Detection of the loss of 1 chromosome from pair III in Saccharomyces cerevisiae yeasts

A diploid strain of Saccharomyces cerevisiae, T6 is described which monitors both mitotic crossing over and induction of aneuploidy. The chromosome III carries recessive markers: rgh12 of "rough colony" phenotype closely linked to centromere, the left arm is marked with his4, the right arm is marked both with thr4 and the locus of mating type alpha. Expression of all the markers on chromosome III leads to formation of colonies which are rough, require histidine and threonine, and are of alpha mating type. These colonies arise as a result of the loss of a chromosome during mitosis, which makes the strain allow detection of monosomic cells formation. Chromosome XV carries two phenotypically distinguishable and recessive alleles of the gene ade2: ade2-192 (causes red coloration of colonies) and ade2-G45 (causes pink coloration of colonies). Mitotic crossing over generates two reciprocal products which can be revealed together in colonies as pink and red sectors in double-spotted colonies. Both double-spotted and monosomic colonies have been obtained after treatment with gamma-rays. The frequency of mitotic crossing over after irradiation by 1000-3000 Gray increased up to 2-3.2% (the spontaneous level was 0.006%), the frequency of aneuploidy was 0.12 to 0.57% at plating immediately after irradiation (the spontaneous monosomics were not observed among 1.5 X 10(5) cells scored). Induction of mitotic crossing over and aneuploidy by benomyl was rather slight (up to 0.05 and 0.006%, respectively).     

A yeast strain for simultaneous detection of induced mitotic crossing over,mitotic gene conversion and reverse mutation

A diploid yeast strain is described which can be used to study induction of mitotic crossing over, mitotic gene conversion and reverse mutation.Mitotic crossing over can be detected visually as pink and red twin sectored colonies which are due to the formation of homozygous cells of the genotype ade240/ade240 (deep red) and ade-2-119/ade2-119 (pink) from the originally heteroallelic condition ade2-40/ade2-119 which forms white colonies.Mitotic gene conversion is monitored by the appearance of tryptophan non-requiring colonies on selective media. The alleles involved are tryp5-12 and trp5-27 derived from the widely used strain D4.Mutation induction can be followed by the appearance of isoleucine non-requiring colonies on selective media. D7 is homoallelic ilv1-92/ilv1-92. The isoleucine requirement caused by ilv1-92 can be alleviated by true reverse mutation and allele non-specific suppressor mutation.The effects of ethyl methanesulfonate (EMS), nitrous acid, ultraviolet light and hycanthone methanesulfonate were studied with D7 stationary phase cells. Mitotic crossing over as monitored by red/pink twin sectored colonies was almost equally frequent among normal and convertant cells. This showed again that mitotic recombination is not due to the presence fo a few cells committed to meiosis in an otherwise mitotic cell population.The dose-response curves for induction of mitotic gene conversion and reversion of the isoleucine requirement were exponential. In contrast to this, the dose-response curve for induction of twin sectored red and pink colonies reached a plateau at doses giving about 30% cell killing. This could partly be due to lethal segregation in the progeny of treated cells.None of the agents tested would induce only one type of mitotic recombination, gene conversion or crossing over. There was, however, some mutagen specificity in the induction of isoleucine prototrophs.     

Isolation, characterization, and genetic analysis of monosomic, aneuploid mutants of Candida albicans

A white, prototrophic Candida albicans strain, heterozygous for the ADE2 gene (ade2/ADE2), was treated with the antimitotic agent methyl benzimidazole carbamate, and yielded red, adenine-requiring colonies at a rate of 4 x 10(-3), an order of magnitude higher than the spontaneous rate of Ade- colony formation. These red Ade- colonies were small, growing at approximately half the rate of the parent strain, and gave rise to large red colonies spontaneously. When the chromosomes of the small red colonies were separated by pulsed-field gel electrophoresis, the band hybridizing with the ADE2 gene was diminished in staining intensity by half relative to the parent and large red-colony strains. Restriction fragment-length polymorphism analysis and auxotrophic mutant spectra after mutagenesis suggested that the small red Ade- strains were monosomic aneuploids lacking one of a pair of chromosome homologues, while the large red strains had regained a homologue, presumably via a second non-disjunction event. Parasexual genetic analysis of two of the auxotrophs isolated from a putative aneuploid suggested that both mutations were linked to the ADE2 gene. These experiments suggest that targeted chromosome loss and monosomic, aneuploid strains have the potential to extend the scope of genetic analysis in this diploid, asexual organism.     

