The detection of mitotic and meiotic chromosome gain in the yeast Saccharomyces cerevisiae: effects of methyl benzimidazol-2-yl carbamate, methyl methanesulfonate, ethyl methanesulfonate, dimethyl sulfoxide, propionitrile and cyclophosphamide monohydrate

The diploid yeast strain BR1669 was used to study induction of mitotic and meiotic chromosome gain by selected chemical agents. The test relies on a gene dosage selection system in which hyperploidy is detected by the simultaneous increase in copy number of two alleles residing on the right arm of chromosome VIII: arg4-8 and cup1S (Rockmill and Fogel. 1988; Whittaker et al., 1988). Methyl methanesulfonate (MMS) induced mitotic, but not meiotic, chromosome gain. Methyl benzimidazol-2-yl carbamate (MBC) and ethyl methanesulfonate (EMS) induced both mitotic and meiotic chromosome gain. Propionitrile, a polar aprotic solvent, induced only mitotic chromosome gain; a reliable response was only achieved by overnight incubation of treated cultures at 0 degrees C. MBC is postulated to act by binding directly to tubulin. The requirement for low-temperature incubation suggests that propionitrile also induces aneuploidy by perturbation of microtubular dynamics. The alkylating agents MMS and EMS probably induce recombination which might in turn perturb chromosome segregation. Cyclophosphamide monohydrate and dimethyl sulfoxide (DMSO) failed to induce mitotic or meiotic chromosome gain.     

Reevaluation of the 9 compounds reported conclusive positive in yeast Saccharomyces cerevisiae aneuploidy test systems by the Gene-Tox Program using strain D61.M of Saccharomyces cerevisiae

The state of aneuploidy test methodology was appraised by the U.S. Environmental Protection Agency in 1986 in analyzing published data. In Saccharomyces cerevisiae 9 chemicals were reported to be conclusive positive for aneuploidy induction in either mitotic or meiotic cells. We reevaluated these 9 chemicals using Saccharomyces cerevisiae D61.M, a strain that detects mitotic chromosome malsegregation. Acetone (lowest effective dose (LED): 40 microliters/ml), bavistan (LED: 5 micrograms/ml), benomyl (LED: 30 micrograms/ml) and oncodazole (LED: 4 micrograms/ml) induced a dose-dependent increase in the frequencies of chromosomal malsegregation. Ethyl methanesulfonate (EMS; highest tested dose (HTD): 1000 micrograms/ml) and methyl methanesulfonate (MMS; HTD: 100 micrograms/ml) did not induce malsegregation but were both potent inducers of other genetic events, detected by an increase in the frequencies of cyhR cells. No increases in both endpoints (malsegregation and other genetic events) were observed after treatment of S. cerevisiae D61.M with cyclophosphamide (CP; HTD: 16 mg/ml) in the absence of S9, p-D,L-fluorophenylalanine (p-FPA; HTD: 250 micrograms/ml) and phorbol-12-myristate-13-acetate (TPA; HTD: 50 micrograms/ml). A marginal increase in the frequency of mitotic chromosome malsegregation was obtained with cyclophosphamide in the presence of S9. Thus our test results largely disagree with those previously published by various authors and taken as conclusive by EPA. We interpret the discrepancies to be due to lack of properly controlled testing (e.g., no check for multiple mutational events). Only with a careful test design it is possible to discriminate between chemicals inducing only chromosome loss and no other genetic effects (e.g., acetone, oncodazole), chemicals inducing a variety of genetic damage but no chromosome loss (e.g., EMS, MMS) and chemicals inducing neither chromosome loss nor other genetic events in yeast (e.g., TPA, p-FPA).     

Effect of mutagens, chemotherapeutic agents and defects in DNA repair genes on recombination in F' partial diploid Escherichia coli.

