Multiple regulation of STE2, a mating-type-specific gene of Saccharomyces cerevisiae

G-protein-coupled Receptors in Fungi

G-protein-coupled receptors (GPCRs) are the largest family of transmembrane receptors in fungi. These receptors have an important role in the transduction of extracellular signals into intracellular sites in response to diverse stimuli. They enable fungi to coordinate cell function and metabolism, thereby promoting their survival and propagation, and sense certain fundamentally conserved elements, such as nutrients, pheromones, and stress, for adaptation to their niches, environmental stresses, and host environment, causing disease and pathogen virulence. This chapter highlights the role of GPCRs in fungi in coordinating cell function and metabolism. Fungal cells sense the molecular interactions between extracellular signals. Their respective sensory systems are described here in detail.

Tracking yeast pheromone receptor Ste2 endocytosis using fluorogen-activating protein tagging

To observe internalization of the yeast pheromone receptor Ste2 by fluorescence microscopy in live cells in real time, we visualized only those molecules present at the cell surface at the time of agonist engagement (rather than the total cellular pool) by tagging this receptor at its N-terminus with an exocellular fluorogen-activating protein (FAP). A FAP is a single-chain antibody engineered to bind tightly a nonfluorescent, cell-impermeable dye (fluorogen), thereby generating a fluorescent complex. The utility of FAP tagging to study trafficking of integral membrane proteins in yeast, which possesses a cell wall, had not been examined previously. A diverse set of signal peptides and propeptide sequences were explored to maximize expression. Maintenance of the optimal FAP-Ste2 chimera intact required deletion of two, paralogous, glycosylphosphatidylinositol (GPI)-anchored extracellular aspartyl proteases (Yps1 and Mkc7). FAP-Ste2 exhibited a much brighter and distinct plasma membrane signal than Ste2-GFP or Ste2-mCherry yet behaved quite similarly. Using FAP-Ste2, new information was obtained about the mechanism of its internalization, including novel insights about the roles of the cargo-selective endocytic adaptors Ldb19/Art1, Rod1/Art4, and Rog3/Art7.

Creation of Stable Heterothallic Strains of Komagataella phaffii Enables Dissection of Mating Gene Regulation

The methylotrophic yeast Komagataella phaffii (Pichia pastoris) is homothallic and has been reported to switch mating type by an ancient inversion mechanism. Two mating-type (MAT) loci include homologs of the MATa and MATα transcription factor genes, with the expression from one locus downregulated by telomere position effects. However, not much is known about mating gene regulation, since the mixture of mating types complicates detailed investigations. In this study, we developed K. phaffii strains with stable mating types by deletion of the inverted-repeat region required for mating-type switching. These heterothallic strains retain their ability to mate with cells of the opposite mating type and were used to further elucidate mating gene regulation. Functional analysis of MAT mutant strains revealed the essential role of MATa2 and MATα1 in diploid cell formation. Disruption of MATa1 or MATα2 did not affect mating; however, in diploid cells, both genes are required for sporulation and the repression of shmoo formation. The heterothallic strains generated in this study allowed the first detailed characterization of mating gene regulation in K. phaffii They will be a valuable tool for further studies investigating cell-type-specific behavior and will enable in-depth genetic analyses and strain hybridization in this industrially relevant yeast species.

Dissection of quantitative traits by bulk segregant mapping in a protoploid yeast species

Since more than a decade ago, Saccharomyces cerevisiae has been used as a model to dissect complex traits, revealing the genetic basis of a large number of traits in fine detail. However, to have a more global view of the genetic architecture of traits across species, the examination of the molecular basis of phenotypes within non-conventional species would undoubtedly be valuable. In this respect, the Saccharomycotina yeasts represent ideal and potential non-model organisms. Here we sought to assess the feasibility of genetic mapping by bulk segregant analysis in the protoploid Lachancea kluyveri (formerly S. kluyveri) yeast species, a distantly related species to S. cerevisiae For this purpose, we designed a fluorescent mating-type marker, compatible with any mating-competent strains representative of this species, to rapidly create a large population of haploid segregants (>10(5) cells). Quantitative trait loci can be mapped by selecting and sequencing an enriched pool of progeny with extreme phenotypic values. As a test bed, we applied this strategy and mapped the causal loci underlying halotolerance phenotypes in L. kluyveri Overall, this study demonstrates that bulk segregant mapping is a powerful way for investigating the genetic basis of natural variations in non-model yeast organisms and more precisely in L. kluyveri.

