Biochemical analysis of yeast G(alpha) mutants that enhance adaptation to pheromone

The mating-specific heterotrimeric G(alpha) protein of Saccharomyces cerevisiae, Gpa1, negatively regulates activation of the pheromone response pathway both by sequestering G(beta)gamma and by triggering an adaptive response through an as yet unknown mechanism. Previous genetic studies identified mutant alleles of GPA1 that downregulate the pheromone response independently of the pheromone receptor (GPA1E364K), or through a receptor-dependent mechanism (GPA1N388D). To further our understanding of the mechanism of action of these mutant alleles, their corresponding proteins were purified and subjected to biochemical analysis. The receptor-dependent activity of Gpa1N388D was further analyzed using yeast strains expressing constitutively active receptor (Ste2) mutants, and C-terminal truncation mutant forms of Gpa1. A combination of G(alpha) affinity chromatography, GTP binding/hydrolysis studies, and genetic analysis allowed us to assign a distinct mechanism of action to each of these mutant proteins.     

G protein mutations that alter the pheromone response in Saccharomyces cerevisiae.

The GPA1 gene of Saccharomyces cerevisiae encodes a G alpha protein that couples the membrane-bound pheromone receptors to downstream elements in the mating response pathway. We have isolated seven mutant alleles of GPA1 that confer pheromone resistance: G50D (a glycine-to-aspartate change at position 50), G322E, G322R, E355K, E364K, G470D, and an E364K-G470D double mutant. All of the mutations lie within large regions that are highly conserved between Gpa1 and four other G alpha proteins; four of the changes are located in domains with proposed functions. On the basis of a gentic analysis, the pheromone-unresponsive GPA1 alleles can be divided into two classes: those that encode constitutively activated proteins and those that encode proteins unable to respond to the upstream signal. Our results support the hypothesis that the activated form of Gpa1 stimulates adaptation to pheromone.     

Effect of the pheromone-responsive G(alpha) and phosphatase proteins of Saccharomyces cerevisiae on the subcellular localization of the Fus3 mitogen-activated protein kinase

The mating-specific G(alpha) protein of Saccharomyces cerevisiae, Gpa1, stimulates adaptation to pheromone by a mechanism independent of G(beta gamma) sequestration. Genetic evidence suggests that Gpa1 targets the Fus3 mitogen-activated protein kinase, and it has recently been shown that the two proteins interact in cells responding to pheromone. To test the possibility that Gpa1 downregulates the mating signal by affecting the localization of Fus3, we created a Fus3-green fluorescent protein (GFP) fusion protein. In vegetative cells, Fus3-GFP was found in both the cytoplasm and the nucleus. Pheromone stimulated a measurable increase in the ratio of nuclear to cytoplasmic Fus3-GFP. In contrast, the relative level of nuclear Fus3-GFP decreased as cells recovered from pheromone arrest and did not increase when cells adapted to chronic stimulus were challenged again. Accumulation of Fus3-GFP in the nuclei of stimulated cells was also inhibited by overexpression of either wild-type Gpa1, the E364K hyperadaptive mutant form of Gpa1, or the Msg5 dually specific phosphatase. The effects of Gpa1 and Msg5 on Fus3 are partially interdependent. In a genetic screen for adaptive defective mutants, a nonsense allele of the nucleocytoplasmic transport receptor, Kap104, was identified. Truncation of the Kap104 cargo-binding domain blocked the effect of both Gpa1(E364K) and Msg5 on Fus3-GFP localization. Based on these results, we propose that Gpa1 and Msg5 work in concert to downregulate the mating signal and that they do so by inhibiting the pheromone-induced increase of Fus3 in the nucleus. Kap104 is required for the G(alpha)/phosphatase-mediated effect on Fus3 localization.     

Substitutions in the pheromone-responsive Gbeta protein of Saccharomyces cerevisiae confer a defect in recovery from pheromone treatment.

