Sexual identity in the yeast Saccharomyces cerevisiae is controlled by the MAT locus. Transcriptional activators and repressors encoded by MATa or MATα alleles control the expression of a limited number of cell type-specific gene products that distinguish the two haploid mating types, the a cell and the α cell (24, 31). Chief among the cell type-specific products expressed is a receptor-ligand system which is used to direct the mating of the a and the α cells to form the a/α diploid. The a cell secretes the farnesylated peptide a-factor and expresses at its surface the α-factor receptor (Ste2p), a G protein-coupled receptor which confers detection of the α-factor peptide specifically produced and secreted by the α cell. Likewise, the α cell expresses a distinct G protein-coupled receptor, the a-factor receptor (Ste3p), which detects the a-factor secreted by the a cell. This system of pheromones and receptors enables the communication of mating (for reviews, see references 18 and 19). Detection of pheromone alerts the cell to the proximity of a potential mating partner and prepares the cell for conjugation both through transcriptional induction of mating genes and through arrest of the cell cycle in G1 at Start. Through polarized growth of the cell body, the two mating partners extend mating projections towards one another. The tips of the mating projections meet, cells adhere to one another, and, with the joining of the cell walls, the prezygote is formed. Finally, with dissolution of the intervening cell walls and subsequent fusion of cytoplasms and nuclei, the diploid zygote is formed: a cell with a characteristic dumbbell morphology, having two terminal bulbs derived from the cell bodies of the two haploid mating partners connected via a conjugation bridge derived from the tip-to-tip fusion of the two mating projections. The mating process culminates with the transition of the new diploid cell to vegetative growth: the cells transition from G1 to S, DNA replication is initiated, and a first mitotic bud begins to emerge from the midpoint of the zygotic conjugation bridge. Prior to zygote formation, during mating, pheromone signaling activates the cell cycle kinase inhibitor protein Far1p, which binds to and inhibits the Cdc28/Cln cell cycle kinase, and thus causes G1 arrest. The reinitiation of the mitotic cycle for the new diploid cell requires that this inhibition be relieved. The STE3DAF mutation is a STE3 promoter mutation which confers cell type-independent expression of the a-factor receptor (Ste3p) (13). With this mutant it was found that the inappropriate expression of Ste3p in the a cell context leads to a striking inhibition of the pheromone signal transduction pathway, apparently exerted at the level of the Gβγ component of the heterotrimeric G protein, i.e., the first postreceptor signaling step (6, 13, 17). Inhibition depends on Ste3p and at least one MATa-specific gene product that is neither a-factor nor Ste2p (13). As Ste3p and the hypothetical a-specific interactor normally reside in different cell types, the biological relevance of this striking interaction has remained a mystery. Kim et al. (17) have suggested that Ste3p and its a cell interactor may gain access to one another in the zygote following fusion of the two mating partners and that the resulting inhibition of the pheromone response could serve to promote the transition of the zygote into a vegetative mode of growth. The present work identifies the a-specific Ste3p interactor as Asg7p and provides evidence which suggests that the inhibition of the pheromone response provided by Ste3p-Asg7p may indeed play a role in promoting the transition of the zygote to vegetative growth.