The use of a double-marker shuttle vector to study DNA double-strand break repair in wild-type and radiation-sensitive mutants of the yeast Saccharomyces cerevisiae

An episomal DNA vector (YpJA18), encoding two selectable recombinant yeast genes (TRP1, URA3), was constructed to assess the fidelity of DNA repair in haploid repair-competent (RAD) wild-type yeast and several radiation-sensitive mutants. Either a DNA double-strand break (DSB) or a double-strand gap of 169 bp (DSG) was introduced by restriction enzymes in-vitro within the coding sequence of the URA3 gene of this vector. To eliminate transfer artefacts, selection was first applied for the undamaged TRP1 gene followed by counter selection for URA3 gene activity, which indicated correct repair of the DSB and DSG. Correct repair of the damaged URA3 gene was found to be about 90% in RAD cells (normalized for the expression of undamaged URA3 in TRP ⁺ transformants). Plasmids isolated from the transformants (URA ⁺ TRP ⁺) carry both unique sites (ApaI and NcoI) within the URA3 gene indicating the precise restitution of the 169-bp gap. An excision-repair-defective rad4-4 mutant repaired these lesions as correctly as RAD cells, whereas the mutants rad50-1, rad51-1 and rad54-1, proven to be defective in DSB repair and mitotic recombination, showed less than 5% correct repair of such lesions. In contrast, a representative of the RAD6 epistasis group of genes, the rev2-1 mutant which is sensitive towards UV and ionizing radiation, had a significantly reduced ability (about 20%) for the correct repair of both DSBs and DSGs.     

Cloning by genetic complementation and restriction mapping of the yeast HEM1 gene coding for 5-aminolevulinate synthase

Summary We have cloned the structural gene HEM1 for 5-aminolevulinate (ALA) synthase from Saccharomyces cerevisiae by transformation and complementation of a yeast hem1–5 mutant which was previously shown to lack ALA synthase activity (Urban-Grimal and Labbe Bois 1981) and had no immunodetectable ALA synthase protein when tested with yeast ALA synthase antiserum. The gene was selected from a recombinant cosmid pool which contained wild-type yeast genomic DNA fragments of an average size of 40 kb. The cloned gene was identified by the restauration.of growth on a non fermentable carbon source without addition of exogenous ALA. Sub cloning of partial Sau3A digests and functional analysis by transformation allowed us to isolate three independent plasmids, each carrying a 6 kb yeast DNA fragment inserted in either orientation into the single BamHI site of the vector pHCG3 and able to complement hem1–5 mutation. Analysis of the three plasmids by restriction endonucleases showed that HEM1 is contained within a 2.9 kb fragment. The three corresponding yeast trans formants present a 1, 2.5 and 16 fold increase in ALA synthase activity as compared to the wild-type strain. The gene product immunodetected in the transformant yeast cells has identical size as the wild-type yeast ALA synthase and its amount correlates well with the increase in ALA synthase activity.     

Allelism of SNQ1 and ATR1, genes of the yeast Saccharomyces cerevisiae required for controlling sensitivity to 4-nitroquinoline-N-oxide an aminotriazole

Summary SNQ1 gene function is required for the expression of resistance to 4NQO in wild-type yeast. The sequence of a 3.7 kb yeast DNA containing the gene SNQ1 was determined. The SNQ1 gene consists of an open reading frame of 1641 bp and encodes, according to the hydrophobicity analysis of the putative protein, a transmembrane protein of 547 amino acids. Homology searches in yeast genome databanks revealed a 100% sequence homology with gene ATR1 which controls resistance to aminotriazole in S. cerevisiae. Pre-treatment of wild-type yeast, but not of snq1-0::LEU2 disruption mutants, with sublethal doses of aminotriazole induced hyper-resistance to 4-nitroquinoline-N-oxide. Partial deletion of the nucleotide sequence coding for a putative ATP-binding site has no, or little, influence on resistance to 4NQO whereas total deletion of the region coding for this ATP-binding domain leads to 4NQO-sensitive nullmutants.Abbreviation 4NQO 4-nitroquinoline-N-oxide - aminotriazole 3-amino-1,2,4-triazole - HYR hyper-resistance     

Isolation of the TRP2 and the TRP3 genes of Saccharomyces cerevisiae by functional complementation in yeast

Summary This paper describes the isolation of the TRP2 and the TRP3 genes of Saccharomyces cerevisiae. Two pools of plasmids consisting of BamHI and Sa1GI yeast DNA inserts into the bifunctional yeast — Escherichia coli vector pLC544 (Kingsman et al. 1979) were constructed in E. coli and used for the isolation of the two genes by selection for functional complementation of trp2 and trp3 mutations, respectively, in yeast.The TRP2 gene was isolated on a 6.2 kb BamHl and a 5.8 kb Sa1GI yeast DNA fragment which shared an identical 4.5 kb BamHI-SaIGI fragment. The TRP3 gene was located on a 5.2 kb BamHl fragment.By physical, genetic and physiological experiments it could be shown that the cloned yeast DNA fragments contained the whole structural sequences as well as the regulatory regions of the TRP2 and the TRP3 genes.     

