In Saccharomyces cerevisiae the subcellular distribution of Bcy1 is carbon source dependent. In glucose-grown cells, Bcy1 is almost exclusively nuclear, while it appears more evenly distributed between nucleus and cytoplasm in carbon source-derepressed cells. Here we show that phosphorylation of its N-terminal domain directs Bcy1 to the cytoplasm. Biochemical fractionation revealed that the cytoplasmic fraction contains mostly phosphorylated Bcy1, whereas unmodified Bcy1 is predominantly present in the nuclear fraction. Site-directed mutagenesis of two clusters (I and II) of serines near the N terminus to alanine resulted in an enhanced nuclear accumulation of Bcy1 in ethanol-grown cells. In contrast, substitutions to Asp led to a dramatic increase of cytoplasmic localization in glucose-grown cells. Bcy1 modification was found to be dependent on Yak1 kinase and, consequently, in ethanol-grown yak1 cells the Bcy1 remained nuclear. A two-hybrid screen aimed to isolate genes encoding proteins that interact with the Bcy1 N-terminal domain identified Zds1. In ethanol-grown zds1 cells, cytoplasmic localization of Bcy1 was largely absent, while overexpression of ZDS1 led to increased cytoplasmic Bcy1 localization. Zds1 does not regulate Bcy1 modification since this was found to be unaffected in zds1 cells. However, in zds1 cells cluster II-mediated, but not cluster I-mediated, cytoplasmic localization of Bcy1 was found to be absent. Altogether, these results suggest that Zds1-mediated cytoplasmic localization of Bcy1 is regulated by carbon source-dependent phosphorylation of cluster II serines, while cluster I acts in a Zds1-independent manner.Throughout the eukaryotic kingdom cyclic AMP (cAMP)-dependent protein kinases (PKAs) play important and diverse roles in signal transduction (for reviews, see references 2, 7, and 28 and references therein). Structurally, PKAs are conserved, consisting of two catalytic subunits that bind, in their inactive configuration, to a regulatory subunit homodimer. Binding of cAMP to the regulatory subunit results in dissociation, and thereby activation, of the catalytic subunits (7, 28). The multitude of intracellular PKA substrates and their different subcellular distribution raises important questions about the specificity, timing, and substrate targeting of PKA-mediated signaling. One regulatory level to ensure proper signal transduction is specific targeting of signaling components to subcellular compartments. In multicellular eukaryotes A-kinase anchor proteins (AKAPs) have been identified that target type I or type II (RI or RII) PKA-regulatory subunits to their effector substrates localized in various subcellular compartments (for recent reviews, see references 5 and 6 and references therein). AKAPs possess a site for constitutive avid binding of RI or RII and a targeting domain that complexes with subcellular structures. Directing PKA to specific microenvironments facilitates phosphorylation of colocalized effector molecules.In contrast to cells from multicellular organisms, yeast...