Positive and negative regulatory elements control expression of the yeast retrotransposon Ty3

We report the results of an analysis of Ty3 transcription and identification of Ty3 regions that mediate pheromone and mating-type regulation to coordinate its expression with the yeast life cycle. A set of strains was constructed which was isogenic except for the number of Ty3 elements, which varied from zero to three. Analysis of Ty3 expression in these strains showed that each of the three elements was transcribed and that each element was regulated. Dissection of the long terminal repeat regulatory region by Northern blot analysis of deletion mutants and reporter gene analysis showed that the upstream junction of Ty3 with flanking chromosomal sequences contained a negative control region. A 19-bp fragment (positions 56-74) containing one consensus copy and one 7 of 8-bp match to the pheromone response element (PRE) consensus was sufficient to mediate pheromone induction in either haploid cell type. Deletion of this region, however, did not abolish expression, indicating that other sequences also activate transcription. A 24-bp block immediately downstream of the PRE region contained a sequence similar to the a1-alpha 2 consensus that conferred mating-type control. A single base pair mutation in the region separating the PRE and a1-alpha 2 sequences blocked pheromone induction, but not mating-type control. Thus, the long terminal repeat of Ty3 is a compact, highly regulated, mobile promoter which is responsive to cell type and mating.

Honest signalling among gametes

The gametes of many lower eukaryotic organisms emit pheromones that attract gametes of the opposite mating type or sex. Gametes move or grow in the direction of the highest pheromone concentration, suggesting that the strength of the pheromonal signal is used to infer proximity, or that the strongest signal is most likely to be notice. Here I offer a new explanation of pheromonal signalling and chemotaxis in gametes. I show that pheromonal signals can be interpreted as sexually selected traits that honestly advertise variation in quality among gametes, given that signals are costly to produce and that gametes compete; by 'quality' I refer to some aspect of a gamete's fitness. A gamete's preference for a mating partner, then, is predicted to vary with the quality of a prospective partner as inferred from the strength of its signal. This view can explain characteristics of the signalling and mate selection behaviours of gametes that are not predicted by models of mate choice based on proximity or 'passive attraction' to the strongest signal. These include repeated partner exchanges, escalated exchanges of mating pheromones, and rejection of gametes that signal at low levels.

The pheromone signal pathway in Saccharomyces cerevisiae

Haploid cells of the yeast Saccharomyces cerevisiae normally undergo a budding life cycle, but after binding the appropriate mating pheromone they undergo a different developmental pathway that leads to conjugation. This intercellular communication between the two mating types activates a signal transduction pathway that stimulates the diverse physiological changes required for conjugation, such as induction of cell surface agglutinins, cell division arrest in G1, morphogenesis to form a conjugation tube, and cell fusion. The components of this pathway include a G protein-coupled receptor, several protein kinases, and a pheromone-responsive transcription factor. The molecular mechanisms that transduce the pheromone signal are remarkably similar to the mechanisms of hormone signaling used in multicellular organisms. Thus, the analysis of the pheromone signal pathway in yeast directly contributes to the study of cell growth and development in other eukaryotic organisms.

Relative contributions of MCM1 and STE12 to transcriptional activation of a- and alpha-specific genes from Saccharomyces cerevisiae

We have examined the relative contributions of MCM1 and STE12 to the transcription of the a-specific STE2 gene by using a 367 bp fragment from the STE2 5'-noncoding region to drive expression of a reporter lacZ gene. Mutation of the MCM1 binding site destroyed MCM1.alpha 2-mediated repression in alpha cells and dramatically reduced expression in a cells. The residual expression was highly stimulated by exposure of cells to pheromone. Likewise, the loss of STE12 function reduced lacZ expression driven by the wild-type STE2 fragment. In the absence of both MCM1 and STE12 functions, no residual expression was observed. Thus, the STE2 fragment appears to contain two distinct upstream activation sequences (UASs), one that is responsible for the majority of expression in cells not stimulated by pheromone, and one that is responsible for increased expression upon pheromone stimulation. In further support of this idea, a chemically synthesized version of the STE2 MCM1 binding site had UAS activity, but the activity was neither stimulated by pheromone nor reduced in ste12 mutants. Although transcription of alpha-specific genes also requires both MCM1 and STE12, these genes differ from a-specific genes in that they have a single, MCM1-dependent UAS system. The activity of the minimal 26 bp UAS from the alpha-specific STE3 gene was both stimulated by pheromone and reduced in ste12 mutants. These data suggest that at alpha-specific genes STE12 and MCM1 exert their effects through a single UAS.

