Biogenesis of Mitochondria: Analysis of Deletion of Mitochondrial Antibiotic Resistance Markers in Petite Mutants of Saccharomyces cerevisiae

Yeast strains carrying markers in several mitochondrial antibiotic resistance loci have been employed in a study of the retention and deletion of mitochondrial genes in cytoplasmic petite mutants. An assessment is made of the results in terms of the probable arrangement and linkage of mitochondrial genetic markers. The results are indicative of the retention of continuous stretches of the mitochondrial genome in most petite mutants, and it is therefore possible to propose a gene order based on co-retention of different markers. The order par, mik1, oli1 is suggested from the petite studies in the case of three markers not previously assigned an unambiguous order by analysis of mitochondrial gene recombination. The frequency of separation of markers by deletion in petites was of an order similar to that obtained by recombination in polar crosses, except in the case of the ery1 and cap1 loci, which were rarely separated in petite mutants. The deletion or retention of the locus determining polarity of recombination (ω) was also demonstrated and shown to coincide with deletion or retention of the ery1, cap1 region of the mitochondrial genome. Petites retaining this region, when crossed with rho⁺ strains, display features of polarity of recombination and transmission similar to the parent rho⁺ strain. By contrast a petite determined to have lost the ω⁺ locus did not show normal polarity of marker transmission. Differences were observed in the relative frequency of retention of markers in a number of strains and also when comparing petites derived spontaneously with those obtained after ultraviolet light mutagenesis. By contrast, a similar pattern of marker retention was seen when comparing spontaneous with ethidium bromide-induced petites.     

Functional Alcohol Dehydrogenase Mutants of Saccharomyces cerevisiae Conferring Temperature-Conditional Allyl Alcohol Resistance

Selection for allyl alcohol resistance in respiratory incompetent yeast is a highly specific method for isolating functional mutations at ADH1, the gene coding for the cytoplasmic alcohol dehydrogenase, ADHI. Because of the nature of this selection scheme, the ADHI activity of such mutants is retained, but the kinetic characteristics of the enzymes are altered. The high specificity for targeting functional mutations at this locus suggested that selection for enzyme variants with more subtle phenotypic effects might be possible. Here, we describe functional ADHI mutants that are temperature-conditional in their allyl alcohol resistance. Haploid cells of one of these mutants grow well on plates at 10 mM allyl alcohol at 19 degrees, but not at 37 degrees, the restrictive temperature. A second mutant grows well at 10 mM at 37 degrees, but its growth is restricted at 19 degrees. What distinguishes these mutants from other temperature-sensitive mutants is that the temperature-conditional growth phenotypes described here must be due to interactions between allyl alcohol levels and ADHI functional properties and cannot be due to lability of the enzyme at the restrictive temperature. This system shows promise for the investigation of functional enzyme variants that differ by only one or two amino acid residues but have significant temperature- and substrate-conditional effects on growth phenotypes in both the haploids and the diploids.     

Mutants of Saccharomyces cerevisiae with defective vacuolar function.

Mutants of the yeast Saccharomyces cerevisiae that have a small vacuolar lysine pool were isolated and characterized. Mutant KL97 (lys1 slp1-1) and strain KL197-1A (slp1-1), a prototrophic derivative of KL97, did not grow well in synthetic medium supplemented with 10 mM lysine. Genetic studies indicated that the slp1-1 mutation (for small lysine pool) is recessive and is due to a single chromosomal mutation. Mutant KL97 shows the following pleiotropic defects in vacuolar functions. (i) It has small vacuolar pools for lysine, arginine, and histidine. (ii) Its growth is sensitive to lysine, histidine, Ca2+, heavy metal ions, and antibiotics. (iii) It has many small vesicles but no large central vacuole. (iv) It has a normal amount of the vacuolar membrane marker alpha-mannosidase but shows reduced activities of the vacuole sap markers proteinase A, proteinase B, and carboxypeptidase Y.     

Petite deletion map of the mitochondrial oxi3 region in Saccharomyces cerevisiae.

Summary Fifty eight mitochondrial mutants (p ⁺ mit^- mutants), all deficient in cytochrome oxidase activity and previously assigned to the genetic region oxi3 on the mitochondrial DNA, were mapped by the method of petite deletion mapping.This procedure resulted in the identification of at least twenty one different classes of oxi3 mutants, which could be arranged in a linear order.Moreover, it provided a set of twenty three p ^- petite mutants, each containing a differentially deleted mit DNA segment included in the oxi3 region. The two sets of mutants, p ⁺ oxi3 ^- and p ^- oxi3 ⁺, will be of interest for a further genetic and physical analysis of this mitochondrial DNA segment which spans over about ten thousand base pairs and controls the subunit I of cytochrome oxidase.     

Glucose Metabolism in gcr Mutants of Saccharomyces cerevisiae

A gcr2 null mutant of Saccharomyces cerevisiae grows well on glucose in spite of its lower level of glycolytic enzymes between triose phosphates and pyruvate. A quantitative analysis shows that these levels are adequate to the flux but glycerate phosphates are elevated.     

