Ribosomal DNA magnification in Saccharomyces cerevisiae.

Strains monosomic for chromosome I of Saccharomyces cerevisiae contain 25 to 35% fewer rRNA genes than do normal diploid strains. When these strains are repeatedly subcultured, colonies are isolated that have magnified their number of rRNA genes to the diploid amount while remaining monosomic for chromosome I. We have determined the amount of DNA complementary to rRNA in viable haploid spores derived from a magnified monosomic strain. Some of these haploids contained 24 to 48% more rRNA genes than a normal euploid strain. These extra genes may be responsible for the increased number of rRNA genes in the strain monosomic for chromosome I. Genetic analysis of the haploids containing extra rRNA genes suggested that these genes are linked to chromosomal DNA and are heterozygous. They were not closely linked to any centromere and were not located on chromosome I. Furthermore, all the DNA complementary to rRNA in one of these haploid strains with magnified rRNA genes sedimented at a chromosomal molecular weight, consistent with chromosomal linkage. In addition, several new mutations mapping on chromosome I were used to show that ribosomal DNA magnification was not due to a chromosome I duplication.     

Genome size and ploidy level: new insights for elucidating relationships in Zygosaccharomyces species

Ploidy is a fundamental genetic trait with important physiological and genomic implications. We applied complementary molecular tools to highlight differences in genome size and ploidy between Zygosaccharomyces rouxii strain CBS 732T and other related wild strains (ATCC 42981, ABT 301, and ABT 601). The cell cycle analysis by flow cytometry revealed a genome size of 12.7+/-0.2 Mb for strain CBS 732T, 21.9+/-0.2 Mb for ATCC 42981, 28.1+/-1.3 Mb for ABT 301, and 39.00+/-0.3 Mb for ABT 601. Moreover, karyotyping analysis showed a high variability, with wild strains having a higher number of chromosomal bands than CBS 732T. The ploidy level was assessed comparing genome size from flow cytometry with the average haploid size from electrophoretic karyotyping. Strain CBS 732T showed an haploid DNA content, whereas the wild strains a diploid DNA content. In addition gene probe-chromosome hybridization targeted to ZSOD genes showed that wild strains with a diploid DNA content have two ZSOD copies located on different chromosomes.     

Caffeine enhancement of radiation killing in different strains of Saccharomyces cerevisiae.

Summary Haploid and diploid wild type strains, and three classes of radiation-sensitive mutants of Saccharomyces cerevisiae were tested for enhancement of UV-inactivation by caffeine in growth medium. In addition, the sensitizing effect of caffeine was studied in a haploid and a diploid wild type strain after gamma-irradiation. The drug sensitized the UV-irradiated cells of all strains except those reported to be only slightly UV-sensitive but highly sensitive to ionizing radiation. After gamma-irradiation, no caffeine-enhancement of killing was observed in stationary phase cells of either the haploid or the diploid strain. However, log-phase cells of both strains were partially sensitized.The results of both sets of experiments suggested that caffeine interferes with a recombinational repair occurring in cells in S or G2 phase.     

Efficient production of ethanol from raw starch by a mated diploid Saccharomyces cerevisiae with integrated α-amylase and glucoamylase genes

The goal of this research was to construct a stable and efficient process for the production of ethanol from raw starch, using a recombinant Saccharomyces cerevisiae, which is productive even under conditions such as non-selection or long-term operation. Three recombinant yeast strains were used, two haploid strains (MT8-1SS and NBRC1440SS) and one diploid strain (MN8140SS). The recombinant strains were constructed by integrating the glucoamylase gene from Rhizopus oryzae fused with the 3′-half of the α-agglutinin gene as the anchor protein, and the α-amylase gene from Streptococcus bovis, respectively, into their chromosomal DNA by homologous recombination. The diploid strain MN8140SS was constructed by mating these opposite types of integrant haploid strains in order to enhance the expression of integrated amylase genes. The diploid strain had the highest ethanol productivity and reusability during fermentation from raw starch. Moreover, the ethanol production rate of the integrant diploid strain was maintained when batch fermentation was repeated three times (0.67, 0.60, and 0.67 g/l/h in each batch). These results clearly show that a diploid strain developed by mating two integrant haploid strains is useful for the establishment of an efficient ethanol production process.     

