Isozymes of glycogen synthase

Mutant alleles of the gene PFK2 have been obtained that alter the sensitivity to ATP inhibition of the soluble yeast phosphofructokinase. One of the alleles makes the enzyme sensitive to micromolar concentrations of ATP. Intragenic revertants of PFK2 mutants confirm that the PFK2 gene determines not only the regulatory properties of the soluble enzyme but also the catalytic activity of particulate phosphofructokinase.     

Allosteric regulation of glycogen synthase controls glycogen synthesis in muscle

Glycogen synthase (GS), a key enzyme in glycogen synthesis, is activated by the allosteric stimulator glucose-6-phosphate (G6P) and by dephosphorylation through inactivation of GS kinase-3 with insulin. The relative importance of these two regulatory mechanisms in controlling GS is not established, mainly due to the complex interplay between multiple phosphorylation sites and allosteric effectors. Here we identify a residue that plays an important role in the allosteric activation of GS by G6P. We generated knockin mice in which wild-type muscle GS was replaced by a mutant that could not be activated by G6P but could still be activated normally by dephosphorylation. We demonstrate that knockin mice expressing the G6P-insensitive mutant display an ～80% reduced muscle glycogen synthesis by insulin and markedly reduced glycogen levels. Our study provides genetic evidence that allosteric activation of GS is the primary mechanism by which insulin promotes muscle glycogen accumulation in?vivo.     

Calmodulin-dependent glycogen synthase kinase

A cAMP-independent glycogen synthase kinase has been purified from rabbit liver. This kinase is completely dependent on the presence of calmodulin and Ca2+ for activity. Half-maximal activation required about 0.1 microM calmodulin. Complete inhibition was obtained in the presence of ethylene glycol bis(beta-aminoethyl ether)N,N,N',N'-tetraacetic acid or trifluoperazine. This calmodulin-dependent synthase kinase does not phosphorylate phosphorylase, myosin light chain, casein, or histone. It rapidly incorporates 0.4 to 0.5 mol of 32P/mol of synthase subunit into the NH2-terminal domain, resulting in partial inactivation of glycogen synthase. These results indicate the existence of a calmodulin-dependent kinase which may be specific for glycogen synthase.     

Inhibitory effect of polycations on phosphorylation of glycogen synthase by glycogen synthase kinase 3

Several polycations were tested for their abilities to inhibit the activity of glycogen synthase kinase 3 (GSK-3). L-Polylysine was the most powerful inhibitor of GSK-3 with half-maximal inhibition of glycogen synthase phosphorylation occurring at approx. 100 nM. D-Polylysine and histone H1 were also inhibitory, but the concentration dependence was complex, and DL-polylysine was the least effective inhibitor. Spermine caused about 50% inhibition of GSK-3 at 0.7 mM and 70% inhibition at 4 mM. Inhibition of GSK-3 by L-polylysine could be blocked or reversed by heparin. A heat-stable polycation antagonist isolated from swine kidney cortex also blocked the inhibitory effect of L-polylysine on GSK-3 and blocked histone H1 stimulation of protein phosphatase 2A activity. Under the conditions tested, L-polylysine also inhibited GSK-3 catalyzed phosphorylation of type II regulatory subunit of cAMP-dependent protein kinase and a 63 kDa brain protein, but only slightly inhibited phosphorylation of inhibitor 2 or proteolytic fragments of glycogen synthase that contain site 3 (a + b + c). L-Polylysine at a concentration (200 nM) that caused nearly complete inhibition of GSK-3 stimulated casein kinase I and casein kinase II, but had virtually no effect on the catalytic subunit of cAMP-dependent protein kinase. These results suggest that polycations can be useful in controlling GSK-3 activity. Polycations have the potential to decrease the phosphorylation state of glycogen synthase at site 3, both by inhibiting GKS-3 as shown in this study and by stimulating the phosphatase reaction as shown previously (Pelech, S. and Cohen, P. (1985) Eur. J. Biochem. 148, 245-251).     