The pheromone-responsive Galpha protein of Saccharomyces cerevisiae, Gpa1p, stimulates an adaptive mechanism that downregulates the mating signal. In a genetic screen designed to identify signaling elements required for Gpa1p-mediated adaptation, a large collection of adaptive-defective (Adp-) mutants were recovered. Of the 49 mutants characterized thus far, approximately three-quarters exhibit a dominant defect in the negative regulation of the pheromone response. Eight of the dominant Adp- mutations showed tight linkage to the gene encoding the pheromone-responsive Gbeta, STE4. Sequence analysis of the STE4 locus in the relevant mutant strains revealed seven novel STE4 alleles, each of which was shown to disrupt proper regulation of the pheromone response. Although the STE4 mutations had only minor effects on basal mating pathway activity, the mutant forms of Gbeta dramatically affected the ability of the cell to turn off the mating response after exposure to pheromone. Moreover, the signaling activity of the aberrant Gbetagamma subunits was suppressed by G322E, a mutant form of Gpa1p that blocks the pheromone response by sequestering Gbetagamma, but not by E364K, a hyperadaptive form of Gpa1p. On the basis of these observations, we propose that Gpa1p-mediated adaptation involves the binding of an unknown negative regulator to Gbetagamma.     

The yeast pheromone-responsive Gα protein stimulates recovery from chronic pheromone treatment by two mechanisms that are activated at distinct levels of stimulus

The pheromone response ofSaccharomyces cerevisiae is mediated by a receptor-coupled heterotrimeric G protein. The βγ subunit of the G protein stimulates a PAK/MAP kinase cascade that leads to cellular changes preparatory to mating, while the pheromone-responsive Gα protein, Gpa1, antagonizes the Gβγ-induced signal. In its inactive conformation, Gpa1 sequesters Gβγ and tethers it to the receptor. In its active conformation, Gpa1 stimulates adaptive mechanisms that downregulate the mating signal, but which are independent of α-βγ binding. To elucidate these potentially novel signaling functions of Gα in yeast, epistasis analyses were performed using N388D, a hyperadaptive mutant form of Gpa1, and null alleles of various loci that have been implicated in adaptation. The results of these experiments indicate the existence of signaling thresholds that affect the yeast mating reaction. At low pheromone concentration, the Regulator of G Protein Signaling (RGS) homologue and putative guanosine triphosphatase (GTPase) activating protein, Sst2, appears to stimulate sequestration of Gβγ by Gpa1. Throughout the range of pheromone concentrations sufficient to cause cell cycle arrest, Gpa1 stimulates adaptive mechanisms that are partially dependent on Msg5 and Mpt5. Gpa1-mediated adaptation appears to be independent of Afr1, Akr1, and the carboxy-terminus of the pheromone receptor.     

Genetic identification of residues involved in association of alpha and beta G-protein subunits.

The GPA1, STE4, and STE18 genes of Saccharomyces cerevisiae encode the alpha, beta, and gamma subunits, respectively, of a G protein involved in the mating response pathway. We have found that mutations G124D, W136G, W136R, and delta L138 and double mutations W136R L138F and W136G S151C of the Ste4 protein cause constitutive activation of the signaling pathway. The W136R L138F and W136G S151C mutant Ste4 proteins were tested in the two-hybrid protein association assay and found to be defective in association with the Gpa1 protein. A mutation at position E307 of the Gpa1 protein both suppresses the constitutive signaling phenotype of some mutant Ste4 proteins and allows the mutant alpha subunit to physically associate with a specific mutant G beta subunit. The mutation in the Gpa1 protein is adjacent to the hinge, or switch, region that is required for the conformational change which triggers subunit dissociation, but the mutation does not affect the interaction of the alpha subunit with the wild-type beta subunit. Yeast cells constructed to contain only the mutant alpha and beta subunits mate and respond to pheromones, although they exhibit partial induction of the pheromone response pathway. Because the ability of the modified G alpha subunit to suppress the Ste4 mutations is allele specific, it is likely that the residues defined by this analysis play a direct role in G-protein subunit association.     

Analysis of the receptor binding domain of Gpa1p, the G(alpha) subunit involved in the yeast pheromone response pathway.