The ability of mutagenic agents, nonmutagenic substances and defects in DNA repair to alter the genotype of F' partial diploid (F30) Escherichia coli was determined. The frequency of auxotrophic mutants and histidine requiring (His-) haploid colonies was increased by mutagen treatment but Hfr colonies were not detected in F30 E. coli even with specific selection techniques. Genotype changes due to nonreciprocal recombination were determined by measuring the frequency of His- homogenotes, eg. F' hisC780, hisI+/hisC780, hisI+, arising from a His+ heterogenote, F' hisC780 hisI+/hisC+, his1903. At least 75% of the recombinants were homozygous for histidine alleles which were present on the F' plasmid (exogenote) of the parental hetergenote rather than for histidine alleles on the chromosome. Mutagens, chemotherapeutic agents which histidine alleles on the chromosome. Mutagens, chemotherapeutic agents which block DNA synthesis and a defective DNA polymerase I gene, polA1, were found to increase the frequency of nonreciprocal recombination. A defect in the ability to excise thymine dimers, uvrC34, did not increase spontaneous nonreciprocal recombination. However, UV irradiation but not methyl methanesulfonate (MMS) induced greater recombination in this excision-repair defective mutant than in DNA-repair-proficient strains. Mutagenic agents, with the exception of ethyl methanesulfonate (EMS), induced greater increases in recombination than the chemotherapeutic agents or the polA1 mutation. EMS, which causes relatively little degradation of DNA, was more mutagenic but less recombinogenic than MMS, a homologous compound ths that inhibition of DNA occurring single-stranded regions in replicative intermediates of the DNA. Mutagens which cause the rapid breakdown of DNA may, in addition, introduce lesions into the genome that increase the number of single-stranded regions thus inducing even higher frequencies of recombination.     

A comparison of the genetic activity of pyrvinium pamoate with that of several other anthelmintic drugs in Saccharomyces cerevisiae

Several anthelmintic drugs that are used routinely in oxyuriasis therapy were analyzed for genotoxicity in a diploid mitotic recombination and gene conversion assay (strain D5 of Saccharomyces cerevisiae), and in a haploid yeast reversion assay (strain XV185-14C). Piperazine citrate, piperazine adipate, mebendazole and thiabendazole did not appear to be genotoxic in either yeast strain. Pyrvinium pamoate induced the reversion of the missense, nonsense and frameshift alleles in strain XV185-14C, whereas pyrantel pamoate induced only the reversion of the frameshift allele. Pyrvinium pamoate was recombinogenic in strain D5, and there is an indication that pyrantel pamoate, at the lowest dose that was tested, might induce gene conversion or aneuploidy.     

Combined mutagenicity of methyl methanesulfonate and ethyl methanesulfonate in Chinese hamster V79 cells.

The combined effects of methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS) on the induction of 6-thioguanine (6TG)-resistant mutants and chromosome aberrations were examined in Chinese hamster V79 cells. Cells were simultaneously treated with EMS at a concentration of D20 and MMS at various concentrations for 3, 6 or 9 h. In other experiments cells were simultaneously treated with MMS at a concentration of D20 and EMS at various concentrations for 3, 6 or 9 h. The mathematical analysis of the combined effects of both chemicals for cell killing (cytotoxicity) and 6TG-resistant mutations indicates that synergistic interactions were observed for both cell killing and mutations induced by MMS and EMS. The frequency of chromosome aberrations induced by simultaneous treatment with MMS at a concentration of D20 and EMS at various concentrations for 3 h was additive. However, the frequency of chromosome aberrations induced by EMS at a concentration of D20 and MMS at various concentrations for 3 h was not significantly different from those induced by MMS alone.     

Loss of heterozygosity and DNA damage repair in Saccharomyces cerevisiae

Loss of heterozygosity (LOH) of tumor suppressor genes is a crucial step in the development of sporadic and hereditary cancer. Understanding how LOH events arise may provide an opportunity for the prevention or early intervention of cancer development. In an effort to investigate the source of LOH events, we constructed MATalphacan1Delta::LEU2 and MATa CAN1 haploid yeast strains and examined canavanine-resistance mutations in a MATa CAN1/MATalphacan1Delta::LEU2 heterozygote formed by mating UV-irradiated and nonirradiated haploids. An increase in LOH was observed when the irradiated CAN1 haploid was mated with nonirradiated can1Delta::LEU2, while reversed irradiation only marginally increased LOH. In the rad51Delta background, allelic crossover type LOH increased following UV irradiation but not gene conversion. In the rad52Delta background, neither type of LOH increased. The chromosome structure following LOH and the requirement for Rad51 and Rad52 proteins indicated the involvement of gene conversion, allelic crossover and break-induced replication. We argued that LOH events could have occurred during the repair of double-strand breaks on a functional (damaged) but not nonfunctional (undamaged) chromosome through recombination.     

