Proteinase activities of Saccharomyces cerevisiae during sporulation.

Sporulation in Saccharomyces cerevisiae occurs in the absence of a exogenous nitrogen source. Thus, the internal amino acid pool and the supply of nitrogen compounds from protein and nucleic acid turnover must be sufficient for new protein synthesis. Since sporulation involves an increased rate of protein turnover, an investigation was conducted of the changes in the specific activity of various proteinases. A minimum of 30% of the vegetative proteins was turned over during the course of sporulation. There was a 10- to 25-fold increase in specific activity of various proteinases, with a maximum activity around 20 h after transfer into the sporulation medium. The increase in activities was due to de novo synthesis since inhibition of protein synthesis by cycloheximide blocks both an increase in proteinase activities and sporulation. There was no increase observed in proteinase activities of nonsporogenic cultures (a and alpha/alpha strains) inoculated into the sporulation medium, suggesting that the increase in proteinase activities is "sporulation specific" and not a consequence of step-down conditions. The elution patterns through diethylaminoethyl-Sephadex chromatography of various proteinases extracted from T0 and T18 cells were similar, and no new species was observed.     

Metabolism of myo-inositol during sporulation of myo-inositol-requiring Saccharomyces cerevisiae.

We investigated the sporulation properties of a series of diploid Saccharomyces cerevisiae strains homozygous for inositol auxotrophic markers. The strains required different amounts of inositol for the completion of sporulation. Shift experiments revealed two phases of inositol requirement during sporulation which coincided with the two phases of lipid synthesis found by earlier workers. Phase I was at the beginning and during premeiotic deoxyribonucleic acid synthesis; phase II immediately preceded the appearance of mature asci. Of the inositol taken up by sporulating cells, 90% was incorporated into inositol phospholipids. By two-dimensional thin-layer chromatography, eight compounds were resolved, one of which was sporulation specific. The majority of the inositol phospholipids were, however, identical to those found in vegetatively growing cells. In the absence of inositol, the cells did not sporulate but, after a certain time, were unable to return to vegetative growth. These nonsporulating cells did, however, incorporate acetate into lipids and double their deoxyribonucleic acid content in the premeiotic phase. We believe that it is this lack of coordination of biosynthetic events which causes inositol-less death on sporulation media without inositol.     

Characterization and localization of the sporulation glucoamylase of Saccharomyces cerevisiae

Glucoamylase (SGA) was purified approximately 250-fold from sporulating Saccharomyces cerevisiae cells. The partially purified enzyme was active against glycogen, starch, maltotriose and maltose. It exhibited maximum catalytic activity against glycogen at pH 5.5. The enzyme appears to be glycosylated, because it bound to lentil-lectin Sepharose. SGA was expressed in vegetatively growing cells under the control of the GAL1 promoter, and the cellular location of the enzymatic activity determined by fractionation techniques. SGA was preferentially recovered in fractions which were enriched for the vacuolar hydrolases, carboxypeptidase Y and alpha-mannosidase.     

Two-dimensional protein patterns during growth and sporulation in Saccharomyces cerevisiae.

Proteins synthesized by Saccharomyces cerevisiae in presporulation and sporulation media were compared by using sporulating (a/alpha) and nonsporulating (a/a and alpha/alpha) yeast strains. Total cellular proteins were labeled with [35S]methionine and analyzed by two-dimensional polyacrylamide gel electrophoresis. Autoradiograms and/or fluorograms showed some 700 spots per gel. Nine proteins were synthesized by a/alpha cells which were specific to vegetative, log-phase conditions. During incubation in sporulation medium, sporulating (a/alpha) cells synthesized 11 proteins not present in vegetatively growing cell. These same 11 proteins, however, were synthesized by nonsporulating (a/a and alpha/alpha) cells on sporulation medium as well. Nonsporulating diploids (a/a and alpha/alpha) were also examined with the electron microscope at various times during their incubation in sporulation medium. Certain cellular responses found to be unique to meiotic yeast cells in previous studies were exhibited by the nonsporulating controls. The degree to which all cell types (a/alpha, a/a, and alpha/alpha) were committed to sporulation was also determined by shifting cells from sporulation medium to vegetative medium. Some commitment to the meiotic pathway was observed in both the a/alpha and the a/a, alpha/alpha cells.     

Characterization of a chicken polyubiquitin gene preferentially expressed during spermatogenesis.

We have previously reported that a chicken polyubiquitin gene (Ub II) not expressed under normal or heat shock conditions in chick fibroblasts is transcribed during spermatogenesis [(1987) Nucleic Acids Res. 15, 9604]. The level of Ub II mRNA is several-fold higher in testis cells than in somatic tissues. The gene Ub II possesses characteristic features not seen in the polyubiquitin gene expressed in heat shock conditions (Ub I). The 5' noncoding region of Ub II shows the consensus cAMP regulatory element (CRE) followed immediately downstream by a CA dinucleotide. It has been proposed that this extended CRE may be involved in the coordinate expression of various genes during spermatogenesis.     

