Mating reaction in Saccharomyces cerevisiae

Summary Conspicuous cell agglutination occurred when cells of the a and types were mixed together and cultured, while it did not when the strains not to mate each other were mixed. In the former case the ability of cells to agglutinate developed gradually with time after the mixing. The agglutination was inhibited by cycloheximide but not by chloramphenicol. Relation between yeast sexual hormones and the mating-specific cell agglutination is discussed.     

Mating reaction in Saccharomyces cerevisiae

A diffusible sex-specific substance called substance-I (S-I) was isolated from culture filtrate of type strains of the yeast Saccharomyces cerevisiae. The isolated S-I, an oligopeptide, induced sexual cell agglutinability in inducible a type strains and enhanced the agglutinability in constitutive a type strains. The induction of sexual agglutinability was detected in 30 min and reached maximum in 90 min, when 0.2 g/ml of S-I was added to inducible a type cells. The a type-specific factor responsible for sexual cell agglutination, called a type agglutination factor (aAF), was shown to be produced during the induction or the enhancement of agglutinability of a type cells by S-I. The aAF produced in response to S-I was not different in the susceptibility to proteolytic enzymes and disulfide-cleaving agents from those produced constitutively in the absence of S-I.     

Mating reaction in Saccharomyces cerevisiae

Summary We studied changes in autolytic activity of cells in the course of mating, using heterothallic haploid strains of Saccharomyces cerevisiae. Autolytic activity was determined by measuring protein and sugar released in the medium. The autolytic activity increased very rapidly after mixing a and type haploid cells, while such a conspicuous change was not observed with separate cultures of a or type cells. Increase due to mating in release of sugar was more conspicuous than that of protein. Increase in autolytic activity preceded the appearance of conjugating cells.     

Mating reaction in Saccharomyces cerevisiae

Summary Haploid Saccharomyces yeasts showed sexual agglutination when a and type cells were mixed. Two types of a type strains were found; one constitutive and the other inducible concerning agglutinability. In type strains, no such differentiation was observed. Agglutination was inhibited by protease treatment. Secretion from type cells induced agglutinability in inducible a type cells. The activity of the secreted principle was heat-stable. The secretion is thought to induce de novo synthesis of proteinous sex-specific substances or to uncover preexisting sex substances.     

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.     

Mating reaction in Saccharomyces cerevisiae VI. Effect of 2-deoxyglucose on conjugation

The effect of 2-deoxyglucose (2-dG) on the mating reaction ofSaccharomyces cerevisiae was investigated and the followingresults were obtained. 1) The cell fusion process of the mating reaction was completelyinhibited by 0.05% 2-dG added to a culture medium containing2% D-glucose. This inhibition was partially reversed by raisingthe glucose concentration in the medium. 2) Sexual cell agglutination was hardly affected by 2-dG. 3) 2-dG at concentrations inhibiting cell fusion considerablysuppressed the incorporation of ¹⁴C-glucose into the cell wallpolysaccharides, glucan and mannan. 4) Glucose uptake and protein synthesis were only slightly inhibitedby 2-dG. 5) No enhancement of bulk polysaccharide synthesis was detectedduring mating. ¹Present address: Biological Institute, Faculty of Science,Nagoya University, Chikusa-ku, Nagoya 464, Japan. (Received April 20, 1974; )     

Analysis of Homothallic Saccharomyces cerevisiae Strain Mating during Must Fermentation

Genetic instability and genome renewal may cause loss of heterozygosity (LOH) in homothallic wine yeasts (Saccharomyces cerevisiae), leading to the elimination of the recessive lethal or deleterious alleles that decrease yeast fitness. LOH was not detected in genetically stable wine yeasts during must fermentation. However, after sporulation, the heterozygosity of the new yeast population decreased during must fermentation. The frequency of mating between just-germinated haploid cells from different tetrads was very low, and the mating of haploid cells from the same ascus was favored because of the physical proximity. Also, mating restriction between haploid cells from the same ascus was found, leading to a very low frequency of self spore clone mating. This mating restriction slowed down the LOH process of the yeast population, maintaining the heterozygote frequency higher than would be expected assuming a fully random mating of the haploid yeasts or according to the Mortimer genome renewal proposal. The observed LOH occurs because of the linkage of the locus MAT to the chromosome III centromere, without the necessity for self spore clone mating or the high frequency of gene conversion and rapid asymmetric LOH observed in genetically unstable yeasts. This phenomenon is enough in itself to explain the high level of homozygosis found in natural populations of wine yeasts. The LOH process for centromere-linked markers would be slower than that for the nonlinked markers, because the linkage decreases the frequency of newly originated heterozygous yeasts after each round of sporulation and mating. This phenomenon is interesting in yeast evolution and may cause important sudden phenotype changes in genetically stable wine yeasts.     