Allelic and Ectopic Interactions in Recombination-Defective Yeast Strains

Ectopic recombination in the yeast Saccharomyces cerevisiae has been investigated by examining the effects of mutations known to alter allelic recombination frequencies. A haploid yeast strain disomic for chromosome III was constructed in which allelic recombination can be monitored using leu2 heteroalleles on chromosome III and ectopic recombination can be monitored using ura3 heteroalleles on chromosomes V and II. This strain contains the spo13-1 mutation which permits haploid strains to successfully complete meiosis and which rescues many recombination-defective mutants from the associated meiotic lethality. Mutations in the genes RAD50, SPO11 and HOP1 were introduced individually into this disomic strain using transformation procedures. Mitotic and meiotic comparisons of each mutant strain with the wild-type parental strain has shown that the mutation in question has comparable effects on ectopic and allelic recombination. Similar results have been obtained using diploid strains constructed by mating MATa and MAT alpha haploid derivatives of each of the disomic strains. These data demonstrate that ectopic and allelic recombination are affected by the same gene products and suggest that the two types of recombination are mechanistically similar. In addition, the comparison of disomic and diploid strains indicates that the presence of a chromosome pairing partner during meiosis does not affect the frequency of ectopic recombination events involving nonhomologous chromosomes.     

Nucleotide excision repair deficiency causes elevated levels of chromosome gain in Saccharomyces cerevisiae

Aneuploidy is the most frequent aberration observed in tumor cells, and underlies many debilitating and cancer-prone congenital disorders. Aneuploidy most often arises as a consequence of chromosomal non-disjunction, however, little is known about the genetic and epigenetic factors that affect the chromosomal segregation process. As many cancer-prone syndromes are associated with defects in DNA repair pathways we decided to investigate the relationship between DNA repair in mutation avoidance pathways, namely base and nucleotide excision, and mismatch repair (MMR), and aneuploidy in the yeast Saccharomyces cerevisiae. Isogenic haploid and diploid DNA repair deficient yeast strains were constructed, and spontaneous levels of intra- and inter-chromosomal recombination, forward mutation, chromosome gain, and loss were measured. We show that the nucleotide excision repair (NER) pathway is required for accurate chromosomal disjunction. In the absence of Rad1, Rad2, or Rad4, spontaneous levels of chromosome XV gain were significantly elevated in both haploid and diploid mutant strains. Thus, chromosome gain may be an additional cancer predisposing event in NER deficient patients.     

Increased inactivation of Saccharomyces cerevisiae by protraction of UV irradiation.

The principle of equi-effectivity of the product of intensity and exposure time (principle of Bunsen-Roscoe) of UV irradiation has been assumed to be valid for the inactivation of microorganisms in general. Earlier studies claimed higher survival of Escherichia coli B/r with fractionated irradiation compared with single-exposure survival. However, data on the inactivation effect of protraction of UV irradiation are not available. By means of a specially designed UV irradiation apparatus which secured absolute UV dose measurements throughout the experiments, the effects of variation of UV irradiation intensities (253.7 nm) and exposure times were tested on the inactivation of a bacterial virus (Staphylococcus aureus phage A994), a vegetative bacterial strain (E. coli ATCC 25922), and bacterial spores (Bacillus subtilis ATCC 6633) as well as three haploid laboratory strains (RC43a, YNN281, and YNN282) and two diploid strains (commercial bakery yeast strain and laboratory strain YNN281 x YNN282) or yeast (Saccharomyces cerevisiae) and spores of the latter diploid yeast strain. Each test organism was exposed to three UV intensities (0.02, 0.2, and 2 W/m2), with corresponding exposure times resulting in three dose levels for each intensity. Differences in inactivation rates were tested by analyses of variance and Newman-Keuls tests. Virus and bacteria showed no differences in inactivation rates by variation of intensities and exposure times within selected UV doses; hence, the principle of Bunsen-Roscoe could not be rejected for these strains. However, in the eukaryotic test strains of S. cerevisiae longer exposure times with lower intensities led to enhanced inactivation in both haploid and diploid strains, with a more pronounced effect in the diploid yeast strains, whereas in yeast spores in this dose rate effect could not be observed.     