Mutants of Saccharomyces cerevisiae deficient in adenine phosphoribosyltransferase

Spontaneous and ethyl methanesulfate induced mutants of Saccharomyces cerevisiae, with partial and complete deficiency of adenine phosphoribosyltransferase (APRT, EC 2.4.2.7), were isolated by selection for resistance to 8-azaadenine. Matings between totally deficient mutants and tester strain resulted in diploid heterozygotes that were sensitive to azaadenine. Upon sporulation and tetrad analysis, azaadenine resistance (and APRT deficiency) segregated as expected for a single Mendelian gene. Hypoxanthine-guanine phosphoribosyltransferase (EC 2.4.2.8) activity in the mutants was similar to that in the wild-type cells. There was no detectable activity of adenine aminohydrolase (EC 3.5.4.2) in the wild-type or mutant cells.     

Mutants of Saccharomyces cerevisiae resistant to a quaternary ammonium salt

Three quaternary ammonium salts were compared in respect of their ability to select resistant mutants of S. cerevisiae. The mutants tolerating slightly higher IM compound concentration were analysed. They appeared to be the products of nuclear gene mutation segregating monogenically but strongly influenced by genetic background. The mutant IMR when transformed to rho degrees lost resistance below the level of minimal inhibitory concentration of original strain. Possible hypothesis explaining this phenomenon is presented.     

Mutants of Saccharomyces cerevisiae resistant to carbon catabolite repression.

Summary Mutants with defective carbon catabolite repression have been isolated in the yeast Saccharomyces cerevisiae using a selective procedure. This was based on the fact that invertase is a glucose repressible cell wall enzyme which slowly hydrolyses raffinose to yield fructose and that the inhibitory effects of 2-deoxyglucose can be counteracted by fructose. Repressed cells were plated on a raffinose-2-deoxyglucose medium and the resistant cells growing up into colonies were tested for glucose non-repressible invertase and maltase. The yield of regulatory mutants was very high. All were equally derepressed for invertase and maltase, no mutants were obtained with only non-repressible invertase synthesis which was the selected function. A total of 61 mutants isolated in different strains were allele tested and could be attributed to three genes. They were all recessive. Mutants in one gene had reduced hexokinase activities, the other class, located in a centromere linked gene, had elevated hexokinase levels and was inhibited by maltose. Mutants in a third gene were isolated on a 2-deoxyglucose galactose medium and had normal hexokinase levels. A partial derepression was observed for malate dehydrogenase in all mutants. Isocitrate lyase, however, was still fully repressible.     

Uninducible Mutants in the gal i Locus of Saccharomyces cerevisiae

Uninducible galactose nonfermenter mutants of Saccharomyces cerevisiae have been isolated and mapped in the gal i locus. They appear to be analogous to the i(s) mutations found in the regulatory genes of the Escherichia coli lactose and galactose systems. The susceptibility to suppression by an ochre suppressor of an i allele in an i(s)i(-) double mutant suggests that the i locus in S. cerevisiae codes for a protein.     

Mutants of Saccharomyces cerevisiae supersensitive to the mutagenic effect of 6-N-hydroxylaminopurine

Yeast mutants hypersensitive to the mutagenic action of 6-N-hydroxylaminopurine (HAP) were obtained by EMS mutagenesis. One of the mutants segregated monogenically and possessed reduced capacity to utilize HAP as a purine source. A set of diploids suitable for parallel study of mutagenesis and induction of recombination, and differing in the trait of mutability after exposure to HAP ("hm" trait or HAP mutability), were constructed. It was shown that a weak recombinogenic effect of HAP is not enhanced in "hm" mutants when HAP mutability increases.     

Prion-Dependent Lethality of sup45 Mutants in Saccharomyces cerevisiae

In yeast Saccharomyces cerevisiae translation termination factors eRF1 (Sup45) and eRF3 (Sup35) are encoded by the essential genes SUP45 and SUP35 respectively. Heritable aggregation of Sup35 results in formation of the yeast prion [PSI⁺]. It is known that combination of [PSI⁺] with some mutant alleles of the SUP35 or SUP45 genes in one and the same haploid yeast cell causes synthetic lethality. In this study, we perform detailed analysis of synthetic lethality between various sup45 nonsense and missense mutations on one hand, and different variants of [PSI⁺] on the other hand. Synthetic lethality with sup45 mutations was detected for [PSI⁺] variants of different stringencies. Moreover, we demonstrate for the first time that in some combinations, synthetic lethality is dominant and occurs at the postzygotic stage after only a few cell divisions. The tRNA suppressor SUQ5 counteracts the prion-dependent lethality of the nonsense alleles but not of the missense alleles of SUP45, indicating that the lethal effect is due to the depletion of Sup45. Synthetic lethality is also suppressed in the presence of the C-proximal fragment of Sup35 (Sup35C) that lacks the prion domain and cannot be included into the prion aggregates. Remarkably, the production of Sup35C in a sup45 mutant strain is also accompanied by an increase in the Sup45 levels, suggesting that translationally active Sup35 up-regulates Sup45 or protects it from degradation.Key Words: Sup45, Sup35, eRF1, eRF3, amyloid, [PSI⁺], translation termination, Saccharomyces cerevisiae     

