Mutagenic effect of freezing on nuclear DNA of Saccharomyces cerevisiae.

Although fragmentation of DNA has been observed in cells undergoing freezing procedures, a mutagenic effect of sub-zero temperature treatment has not been proved by induction and isolation of mutants in nuclear DNA (nDNA). In this communication we supply evidence for mutagenicity of freezing on nDNA of Saccharomyces cerevisiae cells. In the absence of cryoprotectors, cooling for 2 h at +4°C and freezing for 1 h at -10°C and 16 h at -20°C, with a cooling rate of 3°C/min, resulted in induction of frame-shift and reverse mutations in microsatellite and coding regions of nDNA. The sub-zero temperature exposure also has a strong recombinogenic effect, evidenced by induction of gene-conversion and crossing-over events. Freezing induces mutations and enhances recombination with a frequency equal to or higher than that of methylmethanesulphonate at comparable survival rates. The signals for the appearance of nDNA lesions induced by freezing are detected and transduced by the DNA damage pathway. Extracellular cryoprotectors did not prevent the mutagenic effect of freezing, while accumulation of trehalose inside cells reduced nDNA cryodamage. Freezing of cells is accompanied by generation of high ROS levels, and the oxidative stress raised during the freeze-thaw process is the most likely reason for the DNA damaging effect. Experiments with mitochondrial rho⁻ mutants or scavengers of ROS indicated that mutagenic and recombinogenic effects of sub-zero temperatures can be decreased but not eliminated by reduction of ROS level. The complete protection against cryodamage in nDNA required simultaneous usage of intracellular cryoprotector and ROS scavenger during the freeze-thaw process.

The Kluyveromyces lactis CPY homologous genes: cloning and characterization of the KlPCL1 gene.

A 3.85-kb genomic fragment containing the KlPCL1 gene, with an open reading frame (ORF) of 1359 bp, was isolated from Kluyveromyces lactis genomic library by heterologous colony hybridization using the Saccharomyces cerevisiae PRC1 (ScPRC1) gene as a probe. The KlPCL1 nucleotide sequence was identical to the KLLAOC17490g ORF of K. lactis and showed >55 % identity with S. cerevisiae YBR139w and PRC1 genes encoding carboxypeptidases. The deduced KlPcl1p amino acid sequence displayed strong similarities to yeast and higher eukaryotic carboxypeptidases. In silico analyses revealed that KlPcl1p contained several highly conserved regions characteristic of the serine-type carboxypeptidases, such as the catalytic triad in the active site and the LNGGPGCSS, FHIAGESYAGHYIP and ICNWLGN motifs involved in the substrate binding. All this suggests that the KlPCL1 gene product belongs to the serine carboxypeptidase family. Sporulation and ascus dissection of a diploid strain heterozygous for single-copy disruption of KlPCL1 revealed that this gene is not essential in K. lactis. Further analyses of haploid and diploid deletion mutants demonstrated that disruption of the KlPCL1 gene neither impaired sporulation nor affected growth abilities of K. lactis cells under a variety of physiological conditions, e.g., growth on different carbon sources, at various temperatures or pH of the medium, and under nitrogen depletion.

Transposition of Saccharomyces cerevisiae Ty1 retrotransposon is activated by improper cryopreservation.

Ty1 is a retrotransposon of the yeast Saccharomyces cerevisiae whose transposition at new locations in the host genome is activated by stress conditions, such as exposure to UV light, X-rays, nitrogen starvation. In this communication, we supply evidence that cooling for 2 h at +4 degrees C followed by freezing for 1 h at -10 degrees C and 16 h at -20 degrees C also increased Ty1 transposition. The mobility of Ty1 was induced by cooling at slow rates (3 degrees C/min) and the accumulation of trehalose inside cells or the cooling at high rates (100 degrees C/min) inhibited significantly the induction of the transposition. The freeze-induced Ty1 transposition did not occur in mitochondrial mutants (rho-) and in cells with disrupted SCO1 gene (Deltasco1 cells) evidencing that the Ty1 transposition induced by cooling depends on the mitochondrial oxidative phosphorylation. We also found that the freeze induced Ty1 transposition is associated with increased synthesis and accumulation of superoxide anions (O2-) into the cells. Accumulation of O2- and activation of Ty1 transposition were not observed after cooling of cells with compromised mitochondrial functions (rho-, Deltasco1), or in cells pretreated with O2- scavengers. It is concluded that (i) elevated levels of reactive oxygen species (ROS) have a key role in activation the transposition of Ty1 retrotransposon in yeast cells undergoing freezing and (ii) given the deleterious effect of increased ROS levels on cells, special precautions should be taken to avoid ROS production and accumulation during cryopreservation procedures.

