Substrate priming enhances phosphorylation by the budding yeast kinases Kin1 and Kin2.

Multisite phosphorylation of proteins is a common mechanism for signal integration and amplification in eukaryotic signaling networks. Proteins are commonly phosphorylated at multiple sites in an ordered manner, whereby phosphorylation by one kinase primes the substrate by generating a recognition motif for a second kinase. Here we show that substrate priming promotes phosphorylation by Saccharomyces cerevisiae Kin1 and Kin2, kinases that regulate cell polarity, exocytosis, and the endoplasmic reticulum (ER) stress response. Kin1/Kin2 phosphorylated substrates within the context of a sequence motif distinct from those of their most closely related kinases. In particular, the rate of phosphorylation of a peptide substrate by Kin1/Kin2 increased >30-fold with incorporation of a phosphoserine residue two residues downstream of the phosphorylation site. Recognition of phosphorylated substrates by Kin1/Kin2 was mediated by a patch of basic residues located in the region of the kinase αC helix. We identified a set of candidate Kin1/Kin2 substrates reported to be dually phosphorylated at sites conforming to the Kin1/Kin2 consensus sequence. One of these proteins, the t-SNARE protein Sec9, was confirmed to be a Kin1/Kin2 substrate both in vitro and in vivo Sec9 phosphorylation by Kin1 in vitro was enhanced by prior phosphorylation at the +2 position. Recognition of primed substrates was not required for the ability of Kin2 to suppress the growth defect of secretory pathway mutants but was necessary for optimal growth under conditions of ER stress. These results suggest that at least some endogenous protein substrates of Kin1/Kin2 are phosphorylated in a priming-dependent manner.

In vitro reconstitution of Rab GTPase-dependent vesicle clustering by the yeast lethal giant larvae/tomosyn homolog, Sro7.

Intracellular traffic in yeast between the Golgi and the cell surface is mediated by vesicular carriers that tether and fuse in a fashion that depends on the function of the Rab GTPase, Sec4. Overexpression of either of two Sec4 effectors, Sro7 or Sec15, results in the formation of a cluster of post-Golgi vesicles within the cell. Here, we describe a novel assay that recapitulates post-Golgi vesicle clustering in vitro utilizing purified Sro7 and vesicles isolated from late secretory mutants. We show clustering in vitro closely replicates the in vivo clustering process as it is highly dependent on both Sro7 and GTP-Sec4. We also make use of this assay to characterize a novel mutant form of Sro7 that results in a protein that is specifically defective in vesicle clustering both in vivo and in vitro. We show that this mutation acts by effecting a conformational change in Sro7 from the closed to a more open structure. Our analysis demonstrates that the N-terminal propeller needs to be able to engage the C-terminal tail for vesicle clustering to occur. Consistent with this, we show that occupancy of the N terminus of Sro7 by the t-SNARE Sec9, which results in the open conformation of Sro7, also acts to inhibit vesicle cluster formation by Sro7. This suggests a model by which a conformational switch in Sro7 acts to coordinate Rab-mediated vesicle tethering with SNARE assembly by requiring a single conformational state for both of these processes to occur.