The mcm17 mutation of yeast shows a size-dependent segregational defect of a mini-chromosome

Mini-chromosome-maintenance (mcm) mutants were described earlier as yeast mutants which could not stably maintain mini-chromosomes. Out of these, the ARS-specific class has been more extensively studied and is found to lose chromosomes and mini-chromosomes due to a defect in the initiation of DNA replication at yeast ARSs. In the present study we have identified a number of mcm mutants which show size-dependent loss of mini-chromosomes. When the size of the mini-chromosome was increased, from about 15 kb to about 60 kb, there was a dramatic increase in its mitotic stability in these mutants, but not in the ARS-specific class of mutants. One mutant, mcm17, belonging to the size-dependent class was further characterized. In this mutant, cells carried mini-chromosomes in significantly elevated copy numbers, suggesting a defect in segregation. This defect was largely suppressed in the 60-kb mini-chromosome. A non-centromeric plasmid, the TRP1ARS1 circle, was not affected in its maintenance. This mutant also displayed enhanced chromosome-III loss during mitosis over the wild-type strain, without elevating mitotic recombination. Cloning and sequencing of MCM17 has shown it to be the same as CHL4, a gene required for chromosome stability. This gene is non-essential for growth, as its disruption or deletion from the chromosome did not affect the growth-rate of cells at 23 °C or 37 °C. This work suggests that centromere-directed segregation of a chromosome in yeast is strongly influenced by its length. Received: 20 October 1996 / 2 May 1997     

Identification and isolation of the cytochrome oxidase subunit II gene in mitochondria of the yeast Hansenula saturnus

Summary Mitochondrial DNA from the petite negative yeast Hansenula saturnus has been isolated and sized by digestion with restriction enzymes. The size of the mitochondrial genome is approximately 47 kb. The gene for subunit II of cytochrome oxidase was localized in the genome by Southern blotting using a [³²P]-labeled probe containing the subunit II gene of the yeast Saccharomyces cerevisiae. The probe hybridized to a 1.7 kb HindIII-BamHI fragment under stringent conditions (65°C), indicating a high degree of homology between the S. cerevisiae and H. saturnus mitochondrial DNA fragments. The 1.7 kb fragment from H. saturnus was cloned into pBR322 and physically mapped. The map was used to obtain the nucleotide sequence of the subunit II gene (Lawson and Deters presented in the accompanying paper).     

Cloning and sequencing of URA10, a second gene encoding orotate phosphoribosyl transferase in Saccharomyces cerevisiae

Summary Orotate phosphoribosyl transferase (OPRTase) catalyses the transformation of orotate to OMP in the pyrimidine pathway. In the yeast Saccharomyces cerevisiae, the URA5 gene is known to encode this enzyme activity. In this paper we present the cloning and sequencing of a yeast gene, named URA10, encoding a second OPRTase enzyme. Comparison of the predicted amino acid sequences between URA5 and URA10 genes shows more than 75% similarity. These sequences have also been compared to those of Escherichia coli, Podospora anserina, Sordaria macrospora and Dictyostelium discoideum. Remarkable similarities in the primary structure of these proteins have been found. Gene disruption experiments revealed that URA10 gene expression is responsible for the leaky phenotype of a ura5 mutant. Assays of OPRTase activity in extracts from ura5 and ura10 mutants indicate that the URA10 product contributes only 20% of the total activity found in wild type cells.     

Molecular genetic properties of the yeast Torulaspora pretoriensis: Characterization of chromosomal DNA and genetic transformation by Saccharomyces cerevisiae-based plasmids

Chromosomal DNA banding patterns were obtained for three strains of Torulaspora pretoriensis by contour-clamped homogenous-electric-field gel electrophoresis. Chromosomes were resolved into six or seven bands in the range of 800 to 2000 kb, and a polymorphism of these lengths was observed. By Southern-blot analysis, the three strains were shown to lack the DNA sequences homologous to the URA3, LEU2, TRP1, and HO genes of Saccharomyces cerevisiae. A uracil auxotrophic mutant derived from T. pretoriensis was transformed with three plasmids (YEp24, YRpHI, and YCp50) carrying the URA3 gene of S. cerevisiae by the lithium acetate method.     