Characterization of a Mutation in Yeast Causing Nonrandom Chromosome Loss during Mitosis

Diploid strains of the yeast Saccharomyces cerevisiae homozygous for a recessive chromosome loss mutation (chl) exhibit a high degree of mitotic instability. Cells become monosomic for chromosome III at a frequency of approximately one percent of all cell divisions. Chromosome loss at this high frequency is also found for chromosome I, and at lesser frequencies for chromosomes VIII and XVI. In contrast, little or no chromosome loss is found for six other linkage groups tested (II, V, VI, VII, XI and XVII). The chl mutation also induces a ten-fold increase in both intergenic and intragenic mitotic recombination on all ten linkage groups tested. The chl mutation does not cause an increase in spontaneous mutations, nor are mutant strains sensitive to UV or γ irradiation. The effects of chl during meiosis are observed primarily in reduced spore viability. A decrease in chromosome III linkage relationships is also found.     

Procedures used in the induction of mitotic recombination and mutation in the yeast Saccharomyces cerevisiae.

Techniques are described for the use of various yeast strains to detect the induction of (1) mitotic crossing-over, (2) mitotic gene conversion, (3) forward mutation and (4) reverse mutation. The technique for the detection of mitotic crossing over is based on a diploid that carries two different alleles of the gene locus ade2. These alleles differ in their extent of colony pigmentation engendered on low-adenine media, and they complement each other to the effect that the diploid is white. Mitotic crossing over results in the formation of twin-sectored colonies with a red and a pink sector. The technique for the detection of mitotic gene conversion is based on the use of a heteroallelic diploid carrying two non-complementing alleles that cause a nutritional requirement. Mitotic gene conversion leads to the restoration of intact and dominant wild-type alleles that alleviate the nutritional requirement so that convertant cells can be selected on a minimal medium. The forward mutation technique is based on the use of a haploid strain with a defect in the ade2-gene locus which causes the formation of red colonies. Induction of forward mutation in a number of other loci prevents the accumulation of this red pigment so that induction of mutation can be detected by the formation of pink and white colonies. The reverse mutation technique is based on the restoration or compensation of a mutational defect causing a growth requirement. Mutants can be selected for on a minimal medium.     

The genomic instability of yeast cdc6-1/cdc6-1 mutants involves chromosome structure and recombination

When diploid cells of Saccharomyces cerevisiae homozygous for the temperature-sensitive cell division cycle mutation cdc6-1 are grown at a semipermissive temperature they exhibit elevated genomic instability, as indicated by enhanced mitotic gene conversion, mitotic intergenic recombination, chromosomal loss, chromosomal gain, and chromosomal rearrangements. Employing quantitative Southern analysis of chromosomes separated by transverse alternating field gel electrophoresis (TAFE), we have demonstrated that 2N-1 cells monosomic for chromosome VII, owing to the cdc6-1 defect, show slow growth and subsequently yield 2N variants that grow at a normal rate in association with restitution of disomy for chromosome VII. Analysis of TAFE gels also demonstrates that cdc6-1/cdc6-1 diploids give rise to aberrant chromosomes of novel lengths. We propose an explanation for the genomic instability induced by the cdc6-1 mutation, which suggests that hyper-recombination, chromosomal loss, chromosomal gain and chromosomal rearrangements reflect aberrant mitotic division by cdc6-1/cdc6-1 cells containing chromosomes that have not replicated fully.     

