Mutational analysis of the role of N-glycosylation in alpha-factor receptor function.

The alpha-factor mating pheromone receptor (encoded by STE2) activates a G protein signaling pathway that stimulates the conjugation of Saccharomyces cerevisiae yeast cells. The alpha-factor receptor is known to undergo several forms of post-translational modification, including phosphorylation, mono-ubiquitination, and N-linked glycosylation. Since phosphorylation and mono-ubiquitination have been shown previously to play key roles in regulating the signaling activity and membrane trafficking of the alpha-factor receptors, the role of N-linked glycosylation was investigated in this study. The Asn residues in the five consensus sites for N-linked glycosylation present in the extracellular regions of the receptor protein were mutated to prevent carbohydrate attachment at these sites. Mutation of two sites near the receptor N-terminus (N25Q and N32Q) diminished the degree of receptor glycosylation, and the corresponding double mutant was not detectably N-glycosylated. The nonglycosylated receptors displayed normal function and subcellular localization, indicating that glycosylation is not important for wild-type receptor activity. However, mutation of the glycosylation sites resulted in improved plasma membrane localization for the Ste2-3 mutant receptors that are normally retained intracellularly at elevated temperatures. These results suggest that N-glycosylation may be involved in the sorting process for misfolded Ste2 proteins, and may similarly affect certain mutant receptors whose altered trafficking is implicated in human diseases.

Constitutive activation of the Saccharomyces cerevisiae transcriptional regulator Ste12p by mutations at the amino-terminus.

The transcriptional activator Ste12p is required for the expression of genes induced by mating pheromone in the yeast Saccharomyces cerevisiae. We identified mutations in the amino-terminal DNA-binding domain of Ste12p that lead to constitutively high-level transcription of pheromone-induced genes. The behaviour of these mutant proteins is consistent with an enhanced DNA-binding ability. Cells carrying these hyperactive proteins retain their sensitivity to pheromone treatment, and their phenotype is largely dependent on the presence of at least one of the MAP kinases (Fus3p or Kss1p) and the scaffold protein Ste5p. Deletion of either FUS3 or KSS1 leads to a marked increase in Ste12p activity, consistent with a negative regulatory role for Fus3p, similar to that described for Kss1p. The properties of the constitutive mutants support the idea that the pheromone response pathway plays a role in basal as well as pheromone-induced transcription.

Interaction between transmembrane domains five and six of the alpha -factor receptor.

The alpha-factor pheromone receptor (STE2) activates a G protein signal pathway that induces conjugation of the yeast Saccharomyces cerevisiae. Previous studies implicated the third intracellular loop of this receptor in G protein activation. Therefore, the roles of transmembrane domains five and six (TMD5 and -6) that bracket the third intracellular loop were analyzed by scanning mutagenesis in which each residue was substituted with cysteine. Out of 42 mutants examined, four constitutive mutants and two strong loss-of-function mutants were identified. Double mutants combining Cys substitutions in TMD5 and TMD6 gave a broader range of phenotypes. Interestingly, a V223C mutation in TMD5 caused constitutive activity when combined with the L247C, L248C, or S251C mutations in TMD6. Also, the L226C mutation in TMD5 caused constitutive activity when combined with either the M250C or S251C mutations in TMD6. The residues affected by these mutations are predicted to fall on one side of their respective helices, suggesting that they may interact. In support of this, cysteines substituted at position 223 in TMD5 and position 247 in TMD6 formed a disulfide bond, providing the first direct evidence of an interaction between these transmembrane domains in the alpha-factor receptor. Altogether, these results identify an important region of interaction between conserved hydrophobic regions at the base of TMD5 and TMD6 that is required for the proper regulation of receptor signaling.

The C terminus of the Saccharomyces cerevisiae alpha-factor receptor contributes to the formation of preactivation complexes with its cognate G protein.

