Proton extrusion inSaccharomyces cerevisiae mutants in very dilute suspensions

Substrate-induced H⁺ extrusion was studied in dilute (0.04–0.5 mg dry mass per mL) unbuffered suspensions ofS. cerevisiae. Wild-type strains 196-2 and K and 196-2-derived mutants altered in hexose transport, glucosephosphate isomerase, mannosephosphate isomerase, pyruvate kinase, and arho petite mutant were characterized as to growth, biochemical and H⁺-pumping properties. Their H⁺ extrusion differed, depending on strain, growth conditions, and the H⁺-efflux-inducing substrate; the efficiency of the process depended critically on the balance between substrate uptake, its dissimilation, attendant mobilization of energy sources and build-up of acidity sources in the cell, and the energy supply to H⁺excreting systems.     

Mating reaction inSaccharomyces cerevisiae

The effect of proteolytic enzymes on sexual agglutinability of haploid cells of the yeastSaccharomyces cerevisiae was examined. Sexual agglutinability of cells of botha and α types was lost on treatment with alkaline protease and two kinds of neutral proteases ofBacillus subtilis, pronase and α-chymotrypsin. Agglutinability of α type cells was lost after treatment with acid protease ofRhizopus chinensis and trypsin, but that ofa type cells was not. These results indicate that the sex-specific substance responsible for the sexual agglutination (agglutination factor) ina type cells differs from that in α type cells. Agglutination factors were solubilized from cell-wall fractions of both mating types by Glusulase treatment. These crude factors specifically inhibited the agglutinability of cells of the opposite mating type with little effect on the agglutinability of cells of the same mating type.     

Transport ofl-tryptophan inSaccharomyces cerevisiae

In addition to the general amino acid transport system (GAP) ofS. cerevisiae l-tryptophan is transported by another system with approximately 25% capacity of GAP, with aK _T of 0.41±0.08 mmol/L and with a similar specificity as GAP (lower inhibition by Met, Pro, Ser, Thr and 2-aminoisobutyric acid; greater inhibition by Glu and His). The pH optimum of this system is at 5.0–5.5, activation energy above the transition point (20°C) was 20 kJ/mol, below the transition point 55 kJ/mol. The transport by this system was virtually unidirectional, efflux amounting to at most 10% into a tryptophan-free medium. The transport itself was blocked by 2,4-dinitrophenol, antimycin A and uranyl nitrate. The system was synthesized de novo during preincubation with glucose=fructose>trehalose >ethanol within 30 min, and was degraded with a half-time of 15 min in the absence of further synthesis. The accumulation ratios ofl-tryptophan ingap1 mutants were concentration-dependent (200∶1 at 1 μmoll-Trp/L, 4∶1 at 2.5 mmoll-Trp/L) and decreased with increasing suspension density from 200∶1 to 5∶1 (for 10 μmoll-Trp/L). The involvement of hydrogen ions in the uptake was clearly demonstrated by the effect of D₂O even if it could not be established by either shifts of pH_out or membrane depolarization.     

The RAS-adenylate cyclase pathway and cell cycle control inSaccharomyces cerevisiae

The cell cycle ofSaccharomyces cerevisiae contains a decision point in G₁ called start, which is composed of two specific sites. Nutrient-starved cells arrest at the first site while pheromone-treated cells arrest at the second site. Functioning of the RAS-adenylate cyclase pathway is required for progression over the nutrient-starvation site while overactivation of the pathway renders the cells unable to arrest at this site. However, progression of cycling cells over the nutrient-starvation site does not appear to be triggered by the RAS-adenylate cyclase pathway in response to a specific stimulus, such as an exogenous nutrient. The essential function of the pathway appears to be limited to provision of a basal level of cAMP. cAMP-dependent protein kinase rather than cAMP might be the universal integrator of nutrient availability in yeast. On the other hand stimulation of the pathway in glucose-derepressed yeast cells by rapidly-fermented sugars, such as glucose, is well documented and might play a role in the control of the transition from gluconeogenic growth to fermentative growth. The initial trigger of this signalling pathway is proposed to reside in a glucose sensing complex which has both a function in controlling the influx of glucose into the cell and in activating in addition to the RAS-adenylate cyclase pathway all other glucose-induced regulatory pathways in yeast. Two crucial problems remaining to be solved with respect to cell cycle control are the nature of the connection between the RAS-adenylate cyclase pathway and nitrogen-source induced progression over the nutrient-starvation site of start and second the nature of the downstream processes linking the RAS-adenylate cyclase pathway to Cyclin/CDC28 controlled progression over the pheromone site of start.Abbreviations cAMP-PK cAMP-dependent protein kinase     