Calcium-dependent regulation of glycogen synthase activity in a muscle glycogen particle

The calcium-dependent inactivation of glycogen synthase in an isolated glycogen-protein complex (glycogen pellet) from rabbit skeletal muscle has been investigated. Addition of 1 mm Ca²⁺, 10 mm Mg²⁺, and 1 mm ATP-γ-S to a concentrated suspension of glycogen pellet resulted in a rapid activation of glycogen phosphorylase concomitant with an inactivation of glycogen synthase. These conversion reactions were blocked by ethylene glycol bis(β-aminoethyl ether) N, N′-tetraacetic acid or by pretreatment of the complex with an antiserum to purified phosphorylase kinase. These data suggest that in the glycogen-protein complex, which may be a functional unit of glycogen metabolism in vivo, phosphorylase kinase can catalyze a Ca²⁺-dependent activation of glycogen phosphorylase synchronized with an inactivation of glycogen synthase. If under similar conditions phosphoprotein phosphatase activity was assayed using exogenous [³²P]phosphorylase, there was an apparent inactivation of the phosphatase. Evidence is presented that this apparent inactivation of phosphatase was due to an accumulation of endogenous phosphorylase a which acted as an inhibitor to the exogenous [³²P]-phosphorylase.     

Overexpression of glycogen synthase in mouse muscle results in less branched glycogen

Glycogen, a branched polymer of glucose, serves as an energy reserve in many organisms. The degree of branching likely reflects the balance between the activities of glycogen synthase and branching enzyme. Mice overexpressing constitutively active glycogen synthase in skeletal muscle (GSL30) have elevated muscle glycogen. To test whether excess glycogen synthase activity affected glycogen branching, we examined the glycogen from skeletal muscle of GSL30 mice. The absorption spectrum of muscle glycogen determined in the presence of iodine was shifted to higher wavelengths in the GSL30 animals, consistent with a decrease in the degree of branching. As judged by Western blotting, the levels of glycogenin and the branching enzyme were also elevated. Branching enzyme activity also increased approximately threefold. However, this compared with an increase in glycogen synthase of some 50-fold, so that the increase in branching enzyme in response to overexpression of glycogen synthase was insufficient to synthesize normally branched glycogen.     

Kinetic properties of glycogen synthase from skeletal muscle after phosphorylation by glycogen synthase kinase 4

Glycogen synthase I (EC 2.4.1.11) from rat and from rabbit skeletal muscle was phosphorylated in vitro by glycogen synthase kinase 4 (EC 2.7.1.37) to the extent of 0.8 phosphates/subunit. For both phosphorylated enzymes, the activity ratio (activity without glucose 6-P divided by activity with 8 mM glucose 6-P) was 0.8 when determined with low concentrations of glycogen synthase and/or short incubation times. However, the activity ratio was 0.5 with high enzyme concentrations and longer incubation times. It was found that the lower activity ratios result largely from UDP inhibition of activity measured in the absence of glucose 6-P. Inhibition by UDP was much less pronounced for glycogen synthase I, indicating that a major consequence of phosphorylation by glycogen synthase kinase 4 is an increased sensitivity to UDP inhibition.     

Characteristic properties of the complex of glycogen synthase with glycogen

The glycogen synthase I--glycogen complex isolated from rabbit skeletal muscles is stable during precipitation with trichloroacetic acid and Sepharose 2B chromatography. The complex catalyzes the synthesis (lengthening) of the alpha-1.4-glucosyl chains when endogenous or exogenous enzyme-free glycogen is used, the initial rates of this synthesis being identical. Preincubation with glycogen does not cause activation of the complex or formation of additional glycogen synthase I--polysaccharide bonds. The complex is characterized by saturation with respect to glycogen; the molar concentration ratios of the non-reducible chain and protein monomer within the complex does not exceed 100. An increase in the length of the synthesized alpha-1.4-glycosyl chains of glycogen results in a decrease of the rate of the glycogen synthase reaction in time.     

Control of glycogen content in retina: allosteric regulation of glycogen synthase

Retinal tissue is exceptional because it shows a high level of energy metabolism. Glycogen content represents the only energy reserve in retina, but its levels are limited. Therefore, elucidation of the mechanisms controlling glycogen content in retina will allow us to understand retina response under local energy demands that can occur under normal and pathological conditions. Thus, we studied retina glycogen levels under different experimental conditions and correlated them with glucose-6-phosphate (G-6-P) content and glycogen synthase (GS) activity. Glycogen and G-6-P content were studied in ex vivo retinas from normal, fasted, streptozotocin-treated, and insulin-induced hypoglycemic rats. Expression levels of GS and its phosphorylated form were also analyzed. Ex vivo retina from normal rats showed low G-6-P (14±2 pmol/mg protein) and glycogen levels (43±3 nmol glycosyl residues/mg protein), which were increased 6 and 3 times, respectively, in streptozotocin diabetic rats. While no changes in phosphorylated GS levels were observed in any condition tested, a positive correlation was found between G-6-P levels with GS activity and glycogen content. The results indicated that in vivo, retina glycogen may act as an immediately accessible energy reserve and that its content was controlled primarily by G-6-P allosteric activation of GS. Therefore, under hypoglycemic situations retina energy supply is strongly compromised and could lead to the alterations observed in type 1 diabetes.     

