The ubiquitin-conjugating enzyme Rad6 (Ubc2) is required for silencing in Saccharomyces cerevisiae.

It has been previously shown that genes transcribed by RNA polymerase II (RNAP II) are subject to position effect variegation when located near yeast telomeres. This telomere position effect requires a number of gene products that are also required for silencing at the HML and HMR loci. Here, we show that a null mutation of the DNA repair gene RAD6 reduces silencing of the HM loci and lowers the mating efficiency of MATa strains. Likewise, rad6-delta reduces silencing of the telomere-located RNAP II-transcribed genes URA3 and ADE2. We also show that the RNAP III-transcribed tyrosyl tRNA gene, SUP4-o, is subject to position effect variegation when located near a telomere and that this silencing requires the RAD6 and SIR genes. Neither of the two known Rad6 binding factors, Rad18 and Ubr1, is required for telomeric silencing. Since Ubrl is the recognition component of the N-end rule-dependent protein degradation pathway, this suggests that N-end rule-dependent protein degradation is not involved in telomeric silencing. Telomeric silencing requires the amino terminus of Rad6. Two rad6 point mutations, rad6(C88A) and rad6(C88S), which are defective in ubiquitin-conjugating activity fail to complement the silencing defect, indicating that the ubiquitin-conjugating activity of RAD6 is essential for full telomeric silencing.     

RAD51-independent inverted-repeat recombination by a strand-annealing mechanism

Recombination between inverted repeats is RAD52 dependent, but reduced only modestly in the rad51Δ mutant. RAD59 is required for RAD51-independent inverted-repeat recombination, but no clear mechanism for how recombination occurs in the absence of RAD51 has emerged. Because Rad59 is thought to function as an accessory factor for the single-strand annealing activity of Rad52 one possible mechanism for spontaneous recombination could be by strand annealing between repeats at a stalled replication fork. Here we demonstrate the importance of the Rad52 single-strand annealing activity for generating recombinants by showing suppression of the rad52Δ, rad51Δ rad52Δ and rad52Δ rad59Δ inverted-repeat recombination defects by the rfa1-D228Y mutation. In addition, formation of recombinants in the rad51Δ mutant was sensitive to the distance between the inverted repeats, consistent with a replication-based mechanism. Deletion of RAD5 or RAD18, which are required for error-free post-replication repair, reduced the recombination rate in the rad59Δ mutant, but not in wild type. These data are consistent with RAD51-independent recombinants arising by a faulty template switch mechanism that is distinct from nascent strand template switching.     

In vivo roles of Rad52, Rad54, and Rad55 proteins in Rad51-mediated recombination

Repairing a double-strand break by homologous recombination requires binding of the strand exchange protein Rad51p to ssDNA, followed by synapsis with a homologous donor. Here we used chromatin immunoprecipitation to monitor the in vivo association of Saccharomyces cerevisiae Rad51p with both the cleaved MATa locus and the HML alpha donor. Localization of Rad51p to MAT precedes its association with HML, providing evidence of the time needed for the Rad51 filament to search the genome for a homologous sequence. Rad51p binding to ssDNA requires Rad52p. The absence of Rad55p delays Rad51p binding to ssDNA and prevents strand invasion and localization of Rad51p to HML alpha. Lack of Rad54p does not significantly impair Rad51p recruitment to MAT or its initial association with HML alpha; however, Rad54p is required at or before the initiation of DNA synthesis after synapsis has occurred at the 3' end of the invading strand.     