The Saccharomyces cerevisiae G protein alpha subunit Gpa1p is involved in the response of both MATa and MAT alpha cells to pheromone. We mutagenized the GPA1 C terminus to characterize the receptor-interacting domain and to investigate the specificity of the interactions with the a- and alpha-factor receptors. The results are discussed with respect to a structural model of the Gpa1p C terminus that was based on the crystal structure of bovine transducin. Some mutants showed phenotypes different than the pheromone response and mating defects expected for mutations that affect receptor interactions, and therefore the mutations may affect other aspects of Gpa1p function. Most of the mutations that resulted in pheromone response and mating defects had similar effects in MATa and MAT alpha cells, suggesting that they affect the interactions with both receptors. Overexpression of the pheromone receptors increased the mating of some of the mutants tested but not the wild-type strain, consistent with defects in mutant Gpa1p-receptor interactions. The regions identified by the mating-defective mutants correlated well with the regions of mammalian G(alpha) subunits implicated in receptor interactions. The strongest mating type-specific effects were seen for mutations to proline and a mutation of a glycine residue predicted to form a C-terminal beta turn. The analogous beta turn in mammalian G(alpha) subunits undergoes a conformational change upon receptor interaction. We propose that the conformation of this region of Gpa1p differs during the interactions with the a- and alpha-factor receptors and that these mating type-specific mutations preclude the orientation necessary for interaction with one of the two receptors.     

G protein signaling governing cell fate decisions involves opposing Galpha subunits in Cryptococcus neoformans

Communication between cells and their environments is often mediated by G protein-coupled receptors and cognate G proteins. In fungi, one such signaling cascade is the mating pathway triggered by pheromone/pheromone receptor recognition. Unlike Saccharomyces cerevisiae, which expresses two Galpha subunits, most filamentous ascomycetes and basidiomycetes have three Galpha subunits. Previous studies have defined the Galpha subunit acting upstream of the cAMP-protein kinase A pathway, but it has been unclear which Galpha subunit is coupled to the pheromone receptor and response pathway. Here we report that in the pathogenic basidiomycetous yeast Cryptococcus neoformans, two Galpha subunits (Gpa2, Gpa3) sense pheromone and govern mating. gpa2 gpa3 double mutants, but neither gpa2 nor gpa3 single mutants, are sterile in bilateral crosses. By contrast, deletion of GPA3 (but not GPA2) constitutively activates pheromone response and filamentation. Expression of GPA2 and GPA3 is differentially regulated: GPA3 expression is induced by nutrient-limitation, whereas GPA2 is induced during mating. Based on the phenotype of dominant active alleles, Gpa2 and Gpa3 signal in opposition: Gpa2 promotes mating, whereas Gpa3 inhibits. The incorporation of an additional Galpha into the regulatory circuit enabled increased signaling complexity and facilitated cell fate decisions involving choice between yeast growth and filamentous asexual/sexual development.     

The yeast G-protein homolog is involved in the mating pheromone signal transduction system.

I have isolated a new type of sterile mutant of Saccharomyces cerevisiae, carrying a single mutant allele, designated dac1, which was mapped near the centromere on chromosome VIII. The dac1 mutation caused specific defects in the pheromone responsiveness of both a and alpha cells and did not seem to be associated with any pleiotropic phenotypes. Thus, in contrast to the ste4, ste5, ste7, ste11, and ste12 mutations, the dac1 mutation had no significant effect on such constitutive functions of haploid cells as pheromone production and alpha-factor destruction. The characteristics of this phenotype suggest that the DAC1 gene encodes a component of the pheromone response pathway common to both a and alpha cells. Introduction of the GPA1 gene encoding an S. cerevisiae homolog of the alpha subunit of mammalian guanine nucleotide-binding regulatory proteins (G proteins) into sterile dac1 mutants resulted in restoration of pheromone responsiveness and mating competence to both a and alpha cells. These results suggest that the dac1 mutation is an allele of the GPA1 gene and thus provide genetic evidence that the yeast G protein homolog is directly involved in the mating pheromone signal transduction pathway.     