Association of Disomic Chromosome Loss with Ems-Induced Conversion in Yeast

Experimental tests with the yeast Saccharomyces cerevisiae of a previously proposed model suggesting a causal relationship between disomic chromosome loss (n + 1 → n) and centromere-adjacent mitotic gene conversion were performed. Disomic haploid cells heteroallelic at two loci on the left arm of chromosome III were exposed to ethyl methanesulfonate (EMS) under nonlethal conditions; EMS-induced prototrophic gene convertants were selected and tested for coincident chromosome loss. The principal results are: (1) The frequency of chromosome loss among EMS-induced gene convertants selected to arise near the centromere is markedly enhanced over basal levels and remains constant, independent of EMS exposure. There is little such enhancement among EMS-induced convertants selected to arise far from the centromere. (2) Chromosome loss is almost completely associated with induced conversion of the centromere-proximal allele at the centromere-adjacent heteroallelic locus. This result is identical to (and confirms) results found previously for spontaneous loss-associated conversion. (3) The conversion polarity at the centromere-adjacent locus among unselected (nonloss-associated) induced or spontaneous mitotic convertants is identical to that among meiotic convertants and markedly favors the contromere-distal allele. These findings are wholly consistent with, and strengthen, the hypothesis that structural involvement of centromeric regions in nearby recombinational events may interfere with proper segregational function and lead to mitotic chromosome loss.     

Genetic damage induced by ethyl alcohol in Aspergillus nidulans.

Heterozygous diploid conidia of Aspergillus nidulans were treated during germination with ethyl alcohol in concentrations ranging from 0.25% to 20% (v/v). The diploid strain carried three recessive conidial color mutations, in addition to genetic markers on all eight pairs of linkage groups. It was thereby possible to detect events of crossing over, non-disjunction, and mutation. An increase in the dose of ethanol was associated with a decrease in conidial viability and an increase in the relative and absolute frequencies of formation of (a) normal colonies which produced colored sectors and (b) phenotypically abnormal colonies, the majority of which (83.1%) produced normal sectors. At a concentration of 5% (v/v) ethanol, the survivors included 17.59% of the former and 44.7% of the latter colonies. Genetic analysis of the various segregants suggested that the frequencies of both mitotic crossing over and non-disjunction or the misdistribution of chromosomes were increased by ethanol. Among 133 abnormal colonies which segregated normal clones, 79 (59.4%) were associated with one of these genetic events. A total of 297 haploids and 130 diploids arose as normal segregants from the abnormal colonies. There were 31 recognizable events of non-disjunction and 14 crossing over in linkage groups I and II, where these events could be distinguished. These data suggested that the predominant effect of ethanol was a disruption of chromosome distribution. A cytological examination of ethanol-treated, germinating conidia revealed an interference with the mitotic spindle apparatus. The frequency of detectable spindles decreased more than 3-fold after 8 h exposure to 5% (v/v) ethanol. This finding supported the conclusion that ethanol disrupted chromosome distribution, and suggested the mechanism by which it does so. Human clinical data on alcohol consumption were examined in light of these findings.     

Nuclear inheritance of resistance to antimycin A in Saccharomyces cerevisiae.

Summary A group of 30 independent mutants of Saccharomyces cerevisiae, resistant to the respiratory inhibitor antimycin A, was investigated from a genetical and biochemical point of view. All the mutants can be grouped into two nuclear loci: AMY1 maps on the VII chromosome, between leu 1 and trp 5; AMY2 is close to its centromere on either chromosome XVIII or XIX. Both genes do not affect mitochondrial structures or functions.     

