Abstract
Eukaryotic glycogen synthase activity is regulated by reversible phosphorylation at multiple sites. Of the two GS isoforms found in mammals, the muscle enzyme (muscle glycogen synthase) has received more attention and the relative importance of every known phosphorylation site in the control of its activity and intracellular distribution has been previously addressed. We have analyzed the impact of the dephosphorylation at the homologous sites of the glycogen synthase liver (LGS) isoform. Serine residues at these sites were replaced by non-phosphorylatable alanine residues, singly or in pairs, and the resultant LGS variants were expressed in cultured cells using adenoviral vectors. The sole mutation at site 2 (Ser7) yielded an enzyme that was almost fully active and able to induce glycogen deposition in primary hepatocytes incubated in the absence of glucose and in FTO2B cells, a cell line that does not normally synthesize glycogen. Mutation at site 2 was also sufficient to trigger the aggregation and translocation of LGS from the cytoplasm to the hepatocyte cell cortex in the absence of glucose. However, this redistribution was not observed in hepatocytes incubated without glucose when an additional mutation (E509A), which renders the enzyme inactive, was introduced. This result suggests that LGS translocation is strictly dependent on glycogen synthesis.
Highlights
In mammals there are two GS isoforms, liver glycogen synthase (LGS), whose expression is tissue-specific, and muscle glycogen synthase (MGS), which is expressed in almost all tissues (1)
Rat primary hepatocytes were infected with these adenoviruses or with control adenoviruses encoding -galactosidase from Escherichia coli (-galactosidase) or wild-type rat LGS (LGS WT)
By analyzing total GS activity in cell homogenates, we first checked that similar amounts of the liver glycogen synthase WT (LGS WT) and mutant forms were expressed in all cases (Fig. 2A)
Summary
CCACCTGCCCCATCAGG and reverse primer, 5Ј-CCTGATGGGGCAGGTGGTACTG; site 3c forward primer, CCCCA-. Construction of Recombinant Adenoviruses—Recombinant TCAGGAGCCCAGACTTC and reverse primer, GAAGTCT-. Adenovirus coding for wild-type liver GS (LGS WT) has been GGGCTCCTGATGGGG; site 4 forward primer, CCATCAG-. Ser to Ala mutations were introduced into GATCCCAGACTTCAGCTCCTCAGAGC and reverse primer, pACCMV-RnLGS plasmid at sites 2, 2a, 3a, 3b, 3c, 4, and 5 by GCTCTGAGGAGCTGAAGTCTGGGATCCTGATGG; and site-directed mutagenesis using the following primers: site 2 site 5 forward primer, CTCAGAGCGCCGATGTGGAAAAC-. The adenoviruses coding for mutated LGS in these. GAG; site 2a forward primer, CTGTGACGGCCCTTGG- sites or in combinations of two were constructed as described. RnLGS and pACCMV-RnLGS 2 ϩ 3b plasmids using the forward primer (ccatcatactatgcgccctggggttacacg) and reverse primer (CGTGTAACCCCAGGGCGCATAGTATGATGG). The LGS sequence is shorter than that of MGS and does not contain sites 1a and 1b. (w/v) collagen solution (Sigma) at a final density of 8 ϫ 104 cells/cm
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