Synthesis of a spore-specific surface antigen during sporulation of Saccharomyces cerevisiae

Antisera raised against purified yeast ascospores caused agglutination of both ascospores and vegetative cells. A spore-specific activity was obtained by absorbing out anti-vegetative activity with vegetative cells. The anti-vegetative cell activity was directed against mannan, and was probably due to exposure of some spore coat mannan at the spore surface since concanavalin A and lentil lectin also caused agglutination of ascospores. The spore-specific activity was probably determined by a protein or proteins, since extraction of spores with a mixture of sodium dodecyl sulphate and dithiothreitol markedly affected their agglutination by the spore-specific serum. The spore-specific antigen was synthesized in a soluble form during sporulation several hours before the appearance of the spore surface and the pool of soluble antigen declined as the spore was assembled. Synthesis of the soluble antigen was inhibited by adding cycloheximide at all times up to its first appearance in the sporulating cell.     

Topological and mutational analysis of Saccharomyces cerevisiae Fks1

Fks1, with orthologs in nearly all fungi as well as plants and many protists, plays a central role in fungal cell wall formation as the putative catalytic component of β-1,3-glucan synthase. It is also the target for an important new antifungal group, the echinocandins, as evidenced by the localization of resistance-conferring mutations to Fks1 hot spots 1, 2, and 3 (residues 635 to 649, 1354 to 1361, and 690 to 700, respectively). Since Fks1 is an integral membrane protein and echinocandins are cyclic peptides with lipid tails, Fks1 topology is key to understanding its function and interaction with echinocandins. We used hemagglutinin (HA)-Suc2-His4C fusions to C-terminally truncated Saccharomyces cerevisiae Fks1 to experimentally define its topology and site-directed mutagenesis to test function of selected residues. Of the 15 to 18 transmembrane helices predicted in silico for Fks1 from evolutionarily diverse fungi, 13 were experimentally confirmed. The N terminus (residues 1 to 445) is cytosolic and the C terminus (residues 1823 to 1876) external; both are essential to Fks1 function. The cytosolic central domain (residues 715 to 1294) includes newly recognized homology to glycosyltransferases, and residues potentially involved in substrate UDP-glucose binding and catalysis are essential. All three hot spots are external, with hot spot 1 adjacent to and hot spot 3 largely embedded within the outer leaflet of the membrane. This topology suggests a model in which echinocandins interact through their lipid tails with hot spot 3 and through their cyclic peptides with hot spots 1 and 2.     

Metabolic rates during sporulation of Saccharomyces cerevisiae on acetate

We have quantified yeast carbon and oxygen consumption fluxes and estimated anabolic fluxes through glyoxylate and gluconeogenic pathways under various conditions of sporulation on acetate. The percentage of sporulation reached a maximum of 55% to 60% after 48 h in sporulation medium, for cells harvested from logarithmic growth in acetate minimal medium. When cells were harvested in the stationary phase of growth before transfer to sporulation medium, the maximum percentage of sporulation decreased to 40% along with the occurrence of meiosis as could be judged by counting of bi- and tetra-nucleated cells. In both experiments, the rates of acetate and oxygen consumption decreased as a function of time when exposed to sporulation medium. Apparently, the decrease of metabolic rates was not due to alkalinization. By systematically varying the cell concentration in sporulation medium from 1.4×10⁷ to 20×10⁷ cell ml^-1, the percentage of sporulating cells was found to decrease in parallel with the rate of acetate consumption. When the sporulation efficiency attained under the different experimental conditions was plotted as a function of the rate of acetate consumption, a linear correlation was found. Anabolic fluxes estimation revealed a decrease of the rate through gluconeogenic and glyoxylate pathways occurring during sporulation progression. The pattern of metabolic fluxes progressively evolved toward a predominance of more oxidative catabolic fluxes than those exhibited under growth conditions. The results obtained are discussed in terms of a characteristic pattern of metabolic fluxes and energetics, associated to the development of yeast sporulation.Abbreviations DAPI 4,6-diamidino-2-phenylindole - dw dry weight - OD₅₄₀ optical density at 540 nm - SEM standard error of the mean - RQ respiratory quotient     

Alternative modes of organellar segregation during sporulation in Saccharomyces cerevisiae

Formation of ascospores in the yeast Saccharomyces cerevisiae is driven by an unusual cell division in which daughter nuclei are encapsulated within de novo-formed plasma membranes, termed prospore membranes. Generation of viable spores requires that cytoplasmic organelles also be captured along with nuclei. In mitotic cells segregation of mitochondria into the bud requires a polarized actin cytoskeleton. In contrast, genes involved in actin-mediated transport are not essential for sporulation. Instead, efficient segregation of mitochondria into spores requires Ady3p, a component of a protein coat found at the leading edge of the prospore membrane. Other organelles whose mitotic segregation is promoted by actin, such as the vacuole and the cortical endoplasmic reticulum, are not actively segregated during sporulation but are regenerated within spores. These results reveal that organellar segregation into spores is achieved by mechanisms distinct from those in mitotic cells.     

Isolation of genes preferentially expressed during Bacillis subtilis spore outgrowth.