Activation of the phosphatidylinositol 3-kinase Vps34 by a G protein alpha subunit at the endosome

In the yeast Saccharomyces cerevisiae, the G protein beta gamma subunits are essential for pheromone signaling. The Galpha subunit Gpa1 can also promote signaling, but the effectors in this pathway are not well characterized. To identify candidate Gpa1 effectors, we expressed the constitutively active Gpa1(Q323L) mutant in each of nearly 5000 gene-deletion strains and measured mating-specific responses. Our analysis reveals a requirement for both the catalytic (Vps34) and regulatory (Vps15) subunits of the sole phosphatidylinositol 3-kinase in yeast. We demonstrate that Gpa1 is present at endosomes, where it interacts directly with both Vps34 and Vps15 and stimulates increased production of phosphatidylinositol 3-phosphate. Notably, Vps15 binds to GDP-bound Gpa1 and is predicted to have a seven-WD repeat structure similar to that of known G protein beta subunits. These findings reveal two new components of the pheromone signaling pathway. More remarkably, these proteins appear to comprise a preformed effector-G beta subunit assembly and function at the endosome rather than at the plasma membrane.     

Mutagenesis of Ste18, a putative G gamma subunit in the Saccharomyces cerevisiae pheromone response pathway.

The yeast STE18 gene product has sequence and functional similarity to the gamma subunits of G proteins. The cloned STE18 gene was subjected to a saturation mutagenesis using doped oligonucleotides. The populations of mutant genes were screened for two classes of STE18 mutations, those that allowed for increased mating of a strain containing a defective STE4 gene (compensators) and those that inhibited mating even in the presence of a functional STE18 gene (dominant negatives). Three amino acid substitutions that enhanced mating in a specific STE4 (G beta) point mutant background were identified. These compensatory mutations were allele specific and had no detectable phenotype of their own; they may define residues that mediate an association between the G beta and G gamma subunits or in the association of the G beta gamma subunit with other components of the signalling pathway. Several dominant negative mutations were also identified, including two C terminal truncations. These mutant proteins were unable to function in signal transduction by themselves, but they prevented signal transduction mediated by pheromone, as well as the constitutive signalling which is present in cells defective in the GPA1 (G alpha) gene. These mutant proteins may sequester G beta or some other component of the signalling machinery in a nonfunctional complex.     

Effects of expression of mammalian G alpha and hybrid mammalian-yeast G alpha proteins on the yeast pheromone response signal transduction pathway.

Scg1, the product of the Saccharomyces cerevisiae SCG1 (also called GPA1) gene, is homologous to the alpha subunits of G proteins involved in signal transduction in mammalian cells. Scg1 negatively controls the pheromone response pathway in haploid cells. Either pheromonal activation or an scg1 null mutation relieves the negative control and leads to an arrest of cell growth in the G1 phase of the cell cycle. Expression of rat G alpha s was previously shown to complement the growth defect of scg1 null mutants while not allowing mating. We have extended this analysis to examine the effects of the short form of G alpha s (which lacks 15 amino acids present in the long form), G alpha i2, G alpha o, and Scg1-mammalian G alpha hybrids. In addition, we have found that constructs able to complement scg1 are also able to inhibit the response to pheromone and mating when expressed in a wild-type SCG1 strain. Overexpression of Scg1 has a similar inhibitory effect. These results are consistent with a model proposed for the action of Scg1 as the alpha component of a heterotrimeric G protein in which the beta gamma component (Ste4/Ste18) activates the pheromone response after dissociation from Scg1. They suggest that the G alpha constructs able to complement scg1 can interact with beta gamma to prevent activation of the pathway but are unable to interact with pheromone receptors to activate the pathway.     

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.     

Regulation of the yeast pheromone response pathway by G protein subunits.