Mating reaction in Saccharomyces cerevisiae. X Agglutinability-inactivating factor: A factor which destroys sexual agglutinability of a mating-type cells

From cells of Saccharomyces cerevisiae a factor has been extracted that destroys the agglutinability of a mating-type cells specifically. It was found in the cell extracts of diploid and tetraploid strains as well as haploid strains of a and mating types. It is heat-labile and the molecular weight is about 50000. It is adsorbed by neither a cells nor cells. Its biological activity is dependent on the incubation temperature and the pH, and is completely inhibited by phenylmethylsulfonyl fluoride, a potent inhibitor of the serine proteases. All the results described in this paper indicate that this factor is a proteolytic enzyme.     

New Potential Cell Wall Glucanases of Saccharomyces cerevisiae and Their Involvement in Mating

Biotinylation of intact Saccharomyces cerevisiae cells with a nonpermeant reagent (Sulfo-NHS-LC-Biotin) allowed the identification of seven cell wall proteins that were released from intact cells by dithiothreitol (DTT). By N-terminal sequencing, three of these proteins were identified as the known proteins β-exoglucanase 1 (Exg1p), β-endoglucanase (Bgl2p), and chitinase (Cts1p). One protein was related to the PIR protein family, whereas the remaining three (Scw3p, Scw4p, and Scw10p [for soluble cell wall proteins]) were found to be related to glucanases. Single knockouts of these three potential glucanases did not result in dramatic phenotypes. The double knockout of SCW4 and the homologous gene SCW10 resulted in slower growth, significantly increased release of proteins from intact cells by DTT, and highly decreased mating efficiency when these two genes were disrupted in both mating types. The synergistic behavior of the disruption of SCW4 and SCW10 was partly antagonized by the disruption of BGL2. The data are discussed in terms of a possible counterplay of transglucosidase and glucosidase activities.     

Prm1 Targeting to Contact Sites Enhances Fusion during Mating in Saccharomyces cerevisiae

