Mating-type suppression of the DNA-repair defect of the yeast rad6Δ mutation requires the activity of genes in the RAD52 epistasis group

The RAD6 gene of Saccharomyces cerevisiae is required for post-replication repair of UV-damaged DNA, UV mutagenesis, and sporulation. Here, we show that the radiation sensitivity of a MAT a rad6 strain can be suppressed by the MAT2 gene carried on a multicopy plasmid. The a1-2 suppression is specific to the RAD6 pathway, as mutations in genes required for nucleotide excision repair or for recombinational repair do not show such mating-type suppression. The a1-2 suppression of the rad6 mutation requires the activity of the RAD52 group of genes, suggesting that suppression occurs by channelling of post-replication gaps present in the rad6 mutant into the RAD52 recombinational repair pathway. The a1-2 repressor could mediate this suppression via an enhancement in the expression, or the activity, of recombination genes.     

A DNA sequence in Saccharomyces exiguus is homologous with the HO gene of Saccharomyces cerevisiae

Summary The DNA of Saccharomyces exiguus was analyzed by Southern hybridization using cloned MATa, MAT, and HO genes of Saccharomyces cerevisiae as probes. It was shown that S. exiguus has a DNA sequence homologous with the HO gene of S. cerevisiae and that this DNA sequence is on a chromosome of about 940 kb of DNA in S. exiguus. However, there is no DNA sequence in S. exiguus that is homologous with the MAT genes of S. cerevisiae.     

Mapping of the RIB5 gene in Saccharomyces cerevisiae using UV light as an enhancer of rad52-mediated chromosome loss

Summary Ribs mutants of S. cerevisiae are blocked at the end of the riboflavin biosynthetic pathway. Using UV light to increase rad52-mediated chromosome loss, we have assigned the rib5 mutation to chromosome II. Tetrad analysis of crosses between rib5 and other markers on chromosome II shows that the RIB5 gene is located on the right arm of this chromosome, closely linked to HIS7.     

Interactions of the RAD7 and RAD23 excision repair genes of Saccharomyces cerevisiae with DNA repair genes in different epistasis groups

Summary The RAD7 and RAD23 genes of S. cerevisiae affect the efficiency of excision repair of UV-damaged DNA. We have examined the UV survival of strains carrying the rad7 or rad23 deletion mutation in combination with deletion mutations in genes affecting different DNA repair pathways. As expected, the rad7 and rad23 mutations interact epistatically with the excision repair defective rad1 mutation, and synergistically with the rad6 and rad52 mutations that affect the postreplication repair and recombinational repair pathways, respectively. However, the rad7rad6 and the rad23rad6 mutants exhibit the same level of UV sensitivity as the radlrad6 mutant. This observation is of interest since, in contrast to the rad7 or the rad23 mutations, the rad1 mutant is very UV sensitive and highly excision defective. This observation suggests that RAD6 and RAD7 and RAD23 genes compete for the same substrate during DNA repair.     

Induction of heterothallic strains and their genetic and physiological characterization in a homothallic strain of the yeast Saccharomyces exiguus

Summary We isolated heterothallic strains from a homothallic strain of S. exiguus by mutagenization with UV or ethylmethanesulfonate (EMS). A gene, not linked to the mating-type locus, was found to control homothallism in the yeast, as in S. cerevisiae. Pheromone of S. exiguus (^se pheromone) induced formation of large pear-shaped cells (shmooing) in a strains of S. exiguus, S. cerevisiae, and S. kluyveri, and sexual agglutinability of an inducible a strain of S. cerevisiae. ^se Pheromone is a peptidyl substance a little different from pheromone of S. cerevisiae. a Pheromone of S. exiguus acts only on a cells of S. exiguus. Contrary to the above results, neither sexual agglutination nor zygote formation occurred among these three Saccharomyces yeasts.     

