Abstract
Control of glycogen synthase activity by protein phosphorylation is important for regulating the synthesis of glycogen. In this report, we describe a regulatory linkage between the ability of yeast cells to respire and activation of glycogen synthase. Strains containing respiration-deficient mutations in genes such as COQ3, required for the synthesis of coenzyme Q, were reduced in their ability to accumulate glycogen in response to limiting glucose. This lowered glycogen accumulation results from inactivation of the rate-determining enzyme, glycogen synthase (Gsy2p). Reduced glycogen synthase activity is coincident with lowered glucose 6-phosphate and ATP levels in the respiration-deficient cells deprived of glucose. Alanine substitutions of three previously characterized phosphorylation sites in Gsy2p, Ser-650, Ser-654, or Thr-667, each suppressed the glycogen defect in cells unable to respire, suggesting that inactivation of this enzyme is mediated by phosphorylation of these residues. Inactivation of glycogen synthase requires the RAS signaling pathway that controls cAMP-dependent protein kinase and is independent of Pho85p previously identified as a Gsy2p kinase. These results suggest that yeast cells unable to shift from a fermentative to a respiratory metabolic regimen block accumulation of glycogen by inactivating Gsy2p through protein phosphorylation.
Highlights
Expression of many metabolic pathways in yeast is regulated by the availability of nutrients in the growth medium
These results suggest that while the cAMP-dependent protein kinase (cAPK) pathway is required for inactivation of Gsy2p in coq3 mutant cells, there is no sustained elevation of cAMP levels or cAPK activity during the lag or second growth phase compared with respiration-competent strains
It was proposed that lowered ATP levels found in respirationdeficient cells growing in glucose-depleted medium impair the energy-requiring pathway leading to glycogen synthesis [29]
Summary
Expression of many metabolic pathways in yeast is regulated by the availability of nutrients in the growth medium. GSY2 transcription is increased as cells deplete glucose from their growth medium [6] Release of this glucose repression is mediated by the cAMP pathway, which, in yeast, is regulated by Ras1p and Ras2p (6 –14). Gsy2p continues to be significantly phosphorylated in pho mutant cells grown to early stationary phase, suggesting that there is at least one other protein kinase that can reduce glycogen synthase activity by phosphorylation [18, 20]. Our results strongly suggest that this lowered glycogen accumulation is the direct result of hyperphosphorylation of Gsy2p, leading to a block in the activation of this rate-determining enzyme This inactivation of Gsy2p requires the Ras2p signaling pathway that controls cAPK and is independent of Pho85p kinase
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