Prm1 is a pheromone-regulated membrane glycoprotein involved in the plasma membrane fusion event of Saccharomyces cerevisiae mating. Although this function suggests that Prm1 should act at contact sites in pairs of mating yeast cells where plasma membrane fusion occurs, only a small percentage of the total Prm1 was actually detected on the plasma membrane. We therefore investigated the intracellular transport of Prm1 and how this transport contributes to cell fusion. Two Prm1 chimeras that were sorted away from the contact site had reduced fusion activity, indicating that Prm1 indeed functions at contact sites. However, most Prm1 is located in endosomes and other cytoplasmic organelles and is targeted to vacuoles for degradation. Mutations in a putative endocytosis signal in a cytoplasmic loop partially stabilized the Prm1 protein and caused it to accumulate on the plasma membrane, but this endocytosis mutant actually had reduced mating activity. When Prm1 was expressed from a galactose-regulated promoter and its synthesis was repressed at the start of mating, vanishingly small amounts of Prm1 protein remained at the time when the plasma membranes came into contact. Nevertheless, this stable pool of Prm1 was retained at polarized sites on the plasma membrane and was sufficient to promote plasma membrane fusion. Thus, the amount of Prm1 expressed in mating yeast is far in excess of the amount required to facilitate fusion.Membrane fusion has been studied extensively in the context of viral infection and intracellular membrane fusion. These fusion events are mediated by fusases—proteins that mediate membrane fusion. Some of the best-studied fusases are the SNAREs (soluble N-ethylmaleimide-sensitive factors) that mediate fusion of intracellular organelles and the hemagglutinin (HA) protein of influenza virus that mediates fusion of the viral envelope membrane with host endosomes (13). However, little is known about how the plasma membranes of two cells fuse during cell fusion.Cell fusion is essential for the development of multicellular organisms. Some cell fusion processes involve a single pair of cells, as in sperm-egg fusion. Many other developmental processes require multiple fusion events, as in fusion of myoblasts for muscle formation. However, all fusion events must overcome a common obstacle—maintaining the integrity and selective permeability of the two plasma membranes while fusing the hydrophobic cores of their phospholipid bilayers.We study cell fusion in mating pairs of the yeast Saccharomyces cerevisiae. This organism offers a genetically tractable model amenable to many biochemical and cell biological assays. The mating pathway in yeast is comprised of 5 steps: pheromone signaling, adhesion, degradation of the intervening cell walls, plasma membrane fusion, and karyogamy. S. cerevisiae has two haploid mating types: MATa and MATα. Haploid cells secrete pheromones that bind to G-protein-coupled receptors on the surface of cells of the opposite mating type. Pheromone binding activates a signaling cascade that causes cell cycle arrest, expression of pheromone-inducible genes, and polarized growth to form a mating projection (or shmoo tip). The binding of two cells of opposite mating type to form a mating pair is mediated by complementary agglutinins located on the shmoo tips. Then, the cell walls of the two cells are joined to form a unified wall protecting the mating pair, and the walls between the two cells are degraded. This allows the plasma membranes to come into contact and fuse. The initial fusion pore between cells expands to allow cytoplasmic mixing and, ultimately, karyogamy. After mating is complete, the mitotic cell cycle resumes, and a diploid daughter cell buds from the neck connecting the two parent cells (5, 30).This work focuses on Prm1, a glycoprotein that promotes the plasma membrane fusion step of mating. PRM1 was discovered in a bioinformatic screen designed to identify Prm (pheromone-regulated membrane) proteins (11). Prm1 has four transmembrane domains and functions as a disulfide-linked dimer (20). Prm1-deficient mating pairs experience one of three fates: arrest as late prezygotes (unfused mating pairs with no intervening cell walls), lysis once their plasma membranes come into contact, or fusion. Electron microscopy revealed that the two plasma membranes in a late prezygote were only ∼8 nm apart but did not fuse. Additional studies showed that ∼30% of prm1Δ mating pairs lyse after membrane contact (1, 14). However, 50% of prm1Δ mating pairs fuse on standard yeast extract-peptone-dextrose (YPD) medium, implying that Prm1 is important, but not required, for fusion. Mating becomes more dependent upon Prm1 activity if Ca²⁺ or ergosterol is limiting (1, 15).On the basis of its apparent role in membrane fusion, Prm1 should be targeted to the contact sites where membranes fuse. Surprisingly, only a small amount of Prm1 was found at contact sites, and even less was at shmoo tips or at bud tips in mitotic cells expressing Prm1 from a constitutive promoter. These observations prompted further investigation of Prm1''s intracellular transport. The results revealed that Prm1 does indeed function at contact sites. However, except for the small pool that promotes fusion, Prm1 proteins are transported to vacuoles and rapidly degraded.     

Mating Reaction in Saccharomyces cerevisiae. IV. Retardation of Deoxyribonucleic Acid Synthesis

When a and a type haploid cells of Saccharomyces cere-visiae were mixed and cultured, deoxyribonucleic acid synthesis was retarded but ribonucleic acid and protein syntheses were not. It was found that culture filtrate of a type cells inhibited deoxyribonucleic acid synthesis of a type cells and that of a type cells inhibited that of a type cells. Thus, sex-specific diffusible substances secreted by opposite mating type cells are thought, at least partly, to be responsible for the retardation of deoxyribonucleic acid synthesis.     