Frequencies of mutagen-induced coincident mitotic recombination at unlinked loci in Saccharomyces cerevisiae

Frequencies of coincident genetic events were measured in strain D7 of Saccharomyces cerevisiae. This diploid strain permits the detection of mitotic gene conversion involving the trp5-12 and trp5-27 alleles, mitotic crossing-over and gene conversion leading to the expression of the ade2-40 and ade2-119 alleles as red and pink colonies, and reversion of the ilv1-92 allele. The three genes are on different chromosomes, and one might expect that coincident (simultaneous) genetic alterations at two loci would occur at frequencies predicted by those of the single alterations acting as independent events. Contrary to this expectation, we observed that ade2 recombinants induced by bleomycin, beta-propiolactone, and ultraviolet radiation occur more frequently among trp5 convertants than among total colonies. This excess among trp5 recombinants indicates that double recombinants are more common than expected for independent events. No similar enrichment was found among Ilv(+) revertants. The possibility of an artifact in which haploid yeasts that mimic mitotic recombinants are generated by a low frequency of cryptic meiosis has been excluded. Several hypotheses that can explain the elevated incidence of coincident mitotic recombination have been evaluated, but the cause remains uncertain. Most evidence suggests that the excess is ascribable to a subset of the population being in a recombination-prone state.     

The genetics of resistance to powdery mildew in cultivated oats (Avena sativa L.): current status of major genes

The genetics of resistance to powdery mildew caused by Blumeria graminis f. sp. avenae of four cultivated oats was studied using monosomic analysis. Cultivar ‘Bruno’ carries a gene (Pm6) that shows a recessive mode of inheritance and is located on chromosome 10D. Cultivar ‘Jumbo’ possesses a dominant resistance gene (Pm1) on chromosome 1C. In cultivar ‘Rollo’, in addition to the gene Pm3 on chromosome 17A, a second dominant resistance gene (Pm8) was identified and assigned to chromosome 4C. In breeding line APR 122, resistance was conditioned by a dominant resistance gene (Pm7) that was allocated to chromosome 13A. Genetic maps established for resistance genes Pm1, Pm6 and Pm7 employing amplified fragment length polymorphism (AFLP) markers indicated that these genes are independent of each other, supporting the results from monosomic analysis.     

Long-Tract Mitotic Gene Conversion in Yeast: Evidence for a Triparental Contribution during Spontaneous Recombination

In Saccharomyces cerevisiae, spontaneous mitotic gene conversion at one site is statistically correlated with recombination at other loci. In general, coincident conversion frequencies are highest for tightly linked markers and decline as a function of intermarker distance. Paradoxically, a significant fraction of mitotic gene convertants exhibits concomitant nonreciprocal segregation for multiple and widely spaced markers. We have undertaken a detailed genetic analysis of this class of mitotic recombinants. Our results indicate that mitotic gene conversion in yeast is frequently associated with nonreciprocal segregation of markers centromere-distal to the selected site of conversion. In addition, distal markers are often found to be mosaic within the product colonies. These observations, and others described here, suggest that a percentage of gene conversion in vegetative yeast cells is coupled to a chromosome break and repair mechanism. This hypothesis was further tested using a strain trisomic for chromosome VII which was specially marked to detect homolog-dependent repair events. An association between mitotic gene conversion events and the production of broken chromosomes which are repaired by a homologous-pairing-copy mechanism was supported.     

Isolation of Aneuploid-Generating Mutants of ASPERGILLUS NIDULANS, One of Which Is Defective in Interphase of the Cell Cycle

A method is described for isolating mutants potentially defective in loci involved in mitotic chromosome segregation. Conditional lethal, heat-sensitive (42°) mutants were assayed at a subrestrictive temperature of 37° for an inflated production of colonies displaying phenotypes and behavior patterns of whole chromosome aneuploids. Of 14 mutants, three showed specificity for one disomic phenotype, whereas 11 generated colonies mosaic for different aneuploid phenotypes. This latter group is designated hfa ( high frequency of aneuploid). For ten of the 11 mutants temperature sensitivity and aneuploid production cosegregated, indicating a single mutation in each. These mutations were recessive and nonallelic. Analysis was concentrated on the hfaB3 mutation which is mapped to chromosome VI tightly linked to the methB and tsB loci. The disruptive influence of hfaB3 on mitosis at 37° was shown by (1) ploidy and whole chromosome-type segregation of markers in the breakdown sectors of phenotypically aneuploid colonies obtained from multiply marked homozygous hfaB3 disploids; (2) a high frequency of haploid and nondisjunctional diploid segregants among spontaneous yellow-spored parasexual recombinants taken from green-spored homozygous hfaB3 diploids. The mutation had no effect on meiotic chromosome segregation at 37°. The single interphase nucleus in germlings at 42°, coupled with changes in the mitotic index in temperature exchange experiments, showed hfaB3 to arrest the cell cycle in interphase at restrictive temperature. A conclusion drawn is that the hfaB gene product is required both for entry into mitosis and for normal chromosome segregation in dividing nuclei.     