The yeast GPA1, STE4, and STE18 genes encode proteins homologous to the respective alpha, beta and gamma subunits of the mammalian G protein complex which appears to mediate the response to mating pheromones. Overexpression of the STE4 protein by the galactose-inducible GAL1 promoter caused activation of the pheromone response pathway which resulted in cell-cycle arrest in late G1 phase and induction of the FUS1 gene expression, thereby suppressing the sterility of the receptor-less mutant delta ste2. Disruption of STE18, in turn, suppressed activation of the pheromone response induced by overexpression of STE4, suggesting that the STE18 product is required for the STE4 action. However, overexpression of both the STE4 and STE18 proteins did not generate a stronger pheromone response than overexpression of STE4 in the presence of wild-type levels of STE18. These results suggest that the beta subunit is the limiting component for the pheromone response and support the idea that beta and gamma subunits act as a positive regulator. Furthermore, overexpression of GPA1 prevented cell-cycle arrest but not FUS1 induction mediated by overexpression of STE4. This implies that the alpha subunit acts as a negative regulator presumably through interacting with beta and gamma subunits in the mating pheromone signaling pathway.     

Biochemical and genetic analysis of dominant-negative mutations affecting a yeast G-protein gamma subunit.

Heterotrimeric guanine nucleotide-binding proteins (G proteins) consisting of alpha, beta, and gamma subunits mediate signalling between cell surface receptors and intracellular effectors in eukaryotic cells. To define signalling functions of G gamma subunits (STE18 gene product) involved in pheromone response and mating in the yeast Saccharomyces cerevisiae, we isolated and characterized dominant-negative STE18 alleles. We obtained dominant-negative mutations that disrupt C-terminal sequences required for prenylation of G gamma precursors (CAAX box) and that affect residues in the N-terminal half of Ste18p. Overexpression of mutant G gamma subunits in wild-type cells blocked signal transduction; this effect was suppressed upon overexpression of G beta subunits. Mutant G gamma subunits may therefore sequester G beta subunits into nonproductive G beta gamma dimers. Because mutant G gamma subunits blocked the constitutive signal resulting from disruption of the G alpha subunit gene (GPA1), they are defective in functions required for downstream signalling. Ste18p bearing a C107Y substitution in the CAAX box displayed reduced electrophoretic mobility, consistent with a prenylation defect. G gamma subunits carrying N-terminal substitutions had normal electrophoretic mobilities, suggesting that these proteins were prenylated. G gamma subunits bearing substitutions in their N-terminal region or C-terminal CAAX box (C107Y) supported receptor-G protein coupling in vitro, whereas C-terminal truncations caused partial defects in receptor coupling.     

Dual lipid modification motifs in G(alpha) and G(gamma) subunits are required for full activity of the pheromone response pathway in Saccharomyces cerevisiae

To establish the biological function of thioacylation (palmitoylation), we have studied the heterotrimeric guanine nucleotide-binding protein (G protein) subunits of the pheromone response pathway of Saccharomyces cerevisiae. The yeast G protein gamma subunit (Ste18p) is unusual among G(gamma) subunits because it is farnesylated at cysteine 107 and has the potential to be thioacylated at cysteine 106. Substitution of either cysteine results in a strong signaling defect. In this study, we found that Ste18p is thioacylated at cysteine 106, which depended on prenylation of cysteine 107. Ste18p was targeted to the plasma membrane even in the absence of prenylation or thioacylation. However, G protein activation released prenylation- or thioacylation-defective Ste18p into the cytoplasm. Hence, lipid modifications of the G(gamma) subunit are dispensable for G protein activation by receptor, but they are required to maintain the plasma membrane association of G(betagamma) after receptor-stimulated release from G(alpha). The G protein alpha subunit (Gpa1p) is tandemly modified at its N terminus with amide- and thioester-linked fatty acids. Here we show that Gpa1p was thioacylated in vivo with a mixture of radioactive myristate and palmitate. Mutation of the thioacylation site in Gpa1p resulted in yeast cells that displayed partial activation of the pathway in the absence of pheromone. Thus, dual lipidation motifs on Gpa1p and Ste18p are required for a fully functional pheromone response pathway.     

Scanning mutagenesis of regions in the Galpha protein Gpa1 that are predicted to interact with yeast mating pheromone receptors.