Binding of the alpha-factor pheromone to its G-protein-coupled receptor (encoded by STE2) activates the mating pathway in MATa yeast cells. To investigate whether specific interactions between the receptor and the G protein occur prior to ligand binding, we analyzed dominant-negative mutant receptors that compete with wild-type receptors for G proteins, and we analyzed the ability of receptors to suppress the constitutive signaling activity of mutant Galpha subunits in an alpha-factor-independent manner. Although the amino acid substitution L236H in the third intracellular loop of the receptor impairs G-protein activation, this substitution had no influence on the ability of the dominant-negative receptors to sequester G proteins or on the ability of receptors to suppress the GPA1-A345T mutant Galpha subunit. In contrast, removal of the cytoplasmic C-terminal domain of the receptor eliminated both of these activities even though the C-terminal domain is unnecessary for G-protein activation. Moreover, the alpha-factor-independent signaling activity of ste2-P258L mutant receptors was inhibited by the coexpression of wild-type receptors but not by coexpression of truncated receptors lacking the C-terminal domain. Deletion analysis suggested that the distal half of the C-terminal domain is critical for sequestration of G proteins. The C-terminal domain was also found to influence the affinity of the receptor for alpha-factor in cells lacking G proteins. These results suggest that the C-terminal cytoplasmic domain of the alpha-factor receptor, in addition to its role in receptor downregulation, promotes the formation of receptor-G-protein preactivation complexes.

Point mutations identify a conserved region of the saccharomyces cerevisiae AFR1 gene that is essential for both the pheromone signaling and morphogenesis functions.

Mating pheromone receptors activate a G protein signal pathway that leads to the conjugation of the yeast Saccharomyces cerevisiae. This pathway also induces the production of Afr1p, a protein that negatively regulates pheromone receptor signaling and is required to form pointed projections of new growth that become the site of cell fusion during mating. Afr1p lacks strong similarity to any well-characterized proteins to help predict how it acts. Therefore, we investigated the relationship between the different functions of Afr1p by isolating and characterizing seven mutants that were defective in regulating pheromone signaling. The AFR1 mutants were also defective when expressed as fusions to STE2, the alpha-factor receptor, indicating that the mutant Afr1 proteins are defective in function and not in co-localizing with receptors. The mutant genes contained four distinct point mutations that all occurred between codons 254 and 263, identifying a region that is critical for AFR1 function. Consistent with this, we found that the corresponding region is very highly conserved in the Afr1p homologs from the yeasts S. uvarum and S. douglasii. In contrast, there were no detectable effects on pheromone signaling caused by deletion or overexpression of YER158c, an open reading frame with overall sequence similarity to Afr1p that lacks this essential region. Interestingly, all of the AFR1 mutants showed a defect in their ability to form mating projections that was proportional to their defect in regulating pheromone signaling. This suggests that both functions may be due to the same action of Afr1p. Thus, these studies identify a specific region of Afr1p that is critical for its function in both signaling and morphogenesis.

Combining mutations in the incoming and outgoing pheromone signal pathways causes a synergistic mating defect in Saccharomyces cerevisiae.

Mating pheromones stimulate Saccharomyces cerevisiae yeast cells to form a pointed projection that becomes the site of cell fusion during conjugation. To investigate the role of mating projections, we screened for mutations that enhanced the weak mating defect of MATa ste2-T326 cells that are defective in forming pointed projections. These cells are also 10-fold more sensitive to alpha-factor pheromone because ste2-T326 encodes truncated alpha-factor receptors that are not regulated properly. Mutations in AXL1, STE6 and FUS3 were identified in the screen. AXL1 was studied further because it is required for efficient a-factor pheromone production and for selecting the site for bud morphogenesis. Mutation of AXL1 did not enhance the morphogenesis or pheromone sensitivity defects of ste2-T326. Instead, the synergistic mating defect was apparently due to decreased a-factor production because the axl1Delta ste2-T326 cells mated well with a sst2 alpha mating partner that is supersensitive to a-factor. When combined with a wild-type mating partner, the ste2-T326 axl1Delta cells failed to mate because they did not lock cell walls, one of the earliest steps in conjugation. Analysis of axl1Delta in combination with other mutations that cause defects in morphogenesis or pheromone sensitivity (e.g. bar1, sst2, afr1) indicated that both phenotypes of ste2-T326 cells, supersensitivity to alpha-factor and the defect in forming pointed projections, contributed to the synergistic mating defect. We suggest a model that the synergistic mating defect is caused by the combined effects of ste2-T326 and axl1Delta on the presentation of a-factor to partner cells. Altogether, these results demonstrate an important linkage between the incoming and outgoing pheromone signals during the intercellular communication that promotes yeast mating.

