The STE2 gene product is the ligand-binding component of the alpha-factor receptor of Saccharomyces cerevisiae

The STE2 gene of Saccharomyces cerevisiae encodes a 431-residue protein containing seven hydrophobic segments that is thought to be an essential component of the cell-surface receptor for alpha-factor in MATa haploids. Methods were devised to prepare membrane fractions from MATa cells that retained high levels of alpha-factor binding activity, consistent with the view that the alpha-factor receptor resides in the plasma membrane. To demonstrate that the membrane constituent responsible for alpha-factor binding was the STE2 polypeptide, specific antibodies were generated and used to identify STE2-related polypeptides by radiolabeling, immunoprecipitation, and polyacrylamide gel electrophoresis. Under conditions of complete solubilization, the major form of the STE2 gene product detected was a glycoprotein with an apparent molecular weight of 49,000. Affinity labeling of yeast membrane preparations by chemical cross-linking to 35S-alpha-factor indicated that a molecule of 49,000 molecular weight was the major alpha-factor-binding species. This alpha-factor-binding species was shown to be the product of the STE2 gene in three ways. First, MATa haploids carrying the STE2 gene on a multicopy plasmid overproduced alpha-factor binding activity about 15-fold. Second, MATa cells completely lacking a STE2 gene showed only nonspecific binding of alpha-factor (equivalent to the level displayed by MAT alpha haploids) and possessed no species that could be cross-linked to 35S-alpha-factor. Third, MATa cells expressing a truncated but functional STE2 gene (in which the COOH-terminal 135-hydrophilic residues were deleted) produced a protein detected by cross-linking to 35S-alpha-factor of apparent molecular weight 33,000, close to the size expected for the predicted abbreviated STE2 polypeptide. These findings demonstrate unequivocally that the STE2 gene product is the membrane component responsible for the ligand recognition function of the yeast alpha-factor receptor.     

The Daf2-2 Mutation, a Dominant Inhibitor of the Ste4 Step in the α-Factor Signaling Pathway of Saccharomyces Cerevisiae Matα Cells

A dominant mutation (DAF2-2) resulting in resistance to the mating pheromone alpha-factor in Saccharomyces cerevisiae MATa cells was identified and characterized genetically. Whereas wild-type cells induce a high level of the FUS1 mRNA from a low baseline on exposure to alpha-factor, DAF2-2 cells were constitutive producers of an intermediate level of FUS1 RNA; the level was increased only modestly by alpha-factor. FUS1 constitutivity required STE4, STE5 and STE18, but did not require STE2, the alpha-factor receptor gene. DAF2-2 suppressed the alpha-factor supersensitivity of a STE2 C-terminal truncation, and suppressed lethality due to scg1 mutations. Thus DAF2-2 may act by uncoupling the signaling pathway from alpha-factor binding at some point in the pathway between Scg1 inactivation and the action of Ste4, Ste5 and Ste18; this uncoupling might occur at the expense of partial constitutive activation of the pathway. DAF2-2 suppressed the unconditional cell-cycle arrest phenotype of a dominant "constitutive signaling" allele of STE4 (STE4Hpl), although the constitutive FUS1 phenotype of DAF2-2 was suppressed by ste4 null mutations; therefore DAF2-2 may directly affect the performance of the STE4 step.     

The yeast alpha-factor receptor: structural properties deduced from the sequence of the STE2 gene.

The STE2 gene of the yeast Saccharomyces cerevisiae encodes a component of the receptor for the oligopeptide pheromone alpha-factor. We have cloned and determined the nucleotide sequence of the STE2 gene. A sequence involved in the control of cell-type expression of the STE2 gene was found 5' of an open reading frame that could encode a protein of 431 amino acids. The predicted STE2 protein contains seven hydrophobic segments, suggesting that the alpha-factor receptor is an integral membrane protein. No extensive homology at the primary sequence level was detected between the predicted STE2 protein and other available protein sequences.     