After a single treatment with EMS the number of non-colony-forming cells increases for many generations in yeast populations

The course of lethal events occurring in populations of haploid Saccharomyces cerevisiae after DNA-damaging treatments was studied. After X-irradiation and after incubation with methyl methanesulfonate (MMS) populations recovered according to expectation, if one assumes successive dilution of killed cells by the proliferating survivors. However, populations treated with ethyl methanesulfonate (EMS) for many generations of proliferation contained more inviable cells than expected. This behaviour was not due to EMS or toxic reaction products remaining with the cells after treatment but to residual divisions of lethally mutated cells. In addition the data suggest that lethal fixations may occur in cells originating from later than the first generation after EMS treatment.     

Allelic Complementation in the First Gene for Histidine Biosynthesis in SACCHAROMYCES CEREVISIAE. I. Characteristics of Mutants and Genetic Mapping of Alleles

A number of his1 mutants were tested for suppressibility, for reversion by EMS, ICR-170, and nitrous acid, for their allelic complementation response, and for their temperature sensitivity and osmotic remediability. None of 52 mutants tested was suppressible by a known ochre suppressor. This is a very surprising result compared with other studies of suppressibility in yeast and suggests that another function essential to the cell is associated with the his1 gene product, the polarity effect of a nonsense mutation destroying the activity of the his1 enzyme and this second function.Sixty-four his1 alleles were ordered by allelic mapping methods utilizing gamma rays, X-rays, and MMS. The three maps agree well in placement of alleles and have been oriented on chromosome V of yeast with respect to the centromere. The 18 noncomplementing alleles are localized in the distal half of the gene, whereas the complementing alleles are distributed more or less evenly. Mutations which revert to feedback resistance map in the proximal end. Also at this end are mutations having a very high X-ray or MMS induced homoallelic reversion rate. This suggests that a number of missense mutations can occur in this region which result in innocuous amino acid substitutions in the enzyme. One X-ray map unit is estimated to correspond to about 131 base pairs or 43 amino acids, in agreement with results for the cytochrome-c protein obtained by Parker and Sherman (1969).     

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).     

Chromosomal analysis in mouse eggs fertilized in vitro with sperm exposed to ultraviolet light (UV) and methyl and ethyl methanesulfonate (MMS and EMS)

Chromosome aberrations were analyzed at the first-cleavage metaphase of mouse eggs fertilized in vitro with sperm exposed to ultraviolet light (UV) as well as to methyl and ethyl methanesulfonate (MMS and EMS). The frequencies of chromosome aberrations markedly increased with dose of UV as well as with concentration of MMS and EMS. In the UV-irradiation group, the frequency of chromosome-type aberrations was much higher than that of chromatid-type aberrations. About 90% of chromosome aberrations observed in the eggs following MMS and EMS treatment to sperm were chromosome type in which the frequency of chromosome fragments was the highest. The effects of UV on the induction of chromosome aberrations were clearly potentiated by post-treatment incubation of fertilized eggs in the presence of Ara-C or caffeine, but the effects of MMS and EMS were not pronounced by post-treatment of Ara-C or caffeine. The results indicate a possibility that UV damage induced in mouse sperm DNA is reparable in the eggs during the period between the entry of sperm into the egg cytoplasm and the first-cleavage metaphase.     

Immunofluorescent staining of kinetochores in micronuclei: a new assay for the detection of aneuploidy

The immunofluorescent staining of kinetochores in micronuclei with antikinetochore antibodies was used to develop an in vitro assay for aneuploidy-inducing agents. The results show that about 80% of micronuclei induced by either colchicine or chloral hydrate contained kinetochores; only 9% of X-ray-induced micronuclei reacted positively to the antibody. These findings indicate that the in vitro micronucleus assay coupled with immunofluorescent staining of kinetochores can be a useful method for assessing the ability of chemicals to induce aneuploidy and/or chromosome aberrations.     