Phosphoinositide-specific phospholipase C forms a complex with 14-3-3 proteins and is involved in expression of UV resistance in fission yeast

The fission yeast plc1 ⁺ gene encodes phosphoinositide-specific phospholipase C. The two- hybrid interaction assay with plexA-plc1 ⁺ as a bait revealed that Plc1p interacted with the 14-3-3 proteins Rad24p and Rad25p. Formation of a complex containing Plc1p and Rad24p in vivo was confirmed by an immunological method. As predicted from the fact that rad24 null mutant cells are hypersensitive to UV irradiation, plc1 null mutant cells were almost as sensitive to UV irradiation as rad24 null mutant cells. In addition, deletion of rad24 in the plc1 null mutant cells did not enhance the UV sensitivity, indicating that plc1 ⁺ and rad24 ⁺ belong to the same epistasis group with respect to UV sensitivity. Whereas Rad24p has been reported to be involved in the DNA damage checkpoint pathway, the delay to mitosis after UV irradiation was not defective either in rad24 null mutant cells or in plc1 null mutant cells in our analysis. Thus, Plc1p is responsible for resistance to UV irradiation, but not for the DNA damage checkpoint pathway, in cooperation with 14-3-3 proteins. Received: 10 July 1997 / Accepted: 15 December 1997     

A rapid technique for the visualization of live immobilized yeast cells

We present here a simple, rapid, and extremely flexible technique for the immobilization and visualization of growing yeast cells by epifluorescence microscopy. The technique is equally suited for visualization of static yeast populations, or time courses experiments up to ten hours in length. My microscopy investigates epigenetic inheritance at the silent mating loci in S. cerevisiae. There are two silent mating loci, HML and HMR, which are normally not expressed as they are packaged in heterochromatin. In the sir1 mutant background silencing is weakened such that each locus can either be in the expressed or silenced epigenetic state, so in the population as a whole there is a mix of cells of different epigenetic states for both HML and HMR. My microscopy demonstrated that there is no relationship between the epigenetic state of HML and HMR in an individual cell. sir1 cells stochastically switch epigenetic states, establishing silencing at a previously expressed locus or expressing a previously silenced locus. My time course microscopy tracked individual sir1 cells and their offspring to score the frequency of each of the four possible epigenetic switches, and thus the stability of each of the epigenetic states in sir1 cells. See also Xu et al., Mol. Cell 2006.     

Point mutations in the yeast histone H4 gene prevent silencing of the silent mating type locus HML.

The N-terminal serine and four conserved lysine residues near the N-terminus of yeast histone H4 are acetylated. We found that a mutation that changed the fourth lysine to alanine resulted in specific derepression of the silent mating type locus HML, while mutations that altered the N-terminal serine or the first three lysines had only minor phenotypic effects. Our results support an active role for histone H4 in the silencing of gene expression at this locus.     

Effect of <Emphasis Type="Italic">rad50</Emphasis> mutation on illegitimate recombination in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Genes in the RAD52 epistasis group are involved in repairing DNA double-stranded breaks via homologous recombination. We have previously shown that RAD50 is involved in mitotic nonhomologous integration but not in homologous integration. However, the role of Rad50 in nonhomologous integration has not previously been examined. In the current work, we report that the rad50∆ mutation caused a tenfold decrease in the frequency of nonhomologous integration with the majority of nonhomologous integrants showing an unstable Ura⁺ phenotype. Sequencing analysis of the integration target sites showed that integration events of both ends of the integrating vector in the rad50∆ mutant occurred at different chromosomal locations, resulting in large deletions or translocations on the genomic insertion sites. Interestingly, 47% of events in the rad50∆ mutant were integrated into repetitive sequences including rDNA locus, telomeres and Ty elements and 27% of events were integrated into non-repetitive sequences as compared to 11% of events integrated into rDNA and 70% into non-repetitive sequences in the wild-type cells. These results showed that deletion of RAD50 significantly changes the distribution of different classes of integration events, suggesting that Rad50 is required for nonhomologous integration at non-repetitive sequences more so than at repetitive ones. Furthermore, Southern analysis indicated that half of the events contained deletions at one or at both ends of the integrating DNA fragment, suggesting that Rad50 might have a role in protecting free ends of double-strand breaks. In contrast to the rad50∆ mutant, the rad50S mutant (separation of function allele) slightly increases the frequency of nonhomologous integration but the distribution of integration events is similar to that of wild-type cells with the majority of events integrated into a chromosomal locus. Our results suggest that deletion of RAD50 may block the major pathway of nonhomologous integration into a non-repetitive chromosomal locus and Rad50 may be involved in tethering two ends of the integrating DNA into close proximity that facilitates nonhomologous integration of both ends into a single chromosomal locus.     