The mechanism by which receptors activate heterotrimeric G proteins was examined by scanning mutagenesis of the Saccharomyces cerevisiae pheromone-responsive Galpha protein (Gpa1). The juxtaposition of high-resolution structures for rhodopsin and its cognate G protein transducin predicted that at least six regions of Galpha are in close proximity to the receptor. Mutagenesis was targeted to residues in these domains in Gpa1, which included four loop regions (beta2-beta3, alpha2-beta4, alpha3-beta5, and alpha4-beta6) as well as the N and C termini. The mutants displayed a range of phenotypes from nonsignaling to constitutive activation of the pheromone pathway. The constitutive activity of some mutants could be explained by decreased production of Gpa1, which permits unregulated signaling by Gbetagamma. However, the constitutive activity caused by the F344C and E335C mutations in the alpha2-beta4 loop and F378C in the alpha3-beta5 loop was not due to decreased protein levels, and was apparently due to defects in sequestering Gbetagamma. The strongest loss of the function mutant, which was not detectably induced by a pheromone, was caused by a K314C substitution in the beta2-beta3 loop. Several other mutations caused weak signaling phenotypes. Altogether, these results suggest that residues in different interface regions of Galpha contribute to activation of signaling.     

Interactions between the ankyrin repeat-containing protein Akr1p and the pheromone response pathway in Saccharomyces cerevisiae.

Akr1p, which contains six ankyrin repeats, was identified during a screen for mutations that displayed synthetic lethality with a mutant allele of the bud emergence gene BEM1. Cells from which AKR1 had been deleted were alive but misshapen at 30 degrees C and inviable at 37 degrees C. During a screen for mutants that required one or more copies of wild-type AKR1 for survival at 30 degrees C, we isolated mutations in GPA1, which encodes the G alpha subunit of the pheromone receptor-coupled G protein. (The active subunit of this G protein is G beta gamma, and G alpha plays an inhibitory role in G beta gamma-mediated signal transduction.) AKR1 could serve as a multicopy suppressor of the lethality caused by either loss of GPA1 or overexpression of STE4, which encodes the G beta subunit of this G protein, suggesting that pheromone signaling is inhibited by overexpression of Akr1p. Mutations in AKR1 displayed synthetic lethality with a weak allele of GPA1 and led to increased expression of the pheromone-inducible gene FUS1, suggesting that Akr1p normally (and not just when overexpressed) inhibits signaling. In contrast, deletion of BEM1 resulted in decreased expression of FUS1, suggesting that Bem1p normally facilitates pheromone signaling. During a screen for proteins that displayed two-hybrid interactions with Akr1p, we identified Ste4p, raising the possibility that an interaction between Akr1p and Ste4p contributes to proper regulation of the pheromone response pathway.     

The RGS protein Crg2 regulates both pheromone and cAMP signalling in Cryptococcus neoformans

G proteins orchestrate critical cellular functions by transducing extracellular signals into internal signals and controlling cellular responses to environmental cues. G proteins typically function as switches that are activated by G protein-coupled receptors (GPCRs) and negatively controlled by regulator of G protein signalling (RGS) proteins. In the human fungal pathogen Cryptococcus neoformans, three G protein alpha subunits (Gpa1, Gpa2 and Gpa3) have been identified. In a previous study, we identified the RGS protein Crg2 involved in regulating the pheromone response pathway through Gpa2 and Gpa3. In this study, a role for Crg2 was established in the Gpa1-cAMP signalling pathway that governs mating and virulence. We show that Crg2 physically interacts with Gpa1 and crg2 mutations increase cAMP production. crg2 mutations also enhance mating filament hyphae production, but reduce cell-cell fusion and sporulation efficiency during mating. Although crg2 mutations and the Gpa1 dominant active allele GPA1(Q284L) enhanced melanin production under normally repressive conditions, virulence was attenuated in a murine model. We conclude that Crg2 participates in controlling both Gpa1-cAMP-virulence and pheromone-mating signalling cascades and hypothesize it may serve as a molecular interface between these two central signalling conduits.