Characterization of cytotoxic and genotoxic effects of different compounds in CHO K5 cells with the comet assay (single-cell gel electrophoresis assay)

Different variants of the comet assay were used to study the genotoxic and cytotoxic properties of the following eight compounds: chloral hydrate, colchicine, hydroquinone, DL-menthol, mitomycin C, sodium iodoacetate, thimerosal and valinomycin. Colchicine, mitomycin C, sodium iodoacetate and thimerosal induced genotoxic effects. The other compounds were found to be inactive. The compounds were tested in the standard comet assay as well as in the all cell comet assay (recovery of floating cells after treatment), designed in our laboratory for adherently-growing cells. This latter procedure proved to be more adequate for the assessment of the cytotoxicity for some of the compounds tested (hydroquinone, DL-menthol, thimerosal, valinomycin). Colchicine was positive in the standard comet assay (3h treatment) and in the all cell comet assay (24h treatment). Sodium iodoacetate and thimerosal were positive in the standard and/or the all cell comet assay. Chloral hydrate, hydroquinone, sodium iodoacetate, mitomycin C and thimerosal were also tested in the modified comet assay using lysed cells. Mitomycin C and thimerosal showed effects in this assay, whereas sodium iodoacetate was inactive. This indicates that it does not induce direct DNA damage. Compounds that are known or suspected to form DNA-DNA cross-links or DNA-protein cross-links (chloral hydrate, hydroquinone, mitomycin C and thimerosal) were checked for their ability to reduce ethyl methanesulfonate (EMS)-induced DNA damage. This mode of action could be demonstrated for mitomycin C only.     

Synergism of mutant frequencies in the mouse lymphoma cell mutagenicity assay by binary mixtures of methyl methanesulfonate and ethyl methanesulfonate

The effect of mixed mutagen exposures on the rate and type of induced mutants was studied in the L5178Y/TK+/-----TK-/- mouse lymphoma cell mutagenicity assay. In this assay, exposure to ethyl methanesulfonate (EMS) results in more mutants that form large colonies than small colonies. Exposure to methyl methanesulfonate (MMS) results in more mutants that form small colonies than large colonies. Other reports in the literature suggest that large colony TK-/- mutants appear to result from small-scale, perhaps single-gene mutations, and that small-colony TK-/- mutants appear to be associated with chromosomal mutations. Treating cells for 4 h with simple, 2-component mixtures containing 6.45 micrograms/ml MMS and either 261, 392, 560 or 712 micrograms/ml EMS resulted in synergism of mutants at each mixture level. The frequencies of total mutants were synergized 12, 20, 35 and 72%, respectively, in mixed exposures with graded doses of EMS, above the sums of the mixture components. Small colony mutants were synergized to a greater extent than large colony mutants. The frequencies of small colony mutants in mixed exposures were increased 31, 54, 73 and 123%, respectively, while the frequencies of large colony mutants were increased -7, -6, 11 and 39%. Statistical analyses provide strong evidence of synergism (within the limits of the assay) for total and small-colony mutants at all doses of EMS tested, and for large-colony mutants above 400 micrograms/ml EMS. Similar magnitudes of synergism resulted when other constant levels of MMS (4.30 or 8.60 micrograms/ml) were mixed with the same graded doses of EMS. The degree of synergism was dependent on EMS concentration but not on MMS concentration.     

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.     

Tests which distinguish induced crossing-over and aneuploidy from secondary segregation in Aspergillus treated with chloral hydrate or gamma-rays