Rad51-independent interchromosomal double-strand break repair by gene conversion requires Rad52 but not Rad55, Rad57, or Dmc1

Homologous recombination (HR) is critical for DNA double-strand break (DSB) repair and genome stabilization. In yeast, HR is catalyzed by the Rad51 strand transferase and its “mediators,” including the Rad52 single-strand DNA-annealing protein, two Rad51 paralogs (Rad55 and Rad57), and Rad54. A Rad51 homolog, Dmc1, is important for meiotic HR. In wild-type cells, most DSB repair results in gene conversion, a conservative HR outcome. Because Rad51 plays a central role in the homology search and strand invasion steps, DSBs either are not repaired or are repaired by nonconservative single-strand annealing or break-induced replication mechanisms in rad51Δ mutants. Although DSB repair by gene conversion in the absence of Rad51 has been reported for ectopic HR events (e.g., inverted repeats or between plasmids), Rad51 has been thought to be essential for DSB repair by conservative interchromosomal (allelic) gene conversion. Here, we demonstrate that DSBs stimulate gene conversion between homologous chromosomes (allelic conversion) by >30-fold in a rad51Δ mutant. We show that Rad51-independent allelic conversion and break-induced replication occur independently of Rad55, Rad57, and Dmc1 but require Rad52. Unlike DSB-induced events, spontaneous allelic conversion was detected in both rad51Δ and rad52Δ mutants, but not in a rad51Δ rad52Δ double mutant. The frequencies of crossovers associated with DSB-induced gene conversion were similar in the wild type and the rad51Δ mutant, but discontinuous conversion tracts were fivefold more frequent and tract lengths were more widely distributed in the rad51Δ mutant, indicating that heteroduplex DNA has an altered structure, or is processed differently, in the absence of Rad51.     

Rad6p represses yeast-hypha morphogenesis in the human fungal pathogen Candida albicans

Rad6p plays important roles in post-replication DNA repair, chromatin organization, gene silencing and meiosis. In this study, we show that Rad6p also regulates yeast-hypha morphogenesis in the human pathogen Candida albicans. CaRAD6 gene and cDNAs were isolated and characterized revealing that the gene carries two 5'-proximal introns. CaRad6p shows a high degree of sequence similarity to Rad6 proteins from fungi to man (60-83% identity), and it suppresses the UV sensitivity and lack of induced mutagenesis displayed by a Saccharomyces cerevisiae rad6 mutant. In C. albicans, CaRAD6 expression is induced in response to UV, and CaRad6p depletion confers UV sensitivity, confirming that Rad6p serves a role in protecting this fungus against UV damage. CaRAD6 overexpression inhibits hyphal development, whereas CaRad6p depletion enhances hyphal growth. Also, CaRAD6 mRNA levels decrease during the yeast-hypha transition. These effects are dependent on Efg1p, but not Cph1p, indicating that CaRad6p acts specifically through the Efg1p morphogenetic signalling pathway to repress yeast-hypha morphogenesis.     

Rad4TopBP1 associates with Srr2, an Spc1 MAPK-regulated protein, in response to environmental stress