Pheromone-induced phosphorylation of a G protein beta subunit in S. cerevisiae is associated with an adaptive response to mating pheromone

The mating pheromone response in S. cerevisiae is activated by a G protein-mediated signaling pathway in which G beta gamma is the active transducer of the signal. When exogenous pheromone is added to vegetatively growing cells, G beta is rapidly phosphorylated at several sites; phosphorylation does not require de novo protein synthesis. A mutation in G beta was constructed that eliminates signal-induced phosphorylation. This mutation leads to enhanced sensitivity to and impaired ability to recover from pheromone, but does not affect the ability of G beta gamma to transmit the mating signal. These phenotypes suggest that G protein phosphorylation mediates an adaptive response to pheromone-induced signaling. G beta phosphorylation does not require either the pheromone receptor C-terminus or the product of the SST2 gene, both of which mediate separate adaptive responses to pheromone. However, G beta phosphorylation is greatly facilitated by the presence of the G alpha subunit, which has also been shown to participate in an adaptation to pheromone.

DNA binding-induced conformational change of the yeast transcriptional activator PRTF

Our studies using proteases to probe protein structure establish that binding to the upstream activating sequences (UASs) of two different yeast a-specific genes induces a conformational change in the pheromone/receptor transcription factor (PRTF), which is not observed upon binding to the UASs of either of two alpha-specific genes. We propose that this selective structural alteration exposes an activation region of PRTF when it binds a-specific genes, switching these genes on. The transcriptional activator MAT alpha 1 may activate alpha-specific genes by binding to the PRTF-alpha-specific UAS complex and unmasking the otherwise hidden activation surface of PRTF. We also show that the N-terminal third of PRTF is sufficient for specific DNA binding, while the middle third of the protein interacts with MAT alpha 1.

A regulatory hierarchy for cell specialization in yeast

The specialized sets of genes that determine different cell types in yeast are controlled by combinations of DNA-binding proteins some of which are present only in certain cell types whereas others are present in all cell types. Final differentiation requires an inductive signal that triggers both gene transcription and cell-cycle arrest. Synthesis of the proteins coded by the 'master regulatory' mating-type locus is regulated so as to generate a heterogeneous mitotic cell population containing a stem-cell lineage.

Epigenetic inheritance of transcriptional states in S. cerevisiae

SIR1, one of several genes required for repression of yeast silent mating type loci, has a unique role in repression of the HML alpha locus. Single-cell assays revealed that cells with mutant alleles of SIR1, including presumptive null alleles, existed as populations of genetically identical cells whose members were in one of two different regulatory states. A minority of cells had a repressed HML alpha locus whereas the majority had a derepressed HML alpha locus. The two states were mitotically stable, although rare changes in state were observed during mitotic growth, possibly reflecting heritable changes to the HML alpha locus at or before replication. Analysis of changes in state suggests that SIR1 protein has a role in the establishment but not the maintenance of repression of silent mating type genes, whereas SIR2, SIR3, and SIR4 are required for maintenance.

N alpha acetylation is required for normal growth and mating of Saccharomyces cerevisiae

Acetylation is the most frequently occurring chemical modification of the alpha-NH2 group of eucaryotic proteins and is catalyzed by N alpha-acetyltransferase. The yeast enzyme is encoded by the AAA1 (amino-terminal alpha-amino acetyltransferase) gene. A null mutation (aaa1-1) created by gene replacement, while not lethal, slows cell growth and results in heterogeneous colony morphology. In comparison with wild-type cells, aaa1-1/aaa1-1 diploids cannot enter stationary phase, are sporulation defective, and are sensitive to heat shock. In addition, the aaa1-1 mutation specifically reduces mating functions of MATa cells. These results indicate that N alpha acetylation plays a crucial role in yeast cell growth and mating.