Reaction Order of Saccharomyces cerevisiae Alpha-Factor-Mediated Cell Cycle Arrest and Mating Inhibition

Alpha-factor-mediated cell cycle arrest and mating inhibition of a mating-type cells of Saccharomyces cerevisiae have been examined in liquid cultures. Cell cycle arrest may be monitored unambiguously by the appearance of morphologically abnormal cells after administration of alpha factor, whereas mating inhibition is determined by comparing the mating efficiency in the absence or presence of added alpha factor. For both cell cycle arrest and mating inhibition, a dose-dependent response may be observed at limiting concentrations of the pheromone. If cell cycle arrest and mating inhibition require a small number of alpha-factor molecules, one might expect that responsive/nonresponsive cells = K(alpha factor)(N) where N is the order of dependence of cell cycle arrest (or mating inhibition) on alpha-factor concentration. The value of N has been determined to be 0.98 +/- 0.18 (standard error of the mean) for cell cycle arrest and 1.08 +/- 0.32 for mating inhibition. These results support the notion that saturation of a single site by alpha factor is sufficient to cause cell cycle arrest or mating inhibition of a mating-type cells.     

The Mating System in Saccharomyces

Many, but not all, Saccharomyces species are heterothallic.The mating types in heterothallic species are determined bytwo allelic genes. The mating-type genes occasionally mutatefrom one to the other. Vegetative cells of opposite mating typewere found in some single ascospore colonies. They show conjugationtubes, stimulated by the proximity of cells of the other matingtype. The cultures alao show zygotes, which on sporulation yieldplus(+) and minus(–) progenies. The zygotes bud off diploid vegetative cells which grow fasterthan the original haploid cells and so tend to replace them.If mutation occurs early, replacement is complete and the culturegives no mating reaction but sporulates. If it occurs late,the culture is a mixture of haploid cells giving a mating reactionand diploid cells that will sporulate.     

Conserved WCPL and CX4C Domains Mediate Several Mating Adhesin Interactions in Saccharomyces cerevisiae

Several adhesins are induced by pheromones during mating in Saccharomyces cerevisiae, including Aga1p, Aga2p, Sag1p (Agα1p), and Fig2p. These four proteins all participate in or influence a well-studied agglutinin interaction mediated by Aga1p–Aga2p complexes and Sag1p; however, they also play redundant and essential roles in mating via an unknown mechanism. Aga1p and Fig2p both contain repeated, conserved WCPL and CX₄C domains. This study was directed toward understanding the mechanism underlying the collective requirement of agglutinins and Fig2p for mating. Apart from the well-known agglutinin interaction between Aga2p and Sag1p, three more pairs of interactions in cells of opposite mating type were revealed by this study, including bilateral heterotypic interactions between Aga1p and Fig2p and a homotypic interaction between Fig2p and Fig2p. These four pairs of adhesin interactions are collectively required for maximum mating efficiency and normal zygote morphogenesis. GPI-less, epitope-tagged forms of Aga1p and Fig2p can be co-immunoprecipitated from the culture medium of mating cells in a manner dependent on the WCPL and CX₄C domains in the R1 repeat of Aga1p. Using site-directed mutagenesis, the conserved residues in Aga1p that interact with Fig2p were identified. Aga1p is involved in two distinct adhesive functions that are independent of each other, which raises the possibility for combinatorial interactions of this protein with its different adhesion receptors, Sag1 and Fig2p, a property of many higher eukaryotic adhesins.     

Biogenesis of the Saccharomyces cerevisiae Pheromone a-Factor,from Yeast Mating to Human Disease

Summary: The mating pheromone a-factor secreted by Saccharomyces cerevisiae is a farnesylated and carboxylmethylated peptide and is unusually hydrophobic compared to other extracellular signaling molecules. Mature a-factor is derived from a precursor with a C-terminal CAAX motif that directs a series of posttranslational reactions, including prenylation, endoproteolysis, and carboxylmethylation. Historically, a-factor has served as a valuable model for the discovery and functional analysis of CAAX-processing enzymes. In this review, we discuss the three modules comprising the a-factor biogenesis pathway: (i) the C-terminal CAAX-processing steps carried out by Ram1/Ram2, Ste24 or Rce1, and Ste14; (ii) two sequential N-terminal cleavage steps, mediated by Ste24 and Axl1; and (iii) export by a nonclassical mechanism, mediated by the ATP binding cassette (ABC) transporter Ste6. The small size and hydrophobicity of a-factor present both challenges and advantages for biochemical analysis, as discussed here. The enzymes involved in a-factor biogenesis are conserved from yeasts to mammals. Notably, studies of the zinc metalloprotease Ste24 in S. cerevisiae led to the discovery of its mammalian homolog ZMPSTE24, which cleaves the prenylated C-terminal tail of the nuclear scaffold protein lamin A. Mutations that alter ZMPSTE24 processing of lamin A in humans cause the premature-aging disease progeria and related progeroid disorders. Intriguingly, recent evidence suggests that the entire a-factor pathway, including all three biogenesis modules, may be used to produce a prenylated, secreted signaling molecule involved in germ cell migration in Drosophila. Thus, additional prenylated signaling molecules resembling a-factor, with as-yet-unknown roles in metazoan biology, may await discovery.     