Cloning of a yeast dihydrofolate reductase gene in Escherichia coli

Summary The dihydrofolate reductase gene of Saccharomyces cerevisiae has been isolated by selection of trimethoprim resistant Escherichia coli transformed with a gene bank of yeast DNA in plasmid pBR322. From 9.2 kilobase pair BamHI DNA fragment this gene has been localized to a 1.76 kb fragment, the restriction map of which appears different from those reported for the E. coli and the mouse dihydrofolate reductase genes.The enzyme encoded by the chimeric plasmid was established as yeast dihydrofolate reductase by its sensitivity to antifolates in vivo through growth studies and in vitro by enzyme assay. Since, the expression of this gene occurs independent of its orientation within the chimeric plasmid, the 1.76 kb fragment may contain functional regulatory sequences in addition to the structural sequences for yeast dihydrofolate reductase.This work was carried out in part at Merck & Co., Rahway, New Jersey, USA and at Southern Biotech, Inc., Tampa, Florida. USA     

Plasmid cloning and expression of the E. coli polA + gene in S. cerevisiae

Summary The E. coli polA ⁺ gene has been subcloned from a specialised transducing phage onto a low copy number plasmid. Plasmid-encoded DNA polymerase I was synthesised at 2 to 3 times the wild-type E. coli level, and was biochemically indistinguishable from chromosomally-encoded protein. It was able to counteract the radio sensitivity of polA1, polAex1, polAex2 and polA12 mutants, but no complementation of polA107 mutants occurred, even though the plasmid polA⁺ gene was expressed. S. cerevisiae ars-1 or 2 replicative sequences were introduced into the polA⁺ plasmid. Transformation of yeast with these constructs increased total DNA polymerase levels 2–20 times, depending upon assay conditions. The additional activity was discriminated from yeast DNA polymerases by its ability to use low concentrations of substrate, by its resistance to chemical inhibition, and by co-electrophoresis with pure DNA polymerase I and its proteolytic fragments. The polA⁺ gene was expressed in yeast without the aid of yeast promotor sequences. However, deletion of cloned DNA more than 99 base pairs in front of the structural gene prevented expression in yeast but not in E. coli, indicating that the two organisms use different sequences for expression of the plasmid polA⁺ gene.     

Physical and functional characterization of the cloned lysl + gene of Schizosaccharomyces pombe

The α-aminoadipate pathway for the biosynthesis of lysine is present in yeast and other higher fungi. The lys2 and lys5 mutants of Saccharomyces cerevisiae as well as the lys1– and lys7 –mutants of Schizosacharomyces pombe are blocked at the α-aminoadipate reductase step of this pathway. The cloned lys1 + gene in the plasmid pLYS1 isolated from a S. pombe genomic library complemented lys1– mutant of S. pombe. The cloned LYS2 gene in the plasmid YEp620 and the LYS5 gene in the plasmid pSC5 of S. cerevisiae exhibited heterologous complementation of lys1– and lys7– mutants, respectively, of S. pombe. The homologous lys1 + transformed cells exhibited five fold higher α-aminoadipate reductase activity while the heterologous lys1 + and lys7 + transformed cells exhibited much less activity than the the wild type cells. The DNA insert of the plasmid pLYS1 was determined to be 16.7 kb long and the lys1 + gene has been subcloned within a 9.1 kb Clal-Clal DNA insert of the recombinant plasmids pLYS1B and pLYS1C. The restriction pattern for 12 enzymes of the 9.1 kb DNA insert, (Apal, Aval, BamHI, Clal, EcoRI, EcoRV, HindIII, Hpal, Pstl, Pvull, Sphl, and Xbal), exbibited no obvious similarity to that of the LYS2 gene of S. cerevisiae. A 1.7 kb EcoRI-HindIII DNA fragment of pLYS1B and pLYS1C complemented the lys1-131 mutation in an integrative transformation. Although the lys1 + gene of S.pombe is isofunctional to the LYS2 gene of S. cerevisiae, the restriction sites, and expression of these two genes exhibited considerable divergence.     