Rad4(TopBP1) is a scaffold in a protein complex containing both replication proteins and checkpoint proteins and plays essential roles in both replication and checkpoint responses. We have previously identified four novel fission yeast mutants of rad4+(TopBP1) to explore how Rad4(TopBP1), a single protein, can play multiple roles in genomic integrity maintenance. Among the four novel mutants, rad4-c17(TopBP1) is a thermosensitive mutant. Here, we characterized rad4-c17(TopBP1) and identified a rad4-c17(TopBP1) allele specific suppressor named srr2+ (suppressor of Rad4(TopBP1) R2 domain). srr2+ has previously been identified as an environmental stress-responsive gene (GenBank accession number AL049644.1, locus spcc191.01). srr2+ null cells are sensitive to hydroxyurea (HU) at elevated temperatures. Deletion of srr2+ in rad4-c17(TopBP1) exacerbates the HU sensitivity of the mutant. Overexpression of srr2+ suppresses the rad4-c17(TopBP1) mutant sensitivity to temperature and HU and restores the compromised ability of rad4-c17(TopBP1) to activating Cds1 kinase in response to HU treatment. Furthermore, stress-activated MAPK, Spc1 (also known as StyI or Phh1), induces the expression and phosphorylation of the Srr2 protein. Significantly, environmental stress induces co-precipitation of Srr2 protein with Rad4(TopBP1), and the co-precipitation is compromised in the rad4-c17(TopBP1) mutant. These results have led us to propose a model; Rad4(TopBP1) exists in a large protein complex to coordinate genomic perturbations with checkpoint responses to maintain genomic integrity. In addition, when cells experience environmental stress, Rad4(TopBP1) associates with Srr2, an Spc1 MAPK-responsive protein, to survive the stress, potentially by providing a link of the Spc1 MAPK response to checkpoint responses.     

The topoisomerase II-associated protein, Pat1p, is required for maintenance of rDNA locus stability in Saccharomyces cerevisiae

The Pat1 protein of Saccharomyces cerevisiae was identified during a screen for proteins that interact with topoisomerase II. Previously, we have shown that pat1Δ mutants exhibit a slow-growth phenotype and an elevated frequency of both mitotic and meiotic chromosome mis-segregation. Here, we have studied the effects of deleting the PAT1 gene on chromosomal stability, with particular reference to rates of homologous recombination within the rDNA locus. This locus was analyzed because rDNA-specific hyperrecombination is known to occur in conditional top2 mutants. We show that pat1Δ strains mimic top2 mutants in displaying an elevated rate of intrachromosomal excision recombination at the rDNA locus, but not elsewhere in the genome. The elevated rate of recombination is dependent upon Rad52p, but not upon Rad51p or Rad54p. However, pat1Δ strains display additional manifestations of more general genomic instability, in that they show mild sensitivity to UV light and an increased incidence of interchromosomal recombination between heteroalleles.     

Identification of rad27 Mutations That Confer Differential Defects in Mutation Avoidance, Repeat Tract Instability, and Flap Cleavage

In eukaryotes, the nuclease activity of Rad27p (Fen1p) is thought to play a critical role in lagging-strand DNA replication by removing ribonucleotides present at the 5' ends of Okazaki fragments. Genetic analysis of Saccharomyces cerevisiae also has identified a role for Rad27p in mutation avoidance. rad27Delta mutants display both a repeat tract instability phenotype and a high rate of forward mutations to canavanine resistance that result primarily from duplications of DNA sequences that are flanked by direct repeats. These observations suggested that Rad27p activities in DNA replication and repair could be altered by mutagenesis and specifically assayed. To test this idea, we analyzed two rad27 alleles, rad27-G67S and rad27-G240D, that were identified in a screen for mutants that displayed repeat tract instability and mutator phenotypes. In chromosome stability assays, rad27-G67S strains displayed a higher frequency of repeat tract instabilities relative to CAN1 duplication events; in contrast, the rad27-G240D strains displayed the opposite phenotype. In biochemical assays, rad27-G67Sp displayed a weak exonuclease activity but significant single- and double-flap endonuclease activities. In contrast, rad27-G240Dp displayed a significant double-flap endonuclease activity but was devoid of exonuclease activity and showed only a weak single-flap endonuclease activity. Based on these observations, we hypothesize that the rad27-G67S mutant phenotypes resulted largely from specific defects in nuclease function that are important for degrading bubble intermediates, which can lead to DNA slippage events. The rad27-G240D mutant phenotypes were more difficult to reconcile to a specific biochemical defect, suggesting a structural role for Rad27p in DNA replication and repair. Since the mutants provide the means to relate nuclease functions in vitro to genetic characteristics in vivo, they are valuable tools for further analyses of the diverse biological roles of Rad27p.