Genetic and physical interactions between Schizosaccharomyces pombe Mcl1 and Rad2, Dna2 and DNA polymerase α: evidence for a multifunctional role of Mcl1 in DNA replication and repair

Schizosaccharomyces pombe rad2 is involved in Okazaki fragments processing during lagging-strand DNA replication. Previous studies identified several slr mutants that are co-lethal with rad2 and sensitive to methyl methanesulfonate as single mutants. One of these mutants, slr3-1, is characterized here. Complementation and sequence analyses show that slr3-1 (mcl1-101) is allelic to mcl1⁺, which is required for chromosome replication, cohesion and segregation. mcl1-101 is temperature-sensitive for growth and is highly sensitive to DNA damage. mcl1 cells arrest with 2C DNA content and chromosomal DNA double-strand breaks accumulate at the restrictive temperature. Mcl1p, which belongs to the Ctf4p/SepBp family, interacts both genetically and physically with DNA polymerase . Mutations in rhp51 and dna2 enhance the growth defect of the mcl1-101 mutant. These results strongly suggest that Mcl1p is a functional homologue of Saccharomyces cerevisiae Ctf4p and plays a role in lagging-strand synthesis and Okazaki fragment processing, in addition to DNA repair.     

Characterization of a novel α-amylase from Lipomyces kononenkoae and expression of its gene (LKA1) in Saccharomyces cerevisiae

A highly active -amylase (76 250 Da) secreted by the raw starch-degrading yeast Lipomyces kononenkoae strain IGC4052B was purified and characterized. Using high performance liquid chromatography (HPLC), end-product analysis indicated that the L. kononenkoae -amylase acted by endo-hydrolysis on glucose polymers containing -1,4 and -1,6 bonds, producing mainly maltose, maltotriose and maltotetraose. The following NH₂-terminal amino acids were determined for the purified enzyme: Asp-Cys-Thr-Thr-Val-Thr-Val-Leu-Ser-Ser-Pro-Glu-Ser-Val-Thr-Gly. The L. kononenkoae -amylase-encoding gene (LKA1), previously cloned as a cDNA fragment, was expressed in Saccharomyces cerevisiae under the control of the PGK1 promoter. The native signal sequence efficiently directed the secretion of the glycosylated protein in S. cerevisiae. De-glycosylation of the enzyme indicated that post-translational glycosylation is different in S. cerevisiae from that in L. kononenkoae. Zymogram analysis indicated that glycosylation of the protein in S. cerevisiae had a negative effect on enzyme activity. Southern-blot analysis revealed that there is only a single LKA1 gene present in the genome of L. kononenkoae.     

Evidence that an endo-exonuclease controlled by the NUC2 gene functions in the induction of ‘petite’ mutations in Saccharomyces cerevisiae

Summary Defects in the RAD52 gene of the yeast Saccharomyces cerevisiae reduce the levels of the NUC2 endo-exonuclease by approximately 90% compared to the levels in wild-type strains. To examine the potential role of this nuclease in the induction of mitochondrial petite mutations, congenic RAD52 and rad52-1 haploids were subjected to treatment with ethidium bromide, a well-known inducer of these mutations. The rad52 strain showed a much higher resistance to ethidium bromide-induced petite formation than the corresponding wild-type strain. Two approaches were taken to confirm that this finding reflected the nuclease deficiency, and not some other effect attributable to the rad52-1 mutation. First, a multicopy plasmid (YEp213-10) carrying NUC2 was transformed into a RAD52 strain. This resulted in an increased fraction of spontaneous petite mutations relative to that seen for the same strain without the plasmid and sensitized the strain carrying the plasmid to peptite induction by ethidium bromide treatment. Second, a strain having a nuc2 allele that encodes a temperaturesensitive nuclease was treated with ethidium bromide at the restrictive and permissive temperatures. Petite induction was reduced under restrictive conditions. Enzyme assays revealed that the RAD52 (YEp213-10) strain had the highest level of antibody-precipitable NUC2 endo-exonuclease whereas the nuc2 and rad52 mutants had the lowest levels. Furthermore, addition of ethidium bromide to the reaction mixture stimulated the activity of the nuclease on double-stranded DNA. Peptite induction by antifolate-mediated thymine nucleotide depletion was also inhibited by inactivation of RAD52 indicating that the effect of reduced NUC2 endo-exonuclease was not restricted to ethidium bromide treatment. Taken collectively, these results indicate that the NUC2 gene product functions in the production of mitochondrial petite mutations.     