A fluorescent alpha-factor analogue exhibits multiple steps on binding to its G protein coupled receptor in yeast

The yeast alpha-factor receptor encoded by the STE2 gene is a member of the extended family of G protein coupled receptors (GPCRs) involved in a wide variety of signal transduction pathways. We report here the use of a fluorescent alpha-factor analogue [K(7)(NBD), Nle(12)] alpha-factor (Lys(7) (7-nitrobenz-2-oxa-1,3-diazol-4-yl), norleucine(12) alpha-factor) in conjunction with flow cytometry and fluorescence microscopy to study binding of ligand to the receptor. Internalization of the fluorescent ligand following receptor binding can be monitored by fluorescence microscopy. The use of flow cytometry to detect binding of the fluorescent ligand to intact yeast cells provides a sensitive and reproducible assay that can be conducted at low cell densities and is relatively insensitive to fluorescence of unbound and nonspecifically bound ligand. Using this assay, we determined that some receptor alleles expressed in cells lacking the G protein alpha subunit exhibit a higher equilibrium binding affinity for ligand than the same alleles expressed in isogenic cells containing the normal complement of G protein subunits. On the basis of time-dependent changes in the intensity and shape of the emission spectrum of [K(7)(NBD),Nle(12)] alpha-factor during binding, we infer that the ligand associates with receptors via a two-step process involving an initial interaction that places the fluorophore in a hydrophobic environment, followed by a conversion to a state in which the fluorophore moves to a more polar environment.     

Down regulation of the alpha-factor pheromone receptor in S. cerevisiae

The peptide pheromone, alpha-factor, was found to elicit down regulation of receptor sites on yeast a cell targets. Cellular uptake of alpha-factor accompanied the loss of receptor sites. Receptor-deficient a cells bearing a deletion of the STE2 gene were unable to internalize alpha-factor. Cultures were found to reaccumulate receptor sites following the initial period of down regulation; reaccumulation was dependent upon protein synthesis. Pheromone-resistant mutants, ste4-3 and ste5-3, retained the ability to down regulate receptors but failed to show reaccumulation. Our results suggest that alpha-factor-receptor complexes enter the cell by receptor-mediated endocytosis and that receptors are continuously lost and resynthesized in the presence of alpha-factor. We found no reduction of alpha-factor binding capacity in a cell cultures that had adapted to alpha-factor.     

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.     

Yeast alpha-mating factor receptor and G-protein-linked adenylyl cyclase inhibition requires RAS2 and GPA2 activities.

Saccharomyces cerevisiae expresses two RAS gene products (RAS1 and RAS2) highly homologous to mammalian p21ras which mediate glucose-stimulated cyclic-AMP formation. Mating pheromone inhibits RAS-linked adenylyl cyclase activation and this is dependent upon the alpha-factor receptor (STE2) and its associated G-protein beta-subunit (STE4). We now show that this pheromone effect is independent of mating pathway signalling components "downstream" of STE4 but displays an absolute requirement for an additional G-protein alpha-subunit encoded by GPA2. alpha-mating factor effects also involve a specific suppression of normal RAS2 activity as the constitutively activated mutant RAS2vall9 as well as wild type. RAS1 are insensitive to inhibition. Interaction between GPA2, STE4-STE18, RAS2 and adenylyl cyclase in yeast could give important insight into signalling pathways controlling normal and oncogenic p21ras activity in man.     

The third cytoplasmic loop of a yeast G-protein-coupled receptor controls pathway activation, ligand discrimination, and receptor internalization.

