Deletion of SNF1 affects the nutrient response of yeast and resembles mutations which activate the adenylate cyclase pathway.

We have isolated a snf1/ccr1 mutant of Saccharomyces cerevisiae which loses viability upon starvation and fails to accumulate glycogen in response to abrupt depletion of phosphate or glucose. A snf1 null mutant is sensitive to heat stress and starvation and fails to accumulate glycogen during growth in rich medium. The phenotypes of the snf1 mutants are those commonly associated with an overactivation of the adenylate cyclase pathway. Mutations in adenylate cyclase or RAS2 which decrease the level of cAMP in the cell moderate the snf1 phenotype. In contrast, a mutation in RAS2 (RAS2val19) which increases the level of cAMP or a mutation in the regulatory subunit (BCY1) of cAMP-dependent protein kinase which results in unregulated cAMP-dependent protein kinase activity accentuates the snf1 phenotype. However, the action of SNF1 in the stress response appears at least partly independent of cAMP-dependent protein kinase because a snf1 phenotype is observed in a strain that lacks all three of the genes that encode the catalytic subunits of cAMP-dependent protein kinase. SNF1 therefore acts at least in part through a cAMP-independent pathway.

Exogenous expression of Msx1 renders myoblasts refractory to differentiation into myotubes and elicits enhanced biosynthesis of four unique mRNAs.

Murine myoblast cell lines stably transfected with expression vectors containing homeobox Msx1 cDNA in sense (F31-c) or antisense (F3R1) orientation have contrasting phenotypes. F3R1 cells readily differentiate in medium containing low serum whereas F31-c cells fail to differentiate under these conditions. The mechanism by which exogenous overexpression of Msx1 leads to the altered phenotype of F31-c cells and the downstream targets of Msx1 are unknown. Using the method of differential display, we have identified four cDNAs that represent transcripts up-regulated in F31-c. Two of these cDNAs are homologous to ribosomal proteins S23 and S24 while the third has homology to sequences in the murine Tcp-1 gene. A fourth cDNA does not have appreciable homology to cDNA sequences deposited in the NIH GenBank. Since withdrawal from the cell cycle and enhanced expression of MyoD commonly precede differentiation of myoblasts into myotubes, we also examined regulation of the major cell cycle proteins as well as MyoD by Western blot analysis. We show that the levels of Cdks 2, 4 and 6, cyclins A and D, and the Cdk inhibitor p27 in both proliferating and serum-starved F31-c cells were similar to those in F3R1. Finally, although MyoD protein levels increased in both cell types after 72 h incubation in serum depleted medium, the levels of MyoD in serum-starved F31-c cells were 2-4 fold lower. We postulate that the reduced amount of MyoD is sufficient to permit reversible withdrawal of F31-c cells from the cell cycle, but is inadequate to permit myogenesis.

GAC1 may encode a regulatory subunit for protein phosphatase type 1 in Saccharomyces cerevisiae.

Elevated dosage of the GAC1 gene from the yeast Saccharomyces cerevisiae causes hyperaccumulation of glycogen whereas a gene disruption of GAC1 results in reduced glycogen levels. Glycogen synthase is almost entirely in the active, glucose 6-phosphate-independent, form in cells with increased gene dosage of GAC1 whereas the enzyme is mostly in the inactive form in strains lacking GAC1. GAC1 encodes an 88 kDa protein that is similar to the regulatory subunit (RG1) of phosphoprotein phosphatase type 1 (PP-1) from skeletal muscle that targets PP-1 to glycogen particles. Taken together, these results suggest that GAC1 encodes a regulatory subunit of PP-1. As previously shown for glycogen phosphorylase (GPH1), GAC1 RNA accumulates concomitantly with the appearance of glycogen. A strain with a mutation in the regulatory subunit of the cAMP-dependent protein kinase (bcy1) fails to accumulate GPH1 and GAC1 RNA. These results point to coordinate regulation of enzymes involved in glycogen metabolism at the level of RNA accumulation and indicate that at least part of this control is exerted by the RAS-cAMP pathway.