The response of Ty1 test to genotoxins.

The Ty1 assay is a short-term test for detection of genotoxins based on induction of the transposition of a gene-engineered Ty1 retrotransposon in Saccharomyces cerevisiae cells. Here, we provide evidence that the Ty1 test responds positively in concentration-dependent manner to the carcinogenic genotoxins benz(a)anthracene, benzo(a)pyrene, chenodeoxycholic and taurodeoxycholic free bile acids and to environmental soil samples polluted with carcinogenic substances. The Ty1 test gives negative results with the noncarcinogenic mutagens benz(b)anthracene, benzo(e)pyrene, lithocholic and taurodeoxycholic conjugated bile acids and to soil samples not polluted with carcinogens. Presence or absence of genotoxins in soil samples was evidenced by chemical analysis. Several explanations for the sensitive differential test's response to genotoxins are proposed and discussed. It is concluded that the Ty1 test can complement existing assays in laboratory and environmental studies showing high sensitivity to a wider spectrum of carcinogenic genotoxins.

Mutagenic effect of freezing on mitochondrial DNA of Saccharomyces cerevisiae.

Although suggested in some studies, the mutagenic effect of freezing has not been proved by induction and isolation of mutants. Using a well-defined genetic model, we supply in this communication evidence for the mutagenic effect of freezing on mitochondrial DNA (mtDNA) of the yeast Saccharomyces cerevisiae. The cooling for 2 h at +4 degrees C, followed by freezing for 1 h at -10 degrees C and 16 h at -20 degrees C resulted in induction of respiratory mutations. The immediate freezing in liquid nitrogen was without mutagenic effect. The study of the stepwise procedure showed that the induction of respiratory mutants takes place during the freezing at -10 and -20 degrees C of cells pre-cooled at +4 degrees C. The genetic crosses of freeze-induced mutants evidenced their mitochondrial rho- origin. The freeze-induced rho- mutants are most likely free of simultaneous nuclear mutations. The extracellular presence of cryoprotectants did not prevent the mutagenic effect of freezing while accumulation of cryoprotectors inside cells completely escaped mtDNA from cryodamage. Although the results obtained favor the notion that the mutagenic effect of freezing on yeast mtDNA is due to formation and growth of intracellular ice crystals, other reasons, such as impairment of mtDNA replication or elevated levels of ROS production are discussed as possible explanations of the mutagenic effect of freezing. It is concluded that: (i) freezing can be used as a method for isolation of mitochondrial mutants in S. cerevisiae and (ii) given the substantial development in cryopreservation of cells and tissues, special precautions should be made to avoid mtDNA damage during the cryopreservation procedures.

Enhanced protein export in Saccharomyces cerevisiae nud1 mutants is an active process.

Saccharomyces cerevisiae NUD1 gene codes for a spindle pole body component and nud1 temperature-sensitive mutants arrest at 38 degrees C in late anaphase with a tendency for lysis. We found that addition of 10% sorbitol to the medium complemented the lytic phenotype, and determination of colony-forming units evidenced the viability of nud1 cells for at least 48 hours at 38 degrees C. The protein amount in cell-free medium increased at 38 degrees C, and evidence is presented that intact nud1 cells exported proteins in amounts 10-fold higher compared wild type strains. The observed high amounts of extracellular acid phosphatase, invertase, and bacterial beta-galactosidase suggested the export of secretory proteins. This was evidenced by construction of nudlsec mutants and the observation that interruption of the secretory pathway resulted in absence of protein export at 38 degrees C. Proteins were exported through a cell wall showing increased porosity at 38 degrees C. The extracellular release of Gas1p and the facilitated transformability with plasmid DNA of nud1 cells indicated alternations of their cell walls at 38 degrees C. The export of proteins depends on oxidative phosphorylation as evidenced by disruption of the COX10 gene. Experiments with inhibitors of mitochondrial functions showed that the synthesis of adenosine triphosphate, but not the electron transport along the respiratory chain, has a key role in the export of proteins. The data show that the phenotype of S. cerevisiae nud1 mutants is characterized by enhanced export of secretory proteins and that the passage of proteins through the walls of nud1 cells is an active process.

Protein overexport in a Saccharomyces cerevisiae mutant depends on mitochondrial genome integrity and function.