To identify functional domains of G-protein-coupled receptors that control pathway activation, ligand discrimination, and receptor regulation, we have used as a model the alpha-factor receptor (STE2 gene product) of the yeast Saccharomyces cerevisiae. From a collection of random mutations introduced in the region coding for the third cytoplasmic loop of Ste2p, six ste2sst alleles were identified by genetic screening methods that increased alpha-factor sensitivity 2.5- to 15-fold. The phenotypic effects of ste2sst and sst2 mutations were not additive, consistent with models in which the third cytoplasmic loop of the alpha-factor receptor and the regulatory protein Sst2p control related aspects of pheromone response and/or desensitization. Four ste2sst mutations did not dramatically alter cell surface expression or agonist binding affinity of the receptor; however, they did permit detectable responses to an alpha-factor antagonist. One ste2sst allele increased receptor binding affinity for alpha-factor and elicited stronger responses to antagonist. Results of competition binding experiments indicated that wild-type and representative mutant receptors bound antagonist with similar affinities. The antagonist-responsive phenotypes caused by ste2sst alleles were therefore due to defects in the ability of receptors to discriminate between agonist and antagonist peptides. One ste2sst mutation caused rapid, ligand-independent internalization of the receptor. These results demonstrate that the third cytoplasmic loop of the alpha-factor receptor is a multifunctional regulatory domain that controls pathway activation and/or desensitization and influences the processes of receptor activation, ligand discrimination, and internalization.     

Affinity purification and characterization of a G-protein coupled receptor, Saccharomyces cerevisiae Ste2p

We present an example of expression and purification of a biologically active G-protein coupled receptor (GPCR) from yeast. An expression vector was constructed to encode the Saccharomyces cerevisiae GPCR alpha-factor receptor (Ste2p, the STE2 gene product) containing a 9-amino acid sequence of rhodopsin that served as an epitope/affinity tag. In the construct, two glycosylation sites and two cysteine residues were removed to aid future structural and functional studies. The receptor was expressed in yeast cells and was detected as a single band in a western blot indicating the absence of glycosylation. Ligand binding and signaling assays of the epitope-tagged, mutated receptor showed it maintained the full wild-type biological activity. For extraction of Ste2p, yeast membranes were solubilized with 0.5% n-dodecyl maltoside (DM). Approximately 120 microg of purified alpha-factor receptor was obtained per liter of culture by single-step affinity chromatography using a monoclonal antibody to the rhodopsin epitope. The binding affinity (K(d)) of the purified alpha-factor receptor in DM micelles was 28 nM as compared to K(d)=12.7 nM for Ste2p in cell membranes, and approximately 40% of the purified receptor was correctly folded as judged by ligand saturation binding. About 50% of the receptor sequence was retrieved from MALDI-TOF and nanospray mass spectrometry after CNBr digestion of the purified receptor. The methods described will enable structural studies of the alpha-factor receptor and may provide an efficient technique to purify other GPCRs that have been functionally expressed in yeast.     

Afr1p regulates the Saccharomyces cerevisiae alpha-factor receptor by a mechanism that is distinct from receptor phosphorylation and endocytosis.

The alpha-factor pheromone receptor activates a G protein signaling pathway that induces the conjugation of the yeast Saccharomyces cerevisiae. Our previous studies identified AFR1 as a gene that regulates this signaling pathway because overexpression of AFR1 promoted resistance to alpha-factor. AFR1 also showed an interesting genetic relationship with the alpha-factor receptor gene, STE2, suggesting that the receptor is regulated by Afr1p. To investigate the mechanism of this regulation, we tested AFR1 for a role in the two processes that are known to regulate receptor signaling: phosphorylation and down-regulation of ligand-bound receptors by endocytosis. AFR1 overexpression diminished signaling in a strain that lacks the C-terminal phosphorylation sites of the receptor, indicating that AFR1 acts independently of phosphorylation. The effects of AFR1 overexpression were weaker in strains that were defective in receptor endocytosis. However, AFR1 overexpression did not detectably influence receptor endocytosis or the stability of the receptor protein. Instead, gene dosage studies showed that the effects of AFR1 overexpression on signaling were inversely proportional to the number of receptors. These results indicate that AFR1 acts independently of endocytosis, and that the weaker effects of AFR1 in strains that are defective in receptor endocytosis were probably an indirect consequence of their increased receptor number caused by the failure of receptors to undergo ligand-stimulated endocytosis. Analysis of the ligand binding properties of the receptor showed that AFR1 overexpression did not alter the number of cell-surface receptors or the affinity for alpha-factor. Thus, Afr1p prevents alpha-factor receptors from activating G protein signaling by a mechanism that is distinct from other known pathways.     