Effect of concanavalin A on the mating reaction in Saccharomyces cerevisiae

The effect of concanavalin A (Con A) on the process of massmating of Saccharomyces cereoisiae was studied. Sexual agglutinationwas repressed by Con A at concentrations of 400 µg/mland 500 µg/ml, but zygote formation was little affectedat these concentrations. The action of Con A was antagonizedspecifically by -methyl-D-mannoside. We compared the mode ofinhibitory action on sexual agglutination of Con A with thatof agglutination substances, cell surface glycoproteins responsiblefor sexual agglutination. The agglutination substances inhibitedthe formation of small cell aggregates consisting of less thanfifty cells thought to be necessary for the formation of zygotes.Con A, on the contrary did not inhibit the formation of smallaggregates, but inhibited the formation of large cell aggregatesconsisting of more than hundred cells by interfering with thefusion of small cell aggregates. Univalent Con A inhibited isoagglutination caused by high concentrationsof native Con A. Specific binding of Con A to the cell surfacewas observed by using fluorescent Con A. A procedure to prepareunivalent Con A using Enzygel, a trypsin-Sepharose conjugantis described. ¹ On leave from Osaka City University. ² Present address: Department of Physiology, Japan Women's University,Bunkyo-ku, Tokyo 112, Japan. (Received March 28, 1978; )     

Saccharomyces cerevisiae

Yeast prions are infectious proteins that spread exclusively by mating. The frequency of prions in the wild therefore largely reflects the rate of spread by mating counterbalanced by prion growth slowing effects in the host. We recently showed that the frequency of outcross mating is about 1% of mitotic doublings with 23–46% of total matings being outcrosses. These findings imply that even the mildest forms of the [PSI+], [URE3] and [PIN+] prions impart > 1% growth/survival detriment on their hosts. Our estimate of outcrossing suggests that Saccharomyces cerevisiae is far more sexual than previously thought and would therefore be more responsive to the adaptive effects of natural selection compared with a strictly asexual yeast. Further, given its large effective population size, a growth/survival detriment of > 1% for yeast prions should strongly select against prion-infected strains in wild populations of Saccharomyces cerevisiae.     

Mating reaction inSaccharomyces cerevisiae VIII. Mating-type-specific substances responsible for sexual cell agglutination

The agglutination factors ofa and α mating types ofSaccharomyces cerevisiae were solubilized from isolated cell-wall fractions by treatment with snail enzyme (Glusulase) and shown to be adsorbed specifically by cells of the opposite mating type, resulting in the loss of agglutinability of these cells. The agglutination factors ofa and α types adsorbed by cells of the opposite mating type at pH 5.5 were eluted at pH 9.0. These factors were further purified on Sepharose 4B. From the elution pattern on Sepharose 4B, the molecular weights of the solubilized agglutination factors are estimated to be about one million. Thus purified agglutination factors contained carbohydrate and protein and were considerably resistant to heat treatment. Neutral protease ofBacillus subtilis inactivated botha and α type agglutination factors. Trypsin inactivated the α type agglutination factor only.     

Mating ability during chemically induced G1 arrest of cells of the yeast Saccharomyces cerevisiae

Diploid formation by haploid cells of Saccharomyces cerevisiae was tested during and after treatment with chemical agents which bring about arrest at the cell cycle regulatory step "start." All compounds, except sinefungin, allowed efficient mating. During sinefungin treatment, zygote formation, but not karyogamy, was affected.