The chitin-glucan complex inSaccharomyces cerevisiae

The content of glucosamine in the walls of daughter (without bud scars) and mother (multiscar) cells ofSaccharomyces cerevisiae was examined in a control and after treatment with dilute alkali, acid and buffer. The occurrence of chitin in the bud and birth scars is discussed. The results of IR and X-ray analysis of cell-wall fractions indicate the presence of α-chitin which is a part of the chitin-glucan complex. The size of the crystallite of α-chitin in this complex is about 60 Å.     

Transport of acyclic polyols inSaccharomyces cerevisiae

Acyclic polyols (erythritol, xylitol, ribitol, D-arabinitol, mannitol, sorbitol and galactitol) are not metabolized by Saccharomyces cerevisiae. They are taken up by a fast non-active process, reaching 40-70% distribution referred to total cell water. The uptake is insensitive to temperature, pH (between 4 and 8), 2,4-dinitrophenol and uranyl ions. Its initial rate rises linearly with concentration from 10(-5)M to 1M. The process resembles simple diffusion through large pores or the trapping of the whole solution on the surface. Protoplasts behave like whole cells in this respect. Only erythritol shows a second type of uptake which is inhibitor-insensitive but temperature-dependent.     

Regulation of energy flow and control of the cell cycle inSaccharomyces cerevisiae

Summary Measurements of glucose utilization and ethanol production by a respiratory-deficient mutant ofS. cerevisiae in a batch culture show that during the phase of acceleration, the glucose utilization per newly formed cell,k, is higher than the average value and the fermentationF < 1. In the phase of retardation, on the other hand,k is lower andF > 1. Correlating with the changes in the physiological state of the cell population, these results indicate that a considerable fraction of the total glucose consumed is utilized for the synthesis of polysaccharides in the G₁-phase, whereas reserve carbohydrates are catabolised during (S + G₂ + M)-phases of the cell cycle.A cybernetic model for the regulation of the energy (ATP) flow during the cell cycle is presented. It is postulated that the coupling between the energy-yielding and energy-consuming processes is provided by (i) a feedback regulation of the rate of energy production by the energy level and (ii) formation and breakdown of an intracellular energy storage system with a control function in the G₁S transition during the cell cycle.     

Turnover of canavanine-containing proteins inSaccharomyces cerevisiae

Saccharomyces cerevisiae grown for 2 h in the presence of 0.5 mmol/L canavanine in a synthetic medium with ethanol as the sole carbon source (OEC) exhibited a slowing down of protein synthesis for 3–4 h after a shift to fresh ethanolbased medium containing 1.0 mmol/L arginine (OEA) in comparison with untreated cells grown on OEA. The change of carbon source from ethanol to glucose (OGA) after growth in the OEC medium resulted in an even deeper decline of protein synthesis. The degradation of canavanine-containing proteins in cells pregrown and labelled in an OEC medium after transfer to OEA was more rapid than in the OGA medium. The initial rate of protein degradation during the first hour in the OGA medium was less than 1%/h whereas in the OEA medium it reached almost 10%/h. The fraction of proteins with high turnover (half-life 0.46 h) constituted 8.3% on OEA, while during subsequent growth on OGA it was only 0.75% with a half-life of 0.12 h.     