Hormone-induced expression of the CHS1 gene from Saccharomyces cerevisiae

When MATa cells of Saccharomyces cerevisiae have been treated with the mating hormone alpha-factor an increase in chitin synthase zymogen, as well as chitin content in the cell-wall fraction, have been reported. With a DNA probe derived from the cloned CHS1 gene that codes for chitin synthase I [Bulawa, C. E., Slater, M., Cabib, E., Au-Young, J., Sburlati, A., Adair, W. L. and Robbins, P. (1986) Cell 46, 213-225] a Northern analysis was conducted of CHS1-specific transcripts. alpha-Factor-treated MATa cells revealed more than sixfold elevated steady-state levels of CHS1 mRNA as compared to control cells. MAT alpha cells responded the same way when treated with a-factor although induction rate was somewhat smaller. After hormone application a rapid increase in CHS1 mRNA levels could be observed that occurred also in the absence of ongoing protein synthesis. In order to minimize possible side effects of CHS1-coding sequences on expression and mRNA stability a CHS1::SUC2 chimaeric gene was constructed where 730 bp of the CHS1 promoter region (+20 bp of the coding region) were fused in frame to a fragment of the SUC2 coding region. The fusion protein exhibits invertase activity that has been used to monitor CHS1 promoter activity. By analysis of shortened versions of the CHS1 promoter a 94-bp DNA fragment has been identified that confers hormone inducibility to the CHS1 promoter. According to the published sequence of the CHS1 gene, this fragment contains four repeats of a TGAAACA consensus sequence previously identified in the alpha-factor-inducible BAR1 promoter [Kronstad, J. W., Holly, J. A. and MacKay, V. L. (1987) Cell 50, 369-377]. This heptamer may represent the cis-acting element involved in mating-hormone-mediated gene expression in yeast.

Pheromones and pheromone receptors are the primary determinants of mating specificity in the yeast Saccharomyces cerevisiae

Saccharomyces cerevisiae has two haploid cell types, a and alpha, each of which produces a unique set of proteins that participate in the mating process. We sought to determine the minimum set of proteins that must be expressed to allow mating and to confer specificity. We show that the capacity to synthesize alpha-factor pheromone and a-factor receptor is sufficient to allow mating by mat alpha 1 mutants, mutants that normally do not express any alpha- or a-specific products. Likewise, the capacity to synthesize a-factor receptor and alpha-factor pheromone is sufficient to allow a ste2 ste6 mutants, which do not produce the normal a cell pheromone and receptor, to mate with wild-type a cells. Thus, the a-factor receptor and alpha-factor pheromone constitute the minimum set of alpha-specific proteins that must be produced to allow mating as an alpha cell. Further evidence that the pheromones and pheromone receptors are important determinants of mating specificity comes from studies with mat alpha 2 mutants, cells that simultaneously express both pheromones and both receptors. We created a series of strains that express different combinations of pheromones and receptors in a mat alpha 2 background. These constructions reveal that mat alpha 2 mutants can be made to mate as either a cells or as alpha cells by causing them to express only the pheromone and receptor set appropriate for a particular cell type. Moreover, these studies show that the inability of mat alpha 2 mutants to respond to either pheromone is a consequence of two phenomena: adaptation to an autocrine response to the pheromones they secrete and interference with response to alpha factor by the a-factor receptor.

Constitutive mutants in the yeast pheromone response: ordered function of the gene products

The alpha factor pheromone inhibits the division of yeast a cells. A general method was developed for isolating mutants that exhibit constitutive activation of the pheromone response pathway. A dominant allele of the STE4 locus was recovered in addition to recessive mutations in the SCG1 gene. SCG1 and STE4 are known to encode G alpha and G beta homologs, respectively. Analysis of double mutants suggests that the STE4 gene product functions after the SCG1 product but before the STE5 product.