Deletions and rearrangements in Kluyveromyces lactis mitochondrial DNA

Summary Three classes of respiratory deficient mutants have been isolated from a fusant between Kluyveromyces lactis and Saccharomyces cerevisiae that contains only K. lactis mtDNA. One class (15 isolates), resemble ⁰ mutants of S. cerevisiae as they lack detectable mtDNA. A second class (16 isolates), resemble point mutations (mit ^–) or nuclear lesions (pet ^–) of S. cerevisiae as no detectable change is found in their mtDNA. The third class (five isolates), with deletions and rearrangements in their mtDNA are comparable to S. cerevisiae petite (^–) mutants. Surprisingly, three of the five deletion mutants have lost the same 8.0 kb sector of the mtDNA that encompasses the entire cytochrome oxidase subunit 2 gene and the majority of the adjacent cytochrome oxidase subunit 1 gene. In the other strains, deletions are accompanied by complex rearrangements together with substoiciometric bands and in one instance an amplified sector of 800 bp. By contrast to G+C rich short direct repeats forming deletion sites in S. cerevisiae mtDNA, excision of the 8.0 kb sector in K. lactis mtDNA occurs at an 11 bp A+T rich direct repeat CTAATATATAT. The recovery of three strains manifesting this deletion suggests there are limited sites for intramolecular recombination leading to excision in K. lactis mtDNA.     

Transport properties of a C. albicans amino-acid permease whose putative gene was cloned and expressed in S. cerevisiae

Using a gene bank of C. albicans, the lysine-permease deficiency in a strain of S. cerevisiae was complemented, and the restriction map of the corresponding C. albicans DNA fragment was constructed. Its expression in S. cerevisiae showed that the permease of C. albicans actively transports arginine (K_T=18 mol/l, J_max=26 nmol/min per mg dry weight), lysine (K_T=12 mol/l, J_max=18 nmol/min per mg dry weight), histidine (K_T=37 mol/l, J_max=9.7 nmol/min per mg dry weight), as well as their toxic analogues canavanine and thialysine, with high affinity. The intracellular concentration of basic amino acids transported into S. cerevisiae by the C. albicans permease reaches more than a thousand-times-higher value compared to the external concentration in the medium. Accumulated amino acids do not leave the cells. The uptake is strongly reduced by the protonophores and inhibitors of plasma membrane H⁺-ATPase.     

Heterologous gene expression of the glyphosate resistance marker and its application in yeast transformation

Summary The E. coli aroA gene was inserted between yeast promoter and terminator sequences in different shuttle expression plasmids and found to confer enhanced EPSP synthase activity as well as resistance to glyphosate toxicity. Subsequently, a transformation system using these newly constructed vectors in yeast was characterized. The efficiency of the glyphosate resistance marker for transformation and selection with plasmid pHR6/20-1 in S. cerevisiae laboratory strain SHY2 was found to be relatively high when compared with selection for LEU2 prototrophy. The fate of the recombinant plasmid pHR6/20-1 in the transformants, the preservation of the aroA E. coli DNA fragment in yeast, mitotic stability, EPSP synthase activity, and growth on glyphosate-containing medium have been investigated. As this plasmid also allows direct selection for glyphosate resistant transformants on rich media, the glyphosate resistance marker was used for transforming both S. cerevisiae laboratory strain SHY2 and brewer's yeast strains S. cerevisiae var. uvarum BHS5 and BHS2. In all cases, the vector pHR6/20-1 was maintained as an autonomously replicating plasmid. The resistance marker is, therefore, suitable for transforming genetically unlabeled S. cerevisiae laboratory, wild, and industrial yeast strains.Abbreviations EPSP 5-enolpyruvylshikimate 3-phosphate     

