Time-dependent mitotic recombination in Saccharomyces cerevisiae

The time-dependent appearance of prototrophic recombinants between heterologously located artificial repeats has been studied in Saccharomyces cerevisiae. While initial prototrophic colony numbers from independent cultures were highly variable, additional recombinants were found to arise daily at roughly constant rates irrespective of culture. These late-appearing recombinants could be accounted for neither by detectable growth on the selective media nor by delayed appearance of recombinants present at the time of selective plating. Significantly, at no time did the distributions of recombinants fully match those expected according to the Luria-Delbruck model and, in fact, after the first day, the distributions much more closely approximated a Poisson distribution. Prototrophic recombinants accumulated not only on the relevant selective medium, but also on media unrelated to the acquired prototrophy.     

Mitotic versus meiotic recombination in Saccharomyces cerevisiae

Summary As part of a comparative analysis of spontaneous mitotic and meiotic recombination we have compared the mitotic and meiotic maps of the wild type and yeast hybrids homozygous for reml-l, a mitosis-specific hyper-rec mutation (Golin and Esposito, 1977; Golin, 1979). In wild type yeast strains recombination in centromere proximal intervals occurs relatively more frequently in mitosis than in meiosis. In reml-1/rem1-1 hybrids the distribution of mitotic exchange events is more similar to the distribution observed in meiosis.     

Analysis of meiotic recombination events near a recombination hotspot in the yeast Saccharomyces cerevisiae

The region of yeast chromosome III between the HIS4 and LEU2 genes has an unusually high frequency of meiotic recombination. In order to determine the pattern of cross-over and gene conversion events, we constructed a strain with a number of heterozygous markers in this 25-kb interval. We found that very high levels of reombination are localized to regions of DNA near HIS4. In addition, analysis of the patterns of co-conversion of adjacent markers suggests that there is more than one initiation site contributing to recombination of HIS4.     

In-vitro recombination in rad and rnc mutants of Saccharomyces cerevisiae

Summary Extracts of S. cerevisiae cells can catalyze homologous recombination between plasmids in vitro. Extracts prepared from rad50, rad52 or rad54 disruption mutants all have reduced recombinational activity compared to wild-type. The rad52 and rad54 extracts are more impaired in the recombination of plasmids containing double-strand breaks than of intact plasmids, whereas rad50 extracts are deficient equally for both types of substrate. The nuclease RhoNuc (previously designated yNucR), encoded by the RNC1 (previously designated NUC2) gene and regulated by the RAD52 gene, is not required for recombination when one substrate is single-stranded but is essential for the majority of recombination events when both substrates are double-stranded. Furthermore, elimination of this nuclease restores recombination in rad52 extracts to levels comparable to those in wild-type extracts.     

Formation and stability of linear plasmids in a recombination deficient strain of yeast

Summary Natural termini from macronuclear DNA of the ciliated protozoans Tetrahymena thermophila and Oxytricha fallax can support telomere formation in yeast. However, plasmids carrying these ciliate termini are modified by the addition of DNA which hybridizes to the synthetic oligonucleotide poly [d(C-A)], a sequence which also hybridizes to terminal restriction fragments from yeast chromosomes but not to Tetrahymena or Oxytricha macronuclear DNAs. Thus, in yeast, the creation of new telomeres on ciliate termini involves the acquisition of yeast-specific terminal sequences presumably by either recombination or non-templated DNA synthesis. The RAD52 gene is required for the majority of yeast mitotic and meiotic recombination events. Moreover, the absence of an active RAD52 gene product results in high rates of chromosome loss. Here we demonstrate that terminal restriction fragments from Tetrahymena macronuclear ribosomal DNA (rDNA) support the formation of modified telomeres in a yeast strain carrying a defect in the RAD52 gene. Moreover, linear plasmids bearing these modified ciliate termini are stably propagated in rad52 ^– cells.     