Visualization of receptor-mediated endocytosis in yeast.

We studied the ligand-induced endocytosis of the yeast alpha-factor receptor Ste2p by immuno-electron microscopy. We observed and quantitated time-dependent loss of Ste2p from the plasma membrane of cells exposed to alpha-factor. This ligand-induced internalization of Ste2p was blocked in the well-characterized endocytosis-deficient mutant sac6Delta. We provide evidence that implicates furrow-like invaginations of the plasma membrane as the site of receptor internalization. These invaginations are distinct from the finger-like plasma membrane invaginations within actin cortical patches. Consistent with this, we show that Ste2p is not located within the cortical actin patch before and during receptor-mediated endocytosis. In wild-type cells exposed to alpha-factor we also observed and quantitated a time-dependent accumulation of Ste2p in intracellular, membrane-bound compartments. These compartments have a characteristic electron density but variable shape and size and are often located adjacent to the vacuole. In immuno-electron microscopy experiments these compartments labeled with antibodies directed against the rab5 homologue Ypt51p (Vps21p), the resident vacuolar protease carboxypeptidase Y, and the vacuolar H+-ATPase Vph1p. Using a new double-labeling technique we have colocalized antibodies against Ste2p and carboxypeptidase Y to this compartment, thereby identifying these compartments as prevacuolar late endosomes.

Identification of a polar region in transmembrane domain 6 that regulates the function of the G protein-coupled alpha-factor receptor.

The alpha-factor pheromone receptor (Ste2p) of the yeast Saccharomyces cerevisiae belongs to the family of G protein-coupled receptors that contain seven transmembrane domains (TMDs). Because polar residues can influence receptor structure by forming intramolecular contacts between TMDs, we tested the role of the five polar amino acids in TMD6 of the alpha-factor receptor by mutating these residues to nonpolar leucine. Interestingly, a subset of these mutants showed increased affinity for ligand and constitutive receptor activity. The mutation of the most polar residue, Q253L, resulted in 25-fold increased affinity and a 5-fold-higher basal level of signaling that was equal to about 19% of the alpha-factor induced maximum signal. Mutation of the adjacent residue, S254L, caused weaker constitutive activity and a 5-fold increase in affinity. Comparison of nine different mutations affecting Ser254 showed that an S254F mutation caused higher constitutive activity, suggesting that a large hydrophobic amino acid residue at position 254 alters transmembrane helix packing. Thus, these studies indicate that Gln253 and Ser254 are likely to be involved in intramolecular interactions with other TMDs. Furthermore, Gln253 and Ser254 fall on one side of the transmembrane helix that is on the opposite side from residues that do not cause constitutive activity when mutated. These results suggest that Gln253 and Ser254 face inward toward the other TMDs and thus provide the first experimental evidence to suggest the orientation of a TMD in this receptor. Consistent with this, we identified two residues in TMD7 (Ser288 and Ser292) that are potential contact residues for Gln253 because mutations affecting these residues also cause constitutive activity. Altogether, these results identify a new domain of the alpha-factor receptor that regulates its ability to enter the activated conformation.

Dominant-negative mutations in the G-protein-coupled alpha-factor receptor map to the extracellular ends of the transmembrane segments.

G-protein-coupled receptors (GPCRs) transduce the signals for a wide range of hormonal and sensory stimuli by activating a heterotrimeric guanine nucleotide-binding protein (G protein). The analysis of loss-of-function and constitutively active receptor mutants has helped to reveal the functional properties of GPCRs and their role in human diseases. Here we describe the identification of a new class of mutants, dominant-negative mutants, for the yeast G-protein-coupled alpha-factor receptor (Ste2p). Sixteen dominant-negative receptor mutants were isolated based on their ability to inhibit the response to mating pheromone in cells that also express wild-type receptors. Detailed analysis of two of the strongest mutant receptors showed that, unlike other GPCR interfering mutants, they were properly localized at the plasma membrane and did not alter the stability or localization of wild-type receptors. Furthermore, their dominant-negative effect was inversely proportional to the relative amount of wild-type receptors and was reversed by overexpressing the G-protein subunits, suggesting that these mutants compete with the wild-type receptors for the G protein. Interestingly, the dominant-negative mutations are all located at the extracellular ends of the transmembrane segments, defining a novel region of the receptor that is important for receptor signaling. Altogether, our results identify residues of the alpha-factor receptor specifically involved in ligand binding and receptor activation and define a new mechanism by which GPCRs can be inactivated that has important implications for the evaluation of receptor mutations in other G-protein-coupled receptors.