The STE4 and STE18 genes of yeast encode potential beta and gamma subunits of the mating factor receptor-coupled G protein

The STE4 and STE18 genes are required for haploid yeast cell mating. Sequencing of the cloned genes revealed that the STE4 polypeptide shows extensive homology to the beta subunits of mammalian G proteins, while the STE18 polypeptide shows weak similarity to the gamma subunit of transducin. Null mutations in either gene can suppress the haploid-specific cell-cycle arrest caused by mutations in the SCG1 gene (previously shown to encode a protein with similarity to the alpha subunit of G proteins). We propose that the products of the STE4 and STE18 genes comprise the beta and gamma subunits of a G protein complex coupled to the mating pheromone receptors. The genetic data suggest pheromone-receptor binding leads to the dissociation of the alpha subunit from beta gamma (as shown for mammalian G proteins), and the free beta gamma element initiates the pheromone response.

The MF alpha 1 gene of Saccharomyces cerevisiae: genetic mapping and mutational analysis of promoter elements

The activity and cell-type specificity of the promoter of the MF alpha 1 gene of Saccharomyces cerevisiae were examined by measuring expression of an MF alpha 1-SUC2 gene fusion in MATa, MAT alpha, and MATa/MAT alpha cells. A high level of invertase activity was observed only in MAT alpha cells. Weak expression occurred in MATa cells when the hybrid gene was carried on a multicopy plasmid or on a centromere-containing plasmid, but not when the hybrid gene was integrated at the normal MF alpha 1 locus. Analysis of a set of 5'-deletions of the promoter region of the MF alpha 1-SUC2 gene on the multicopy plasmid indicated that sequences from -354 to -274 upstream of the translational start site were required for high level expression in MAT alpha cells. Smaller internal deletions and insertions within the promoter region of the MF alpha 1-SUC2 gene were inserted into the genome at the normal MF alpha 1 locus. These mutations further delineated four promoter domains important for expression: (1) two 26 bp elements (-365 to -340 and -312 to -287) with imperfect dyad symmetry; (2) a 40 bp segment (-264 to -226) that lies about 120 bp upstream of the TATA box; and (3) the TATA box itself (-128 to -122). The transcriptional start sites of the normal MF alpha 1 promoter and of a mutant lacking the TATA box were determined. The MF alpha 1 locus was mapped to the left arm of chromosome XVI, about 22 cM centromere-proximal to the PEP4 gene.

Transformation of Schwanniomyces occidentalis with an ADE2 gene cloned from S. occidentalis

We have developed an efficient transformation system for the industrial yeast Schwanniomyces occidentalis (formerly Schwanniomyces castellii). The transformation system is based on ade2 mutants of S. occidentalis deficient for phosphoribosylaminoimidazole carboxylase that were generated by mutagenesis. As a selectable marker, we isolated and characterized the S. occidentalis ADE2 gene by complementation in an ade2 strain of Saccharomyces cerevisiae. S. occidentalis was transformed with the recombinant plasmid pADE, consisting of a 4.5-kilobase-pair (kbp) DNA fragment from S. occidentalis containing the ADE2 gene inserted into the S. cerevisiae expression vector pYcDE8 by a modification of the spheroplasting procedure of Beggs (J. D. Beggs, Nature [London] 275:104-108, 1978). Intact plasmids were recovered in Escherichia coli from whole-cell lysates of ADE+ transformants, indicating that plasmids were replicating autonomously. High-molecular-mass species of pADE2 were found by Southern hybridization analysis of intact genomic DNA preparations. The shift to higher molecular mass of these plasmids during electrophoresis in the presence ethidium bromide after exposure to shortwave UV suggests that they exist in a supercoiled form in the transformed host. Subclones of the 4.5-kbp insert indicated that ADE2-complementing activity and sequences conferring autonomous replication in S. occidentalis were located within a 2.7-kbp EcoRI-SphI fragment. Plasmids containing this region cloned into the bacterial vector pUC19 complemented ade2 mutants of S. occidentalis with efficiencies identical to those of the original plasmid pADE.

The carboxy-terminal segment of the yeast alpha-factor receptor is a regulatory domain

The alpha-factor receptor is rapidly hyperphosphorylated on Thr and Ser residues in its hydrophilic C-terminal domain after cells are exposed to pheromone. Mutant receptors in which this domain is altered or removed are biologically active and bind alpha-factor with nearly normal affinity. However, cells expressing the mutant receptors are hypersensitive to pheromone action and appear to be defective in recovery from alpha-factor-induced growth arrest. Mutant receptors with partial C-terminal truncations undergo ligand-induced endocytosis, suggesting that down-regulation of receptor number is not the sole process for adaptation at the receptor level. A mutant receptor lacking the entire C-terminal domain (134 residues) does not display ligand-induced endocytosis. Genetic experiments indicate that the contribution of SST2 function to adaptation does not require the C-terminal domain of the receptor.