From the Charon 4A library of Ferrari et al (J. Bacteriol. 146:430-432, 1981) we isolated three genes involved in Bacillus subtilis spore outgrowth by screening the library by hybridization with labeled RNA from outgrowing spores in the presence of an excess of unlabeled vegetative RNA. Hybridization competition experiments with purified clones showed that the clones contained sequences that were transcribed only during spore outgrowth or preferentially during spore outgrowth. Fragments of the cloned DNAs were subcloned in plasmid pJH101, and by using plasmid integration and PBS1 transduction the chromosomal loci were mapped. The three loci which we mapped are outG and outH, which are located between polC and dnaA, and outI, which is located near pycA. Using the cloned DNAs and derived plasmids in dot hybridization experiments with RNA extracted from cells at different developmental stages, we defined for two clones a region that is transcribed only during the outgrowth phase.     

LRG1 is expressed during sporulation in Saccharomyces cerevisiae and contains motifs similar to LIM and rho/racGAP domains.

We here report the sequence of a yeast gene LRG1 whose deduced amino acid sequence contains sequence motifs similar to LIM domain proteins in the amino-terminal, and to rho/rac GTPase activating proteins (rho/racGAP's) in the carboxy-terminal part. LRG1 expression is differentially regulated showing a peak of expression in sporulating cells. Gene disruption experiments indicate that the gene is not essential and may play a role during mating.     

Evidence for cooperation between cells during sporulation of the yeast Saccharomyces cerevisiae.

Diploid Saccharomyces cerevisiae cells heterozygous for the mating type locus (MATa/MAT alpha) undergo meiosis and sporulation when starved for nitrogen in the presence of a poor carbon source such as potassium acetate. Diploid yeast adenine auxotrophs sporulated well at high cell density (10(7) cells per ml) under these conditions but failed to differentiate at low cell density (10(5) cells per ml). The conditional sporulation-deficient phenotype of adenine auxotrophs could be complemented by wild-type yeast cells, by medium from cultures that sporulate at high cell density, or by exogenously added adenine (or hypoxanthine with some mutants). Adenine and hypoxanthine in addition to guanine, adenosine, and numerous nucleotides were secreted into the medium, each in its unique temporal pattern, by sporulating auxotrophic and prototrophic yeast strains. The major source of these compounds was degradation of RNA. The data indicated that differentiating yeast cells cooperate during sporulation in maintaining sufficiently high concentrations of extracellular purines which are absolutely required for sporulation of adenine auxotrophs. Yeast prototrophs, which also sporulated less efficiently at low cell density (10(3) cells per ml), reutilized secreted purines in preference to de novo-made purine nucleotides whose synthesis was in fact inhibited during sporulation at high cell density. Adenine enhanced sporulation of yeast prototrophs at low cell density. The behavior of adenine auxotrophs bearing additional mutations in purine salvage pathway genes (ade apt1, ade aah1 apt1, ade hpt1) supports a model in which secretion of degradation products, uptake, and reutilization of these products is a signal between cells synchronizing the sporulation process.     

Large-scale functional genomic analysis of sporulation and meiosis in Saccharomyces cerevisiae

We have used a single-gene deletion mutant bank to identify the genes required for meiosis and sporulation among 4323 nonessential Saccharomyces cerevisiae annotated open reading frames (ORFs). Three hundred thirty-four sporulation-essential genes were identified, including 78 novel ORFs and 115 known genes without previously described sporulation defects in the comprehensive Saccharomyces Genome (SGD) or Yeast Proteome (YPD) phenotype databases. We have further divided the uncharacterized sporulation-essential genes into early, middle, and late stages of meiosis according to their requirement for IME1 induction and nuclear division. We believe this represents a nearly complete identification of the genes uniquely required for this complex cellular pathway. The set of genes identified in this phenotypic screen shows only limited overlap with those identified by expression-based studies.     

Inhibiton by sulfanilamide of sporulation in Saccharomyces cerevisiae.

The antimetabolite sulfanilamide inhibits sporulation in Saccharomyces cerevisiae strain AP1. Cells exposed to sulfanilamide at various times during the sporulation process become progressively insensitive to the drug, although accumulation of sulfanilamide by the cells increases with time. Vegetative growth of AP1 is practically unaffected by sulfanilamide; pregrowth of the cells in the presence of the drug does not prevent sporulation. Thus, inhibition is confined to the meiotic phase of the cell cycle. Sensitivity to sulfanilamide is independent of pH. Increasing the time cells are exposed to sulfanilamide results in a progressive reduction of ascus formation; however, the inhibition is reversible since sporulation can occur in cells exposed to the drug for greater than 24 h. The drug arrests the cells at a point before commitment to sporulation, since yeast cells exposed to sulfanilamide for 12 h do not complete the sporulation process when returnedto vegetative medium, but resume mitotic growth instead. Meiotic nuclear division is largely prevented by sulfanilamide, and synthesis of RNA and protein is severely retarded. DNA synthesis is inhibited up to 50%; glycogen synthesis is approximately 90% inhibited. Other yeast strains showed varying sensitivity to sulfanilamide; homothallic strains were generally less affected.