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.

Two new S-phase-specific genes from Saccharomyces cerevisiae.

Two new yeast genes, ASF1 (Anti-Silencing Function) and ASF2, as well as a C-terminal fragment of SIR3, were identified as genes that derepressed the silent mating type loci when overexpressed. ASF2 overexpression caused a greater derepression than did ASF1. ASF1 overexpression also weakened repression of genes near telomeres, but, interestingly, ASF2 had no effect on telomeric silencing. Sequences of these two genes revealed open reading frames of 279 and 525 amino acids for ASF1 and ASF2, respectively. The ASF1 protein was evolutionarily conserved, MCB motifs, sequences commonly present upstream of genes transcribed specifically in S phase, were found in front of both genes, and, indeed, both genes were transcribed specifically in the S phase of the cell cycle. While an asf2 mutant was viable and had no obvious phenotypes, an asf1 mutant grew poorly. Neither mutant exhibited derepression of the silent mating type loci. The asf1 mutant was sensitive to methyl methane sulfonate, slightly UV-sensitive and somewhat deficient in minichromosome maintenance. It also lowered the restrictive temperature of a cdc13ts mutant. These phenotypes suggested a role for ASF1 in DNA repair and chromosome maintenance.

Functional analysis of the interaction between Afr1p and the Cdc12p septin, two proteins involved in pheromone-induced morphogenesis.

Saccharomyces cerevisiae mating pheromones induce production of Afr1p, a protein that negatively regulates pheromone receptor signaling and is required for normal formation of the projection of cell growth that becomes the site of cell fusion during conjugation. Afr1p interacts with Cdc12p, which belongs to a family of filament-forming proteins termed septins that have been studied primarily for their role in bud morphogenesis and cytokinesis. The significance of the interaction between Afr1p and Cdc12p was tested in this study by examining the effects of AFR1 mutations that destroy the Cdc12p-binding domain. The results demonstrate that sequences in the C-terminal half of Afr1p are required for interaction with Cdc12p and for proper localization of Afr1p to the base of the mating projection. However, the Cdc12p-binding domain was not required for regulation of receptor signaling or for mating projection formation. This result was surprising because cells carrying a temperature-sensitive cdc12-6 mutation were defective in projection formation, indicating a role for Cdc12p in this process. Although the Cdc12p-binding domain was no essential for Afr1p function, this domain did improve the ability of Afr1p to promote morphogenesis, suggesting that the proper localization of Afr1p is important for its function.

Mutation of Pro-258 in transmembrane domain 6 constitutively activates the G protein-coupled alpha-factor receptor.

The alpha-factor pheromone receptor stimulates MATa yeast cells to undergo conjugation. The receptor contains seven transmembrane domains that function in ligand binding and in transducing a signal to the cytoplasmic receptor sequences to mediate G protein activation. A genetic screen was used to isolate receptor mutations that constitutively signal in the absence of alpha-factor. The Pro-258-->Leu (P258L) mutation caused constitutive receptor signaling that was equivalent to about 45% of the maximum level observed in wild-type cells stimulated with alpha-factor. Mutations of both Pro-258 and the adjacent Ser-259 to Leu increased constitutive signaling to > or = 90% of the maximum level. Since Pro-258 occurs in the central portion of transmembrane domain 6, and since proline residues are expected to cause a kink in alpha-helical domains, the P258L mutation is predicted to alter the structure of transmembrane domain 6. The P258L mutation did not result in a global distortion of receptor structure because alpha-factor bound to the mutant receptors with high affinity and induced even higher levels of signaling. These results suggest that sequences surrounding Pro-258 may be involved in ligand activation of the receptor. Conformational changes in transmembrane domain 6 may effect a change in the adjacent sequences in the third intracellular loop that are thought to function in G protein activation. Greater than 90% of all G protein-coupled receptors contain a proline residue at a similar position in transmembrane domain 6, suggesting that this aspect of receptor activation may be conserved in other receptors.