Saccharomyces cerevisiae Mutants Resistant to Catabolite Repression: Use in Cheese Whey Hydrolysate Fermentation

Mutants of an industrial-type strain of Saccharomyces cerevisiae which rapidly and completely fermented equimolar mixtures of glucose and galactose to ethanol were isolated. These mutants fell into two general phenotypic classes based upon their fermentation kinetics and enzyme induction patterns. One class apparently specifically effects the utilization of galactose and allows sequential utilization of first glucose and then galactose in an anaerobic fermentation. The second class of mutants was resistant to general catabolite repression and produced maltase, invertase, and galactokinase in the presence of repressive levels of glucose. These mutants were completely dominant and appear to represent an as yet undescribed class of mutant.     

Cytokinin Utilization by Adenine-Requiring Mutants of the Yeast Saccharomyces cerevisiae

By monitoring the growth of several adenine auxotrophs of the yeast Saccharomyces cerevisiae on cytokinin-supplemented media, we have demonstrated that this organism can utilize some of these derivatives as a source of adenine. Growth of a mutant lacking adenylosuccinate synthetase suggests that the conversion of cytokinins to adenine does not involve a hypoxanthine intermediate and may be catalyzed by an enzyme analogous to cytokinin oxidase.     

Mutants of Saccharomyces cerevisiae and Candida utilis with increased susceptibility to digestive enzymes.

Mutants of Candida utilis and a haploid strain of Saccharomyces cerevisiae were isolated, after ultraviolet light mutagenesis, which had increased sensitivities to snail gut enzymes (ses). Three of the five S. cerevisiae mutants tested had increased sensitivities to porcine pepsin, all were more susceptible to a sequential treatment with pepsin, lipase, peptidase, and trypsin, four were sensitive to osmotic shock, and two had increased glucan/mannan ratios in their cell walls. All combinations of mutants showed positive complementation in heterozygous diploids, although complementation between one pair, which had the same phenotype, was incomplete, indicating that four to five different cistrons were involved. All mutations were found to be recessive. Haploid strains bearing pairs of ses mutations were not markedly more sensitive to mammalian digestive enzymes than strains with single mutations. Rat-feeding experiments with three mutants and the parental strains indicated that the protein was efficiently utilized in all cases. Net protein ratios for the two mutants of S. cerevisiae tested were slightly higher than that for their parent, but the differences were of marginal significance.     

Mutants affecting the structure of the cortical endoplasmic reticulum in Saccharomyces cerevisiae

We find that the peripheral ER in Saccharomyces cerevisiae forms a dynamic network of interconnecting membrane tubules throughout the cell cycle, similar to the ER in higher eukaryotes. Maintenance of this network does not require microtubule or actin filaments, but its dynamic behavior is largely dependent on the actin cytoskeleton. We isolated three conditional mutants that disrupt peripheral ER structure. One has a mutation in a component of the COPI coat complex, which is required for vesicle budding. This mutant has a partial defect in ER segregation into daughter cells and disorganized ER in mother cells. A similar phenotype was found in other mutants with defects in vesicular trafficking between ER and Golgi complex, but not in mutants blocked at later steps in the secretory pathway. The other two mutants found in the screen have defects in the signal recognition particle (SRP) receptor. This receptor, along with SRP, targets ribosome-nascent chain complexes to the ER membrane for protein translocation. A conditional mutation in SRP also disrupts ER structure, but other mutants with translocation defects do not. We also demonstrate that, both in wild-type and mutant cells, the ER and mitochondria partially coalign, and that mutations that disrupt ER structure also affect mitochondrial structure. Our data suggest that both trafficking between the ER and Golgi complex and ribosome targeting are important for maintaining ER structure, and that proper ER structure may be required to maintain mitochondrial structure.     

Mutants of H-ras that interfere with RAS effector function in Saccharomyces cerevisiae.

We report a class of interfering mutants of the human H-ras gene capable of inhibiting phenotypes arising from the expression of the activated RAS2 gene, RAS2val19, in the yeast Saccharomyces cerevisiae. All these mutants encode unprocessed H-ras proteins that remain in the cytoplasm. One of the mutants, H-rasarg186, was examined in detail. H-rasarg186 protein is a competitive inhibitor of RAS2val19 protein. It does not interfere with processing and membrane localization of RAS2val19, nor does it appear to compete with RAS protein for its proposed regulator, the CDC25 protein. By several criteria the RAS2val19 adenylate cyclase interaction is unaffected by H-rasarg186. We infer from our results that H-rasarg186 protein interferes with an alternative function of RAS2val19.