Overexpression of the STE4 gene leads to mating response in haploid Saccharomyces cerevisiae.

The STE4 gene of Saccharomyces cerevisiae encodes the beta subunit of the yeast pheromone receptor-coupled G protein. Overexpression of the STE4 protein led to cell cycle arrest of haploid cells. This arrest was like the arrest mediated by mating pheromones in that it led to similar morphological changes in the arrested cells. The arrest occurred in haploid cells of either mating type but not in MATa/MAT alpha diploids, and it was suppressed by defects in genes such as STE12 that are needed for pheromone response. Overexpression of the STE4 gene product also suppressed the sterility of cells defective in the mating pheromone receptors encoded by the STE2 and STE3 genes. Cell cycle arrest mediated by STE4 overexpression was prevented in cells that either were overexpressing the SCG1 gene product (the alpha subunit of the G protein) or lacked the STE18 gene product (the gamma subunit of the G protein). This finding suggests that in yeast cells, the beta subunit is the limiting component of the active beta gamma element and that a proper balance in the levels of the G-protein subunits is critical to a normal mating pheromone response.     

The Pheromone Receptors Inhibit the Pheromone Response Pathway in Saccharomyces Cerevisiae by a Process That Is Independent of Their Associated Gα Protein

Dominant mutations at the DAF2 locus confer resistance to the cell-cycle arrest that normally occurs in MATa cells exposed to α-factor. One of these alleles, DAF2-2, has also been shown to suppress the constitutive signaling phenotype of null alleles of the gene encoding the α subunit of the G protein involved in pheromone signaling. These observations indicate that DAF2-2 inhibits transmission of the pheromone response signal. The DAF2-2 mutation has two effects on the expression of a pheromone inducible gene, FUS1. In DAF2-2 cells, FUS1 RNA is present at an increased basal level but is no longer fully inducible by pheromone. Cloning of DAF2-2 revealed that it is an allele of STE3, the gene encoding the a-factor receptor. STE3 is normally an α-specific gene, but is inappropriately expressed in a cells carrying a STE3(DAF2-2) allele. The two effects of STE3(DAF2-2) alleles on the pheromone response pathway are the result of different functions of the receptor. The increased basal level of FUS1 RNA is probably due to stimulation of the pathway by an autocrine mechanism, because it required at least one of the genes encoding a-factor. Suppression of a null allele of the G(α) subunit gene, the phenotype associated with the inhibitory function of STE3, was independent of a-factor. This suppression was also observed when the wild-type STE3 gene was expressed in a cells under the control of an inducible promoter. Inappropriate expression of STE2 in α cells was able to suppress a point mutation, but not a null allele, of the G(α) subunit gene. The ability of the pheromone receptors to block the pheromone response signal in the absence of the G(α) subunit indicates that these receptors interact with another component of the signal transduction pathway.     

Localization and signaling of G(beta) subunit Ste4p are controlled by a-factor receptor and the a-specific protein Asg7p

Haploid yeast cells initiate pheromone signaling upon the binding of pheromone to its receptor and activation of the coupled G protein. A regulatory process termed receptor inhibition blocks pheromone signaling when the a-factor receptor is inappropriately expressed in MATa cells. Receptor inhibition blocks signaling by inhibiting the activity of the G protein beta subunit, Ste4p. To investigate how Ste4p activity is inhibited, its subcellular location was examined. In wild-type cells, alpha-factor treatment resulted in localization of Ste4p to the plasma membrane of mating projections. In cells expressing the a-factor receptor, alpha-factor treatment resulted in localization of Ste4p away from the plasma membrane to an internal compartment. An altered version of Ste4p that is largely insensitive to receptor inhibition retained its association with the membrane in cells expressing the a-factor receptor. The inhibitory function of the a-factor receptor required ASG7, an a-specific gene of previously unknown function. ASG7 RNA was induced by pheromone, consistent with increased inhibition as the pheromone response progresses. The a-factor receptor inhibited signaling in its liganded state, demonstrating that the receptor can block the signal that it initiates. ASG7 was required for the altered localization of Ste4p that occurs during receptor inhibition, and the subcellular location of Asg7p was consistent with its having a direct effect on Ste4p localization. These results demonstrate that Asg7p mediates a regulatory process that blocks signaling from a G protein beta subunit and causes its relocalization within the cell.     