The properties of the multicopy suppressor of the ogdl mutation in yeast

The 8.1 kb chromosomal fragment partially suppressing the ogdl mutation in Saccharomyces cerevisiae has been cloned. The molecular analysis revealed that its suppressor gene codes for a natural glutamine tRNA_CAG and maps on chromosome XIII in the upstream region of the URA10 gene. The multicopy plasmids containing this tRNA gene also suppressed the standard trpl-l amber mutation and conferred the sensitivity of yeast cells to paromomycin and increased temperature.     

Transformation of Saccharomyces cerevisiae with plasmids containing fragments of yeast 2 μ DNA and a suppressor tRNA gene

Hybrid plasmids have been constructed containing segments of the yeast plasmid 2 DNA, the yeast ochre-suppressing SUP4.0 gene and the bacterial plasmid pBR322. Yeast transformation is detected with a host containing multiple ochre auxotrophic mutations. The transformed SUP4.0 gene is active and can promote growth in the absence of all the requirements. Plasmids containing different fragments of 2 DNA all appear to be active in high frequency transformation of yeast containing 2 DNA, except those containing the HindlII-D fragment. The transforming plasmids undergo recombination with the indigenous 2 DNA. Integration of the transforming plasmid into the host chromosome has been detected by hybridization of restriction enzyme cleaved DNA with labelled pBR322. The plasmids contain restriction enzyme sites which can be used for cloning other genes into yeast.Abbreviations kb kilobase pair - 2 the yeast plasmid of 6.2 kb size     

Effect of gamma rays at the dihydrofolate reductase locus: Deletions and inversions

A series 11 gamma-ray-induced mutants at the dihydrofolate reductase (dhfr)locus in Chinese hamster ovary cells has been examined for the types of DNA sequence change brought about by this form of ionizing radiation. All 11 mutants were found to have suffered major structural changes affecting the dhfrgene. In eight of the mutants, all or part of the dhfrgene has been deleted. The extent of these deletions was examined in seven of these mutants and, for comparison, in two deletion mutants that were induced by UV irradiation. For this purpose, probes from an overlapping set of cosmids that span 210 kb of DNA in this region were used. Three of seven gamma-ray-induced mutants and one UV-induced mutant were shown to have deleted the entire 210-kb region. In the remaining mutants, endpoints ranging from within the dhfrgene to 100 kb downstream were observed. No upstream endpoints were detected, so that an upper limit on the size of these large deletions could not be assigned. Three of the 11 gamma-ray-induced mutants contained an interruption in the dhfrgene without any detectable loss of sequence. Restriction analysis of these interrupted mutants showed that at least 8–14 kb of foreign DNA sequence became joined to the gene at the point of disruption. Cytogenetic analysis of these mutants showed that in two cases an inversion of the banding pattern on chromosome Z-2 had taken place. The inverted dhfrmutants contain very low amounts of dhfrRNA sequences, and the 5 end of an inversion mutant gene exhibits the same pattern of DNA methylation and DNase I-hypersensitivity as the wild-type gene. Our results suggest that ionizing radiation causes primarily, if not exclusively, large deletions and inversions in mammalian cells.     

A screen of yeast respiratory mutants for sensitivity against the mycotoxin citrinin identifies the vacuolar ATPase as an essential factor for the toxicity mechanism

In countries with a hot climate the mycotoxin citrinin represents a serious problem in fungal food-poisoning. In humans the renal system is affected the most and the mitochondrial respiratory chain was identified as a possible sensitive target for this toxin. In addition, citrinin has an antifungal activity that also inhibits the growth of the yeast Saccharomyces cerevisiae. So far the precise mode of action and the subcellular targets for citrinin have not been identified. Therefore, we decided to use the model organism yeast for a genetic approach to identify genes that play a role in the sensitivity against this mycotoxin. A large collection of conditional respiratory deficient yeast mutants was screened for sensitivity against citrinin. One special pet-ts mutant was identified that exhibited a higher sensitivity against citrinin. The genetic system of yeast allowed the isolation of the respective wild-type gene. This yeast gene encodes the Vph2p subunit that is essential for the correct assembly of the vacuolar ATPase. Isolation of the mutated gene and gene-disruption experiments of VPH2 and the partially overlapping small YKL118W gene verified this finding. The wild-type VPH2 gene restores all defects of the mutants. In contrast to this, YKL118W gave no complementation and the null mutant showed no phenotype. Thereby the yeast vacuolar ATPase was found to be important for the toxic effect of citrinin in yeast cells. The consequences of this finding for the molecular mechanism of citrinin action and its relation to the mitochondrial respiratory chain are discussed. Received: 18 November / 27 December 1999