Regulation of sterol biosynthesis inSaccharomyces cerevisiae

Sterol synthesis inSaccharomyces cerevisiae was primarily controlled by the growth rate. At low specific growth rates the intermediates of ergosterol biosynthesis prevailed in cells. At the same time, the total sterol content reached about 6% of dry matter whereas the content of ergosterol was only 2–2.5%, which seems to be the maximum value forS. cerevisiae. After esterification with fatty acids these sterol intermediates are stored in lipid globules together with reserve triacylglycerols. The sporulatingS. cerevisiae cells contained 3.5% sterols and 1.5% ergosterol of dry matter.     

Patterns of wall synthesis inSaccharomyces cerevisiae

Wall formation inSaccharomyces cerevisiae seems to be the result of two main patterns of wall material deposition: (i) around the whole periphery of the cell in nonbudding ones, and (ii) mainly at the tip of the daughter cell or at the cross wall that separates dividing cells. This interpretation has been obtained following experiments in which RNA or protein synthesis has been inhibited. Under these conditions, glucan formation takes place, and wall thickening is probably due to the accumulation of this polysaccharide. Furthermore, once a pattern of wall deposition has been established, it is not modified by inhibition of RNA or protein synthesis.     

Effects of low X-ray doses inSaccharomyces cerevisiae

Summary Three strains ofSaccharomyces cerevisiae with different capacities for repair of radiation damage (RAD, rad18, and rad52) have been tested for their colony forming ability (CFA) and growth rates after application of small X-ray doses from 3.8 mGy to 40 Gy. There was no reproducible increase in CFA observable after application of doses between 3.8 mGy and 4.7 Gy. X-ray doses of 40 Gy causing an inactivation of CFA from 90% to 50%, depending on the repair capacity of the strains used, caused a reduced increase in optical density during 2 h buffer treatment in comparison to unirradiated cells. This reduction however, is reversible as soon as the cells are transferred into nutrient medium. One hour after transfer into growth medium the portions of cells with large buds (G2 and M phase) and cells with small buds (S phase) are drastically different in irradiated cells from those obtained in unirradiated cells. The time necessary for separation of mother and daughter cells is prolonged by X-ray irradiation and the formation of new buds is retarded.     

Rapid kinetics of glucose uptake inSaccharomyces cerevisiae

In a multiple deletion mutanthxt1Δhxt2Δhxt3Δ hxt4Δsnf3Δ ofSaccharomyces cerevisiae growing on 2 % glucose, high-affinity glucose-uptake (lowK _m) was exhibited throughout growth on glucose in contrast to the wild-type, which exhibited the usual low-affinity to high-affinity transition as the glucose in the medium was consumed. elevated levels of invertase activity throughout growth on glucose, in this mutant as compared to the wild-type, indicate that glucose repression may be impaired. Howver, in a mutant containing only theHXT2 gene (hxt1Δhxt3Δhxt4Δ snf3Δ), invertase levels were similar to those in the wild-type. It is likely, therefore, that some of these putative glucose transporters, such asHXT2, also have regulatory roles in cellular metabolism. In triple hexose-kinase mutants, rapid (200-ms) measurements of initial glucose-uptake revealed high-affinity glucose uptake (K _m approx. 2 mmol/L) while measurements on the slower 5-s scale clearly demonstrate that uptake is not linear over this longer period. These results suggest that this high-affinity component does not require a functional hexose-kinase.     

Expression of Japanese quail ovalbumin inSaccharomyces cerevisiae

A cDNA sequence coding for Japanese quail ovalbumin was used for the construction of expression plasmid under the ADH1 promoter of the yeast shuttle vector pVT101-U. The resulting recombinant expression vector pJK2 was used for the transformation ofSaccharomyces cerevisiae. Expression of quail ovalbumin in yeast cells was demonstrated by Western blotting followed by immunochemical detection.