The wild-type yeast Saccharomyces cerevisiae (S. cerevisiae) is able to export less than 1 percent of the protein to be secreted. The reasons for retention of most of the secretory proteins on the cell surface of S. cerevisiae are unknown. Recently, temperature-sensitive (ts) mutants of S. cerevisiae showing an oversecretion phenotype were isolated. In order to study the influence of the mitochondrial genome status on protein export in yeast cells, we have isolated several types of respiratory impaired mitochondrial mutants of either the parental S. cerevisiae strain or their derivative ts protein-overexporting mutants. In this paper we demonstrate by quantitative analyses of exported proteins and by SDS-PAGE analysis that protein overexport in ts mutants requires mitochondrial genome integrity and function.

Activation of Ty transposition by mutagens.

The induction of Ty1 transposition by mutagens (MMS and 4NQO) in asynchronous cultures and cells blocked in G1 and G2/M suggested G1 dependence of activation of Ty1 element by DNA damage. Northern blot analysis revealed immediate five-fold increase in levels of Ty1 transcript after 20min incubation of cells with 1 microg/ml 4NQO and four-fold increase in Ty1 RNA after treatment the cells with 0.1% MMS. Western blot analysis showed no difference in TyA protein in treated and untreated with mutagen cells. Quantitative mutagenicity assay and Northern blot analysis demonstrated dependence of induction of Ty1 element by DNA-damaging agents on the function of RAD9 gene and independence on DUN1 gene.

Genotoxic effect of substituted phenoxyacetic acids.

The potential toxic and mutagenic action of 2,4-dichlorophenoxyacetic acid has been studied in different test systems, and the obtained results range from increased chromosomal damage to no effect at all. We reexamined the effect of this herbicide by simultaneous using three tests based on yeast, transformed hematopoietic, and mouse bone marrow cells. The results obtained demonstrated that 2,4-dichlorophenoxyacetic acid has cytotoxic and mutagenic effects. The positive response of yeast and transformed hematopoietic cells was verified in kinetics and dose-response experiments. The analysis of metaphase chromosomes indicated a statistically proved induction of breaks, deletions, and exchanges after the intraperitoneal administration of 2,4-dichlorophenoxyacetic acid in mice. The study of phenoxyacetic acid and its differently chlorinated derivatives showed that cytotoxicity and mutagenicity are induced by chlorine atoms at position 2 and/or 4 in the benzene ring. The mutagenic effect was abolished by introduction of a third chlorine atom at position 5. Thus 2,4,5-trichlorophenoxyacetic acid was found to have very weak, if any mutagenic effect; however, the herbicide preserved its toxic effect.

NifH and NifM proteins interact as demonstrated by the yeast two-hybrid system.

Biological nitrogen fixation is catalyzed by nitrogenase, a two-component enzyme consisting of the MoFe protein and the Fe protein. Two genes are involved in the formation of active Fe protein: nifH encodes the structural polypeptide, while nifM specifies a stabilizing and activation function by yet unknown mechanisms. Our studies were directed to clarify whether the NifM exerts its function through physical protein-protein interaction with NifH. To accomplish this, we used the yeast two-hybrid system. The simultaneous expression of the GAL4 binding domain-nifH fusion and GAL4 activation domain-nifM fusion resulted in the successful activation of GAL4-responsive HIS3, ADE2, and lacZ reporter genes in the two-hybrid system used. The system was also used to evidence the potential for in vivo NifH and NifM self-association. The results obtained suggest that NifH and NifM form homomers and also associate in between to form higher order complexes, which may be needed to exert the effect of NifM on Fe protein stability and activity.

Protein overexport in a Saccharomyces cerevisiae mutant is not due to facilitated release of cell-surface proteins.

Saccharomyces cerevisiae strain MW11 is a temperature-sensitive mutant which exports twenty times more proteins at 37 degrees C than parental or wild-type strains do. To understand the mechanism underlying the protein overexport in the mutant the possibility of an altered cell-wall structure leading to facilitated release of cell-surface proteins was studied. Data on calcofluor white and zymolyase sensitivities, resistance to killer 1 toxin and determination of exported acid phosphatase and invertase did not provide evidence for alterations in the cell-wall structure that could explain the protein overexport phenotype. The results were obtained in experiments when transcription of mutated gene was discontinued which permits the full expression of the protein overexport phenotype.

A new sensitive test based on yeast cells for studying environmental pollution.