Organization of ribosomal RNA genes in Alternaria alternate Japanese pear pathotype,a host-selective AK-toxin-producing fungus

Summary DNA encoding ribosomal RNA (rRNA) of Alternaria alternata Japanese pear pathotype has been cloned in , replacement vector, , Fix. Restriction endonuclease mapping and Southern hybridization with the 18S and 28S rRNAs of Saccharomyces cerevisiae revealed the A. alternata rDNA to be tandemly repeating 8.15-kilobase pair unit. The restriction fragments of the unit were then subcloned in the plasmid vector Bluescribe M13- and partially sequenced. The determined sequences were compared with previously reported sequences of S. cerevisiae rRNAs and their genes. The locations of DNA sequences encoding the 5.8S, 18S, and 28S rRNAs were determined by homology search using reported sequences. The complete DNA sequence for 5.8S rRNA of the fungus was found to be highly conserved at more than 90 % homology in the fungi analyzed. However, sequence diversities were observed in limited regions involved in a helix structure, the helix (e), found at position 116–137.Deceased     

Some of the swi genes of Schizosaccharomyces pombe also have a function in the repair of radiation damage

Summary In Schizosaccharomyces pombe the frequency of mating-type (MT) switching is reduced by mutations in the swi genes. The ten hitherto known swi genes can be subdivided into three classes: Ia, Ib and II. Strains having swi5 (class Ib), swi9 (class II) and swi10 (class II) mutations do not only show reduced MT switching, but also exhibit an increased sensitivity to UV- and -rays. For that reason, 19 previously described rad genes were tested for their effect on MT switching. We found that swi9, rad10, rad16 and rad20 are allelic with each other indicating that the former allocation of these rad mutations to three different genes must have been erroneous. Among the remaining 16 rad genes examined, rad22 seems to be a new class II swi gene. The double mutants swi5 swi9 and swi5 swi10, but not swi9 swi10, are much more sensitive to radiation than the respective single mutants. Thus a cumulative increase in sensitivity occurs only if the mutants belong to different classes; previously the same correlation was found with regard to cumulative effects in MT switching.     

Evidence for preferential multiplication of the internal unit in tandem repeats of the mating factor a genes in Saccharomyces yeasts

Summary We have determined DNA sequences of the mating factor a genes of Saccharomyces uvarum and Saccharomyces italicus and compared them to that of the MF1 gene of S. cerevisiae. The DNA sequences of the mating factor genes in both species were almost completely identical to that of the MF1 gene of S. cerevisiae except for the number of tandem repeated units; these latter consisted of a spacer peptide and a mature mating factor and there were three units in S. uvarum and five units in S. italicus compared with four units in the MF1 of S. cerevisiae. From the detailed comparison of DNA sequences of the spacer peptide-mating factor units from these three species, the high sequence homology can be recognized in the internal units of the tandem repeats. This suggests that the internal units might be multiplied preferentially in the tandem repeated units of mating factor genes.     

Cloning and integrative deletion of the RAD6 gene of Saccharomyces cerevisiae

Summary Three overlapping plasmids were isolated from a YEp24 library, which restore Rad+ functions to rad6-1 and rad6-3 mutants. Different subclones were made and shown to integrate by homologous recombination at the RAD6 site on chromosome VII, thus verifying the cloned DNA segments to be the RAD6 gene and not a suppressor. The gene resides in a 1.15 kb fragment, which restores Rad⁺ levels of resistance to U.V., MMS and -rays to both rad6-1 and rad6-3 strains. It also restores sporulation ability to rad6-1 diploids.Integrative deletion of the RAD6 gene was shown not to be completely lethal to the yeast. Our results suggest that the RAD6 gene has some cell cycle-specific function(s), probably during late S phase.     