A system of tests with the ascomycete Aspergillus nidulans was devised that can detect 3 primary effects of genotoxic agents: (1) increases in mitotic crossing-over; (2) induced aneuploidy; and (3) clastogenic effects which cause chromosomal imbalance. Conidia of a new diploid tester strain, heterozygous for 4 recessive markers which alter conidial color, are treated and plated onto nonselective media. In cases of induced crossing-over, large color segments are found in normal green colonies, frequently adjacent to reciprocal twin segments. In contrast, both malsegregation and chromosome breakage produce unbalanced types which grow poorly and segregate further. Cases with yellow segregants are replated and their secondary diploid sectors tested for markers which are located on both chromosome arms in coupling with yA. Induced aneuploidy can be distinguished from chromosome breakage by the pattern of marker segregation. Any aneuploid type will produce euploid sectors solely by segregation of whole chromosomes; trisomic colonies (yA / yA / +) will show 1:2 ratios for yellow (homozygous yA) to parental green (yA/+) sectors and have characteristic phenotypes. Other induced unbalanced types, if heterozygous for deletions or aberrations may produce yellow diploid sectors by secondary crossing-over as well as by nondisjunction and such cases show unique patterns of genetic segregation and non- predictable phenotypes. As a complementary test, haploid strains are treated and induced abnormally growing types are replated and classified by phenotype. Aneuploids are unstable and produce many normal sectors, and some of these disomic or trisomic types can be visually identified.In contrast, induced deletions are lethal, and duplications or 'morphological' mutants show much more stable abnormal phenotypes. This test system was used to characterize the primary effects of gamma-rays and chloral hydrate. Results and evidence were as follows: (1) A dose-dependent increase of color segments resulting from reciprocal crossing-over was found after treatment of dividing nuclei in germinating diploid conidia with gamma-rays, but not with chloral hydrate. (2) Highly aneuploid and polyploid types were induced in diploid and haploid germinating conidia by chloral hydrate but not to any significant extent by gamma-rays. (3) gamma-Rays caused a dose- dependent increase off abnormally growing colonies when dormant or germinating diploid conidia were treated. These colonies produced secondary euploid sectors by spontaneous nondisjunction and frequently also by crossing-over, which provided evidence for induced semidominant and recessive lethal mutations of many types.     

Comparative mutagenicity of alkylsulfate and alkanesulfonate derivatives in Chinese hamster ovary cells.

Mutation induction and cell killing produced by selected alkylsulfates and alkanesulfonates have been quantitated using the Chinese hamster ovary/hypoxanthine--guanine phosphoribosyl transferase (CHO/HGPRT) system. Dose--response relationships of cytotoxicity and mutagenicity are presented for two alkylsulfates [dimethylsulfate (DMS), diethylsulfate (DES)] and three alkyl alkanesulfonates [methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), and isopropyl methanesulfonate (iPMS)]. Under the experimental conditions employed, cytotoxicity decreased with the size of the alkyl group. DMS was more toxic than DES, and MMS was more toxic than EMS and iPMS. All agents produced linear dose--response of mutation induction: DMS was more mutagenic than DES, and MMS was more mutagenic than EMS and iPMS based on mutants induced per unit mutagen concentration. However, the following relative mutagenic potency was observed when comparisons were made at 10% survival: DES greater than DMS; EMS greater than MMS greater than iPMS.     

Yeast LEU5 is a PET-like gene that is not essential for leucine biosynthesis

Summary Alpha-IPM synthase catalyzes the first committed step in leucine biosynthesis in the yeast S. cerevisiae. LEU4 is known to encode this enzyme activity. A second gene, LEU5, has been proposed to encode a second enzyme with this activity.We cloned LEU5 and genetically defined the locus. LEU5 maps to chromosome VIII and is tightly linked to CEN8.Five different mutations in LEU5 were analyzed: a sitedirected deletion and a disruption, as well as three distinct mutations produced by chemical mutagenesis. In a leu4 background, each leu5 mutation causes a Leu — phenotype; in a LEU4 background, none of the mutations alters the Leu+ phenotype. This shows that LEU5 is not essential for leucine biosynthesis. In either a leu4 or LEU4 background, each leu5 mutation causes a glycerol — phenotype. This operationally defines LEU5 as a PET gene.Two distinct suppressors of the Pet — phenotype of leu5 strains have been isolated. These suppressors revert the Pet — phenotype of each of four mutant leu5 alleles that were tested. Suppression occurs regardless of the allele at LEU4. Moreover, the suppressors co-revert the Leu — phenotype for each of the four leu5 mutations that is combined with a leu4 allele. This establishes the presence of a gene other than LEU5 that encodes a second alpha-IPM synthase. Further analysis provided no evidence for synthase activity that is encoded by LEU5.Abbreviation EMS ethylmethane sulfonate - IPM isopropylmalate - NPD nonparental ditype - PD parental ditype - TT tetratype     