Mechanisms of mitochondrial DNA escape to the nucleus in the yeast Saccharomyces cerevisiae

The transfer of organelle nucleic acid to the nucleus has been observed in both plants and animals. Using a unique assay to monitor mitochondrial DNA escape to the nucleus in the yeast Saccharomyces cerevisiae, we previously showed that mutations in several nuclear genes, collectively called yme mutants, cause a high rate of mitochondrial DNA escape to the nucleus. Here we demonstrate that mtDNA escape occurs via an intracellular mechanism that is dependent on the composition of the growth medium and the genetic state of the mitochondrial genome, and is independent of an RNA intermediate. Isolation of several unique second-site suppressors of the high rate of mitochondrial DNA-escape phenotype of yme mutants suggests that there are multiple independent pathways by which this nucleic acid transfer occurs. We also demonstrate that the presence of centromeric plasmids in the nucleus can reduce the perceived rate of DNA escape from the mitochondria. We propose that mitochondrial DNA-escape events are manifested as unstable nuclear plasmids that can interact with centromeric plasmids resulting in a decrease in the number of observed events. Received: 21 April / 7 June 1999     

Further evidence of a disparity between conversion and restoration in the his1 locus of Saccharomyces cerevisiae

Summary Heteroduplex repair models of recombination predict that restoration of the parental genotype from heteroduplex will have the same frequency as conversion to the genotype of the homologue. We have reported previously (Savage and Hastings 1981) that the proportion of intragenic reciprocal events in the his1 locus of yeast is too low for this expectation. In this study, two classes of recombination event involving longer lengths of his1 are compared in a series of crosses using a constant right-hand marker. This comparison gives a value for conversion: restoration for the left-hand markers which is independant of the method used before. The values obtained by the two methods are significantly correlated, confirming that there is a disparity in the ratio of conversion to restoration, and that this disparity is seen as a deficiency of restoration for five alleles of his1.     

The influence of mutation rad57-1 on the fidelity of DNA double-strand gap repair in Saccharomyces cerevisiae

The role of the RAD57 gene in double-strand gap (DSG) repair has been examined. The repair of a linearized plasmid, bearing a DSG, has been analyzed in a rad57-1 mutant of Saccharomyces cerevisiae. For effective rejoining of the ends of plasmid DNA in the rad57 mutant the sequence of chromosomal DNA homologous to the DSG region is required. However, DSG repair (restoration of plasmid circularity) in rad57 cells is not accompanied by the recovery of DSGs. The DSG repair, which depends on an homologous chromosomal DNA sequence, requires the cohesive ends of DSGs. The non-cohesive-ended DSGs are repaired in rad57 cells by a pathway independent of the homologous recombination between chromosomal and plasmid DNA. We presume that the rad57-1 mutation is connected with the inhibition of DNA repair synthesis, required for filling the DSG. This situation produces a condition of “homology-dependent ligation”, the alternative minor mechanism of recombinational DSG repair, that takes place in mutant cells. A molecular model for “homology-dependent ligation” in rad57 cells is proposed. Received: 26 March / 29 October 1998     

The effect of canavanine on the maintenance in yeast of chimeric plasmids containing portions of the 2-µm DNA plasmid

Summary We have found that the application of the amino acid analog canavanine to a culture of yeast cells transformed with chimeric plasmids based on the yeast 2-µm DNA plasmid increases the percentage of cells which have lost the transforming plasmid. This effect is found whether the plasmid carries the CAN1 sensitive allele and the yeast strain carries a can1 mutation confering resistance, or the plasmid contains no CAN1 allele and the yeast strain carries the wild-type CAN1 sensitive allele. Canavanine exerts this effect on yeast strains transformed with chimeric plasmids containing either a portion or the entire 2-µm DNA plasmid, yet canavanine does not appear to effect the maintenance of the native 2-µm DNA plasmid complement within the cell. The effect of canavanine on strains transformed with chimeric plasmids is the same whether or not the yeast strain also contains native 2-µm plasmid DNA. Neither the amino acid analog ethionine, the protein synthesis inhibitor cycloheximide, nor the DNA replication inhibitor hydroxyurea exhibit this effect. Some of the experimental results suggest that canavanine may be a curing agent rather than an agent which selects for spontaneous plasmid loss.     

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     

δ Sequences mediate DNA rearrangements in Saccharomyces cerevisiae

Summary A solo sequence flanking the 5 end of the ADHII structural gene, ADR2, can promote a number of DNA rearrangements some of which were investigated in detail. In a selective system haploid mutants were screened in which a solo S sequence flanking ADR2 had been joined to a Ty element. Three different types of events can create such a structure: Reintegration of a Ty sequence at the -ADR2 site, inversion of ADR2 and flanking material, and transposition of ADR2 along with 3 flanking material. The involvement of reciprocal or non-reciprocal exchange mechanisms in creating such events are discussed.     