Different tests based on yeast cells were developed for determination of mutagenic/carcinogenic action; however, they all showed lower sensitivity compared to bacterial tests, the main reason for this being the limited permeability of yeast cells. We found that general permeability of Saccharomyces cerevisiae cells can be increased by mutation and on this basis we developed a more sensitive test. The aim of this study was to prove the applicability of our test, called D7ts1, in environmental studies. Soil, water and air samples were taken during 1998 from regions in Bulgaria with declared low, average or high pollution levels and investigated for presence of mutagenic/carcinogenic activities in the bacterial test of Ames, the yeast D7 test of Zimmermann and our new D7ts1 test. Results obtained evidenced the following conclusions: (1) the usage of D7ts1 test instead of D7 test permits a clearer measurement of positive samples and detects mutagenic/carcinogenic activities undetectable by D7 test; (2) all samples with positive Ames test were positive in the D7ts1 test; however, some samples, clearly positive in the D7ts1, were negative in the Ames test; therefore, the simultaneous usage of D7ts1 and Ames tests in environmental studies is advantageous because it detects dangers for the human health activities to which bacterial cells do not respond; and (3) regions in Bulgaria declared clean were found to be polluted; particularly troubled are the whole-year positive data in the three tests for air samples from a 'clean' region.

Identification of the essential EPE1 gene involved in retention of secreted proteins on the cell surface of Saccharomyces cerevisiae cells.

Saccharomyces cerevisiae yeast cells secrete extracellularly low amounts of a few proteins. The reasons for retardation of secreted proteins on the cell surface remain obscure. We describe here a mutant able to export enhanced amount of proteins. Classical genetic methods, nucleic acids manipulations and cloning procedures were used to isolate and characterize the mutant and to clone and sequence the corresponding wild type gene. The isolated Saccharomyces cerevisiae mutant MW11, is temperature sensitive and exports on average twenty-fold more proteins at 37 degrees C than parental wild type strain (80 micrograms of proteins/1 x 10(8) mutant cells, SEM +/- 5, n22; versus 3 micrograms of proteins/1 x 10(8) parental cells, SEM +/- 1, n22). Protein overexport in the mutant requires a functional SEC1 pathway and is independent of cell lysis. Cloning and sequencing of the corresponding wild type gene identified an open reading frame of 786 bp coding for a hydrophilic protein with predicted molecular mass of 30 kDa and cytosolic localization. The newly identified gene, designated EPE1, is an essential gene. Its DNA and amino acids sequence showed no homology with other yeast genes and proteins. It is concluded that the function of unknown yet genes, such as EPE1 is needed for retention of secreted proteins on the surface of Saccharomyces cerevisiae cells.

Increased activity of wall hydrolytic enzymes may explain the phenotype of Saccharomyces cerevisiae fragile mutants.

Fragile mutants of Saccharomyces cerevisiae require osmotic stabilizers and lyse in hypotonic solutions. A single recessive mutation, srb1, is responsible for their phenotype, but the cause of cell lysis remains uncertain. We have analyzed three possible mechanisms for this behavior: comparative amounts of wall per cell; their chitin content; and the relative activity of wall hydrolytic enzymes activated by osmotic shock. We found normal amounts of wall and higher amounts of chitin in the fragile mutants. Determination of lytic enzymes by radiolabel of the reducing ends of wall polysaccharides gave results suggesting that fragile mutants produce increased amounts of stretch-activated wall hydrolytic enzymes, which may be responsible for their lysis in hypotonic media. These enzymes normally may play a role in cell wall growth and shaping.

Genotoxic effect of 4-aroyl-1-(2-chloroethyl)-1nitrosohydrazinecarboxamides on Saccharomyces cerevisiae cells.

The study of some 4-aroyl-1-(2-chloroethyl)-1-nitrosohydrazinecarboxamides with a Saccharomyces cerevisiae mutagenicity test of increased sensitivity defined two of them, 4-(4-bromobenzoyl)-1-(2-chloroethyl)-1-nitrosohydrazinecarboxam ide and 4-(4-fluorophenyl)-1-(2-chloroethyl)-1-nitrosohydrazine carboxamide as typical cytostatic agents. At concentrations of 2-5 microg/ml the substances kill up to 60%-70% of cells without having any detectable recombinogenic and mutagenic effects. At the same concentrations, lomustine, well known as a cytostatic reference, demonstrated recombinogenic and mutagenic activity on yeast cells. The advantage of the newly synthesized substances is that, in a certain concentration range, their biological activity is mainly cytotoxic without induction of recombinogenic and mutagenic events in surviving cells.