Drug resistance in diploid yeast is acquired through dominant alleles, haploinsufficiency,gene duplication and aneuploidy

Previous studies of adaptation to the glucose analog, 2-deoxyglucose, by Saccharomyces cerevisiae have utilized haploid cells. In this study, diploid cells were used in the hope of identifying the distinct genetic mechanisms used by diploid cells to acquire drug resistance. While haploid cells acquire resistance to 2-deoxyglucose primarily through recessive alleles in specific genes, diploid cells acquire resistance through dominant alleles, haploinsufficiency, gene duplication and aneuploidy. Dominant-acting, missense alleles in all three subunits of yeast AMP-activated protein kinase confer resistance to 2-deoxyglucose. Dominant-acting, nonsense alleles in the REG1 gene, which encodes a negative regulator of AMP-activated protein kinase, confer 2-deoxyglucose resistance through haploinsufficiency. Most of the resistant strains isolated in this study achieved resistance through aneuploidy. Cells with a monosomy of chromosome 4 are resistant to 2-deoxyglucose. While this genetic strategy comes with a severe fitness cost, it has the advantage of being readily reversible when 2-deoxyglucose selection is lifted. Increased expression of the two DOG phosphatase genes on chromosome 8 confers resistance and was achieved through trisomies and tetrasomies of that chromosome. Finally, resistance was also mediated by increased expression of hexose transporters, achieved by duplication of a 117 kb region of chromosome 4 that included the HXT3, HXT6 and HXT7 genes. The frequent use of aneuploidy as a genetic strategy for drug resistance in diploid yeast and human tumors may be in part due to its potential for reversibility when selection pressure shifts.     

Retardation of cell cycle progression in yeast cells recovering from DNA damage: A study at the single cell level

Summary Pedigree analyses of individual yeast cells recovering from DNA damage were performed and time intervals between morphological landmark events during the cell cycle (bud emergence and cell separation), were recorded for three generations. The associated nuclear behavior was monitored with the aid of DAPI staining. The following observations were made: (1) All agents tested (X-rays, MMS, EMS, MNNG, nitrous acid) delayed the first bud emergence after treatment, which indicates inhibition of the initiation of DNA replication. (2) Cells that survived X-irradiation progressed further through the cell cycle in a similar way to control cells. (3) Progress of chemically treated cells became extremely asynchronous because surviving cells stayed undivided for periods of varying length. (4) Prolongation of the time between bud emergence and cell separation was most pronounced for cells treated with the alkylating agents MMS and EMS. This is interpreted as retardation of ongoing DNA synthesis by persisting DNA adducts. (5) Cell cycle prolongation in the second and third generation after treatment was observed only with MMS treated cells. (6) In all experiments, individual cells of uniformly treated populations exhibited highly variable responses.Abbreviations DAPI 4,6-diamidino-2-phenyl-indole - EMS ethyl methanesulfonate - MMS methyl methanesulfonate - MNNG N-methyl-N-nitro-N-nitrosoguanidine     

Multiple New Genes That Determine Activity for the First Step of Leucine Biosynthesis in Saccharomyces Cerevisiae

The first step in the biosynthesis of leucine is catalyzed by α-isopropylmalate (α-IPM) synthase. In the yeast Saccharomyces cerevisiae, LEU4 encodes the isozyme responsible for the majority of α-IPM synthase activity. Yeast strains that bear disruption alleles of LEU4, however, are Leu(+) and exhibit a level of synthase activity that is 20% of the wild type. To identify the gene or genes that encode this remaining activity, a leu4 disruption strain was mutagenized. The mutations identified define three new complementation groups, designated leu6, leu7 and leu8. Each of these new mutations effect leucine auxotrophy only if a leu4 mutation is present and each results in loss of α-IPM synthase activity. Further analysis suggests that LEU7 and LEU8 are candidates for the gene or genes that encode an α-IPM synthase activity. The results demonstrate that multiple components determine the residual α-IPM synthase activity in leu4 gene disruption strains of S. cerevisiae.