Contraction-mediated inactivation of glycogen synthase is accompanied by inactivation of glycogen synthase phosphatase in human skeletal muscle.

Activities of glycogen synthase (GS) and GS phosphatase were determined on human muscle biopsies before and after isometric contraction at 2/3 maximal voluntary force. Total GS activity did not change during contraction (4.92 +/- 0.70 at rest versus 5.00 +/- 0.42 mmol/min per kg dry wt.; mean +/- S.E.M.), whereas both the active form of GS and the ratio of active form to total GS decreased by approximately 35% (P less than 0.01). GS phosphatase was inactivated in all subjects by an average of 39%, from 5.95 +/- 1.30 to 3.63 +/- 0.97 mmol/min per kg dry wt. (P less than 0.01). It is suggested that at least part of the contraction-induced inactivation of GS is due to an inactivation of GS phosphatase.     

Electron microscope studies of glycogen synthase

Summary Glycogen synthase from rabbit muscle was examined with the electron microscope. In preparations of the completely converted glucose-6-phosphate dependent form (GSD) and the independent form (GSI) three structures were observed: toroids, hexagons and stacks of four elements which appear to be aggregates of four toroids. Toroids can be formed from hexagons by radial inward movement of subunits which form the vertices of the hexagons. Analysis of the dimensions of these structures and comparison of the known chemistry of the enzyme to the subunits as inferred from electron microscopy suggests a model for the structure of glycogen synthase. The model allows predictions of types of subunits in the enzyme, their relation to phosphorylatable and -SH sites and the possibilities of control by small effector molecules.     

Multisite phosphorylation of glycogen synthase. Molecular basis for the substrate specificity of glycogen synthase kinase-3 and casein kinase-II (glycogen synthase kinase-5)

Glycogen synthase kinase-3 was isolated from rabbit skeletal muscle by an improved procedure. The purification was estimated to be 67000-fold and 0.2 mg of enzyme was isolated from 5000 g muscle, corresponding to an overall yield of 7%. The preparation was homogeneous by ultracentrifugal and electrophoretic criteria. The enzyme had a relative molecular mass of 47 kDa by sedimentation equilibrium centrifugation and 51 kDa by SDS-polyacrylamide gel electrophoresis. These values demonstrate that glycogen synthase kinase-3 is monomeric. The Stokes radius of 37 nm suggests the molecule to be asymmetric. The activating factor of the Mg-ATP dependent form of protein phosphatase-1 coeluted with glycogen synthase kinase-3 activity at the final step, establishing that these two activities reside in the same protein. Glycogen synthase kinase-3 phosphorylates glycogen synthase at sites-3, while casein kinase-II phosphorylates site-5, just C-terminal to sites-3 (Picton, C., Aitken, A., Bilham, T. and Cohen, P. (1982) Eur. J. Biochem. 124, 37-45). The basis for the substrate specificities of these protein kinases was investigated using chymotryptic peptides that contain the sites phosphorylated by each enzyme. These studies showed that efficient phosphorylation of sites-3, required the presence of phosphate in site-5 and a region of polypeptide more than 20 residues C-terminal to site-5. In contrast, efficient phosphorylation by casein kinase-II does not require this C-terminal region, and the results are consistent with the view that the enzyme recognises acidic residues immediately C-terminal to site-5.     

Purification of bovine heart glycogen synthase

Glycogen synthase was purified to apparent homogeneity from bovine heart muscle by a procedure involving precipitation of the enzyme in the presence of added glycogen by polyethylene glycol, chromatography on DEAE-Sephacel, and high-speed centrifugation through a sucrose-containing buffer. The enzyme was maintained in the presence of glycogen during the isolation procedure. Glycogen synthase I and D preparations were obtained having specific activities of 21-25 and 30-35 units/mg protein at pH 7.8 and 30 degrees C and having activity ratios of 0.5-0.6 and 0.05-0.10, respectively, when assayed in the absence and in the presence of glucose 6-P.     