Enhanced cell permeability increases the sensitivity of a yeast test for mutagens.

ts1 is a mutation which causes a general increase in permeability of Sacharomyces cerevisiae cells in an unspecific manner. The introduction of the ts1 mutation under homozygous conditions into the D7 diploid strain enhanced the sensitivity of the test system described by Zimmermann et al. (1975). The newly constructed strain D7ts1 responded with a four to six times higher frequency compared to the D7 strain for all genetic end-points induced with chemical mutagens (ethyl methanesulfonate, methyl methanesulfonate, hydroxyurea, benzpyrene). The increased sensitivity of D7ts1 is specific only for mutagens active in yeast, since treatment of D7ts1 cells with 5-bromouracil or 5-bromouridine, known to be non-mutagenic in yeast, did not result in the induction of any of the measured genetic alterations. Five out of 14 water samples taken from the environment induced recombinogenic events in D7ts1, whereas all 14 water samples were without effect in the D7 test system. We concluded that D7ts1 cells show a higher sensitivity in the detection of mutagenic or carcinogenic action because of their generally enhanced permeability due to the ts1 mutation.

Transcriptional regulation in the yeast GAL gene family: a complex genetic network.

Regulation of the GAL structural genes in the yeast Saccharomyces cerevisiae is implemented by the products of GAL-specific (GAL4, GAL80, GAL3) and general (GAL11, SWI1, 2, 3, SNF5, 6, numerous glucose repression) genes. Recent work has 1) yielded significant new insights on the DNA binding and transcription activation/Gal80 protein binding functions of the Gal4 activator protein, 2) described the characterization of purified Gal4 protein-Gal80 protein complexes, 3) deconvoluted the multiple and complex glucose repression pathways acting on GAL genes, 4) suggested a new mechanism for the Gal3 protein-mediated induction of GAL structural gene expression, 5) introduced Gal1 protein, a structural gene product, into the regulation scheme, and 6) extended our already substantial understanding of GAL regulatory gene control. The mechanisms which control structural and regulatory gene expression in the GAL family are compared and GAL structural/regulatory gene chromatin structure is discussed.

Low levels of exogenous histone H1 in yeast cause cell death.

To elucidate the function of lysine-rich histone, yeast cells, which are believed to lack this histone, were transformed with an expression vector carrying the sea urchin histone H1 gene under control of an inducible promoter. Expression of full-length protein was tested by immunoblotting and the intracellular distribution was monitored by immunoelectron microscopy. Even low amounts of exogenous H1 led to dramatic changes in intracellular morphology and cell death. The cells that survived had lost either the plasmid or the ability to express the exogenous protein. Thus, even low amounts of canonical histone H1 are lethal to yeast cells.

Secretion of oligomeric Val8-human calcitonin by Saccharomyces cerevisiae.

Monomeric human calcitonin (hCT) gene and oligomeric hCT genes composed of two, three or four head-to-tail linked monomers were fused in-frame to the yeast alpha-factor leader coding sequence wild-type and fragile mutant Saccharomyces cerevisiae strains were transformed with the constructed plasmids and the yield of recombinant protein secreted into the culture medium was measured. The yeast cells secreted equal (molar) amounts of all of the hCT variants. The recombinant proteins remained stable in the growth medium for at least 3 days. The fragile cells secreted about 30% more hCT as compared to the wild-type yeast cells.

Cloning and characterization of a gene which determines osmotic stability in Saccharomyces cerevisiae.

The srb1-1 mutation of Saccharomyces cerevisiae is an ochre allele which renders the yeast dependent on an osmotic stabilizer for growth and gives the cells the ability to lyse on transfer to hypotonic conditions. A DNA fragment which complements both of these phenotypic effects has been cloned. This clone contains a functional gene which is transcribed into a 2.3-kb polyadenylated mRNA molecule. Transformation of yeast strains carrying defined suppressible alleles demonstrated that the cloned fragment does not contain a nonsense suppressor. Integrative transformation and gene disruption experiments, when combined with classical genetic analysis, confirmed that the cloned fragment contained the wild-type SRB1 gene. The integrated marker was used to map SRB1 to chromosome XV by Southern hybridization and pulsed-field gel electrophoresis. A disruption mutant created by the insertion of a TRP1 marker into SRB1 displayed only the lysis ability phenotype and was not dependent on an osmotic stabilizer for growth. Lysis ability was acquired by growth in (or transfer to) an osmotically stabilized environment, but only under conditions which permitted budding. It is inferred that budding cells lyse with a higher probability and that weak points in the wall at the site of budding are involved in the process. The biotechnological potential of the cloned gene and the disruption mutant is discussed.