rsp5, but it decreases the amount of full-length protein in vivo. The second mutation results in the substitution of a tryptophan with a leucine residue in the ubiquitination domain. In rsp5-25 mutants, the UV sensitivity of rfa1-D228Y is suppressed to the same level as in strains overexpressing Rfa1-D228Y. Measurement of the relative rate of protein turnover demonstrated that the half-life of Rfa1-D228Y in rsp5-25 mutants was extended to 65 min compared to a 35-min half-life in wild-type strains. We propose that Rsp5 is involved in the degradation of Rfa1 linking ubiquitination with the replication-recombination machinery.     

Genetic activity of aminofluorene and 2-acetylaminofluorene in strains of Saccharomycetes under conditions of in vitro metabolic activation: influence of rad 1-5 mutation]

It has been shown that the rad1-5 mutation which alters excision repair in Saccharomyces cerevisiae yeast increased reversion frequency of the ochre mutation his7-1 and the frequency of intragenic mitotic recombination in the LYS2 gene induced by 2-aminofluorene and 2-acetylaminofluorene, as compared with the wild type strains activated in vitro by 39 mix from chicken liver.     

Xrs2, a DNA Repair Gene of Saccharomyces Cerevisiae, Is Needed for Meiotic Recombination

The XRS2 gene of Saccharomyces cerevisiae has been previously identified as a DNA repair gene. In this communication, we show that XRS2 also encodes an essential meiotic function. Spore inviability of xrs2 strains is rescued by a spo13 mutation, but meiotic recombination (both gene conversion and crossing over) is highly depressed in spo13 xrs2 diploids. The xrs2 mutation suppresses spore inviability of a spo13 rad52 strain suggesting that XRS2 acts prior to RAD52 in the meiotic recombination pathway. In agreement with the genetic data, meiosis-specific double-strand breaks at the ARG4 meiotic recombination hotspot are not detected in xrs2 strains. Despite its effects on meiotic recombination, the xrs2 mutation does not prevent mitotic recombination events, including homologous integration of linear DNA, mating-type switching and radiation-induced gene conversion. Moreover, xrs2 strains display a mitotic hyper-rec phenotype. Haploid xrs2 cells fail to carry out G2-repair of gamma-induced lesions, whereas xrs2 diploids are able to perform some diploid-specific repair of these lesions. Meiotic and mitotic phenotypes of xrs2 cells are very similar to those of rad50 cells suggesting that XRS2 is involved in homologous recombination in a way analogous to that of RAD50.     

A Saccharomyces Cerevisiae Rad52 Allele Expressing a C-Terminal Truncation Protein: Activities and Intragenic Complementation of Missense Mutations

A nonsense allele of the yeast RAD52 gene, rad52-327, which expresses the N-terminal 65% of the protein was compared to two missense alleles, rad52-1 and rad52-2, and to a deletion allele. While the rad52-1 and the deletion mutants have severe defects in DNA repair, recombination and sporulation, the rad52-327 and rad52-2 mutants retain either partial or complete capabilities in repair and recombination. These two mutants behave similarly in most tests of repair and recombination during mitotic growth. One difference between these two alleles is that a homozygous rad52-2 diploid fails to sporulate, whereas the homozygous rad52-327 diploid sporulates weakly. The low level of sporulation by the rad52-327 diploid is accompanied by a low percentage of spore viability. Among these viable spores the frequency of crossing over for markers along chromosome VII is the same as that found in wild-type spores. rad52-327 complements rad52-2 for repair and sporulation. Weaker intragenic complementation occurs between rad52-327 and rad52-1.     

Spontaneous mutability in UV-sensitive excision-defective strains of Saccharomyces.

The genes RAD1, RAD2, RAD3 and RAD4 encode enzymes in the pathway leading to excision repair of UV-induced DNA damage in Saccharomyces cerevisiae. Four mutant alleles of these loci (rad1-1, rad2-2, rad3-12, and rad4-3) were studied for their effect on spontaneous reversion rate to lysine and histidine independence, by means of the 1000-compartment fluctuation test of von Borstel, Cain and Steinberg. Of these four excision-defective alleles, only rad3-12 was found to substantially increase the spontaneous reversion rate of the nonsense-suppressible lys1-1 allele, both through locus reversion as well as by forward mutation at one of eight suppressor loci. Similarly, only rad3-12 conferred a considerable increase in the reversion frequency of the missense his1-7 mutant. As the RAD3 gene product is believed to mediate the first step in the excision-repair pathway, it is assumed that spontaneous lesions in the rad3 strain are channelled into a mutagenic repair pathway, thus accounting for the enhanced spontaneous mutation rate.     

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.