Repair of 2 um Plasmid DNA in Saccharomyces cerevisiae

Summary We have developed a system for assaying pyrimidine dimers in the 2 m DNA plasmid of Saccharomyces cerevisiae, using Micrococcus luteus UV endonuclease to nick dimer-containing plasmid molecules and measuring percentages of nicked and covalently closed circles on agarose gels. UV-irradiation induced dimers in plasmid DNA, in vivo, at the same rate as in chromosomal DNA. After a dose of 20 Joules·m^–2, approximately 86% of plasmid molecules had. at least one dimer. After 3 h incubation under normal growth conditions only 4% still retained dimers in a wild-type strain. In a rad1 (excision-defective) mutant 81% of plasmid molecules still had dimers after 3 h, suggesting that excision repair operates to remove dimers from plasmid DNA in wild-type yeast. Dimers can be removed from 2 ,um DNA in a rad1 mutant by photoreactivation.     

Interspecific protoplast fusion between the yeasts Saccharomyces cerevisiae and Saccharomyces fermentati

Summary Protoplasts of Saccharomyces cerevisiae his1 trp2 resistant to acriflavine and able to ferment galactose and of Saccharomyces fennentati arg resistant to DL-p-fluorophenylalanine and able to ferment lactose were fused. As a result of fusion two types of prototrophic hybrids were obtained. Type 1 hybrids were able to grow on medium with galactose or lactose as sole carbon source and were sensitive to acriflavine and resistant to DL-p-pfluorophenylalanine. Type 2 hybrids were able to grow on medium with galactose as sole carbon source and were resistant to acriflavine and sensitive to DL-p-fluorophenylalanine.     

Uptake of DNA by fragile mutants of Saccharomyces cerevisiae

Summary When Saccharomyces cerevisiae SY15 rho° mutant cells grown in media stabilized with 10% sorbitol were suspended in 2% sorbitol solutions, 60–70% of the population did not lyse and became permeable to native high molecular weight DNA. Maximal incorporation of DNA to DNase resistant state was measured after 60 min of incubation in presence of 5 g/ml DNA and 10 mM CaCl₂. These results suggest that the fragile mutants might be tested as hosts for transformation of whole yeast cells.     

Construction of stable episomes in Cryptococcus neoformans

We report the generation of stable plasmids constructed by inserting specific DNA sequences into previously known unstable vectors. These sequences were obtained from a DNA library recovered from a previously reported stable minichromosome created by electroporative transformation in Cryptococcus neoformans (Varma and Kwon-Chung 1994). A 6-kb insert from this minichromosome significantly enhanced both the frequencies at which URA5 transformants were obtained as well as the stability of their uracil prototrophy on non-selective media. A 1.5-kb sequence of this insert contained telomeric sequence repeats which when introduced into plasmids resulted in significant increases in transformation frequency. A 1081-bp sequence (STAB), present in the remainder of the insert, had an ARS-like function enhancing the episomal maintenance of plasmids in the transformants regardless of the gene (ADE2/URA5) used as a selection marker. Received: 4 November 1997 / 11 May 1998     

A mutant of Saccharomyces cerevisiae with impaired maintenance of centromeric plasmids

Summary A mutant with unstable maintenance of hybrid plasmids containing either one of the centromeric loci CEN3, CEN6, CEN11 and arsl or the replicator of the 2 plasmid has been obtained. The frequency of loss of hybrid plasmids in the mutant was up to 3 · 10^–1 per one generation versus 10^–2 in the original strain. The unstable maintenance of minichromosomes in the mutant is controlled by a recessive nuclear gene, named SMC for stability of minichromosomes. Loss of some minichromosomes is connected with impairment of their segregation in cell division. In diploids homozygous for smc mitotic chromosomal segregation is not affected but sporulation is impaired. The question of adequacy of usage of minichromosomes for selection of mutants with impaired function of centromeric loci is discussed.     