Lipid Synthesis During Sporulation of Saccharomyces cerevisiae

Lipid synthesis was studied in both sporulating (diploid) and nonsporulating (haploid) cells of Saccharomyces cerevisiae. Two phases of lipid synthesis occur in diploid cells transferred to sporulation medium. Phase I, which occurs during the first 12 h of exposure to sporulation medium, was also observed in the haploid strains. Phase II, occurring from the 20th to the 25th h, coincided with the appearance of mature asci and was observed only in the diploid cells. The majority of phospholipid synthesis took place during period I, whereas neutral lipid synthesis occurred during both periods. Phospholipid synthesis was virtually identical in both type and quantity in the sporulating and nonsporulating strains.     

Novel genetic components controlling invertase production in Saccharomyces cerevisiae

Low levels of invertase (EC 3.2.1.26) activity were observed in most diploid strains of S. cerevisiae used in this work. There was no effect of mating type on invertase levels, and cell surface was not a limiting factor, because an increase in ploidy did not cause further decrease in specific invertase activity. Finally, some diploids showed the activity expected from the additive effects of different SUC genes, and haploid strains possessing two SUC genes expressed very variable invertase activities depending on the strain. This suggested the existence of one or more additional genes which control the levels of invertase. Genetic analysis of SUC5 strains provided evidence of the existence of a new gene, RPS5, which drastically reduced the specific invertase activity in strains possessing active SUC alleles. The recessive allele of this gene (rps5) allows expression of higher levels of invertase. We suggest that genes similar RPS5 are responsible for the low levels of invertase activity observed in diploid strains of S. cerevisiae.     

耐高温酿酒酵母单倍体的RAPD分析

采用随机孢子分析的方法 ,从酿酒酵母的耐热菌株HU TY 1中分离了单倍体HZ系列 ,对其进行生长曲线和发酵力的测定。选取HZ-21、HZ-84菌株进行随机扩增多态性DNA片段的分析 ,显示单倍体菌株与它们的二倍体亲株以及原始出发菌株LK的基因组之间确实存在着多态性DNA片段 ,其中有些可能与菌株的耐热性相关     

A mutation in SPC42, which encodes a component of the spindle pole body, results in production of two-spored asci in Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, SPC42 is an essential gene, which encodes one of the major components of the spindle pole body (SPB). We report on a mutation in the SPC42 gene (spc42-102) that results in a sporulation-specific defect. Mitotic growth of haploid and diploid spc42-102 strains is normal and both exhibit the same growth rates as the isogenic wild-type strains. Many diploid spc42-102/spc42-102 cells undergo normal meiotic nuclear divisions, producing four haploid nuclei. However, a significant fraction of meiotic spc42-102/spc42-102 cells contain two immature SPBs and aberrant nuclei that are not surrounded by a prospore membrane. Some 40% of the resultant asci contain only two spores, while wild-type diploid cells almost always produce four-spored asci. Segregation of auxotrophic markers that are tightly linked to the centromere reveals that two-spore asci formed from spc42-102/spc42-102 diploid cells exclusively contain nonsister haploid spores. Western analysis and measurements of the fluorescent signal from an Spc42p-GFP (green fluorescent protein) fusion reveal that the mutant strain fails to accumulate Spc42p at meiosis. Thus, our results suggest that insufficiency of Spc42p during meiosis results in a pair of immature nonsister SPBs that are not enclosed by prospore membrane.     

Inheritance of the 2μm DNA Plasmid from Saccharomyces

A variety of Saccharomyces strains were examined for the presence of 2micro DNA and, if present, for the pattern of fragments produced by its digestion with site-specific (restriction) endonucleases. Two strains were found that did not contain detectable levels of 2micro DNA, and two strains contained 2micro DNA molecules having only one EcoRI restriction endonuclease recognition site rather than the usual two.-A haploid containing 2micro DNA with one EcoRI restriction site was mated with a haploid containing 2micro DNA with two EcoRI restriction sites and the resulting diploid maintained both types during vegetative growth. Sporulation of the diploid produced four spores, and the clones from these spores contained both types.-A haploid lacking 2micro DNA was mated with a haploid containing 2micro DNA and the resulting diploid contained 2micro DNA. The four clones derived from the haploid spores after sporulation of this diploid all contained 2micro DNA. A rho(-) strain without 2micro DNA was mated to a rho(+) strain with 2micro DNA, and heteroplasmons were selected that had received the nucleus from the strain without 2micro DNA and the mitochondria from the strain with 2micro DNA. Twelve of twenty-four such clones contained 2micro DNA.-I conclude that: (1) the different types of 2micro DNA identified in these strains do not restrict one another, (2) the different types are inherited extrachromosomally, (3) lack of 2micro DNA in two strains is not due to the absence of genes needed for maintenance and (4) the approximately 100 copies of 2micro DNA contained within a single cell are probably clustered within one or a few cytoplasmic organelles.     