Development of papillae on colonies of two isopoly-auxotrophic strains ofSaccharomyces cerevisiae allelic inRAD6 during adenine starvation

Papilla formation on colonies of two isopolyauxotrophic strains (ade 2 his3 leu2 trp1 ura3) allelic inRAD6 was compared in order to find proper conditions for selecting mutants ofSaccharomyces cerevisiae with altered starvation-induced mutability. The most promising for this purpose appeared to be culturing low numbers of colonies on suboptimal plates with a growth-limiting amount of adenine at 28 °C for 20 d. Inactivation of theRAD6 gene which suppresses the level of starvation-associated mutagenesis markedly enhanced papilla formation under these conditions. Formation of almost all papillae on 20-d-old colonies of BJC3 was caused by mutation. Most of the papillae (75%) were white Ade⁺ revertants. Three groups of these papillae were distinguished (Ade⁺, Ade⁺ Rad6⁺ and Ade⁺ Trp⁺). Both, Ade⁺ Rad6⁺ and Ade⁺ Trp⁺ double reversions were very probably caused by a suppressor mutation. The less frequent red papillae had the same auxotrophic markers and UV sensitivity as BJC3 but their outgrowth in liquid media was greater. It appears that creation of these papillae is caused by mutation affecting the cell response to growth limitation by low concenttations of adenine.     

Genetic analysis of the mitochondrial rho-mutability in Saccharomyces. II. Disomy for chromosome IV and spontaneous rho-mutability

The disomy for chromosome IV in the strains studied led to: reduction in the red pigmentation of ade1 mutant colonies; a decrease in spontaneous rho- mutant frequency, and impairment of sporulation in hybrids descended from disomic parents. The nuclear srm1 mutation decreasing the spontaneous rho- mutability promoted the spontaneous extra chromosome loss in the disomics for chromosome IV. This result suggests a close connection between the spontaneous rho- mutability and mitotic chromosome stability.     

Yeast amber suppressors corresponding to tRNA3Leu genes

Amber suppressors previously isolated from the yeast Saccharomyces cerevisiae and belonging to the same phenotypic class (Liebman et al., 1976) were assigned to nine different linkage groups named SUP52 through SUP60. One of these suppressors, SUP52, had been shown to cause the insertion of leucine and had been genetically mapped (Liebman et al., 1977). The following additional amber suppressors were mapped: SUP53 maps near the centromere of chromosome III closely linked to leu2; SUP54 maps on chromosome VII, 6 cM distal to trp5; SUP56 maps on chromosome I, 5.4 cM distal to ade1; SUP57 maps on chromosome VI, closely linked to met10; and SUP58 maps on the left arm of chromosome XI, loosely linked to met14. We show by protein analysis that like SUP52, the suppressors SUP53 through SUP56 are leucine-inserters. Furthermore, by hybridization with a cloned tRNA3Leu probe we demonstrate that at least SUP53, SUP54, SUP55 and SUP56 contain mutations in redundant tRNA3Leu genes because they each generate a new XbaI site in a DNA fragment encompassing a tRNA3Leu gene. These new XbaI sites are predicted by the known sequences of tRNA3Leu genes if the CAA anticodon mutates to the amber suppressing anticodon CTA. It is likely that each of the nine suppressors in this phenotypic class contain similar mutations in different tRNA3Leu genes since we find that there are approximately nine unlinked redundant copies of tRNA3Leu genes in haploid strains.     