The C-terminus of the S. cerevisiae alpha-pheromone receptor mediates an adaptive response to pheromone

STE2 encodes a component of the S. cerevisiae alpha-pheromone receptor that is essential for induction of physiological changes associated with mating. Analysis of C-terminal truncation mutants of STE2 demonstrated that the essential sequences for ligand binding and signal transduction are included within a region containing seven putative transmembrane domains. However, truncation of the C-terminal 105 amino acids of the receptor resulted in a 4- to 5-fold increase in cell-surface pheromone binding sites, a 10-fold increase in pheromone sensitivity, a defect in recovery of cell division after pheromone treatment, and a defect in pheromone-induced morphogenesis. Overproduction of STE2 resulted in about a 6-fold increase in alpha-pheromone binding capacity but did not produce the other phenotypes associated with the ste2-T326 mutant receptor. We conclude that the C-terminus of the receptor is responsible for one aspect of cellular adaptation to pheromone that is distinct from adaptation controlled by the SST2 gene, for decreasing the stability of the receptor, and for some aspect of cellular morphogenesis.

Suppressors of a gpa1 mutation cause sterility in Saccharomyces cerevisiae

The Saccharomyces cerevisiae GPA1 gene encodes a protein highly homologous to the alpha subunit of mammalian G proteins and is essential for haploid cell growth. We have selected 77 mutants able to suppress the lethality resulting from disruption of GPA1 (gpa1::HIS3). Two strains bearing either of two recessive mutations, sgp1 and sgp2, in combination with the disruption mutation, showed a cell type nonspecific sterile phenotype, yet expressed the major alpha-factor gene (MF alpha 1) as judged by the ability to express a MF alpha 1-lacZ fusion gene. The sgp1 mutation was closely linked to gpa1::HIS3 and probably occurred at the GPA1 locus. The sgp2 mutation was not linked to GPA1 and was different from the previously identified cell type nonspecific sterile mutations (ste4, ste5, ste7, ste11 and ste12). sgp2 GPA1 cells showed a fertile phenotype, indicating that the mating defect caused by sgp2 is associated with the loss of GPA1 function. While expression of a FUS1-lacZ fusion gene was induced in wild-type cells by the addition of alpha-factor, mutants bearing sgp1 or sgp2 as well as gpa1::HIS3 constitutively expressed FUS1-lacZ. These observations suggest that GPA1 (SGP1) and SGP2 are involved in mating factor-mediated signal transduction, which causes both cell cycle arrest in the late G1 phase and induction of genes necessary for mating such as FUS1.

Mutations in a gene encoding the alpha subunit of a Saccharomyces cerevisiae G protein indicate a role in mating pheromone signaling

Mutations which allowed conjugation by Saccharomyces cerevisiae cells lacking a mating pheromone receptor gene were selected. One of the genes defined by such mutations was isolated from a yeast genomic library by complementation of a temperature-sensitive mutation and is identical to the gene GPA1 (also known as SCG1), recently shown to be highly homologous to genes encoding the alpha subunits of mammalian G proteins. Physiological analysis of temperature-sensitive gpa1 mutations suggests that the encoded G protein is involved in signaling in response to mating pheromones. Mutational disruption of G-protein activity causes cell-cycle arrest in G1, deposition of mating-specific cell surface agglutinins, and induction of pheromone-specific mRNAs, all of which are responses to pheromone in wild-type cells. In addition, mutants can conjugate without the benefit of mating pheromone or pheromone receptor. A model is presented where the activated G protein has a negative impact on a constitutive signal which normally keeps the pheromone response repressed.