Flow cytometry reveals a high degree of genomic size variation and mixoploidy in various strains of the acellular slime mold Physarum polycephalum

High-resolution flow cytometry, using avian erythrocytes as an internal standard, was employed to study constitutive genome size variation of G2-phase nuclei of Physarum polycephalum strains during the macroplasmodial stage of their life cycle. Our results document a previously unknown extent of genome size variation and mixoploidy in this organism. The unimodal diploid strain Tu 291 displayed the largest genome of the strains tested; in contrast, the Colonia strain displayed only half of the Tu 291 G2-phase fluorescence, confirming its haploid nature. An additional strain, derived from a recent cross between Lu897 and Lu898 amoebae, must have arisen by selfing (propagation of only one of the parental genomes to the macroplasmodial stage), since its nuclei display close to the haploid G2-phase DNA content. The observation of a small fraction of corresponding diploid nuclei within the haploid population of this strain, while maintained as microplasmodia, supports the notion that meiosis in haploid strains may require the presence of diploid nuclei. Two of the descendants of the prototype haploid Colonia strain, which were kept for extended periods of time in submerse culture, proved to be near diploid and mixoploid. Polyploidization and subsequent loss of DNA thus seems to contribute to the extremes of genome size variation in Physarum. In addition to unimodal fluorescence distributions, a number of diploid strains displayed bi- and even trimodal distributions within harvests of a single G2-phase macroplasmodium. Analysis of these mixoploid strains by means of gaussian curve-fitting suggests that the smaller genome size differences in Physarum may arise in step-wise diminution of DNA in approximate units of 3-5% of the original Tu 291 genome.     

Ploidy controls the success of mutators and nature of mutations during budding yeast evolution

BACKGROUND: We used the budding yeast Saccharomyces cerevisiae to ask how elevated mutation rates affect the evolution of asexual eukaryotic populations. Mismatch repair defective and nonmutator strains were competed during adaptation to four laboratory environments (rich medium, low glucose, high salt, and a nonfermentable carbon source). RESULTS: In diploids, mutators have an advantage over nonmutators in all conditions, and mutators that win competitions are on average fitter than nonmutator winners. In contrast, haploid mutators have no advantage when competed against haploid nonmutators, and haploid mutator winners are less fit than nonmutator winners. The diploid mutator winners were all superior to their ancestors both in the condition they had adapted to, and in two of the other conditions. This phenotype was due to a mutation or class of mutations that confers a large growth advantage during the respiratory phase of yeast cultures that precedes stationary phase. This generalist mutation(s) was not selected in diploid nonmutator strains or in haploid strains, which adapt primarily by fixing specialist (condition-specific) mutations. In diploid mutators, such mutations also occur, and the majority accumulates after the fixation of the generalist mutation. CONCLUSIONS: We conclude that the advantage of mutators depends on ploidy and that diploid mutators can give rise to beneficial mutations that are inaccessible to nonmutators and haploid mutators.     

Deoxyribonucleic acid-deficient strains of Candida albicans.

We analyzed a series of germ tube-negative variants isolated from Candida albicans 3153A for deoxyribonucleic acid content. As analyzed by flow microfluorometry, the deoxyribonucleic acid level in these variant strains was 50% of that of the parental strain and equivalent to that of haploid Saccharomyces cerevisiae. This finding was confirmed by comparison of survival rates when exposed to the mutagens ultraviolet light, ethyl methane sulfonate, and methyl methane sulfonate. The diameter of the variant cells as compared to the diameter of the parental 3153A strain showed a relationship similar to that of the diameters of haploid versus diploid S. cerevisiae. These results indicate that those strains may be representative of the imperfect stage of C. albicans.     