Mitotic stability of yeast chromosomes: a colony color assay that measures nondisjunction and chromosome loss

A colony color assay that measures chromosome stability is described and is used to study several parameters affecting the mitotic maintenance of yeast chromosomes, including ARS function, CEN function, and chromosome size. A cloned ochre-suppressing form of a tRNA gene, SUP11, serves as a marker on natural and in vitro-constructed chromosomes. In diploid strains homozygous for an ochre mutation in ade2, cells carrying no copies of the SUP11 gene are red, those carrying one copy are pink, and those carrying two or more copies are white. Thus, the degree of red sectoring in colonies reflects the frequency of mitotic chromosome loss. The assay also distinguishes between chromosome loss (1:0 segregation) and nondisjunction (2:0 segregation). The most dramatic effect on improving mitotic stability is caused by increasing chromosome size. Circular chromosomes increase in stability through a size range up to approximately 100 kb, but do not continue to be stabilized above this value. However, linear chromosomes continue to increase in mitotic stability throughout the size range tested (up to 137 kb). It is possible that the mitotic stability of linear chromosomes is proportional to chromosome length, up to a plateau value that has not yet been reached in our synthetic constructions.     

Meiotic mapping of the nuclear determinant of cell lysis of the osmotic dependent Saccharomyces cerevisiae mutant VY1160

Summary A recessive nuclear mutation, sorb ^-, which determines the ability for lysis of the osmotic dependent Saccharomyces cerevisiae mutant VY1160 has been mapped on the right arm of chromosome I. sorb ^- is not centromere linked and is approximately 31 recombination units from ade1.     

Recessive Lethal Mutations and the Maintenance of Duplication-Bearing Strains of Dictyostelium discoideum

Recessive lethal mutations have been isolated and used to maintain n + 1 aneuploid strains of Dictyostelium discoideum carrying a duplication of part or all of linkage group VII. The recessive lethal mutations, relA351 and relB352, arose spontaneously in diploids; no mutagenic treatment was used in the isolation of these mutations. The probable gene order on linkage group VII is: centromere, relB couA, bsgB, cobA, relA. Maintenance of aneuploids disomic for linkage group VII was made possible by complementation of a rel mutation on each linkage group VII homologue by the corresponding wild-type allele on the other linkage group VII homologue. The duplication-bearing disomic strains were slow-growing and produced faster-growing sectors on the colony edge. Haploid sectors probably arise by a combination of mitotic recombination and subsequent loss of one homologue, diploid sectors may be formed by chromosome doubling to 2n + 2, followed by chromosome loss to return to 2n, and aneuploid sectors may arise by deletion or new mutation.     

A Mapping Method for SACCHAROMYCES CEREVISIAE Using rad52-Induced Chromosome Loss

Saccharomyces cerevisiae diploids homozygous for the rad52-1 mutation have previously been shown to lose chromosomes mitotically. Spontaneous events and events following low levels of X-ray or methyl methanesulfonate treatment result in monosomic diploids, whereas higher levels of treatment result in near haploidization. This rad52-1-dependent chromosome loss has been used to develop a new mapping method which can be used to assign a previously unmapped gene to a chromosome. Chromosome loss mapping can be done in either of two ways: if a diploid, homozygous for rad52-1 but heterozygous for a variety of other recessive markers, is constructed with an unmapped recessive mutation in coupling with known chromosomal markers, chromosome loss will result in the coordinate expression of the mutation and other recessive markers on the same chromosome; if, however, the diploid is constructed with the unmapped mutation in repulsion to chromosomal markers, then even haploidization will never result in the coordinate expression of the unmapped mutation and other markers on the same homologous chromosome pair--This mapping method and subsequent tetrad analyses have been used to locate hom6 on chromosome X, ade4 on chromosome XIII and cdc31 on chromosome XV and to demonstrate that met5, previously assigned to chromosome V, actually maps to chromosome X; the met- marker on chromosome V has been shown to be met6. GAL80 and SUP5, previously assigned to an unmapped fragment, have now been mapped to the right arm of chromosome XIII.