Regulation of the G-protein-coupled alpha-factor pheromone receptor by phosphorylation.

The alpha-factor pheromone receptor activates a G protein signaling cascade that stimulates MATa yeast cells to undergo conjugation. The cytoplasmic C terminus of the receptor is not necessary for G protein activation but instead acts as a regulatory domain that promotes adaptation to alpha-factor. The role of phosphorylation in regulating the alpha-factor receptor was examined by mutating potential phosphorylation sites. Mutation of the four most distal serine and threonine residues in the receptor C terminus to alanine caused increased sensitivity to alpha-factor and a delay in recovering from a pulse of alpha-factor. 32PO4 labeling experiments demonstrated that the alanine substitution mutations decreased the in vivo phosphorylation of the receptor. Phosphorylation apparently alters the regulation of G protein activation, since neither receptor number nor affinity for ligand was significantly altered by mutation of the distal phosphorylation sites. Furthermore, mutation of the distal phosphorylation sites in a receptor mutant that fails to undergo ligand-stimulated endocytosis caused increased sensitivity to alpha-factor, which suggests that regulation by phosphorylation can occur at the cell surface and is independent of endocytosis. Mutation of the distal serine and threonine residues of the receptor also caused a slight defect in alpha-factor-induced morphogenesis, but the defect was not as severe as the morphogenesis defect caused by truncation of the cytoplasmic C terminus of the receptor. These distal residues in the C terminus play a special role in receptor regulation, since mutation of the next five adjacent serine and threonine residues to alanine did not affect the sensitivity to alpha-factor. Altogether, these results indicate that phosphorylation plays an important role in regulating alpha-factor receptor function.

AFR1 promotes polarized apical morphogenesis in Saccharomyces cerevisiae.

The G protein-coupled alpha-factor receptor promotes polarized growth toward a mating partner. alpha-Factor induces the expression of AFR1, which acts together with the receptor C terminus to promote normal morphogenesis. The function of AFR1 was investigated by engineering cells to constitutively express AFR1 without alpha-factor. Constitutive AFR1 expression caused cells to form elongated buds that demonstrate that AFR1 can also interact with the morphogenesis components that promote bud formation. A similar elongated bud phenotype is caused by mutation of the CDC3, CDC10, CDC11, and CDC12 genes, which encode putative filament proteins that form a ring at the bud neck. AFR1 may act directly on the filament proteins, since immunolocalization detected AFR1 at the bud neck and interaction of AFR1 and CDC12 was detected in the two-hybrid protein assay. AFR1 localized to the base of pheromone-induced projections. These results suggest that AFR1 and the putative filament proteins act together with the receptor to facilitate proper localization of components during mating.

AFR1 acts in conjunction with the alpha-factor receptor to promote morphogenesis and adaptation.

Mating pheromone receptors activate a G-protein signaling pathway that induces changes in transcription, cell division, and morphogenesis needed for the conjunction of Saccharomyces cerevisiae. The C terminus of the alpha-factor pheromone receptor functions in two complex processes, adaptation and morphogenesis. Adaptation to alpha-factor may occur through receptor desensitization, and alpha-factor-induced morphogenesis forms the conjugation bridge between mating cells. A plasmid overexpression strategy was used to isolate a new gene, AFR1, which acts together with the receptor C terminus to promote adaptation. The expression of AFR1 was highly induced by alpha-factor. Unexpectedly, cells lacking AFR1 showed a defect in alpha-factor-stimulated morphogenesis that was similar to the morphogenesis defect observed in cells producing C-terminally truncated alpha-factor receptors. In contrast, AFR1 overexpression resulted in longer projections of morphogenesis, which suggests that this gene may directly stimulate morphogenesis. These results indicate that AFR1 encodes a developmentally regulated function that coordinates both the regulation of receptor signaling and the induction of morphogenesis during conjugation.

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.