Studies on the genetic regulation of cytochrome P-450 production in Saccharomyces cerevisiae

An initial survey of 18 haploid strains of Saccharomyces cerevisiae revealed that only 3 of these strains could produce a detectable level of cytochrome P-450. A cross between a cytochrome P-450 producing strain of S. cerevisiae (B/B) and a non-producing strain (D22) gave a diploid which was a non-producer and a 2:2 segregation of producers to non-producers in meiotic tetrads. Of the two producers in each tetrad, one produced a higher level of cytochrome P-450 than the other. We deduce that cytochrome P-450 production in S. cerevisiae is regulated by a single nuclear gene and that a modifier gene is also involved which can enhance the amount of cytochrome P-450 synthesized. Benzo(a)pyrene (an inducer of P-450 in yeast) had no effect on the action of the regulatory gene.     

Use of a genome-wide approach to identify new genes that control resistance of Saccharomyces cerevisiae to ionizing radiation

We have used the recently completed set of all homozygous diploid deletion mutants in budding yeast, S. cerevisiae, to screen for new mutants conferring sensitivity to ionizing radiation. In each strain a different open reading frame (ORF) has been replaced with a cassette containing unique 20-mer sequences that allow the relative abundance of each strain in a pool to be determined by hybridization to a high-density oligonucleotide array. Putative radiation-sensitive mutants were identified as having a reduced abundance in the pool of 4,627 individual deletion strains after irradiation. Of the top 33 strains most sensitive to radiation in this assay, 14 contained genes known to be involved in DNA repair. Eight of the remaining deletion mutants were studied. Only one, which deleted for the ORF YDR014W (which we name RAD61), conferred reproducible radiation sensitivity in both the haploid and diploid deletions and had no problem with spore viability when the haploid was backcrossed to wild-type. The rest showed only marginal sensitivity as haploids, and many had problems with spore viability when backcrossed, suggesting the presence of gross aneuploidy or polyploidy in strains initially presumed haploid. Our results emphasize that secondary mutations or deviations from euploidy can be a problem in screening this resource for sensitivity to ionizing radiation.     

Generation of a large set of genetically tractable haploid and diploid Saccharomyces strains

Saccharomyces cerevisiae has proved to be an invaluable model in classical and molecular genetics studies. Despite several hundreds of isolates already available, the scientific community relies on the use of only a handful of unrelated strains. The lack of sequence information, haploid derivatives and genetic markers has prevented novel strains from being used. Here, we release a set of 55 S. cerevisiae and Saccharomyces paradoxus genetically tractable strains, previously sequenced in the Saccharomyces Genome Resequencing Project. These strains are stable haploid derivatives and ura3 auxotrophs tagged with a 6-bp barcode, recognized by a restriction enzyme to allow easy identification. We show that the specific barcode can be used to accurately measure the prevalence of different strains during competition experiments. These strains are now amenable to a wide variety of genetic experiments and can be easily crossed with each other to create hybrids and segregants, providing a valuable resource for breeding programmes and quantitative genetic studies. Three versions of each strain (haploid Mat a and Mat α and diploid Mat a /α all as ura3 ∷ KanMX-Barcode ) are available through the National Culture Yeast Collection.     

Analysis and dynamics of the chromosomal complements of wild sparkling-wine yeast strains

We isolated Saccharomyces cerevisiae yeast strains that are able to carry out the second fermentation of sparkling wine from spontaneously fermenting musts in El Penedès (Spain) by specifically designed selection protocols. All of them (26 strains) showed one of two very similar mitochondrial DNA (mtDNA) restriction patterns, whereas their karyotypes differed. These strains showed high rates of karyotype instability, which were dependent on both the medium and the strain, during vegetative growth. In all cases, the mtDNA restriction pattern was conserved in strains kept under the same conditions. Analysis of different repetitive sequences in their genomes suggested that ribosomal DNA repeats play an important role in the changes in size observed in chromosome XII, whereas SUC genes or Ty elements did not show amplification or transposition processes that could be related to rearrangements of the chromosomes showing these sequences. Karyotype changes also occurred in monosporidic diploid derivatives. We propose that these changes originated mainly from ectopic recombination between repeated sequences interspersed in the genome. None of the rearranged karyotypes provided a selective advantage strong enough to allow the strains to displace the parental strains. The nature and frequency of these changes suggest that they may play an important role in the establishment and maintenance of the genetic diversity observed in S. cerevisiae wild populations.