MAT alpha 1 protein, a yeast transcription activator, binds synergistically with a second protein to a set of cell-type-specific genes

We show by electrophoresis mobility shift and by DNAase I footprinting assays that the alpha 1 product of the yeast alpha mating-type locus binds to homologous sequences within the control regions of the three known alpha-specific genes. Binding requires both alpha 1 and a second yeast protein(s) (called PRTF) that is present in all three cell types (a, alpha, and a/alpha); neither protein binds alone. Binding and competition experiments using synthetic oligonucleotides indicate that PRTF binds to only part of the homology found at alpha-specific genes and imply that alpha 1 binds to the remainder. Our results suggest that alpha 1 renders gene expression alpha-specific by creating a binding site for PRTF. Similar experiments lead to the idea that PRTF also plays a role in transcription of a-specific genes. Perhaps a-specificity is achieved through the occlusion of the PRTF binding site by alpha 2, the negative regulator encoded by the alpha mating-type locus.

Alpha-factor inhibition of the rate of cell passage through the "start" step of cell division in Saccharomyces cerevisiae yeast: estimation of the division delay per alpha-factor.receptor complex

A highly sensitive, kinetically unambiguous assay for alpha-factor-induced delay of cell passage through the "start" step of cell division in yeast is presented. The assay employs perfusion with periodic microscopy to monitor the bud emergence kinetics on the 20% of cells within an exponentially growing population which exist prior to the alpha-factor execution point of start. The t1/2 for cell passage through start by this population of cells is 31 min in the absence of alpha-factor. The inhibition constant, KI, represents the alpha-factor concentration which produces a 50% inhibition of this rate and is equal to 2 X 10(-10) M. A second assay for maximal cell division arrest by alpha-factor on whole populations of cells is presented. This assay shows a maximum cell division arrest time of 125 +/- 5 h at saturating alpha-factor, and a K50 (that is, an alpha-factor concentration which produces a half-maximal response) of 2.5 X 10(-8) M. Both assays were performed in the effective absence of alpha-factor inactivation. Values of the dissociation constant KD and total number of receptors per cell which specifically mediate cell division arrest or delay were estimated to be 2.5 X 10(-8) M and 10(4), respectively. These estimates, along with the quantitative dose-response data for division arrest which are presented here, are consistent with each receptor.alpha-factor complex which is present on the cell at equilibrium producing a 43 +/- 10 s delay of cell passage through start. Surprisingly, this number is constant within twofold over the entire range of cellular division arrest responses to alpha-factor, that is, from a 1.9-fold inhibition of the rate of cell passage through start at 0.17 nM alpha-factor to a 125 +/- 5 h maximum arrest at saturating alpha-factor concentrations of greater than 170 nM. The possible significance of this observation toward the mechanism of alpha-factor-induced cell division arrest is discussed.

A yeast operator overlaps an upstream activation site

The product of the BAR1 gene of Saccharomyces cerevisiae is synthesized only in the a cell type and inactivates alpha-factor, the mating pheromone made by alpha cells. The MAT alpha 2 protein represses the transcription of a-cell-specific genes, including BAR1, in alpha and a/alpha diploid cells. Transcription of BAR1 in a cells in stimulated upon exposure to alpha-factor. Deletion analysis of the 5' noncoding region of the BAR1 gene revealed that the major upstream activation site (UAS) overlaps the 31 bp operator sequence required for MAT alpha 2 repression. This result has implications for the negative control of transcription in yeast. The deletion analysis also indicated that the sequence TGAAACA mediates alpha-factor stimulation.

Yeast peptide pheromones, a-factor and alpha-factor, activate a common response mechanism in their target cells

We show that in yeast the cell type specificity of pheromone response is determined solely by the species of receptor that a cell synthesizes. The two receptor-pheromone interactions are functionally interchangeable and involve the creation of a common intracellular signal. In particular, we find that provision of a-factor receptor or alpha-factor receptor in mat alpha 1 mutants, which normally do not express either receptor or any other a- or alpha-specific products, allows response to the appropriate pheromone. Moreover, provision of a-factor receptor in a cells lacking alpha-factor receptor restores mating competence to those cells. Finally, an aspect of pheromone response that is normally unique to a-factor action on alpha cells--increased transcription from the alpha-specific STE3 gene--can also be observed following alpha-factor treatment of pseudo-a cells (mat alpha 2 ste3 ste13), special mutants that respond to alpha-factor and also have an active STE3 promoter.