Oligomerization, biogenesis, and signaling is promoted by a glycophorin A-like dimerization motif in transmembrane domain 1 of a yeast G protein-coupled receptor

G protein-coupled receptors (GPCRs) can form dimeric or oligomeric complexes in vivo. However, the functions and mechanisms of oligomerization remain poorly understood for most GPCRs, including the alpha-factor receptor (STE2 gene product) of the yeast Saccharomyces cerevisiae. Here we provide evidence indicating that alpha-factor receptor oligomerization involves a GXXXG motif in the first transmembrane domain (TM1), similar to the transmembrane dimerization domain of glycophorin A. Results of fluorescence resonance energy transfer, fluorescence microscopy, endocytosis assays of receptor oligomerization in living cells, and agonist binding assays indicated that amino acid substitutions affecting the glycine residues of the GXXXG motif impaired alpha-factor receptor oligomerization and biogenesis in vivo but did not significantly impair agonist binding affinity. Mutant receptors exhibited signaling defects that were not due to impaired cell surface expression, indicating that oligomerization promotes alpha-factor receptor signal transduction. Structure-function studies suggested that the GXXXG motif in TM1 of the alpha-factor receptor promotes oligomerization by a mechanism similar to that used by the GXXXG dimerization motif of glycophorin A. In many mammalian GPCRs, motifs related to the GXXXG sequence are present in TM1 or other TM domains, suggesting that similar mechanisms are used by many GPCRs to form dimers or oligomeric arrays.     

Common signal transduction system shared by STE2 and STE3 in haploid cells of Saccharomyces cerevisiae: autocrine cell-cycle arrest results from forced expression of STE2

Induction of STE2 expression using the GAL1 promoter both in a wild-type MATalpha strain and in a MATalpha ste3 strain caused transient cell-cycle arrest and changes in morphology ('shmoo'-like phenotype) in a manner similar to alpha cells responding to alpha-factor. In addition, STE2 expressed in a MATalp[ha ste3 mutant allowed the cell to conjugate with alpha cells but at an efficiency lower than that of wil-type alpha cells. This result indicates that signal(s) generated by alpha-factor in alpha cells can be substituted by signal(s) generated by the interaction of alpha-factor with the expressed STE2 product. When STE2 or STE3 was expressed in a matalpha1 strain (insensitive to both alpha- and a-factors), the cell became sensitive to alpha- or a-factor, respectively, and resulted in morphological changes. These results suggest that STE2 and STE3 are the sole determinants for alpha-factor and a-factor sensitivity, respectively, in this strain. On the other hand, expression of STE2 in an a/alpha diploid cell did not affect the alpha-factor insensitive phenotype. Haploid-specific components may be necessary to transduce the alpha-factor signal. These results are consistent with the idea that STE2 encodes an alpha-factor receptor and STE3 encodes an a-factor receptor, and suggest that both alpha- and a-factors may generate an exchangeable signal(s) within haploid cells.     

The yeast STE12 product is required for expression of two sets of cell-type specific genes

Yeast alpha and a cells transcribe distinct sets of genes involved in mating behavior, alpha-specific genes and a-specific genes, respectively. The alpha 1 product of the alpha mating type locus (MAT alpha) has been the only known activator of either set of genes; it is required for synthesis of RNA from the alpha-specific genes, one of which is the major alpha-factor gene. By screening for mutants that are no longer able to express this gene, we have identified the STE12 gene product as another positive regulator of the alpha-factor gene. alpha ste12 cells are also defective in RNA production from the other known alpha-specific genes. Moreover, a ste12 cells fail to produce wild-type levels of RNA from the a-specific genes. The STE12 gene product is therefore an activator of two sets of genes involved in yeast cell type specialization.