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.

G-protein palmitoyltransferase activity is enriched in plasma membranes.

Heterotrimeric G proteins are covalently modified by lipids. Myristoylation of G-protein alpha subunits and prenylation of gamma subunits are stable modifications. In contrast, palmitoylation of alpha subunits is dynamic and thus has the potential for regulating protein function. Indeed, receptor activation of Gs increases palmitate turnover on the alpha subunit, presumably by stimulating deacylation. The enzymes that catalyze reversible palmitoylation of G-protein alpha subunits have not been characterized. Here we report the identification of a palmitoyl-CoA:protein S-palmitoyltransferase activity that acylates G-protein alpha subunits in vitro. Palmitoyltransferase activity is membrane-associated and requires detergent for solubilization. The preferred G-protein substrate for the enzyme activity is the alpha subunit in the context of the heterotrimer. Both myristoylated and nonmyristoylated G-protein alpha subunits are recognized as substrates. The palmitoyltransferase activity demonstrates a modest preference for palmitoyl-CoA over other fatty acyl-CoA substrates. Palmitoyltransferase activity is high in plasma membrane and present at low or undetectable levels in Golgi, endoplasmic reticulum, and mitochondria of rat liver. The subcellular localization of this enzyme activity is consistent with a role for regulated cycles of acylation and deacylation accompanying activation of G-protein signal transduction pathways.

An arginyl-transfer ribonucleic Acid protein transferase from cereal embryos.

Embryos from rice (Oryza sativa L. var. Bluebonnet) and wheat (Triticum aestivum L.) contain an aminoacyl-tRNA protein transferase which transfers arginine from arginyl-tRNA to the N terminus of a protein acceptor. The activity was measured in vitro in a reaction mixture containing embryo supernatant fraction, buffer, sulfhydryl reagent, and arginyl-tRNA. It was not dependent on the usual cofactors for ribosomal protein synthesis, nor was it sensitive to cycloheximide or puromycin. However, the activity was inhibited by ribonuclease. The enzyme was purified 33-fold from a crude homogenate of rice embryos. An apparent endogenous substrate from rice embryos was prepared free of transferase activity; however, the transferase was not purified sufficiently to show absolute dependence on the presence of this endogenous substrate.