Newly synthesised DNA of high molecular weight in the yeast Saccharomyces cerevisiae

Summary Two species of newly synthesised DNA larger than average replicons have been found in yeast. Their molecular weights are 60 million and 90 million daltons respectively. The exact nature of these molecules is not certain. They may represent entirely novel species of cellular DNA or they could be concatameric replication intermediates of some particular fraction of DNA, such as mitochondrial DNA or rDNA. Alternatively they could result from the fusion of adjacent completed replicons in a small cluster.     

Analysis of interchromosomal mitotic recombination

Summary A novel synthetic locus is described that provides a simple assay system for characterizing mitotic recombinants. The locus consists of the TRP1 and HIS3 genes inserted into chromosome III of S. cerevisiae between the CRY1 and MAT loci. Defined trp1 and his3 alleles have been generated that allow the selection of interchromosomal recombinants in this interval. Trp⁺ or His⁺ recombinants can be divided into several classes based on coupling of the other alleles in the interval. The tight linkage of the CRY1 and MAT loci, combined with the drug resistance and cell type phenotypes that they respectively control, facilitates the classification of the recombinants without resorting to tetrad dissection. We present the distribution of spontaneous recombinants among the classes defined by this analysis. The data suggest that the recombination intermediate can have regions of symmetric strand exchange and that co-conversion tracts can extend over 1–3 kb. Continuous conversion tracts are favored over discontinuous tracts. The distribution among the classes defined by this analysis is altered in recombinants induced by UV irradiation.     

RPD3 (REC3) mutations affect mitotic recombination in Saccharomyces cerevisiae

Prior research identified the recessive rec3-1ts mutation in Saccharomyces cerevisiae which, in homozygous diploid cells, confers a conditional phenotype resulting in reduced levels of spontaneous mitotic recombination and loss of sporulation at the restrictive temperature of 36 °C. We found that a 3.4-kb genomic fragment that complements the rec3-1ts/rec3-1ts mutation and which maps to chromosome XIV, is identical to RPD3, a gene encoding a histone de-acetylase. Sporulation is reduced in homozygous diploid strains containing the rec3-1ts allele at 24 °C, suggesting that this allele of RPD3 encodes a gene product with a reduced function. Sporulation is abolished in diploid strains homozygous for the rpd3Δ or rec3-1ts alleles, as well as in rpd3Δ/rec3-1ts heteroallelic diploids, at the non-permissive temperature. Acid-phosphatase expression has been shown to be RPD3 dependent. We found that acid-phosphatase activity is greater in diploid strains homozygous for the temperature-sensitive rec3-1ts allele than in RPD3/RPD3 strains and increased further when mutant strains are grown at 36 °C. We also tested the rpd3Δ/rpd3Δ strains for their effects on spontaneous mitotic recombination. By assaying a variety of intra- and inter-genic recombination events distributed over three chromosomes, we found that in the majority of cases spontaneous mitotic recombination was reduced in diploid rpd3Δ/rpd3Δ cells (relative to a RPD3/RPD3 control). Finally, although 90% of mitotic recombinant events are initiated in the G₁ phase of the growth cycle (i.e., before DNA synthesis) we show that RPD3 is not regulated in a cell-cycle-dependent manner. These data suggest that mitotic recombination, in addition to gene expression, is affected by changes in chromatin architecture mediated by RPD3. Received: 17 July / 30 November 1998     

Chemical mutagenesis and DNA synthesis in cdc8, a DNA replication mutant of Saccharomyces cerevisiae

Summary Incubation of cdc8 mutants of the yeast Saccharomyces cerevisiae in YPD under permissive conditions, when DNA replication is taking place, prior to transfer to restrictive conditions, strongly stimulates induction of cdc ⁺ colonies of ethyl methane sulphonate (EMS)- and methyl methane sulphonate (MMS)-treated yeast strains HB23 (cdc8-1/cdc8-3), HB26 (cdc8-3/cdc8-3) and HB7 (cdc8-1/cdc8-1). After diepoxybutane (DEB) treatment, both the induction of cdc ⁺ colonies and their stimulation after incubation in YPD under permissive conditions is low. The results obtained show that stimulation of induction of cdc ⁺ colonies under permissive conditions occurs not only after UV-treatment, but also after treatment with such mutagens as EMS and MMS.