Isolation and characterization of the Pichia stipitis xylitol dehydrogenase gene,XYL2, and construction of a xylose-utilizing Saccharomyces cerevisiae transformant

Summary A P. stipitis cDNA library in gt11 was screened using antisera against P. stipitis xylose reductase and xylitol dehydrogenase, respectively. The resulting cDNA clones served as probes for screening a P. stipitis genomic library. The genomic XYL2 gene was isolated and the nucleotide sequence of the 1089 bp structural gene, and of adjacent non-coding regions, was determined. The XYL2 open-reading frame codes for a protein of 363 amino acids with a predicted molecular mass of 38.5 kDa. The XYL2 gene is actively expressed in S. cerevisiae transformants. S. cerevisiae cells transformed with a plasmid, pRD1, containing both the xylose reductase gene (XYL1) and the xylitol dehydrogenase gene (XYL2), were able to grow on xylose as a sole carbon source. In contrast to aerobic glucose metabolism, S. cerevisiae XYL1-XYL2 transformants utilize xylose almost entirely oxidatively.     

Genetic evidence for different RAD52-dependent intrachromosomal recombination pathways in Saccharomyces cerevisiae

Mutations in the RecA-like genes RAD51 and RAD57 reduce the frequency of gene conversion/reciprocal exchange between inverted repeats 7-fold. However, they enhance the frequency of deletions between direct repeats 5–12-fold. These induced deletions are RAD1- and RAD52-dependent. On the basis of these results it is proposed that there are several RAD52-dependent pathways of recombination: the recombinational repair pathway of gene conversion/reciprocal exchange dependent on RAD51 and RAD57; a RAD1-and RAD52-dependent pathway exclusively responsible for deletions that are induced in rad51 and rad57 mutants; and finally, it is possible that the gene conversion/reciprocal exchange events observed in rad51 and rad57 strains represent another RAD52-dependent recombination pathway of gene conversion/reciprocal exchange that does not require Rad51 and Rad57 functions. It is also shown that the RAD10 excision-repair gene is involved in long gene conversion tracts in homologous recombination between inverted repeats, as previously observed for RAD1. Finally, an analysis of meiotic recombination reveals that deletions are induced in meiosis 100-fold above mitotic levels, similar to intrachromosomal gene conversion/reciprocal exchange, and that, in contrast to intrachromosomal meiotic gene conversion (50% association), intrachromosomal meiotic gene conversion is not preferentially associated with reciprocal exchange (12–30% of association).     

Integrative transformation of the yeast Yarrowia lipolytica

Summary An EcoR1 shotgun of Yarrowia lipolytica DNA was inserted into the plasmid YIp333 which carries the LYS2 gene of S. cerevisiae. The resulting plasmid pool was transformed in both S. cerevisiae and Y. lipolytica. Whereas numerous replicating plasmids could be isolated from the S. cerevisiae Lys⁺ transformants, all transformants of Y. lipolytica so far analyzed were found to result from integrative transformation. This occurred at a frequency of 1 to 10 transformants per g of input DNA. Co-transformation occurred at high frequency and resulted in tandem integration of 2 to 10 copies of the incoming DNA. Structural and segregational stability of the transforming DNA were both high.     

Growth of a mutant defective in a putative phosphoinositide-specific phospholipase C of Schizosaccharomyces pombe is restored by low concentrations of phosphate and inositol

A mutant (plc1-1) of Schizosacharomyces pombe unable to grow on a minimal medium containing high amounts of phosphate was selected. On yeast-extract agar its growth is temperature sensitive. Tests in liquid synthetic medium show that growth of the mutant is partially restored by lowering the phosphate and inositol concentrations in the growth medium. The growth defect is fully suppressed by a plasmid encoding a putative protein having the structural features of phosphoinositide-specific phospholipases C (PI-PLC). This protein, of 899 amino-acids, contains the characteristic X and Y domains found in all PI-PLCs of higher and lower eucaryotes and reveals, in addition, an EF-hand motif (putative Ca²⁺-binding site). Like the corresponding enzyme from Saccharomyces cerevisiae, the S. pombe PI-PLC is most similar to the form of PI-PLC isoenzymes. The cloned gene integrates at the plc1 site indicating that plc1 codes for a putative PI-PLC. Plc1 physically maps on the left arm of chromosome II between rad11 and mei3.