Physiological hyperinsulinemia impairs insulin-stimulated glycogen synthase activity and glycogen synthesis

Although chronic hyperinsulinemia has been shown to induce insulin resistance, the basic cellular mechanisms responsible for this phenomenon are unknown. The present study was performed 1) to determine the time-related effect of physiological hyperinsulinemia on glycogen synthase (GS) activity, hexokinase II (HKII) activity and mRNA content, and GLUT-4 protein in muscle from healthy subjects, and 2) to relate hyperinsulinemia-induced alterations in these parameters to changes in glucose metabolism in vivo. Twenty healthy subjects had a 240-min euglycemic insulin clamp study with muscle biopsies and then received a low-dose insulin infusion for 24 (n = 6) or 72 h (n = 14) (plasma insulin concentration = 121 +/- 9 or 143 +/- 25 pmol/l, respectively). During the baseline insulin clamp, GS fractional velocity (0.075 +/- 0.008 to 0.229 +/- 0.02, P < 0.01), HKII mRNA content (0.179 +/- 0.034 to 0.354 +/- 0.087, P < 0.05), and HKII activity (2.41 +/- 0.63 to 3.35 +/- 0.54 pmol x min(-1) x ng(-1), P < 0.05), as well as whole body glucose disposal and nonoxidative glucose disposal, increased. During the insulin clamp performed after 24 and 72 h of sustained physiological hyperinsulinemia, the ability of insulin to increase muscle GS fractional velocity, total body glucose disposal, and nonoxidative glucose disposal was impaired (all P < 0.01), whereas the effect of insulin on muscle HKII mRNA, HKII activity, GLUT-4 protein content, and whole body rates of glucose oxidation and glycolysis remained unchanged. Muscle glycogen concentration did not change [116 +/- 28 vs. 126 +/- 29 micromol/kg muscle, P = nonsignificant (NS)] and was not correlated with the change in nonoxidative glucose disposal (r = 0.074, P = NS). In summary, modest chronic hyperinsulinemia may contribute directly (independent of change in muscle glycogen concentration) to the development of insulin resistance by its impact on the GS pathway.     

Regulation of glycogen synthase activation in isolated hepatocytes

Molecular and Cellular Biochemistry - Glycogen synthase, the regulatory enzyme of glycogen synthesis undergoes multisite phosphorylation leading to its inactivation. The kinases responsible for...     

Phosphorylation of glycogen synthase in isolated rabbit hepatocytes

Specific antibodies were used to purify glycogen synthase from isolated rabbit hepatocytes that had been incubated in a medium containing [³²P]phosphate. The enzyme gave rise to two main ³²P-labeled CNBr fragments of electrophoretic mobilities similar to those obtained after phosphorylation of the enzyme by individual protein kinases in vitro.     

Phosphorylation of rat liver glycogen synthase bound to the glycogen particle

Rat liver glycogen synthase bound to the glycogen particle was partially purified by repeated high-speed centrifugation. This synthase preparation was labeled with ³²P by incubations with cAMP-dependent protein kinase and cAMP-independent synthase (casein) kinase-1 in the presence of [γ-³²P]ATP. The phosphorylated synthase was separated from other proteins in the glycogen pellet by immunoprecipitation with rabbit anti-rat liver glycogen synthase serum. Analysis of the immunoprecipitates by sodium dodecyl sulfate-gel electrophoresis showed that synthase subunits of M_r 85,000 and 80,000 were present in varying proportions. The ³²P-labeled synthase in the immunoprecipitate was digested with trypsin, and the resulting peptides were analyzed by isoelectric focusing. Synthase bound to the glycogen particle was phosphorylated by cAMP-dependent protein kinase at more sites and by cAMP-independent synthase (casein) kinase-1 at less sites than when the homogeneous synthase was incubated with these kinases. Phosphorylation of synthase in the glycogen pellet by either cAMP-dependent protein kinase or cAMP-independent synthase (casein) kinase-1 did not cause a significant inactivation as has been observed when the homogeneous synthase was incubated with these kinases. Inactivation of synthase in the glycogen pellet, however, can be achieved by the combination of both kinases. This inactivation appears to result from the phosphorylation of a new site by cAMP-independent synthase (casein) kinase-1 neighboring a site previously phosphorylated by cAMP-dependent protein kinase.     

Interaction between glycogenin and glycogen synthase

Glycogen synthase plays a key role in regulating glycogen metabolism. In a search for regulators of glycogen synthase, a yeast two-hybrid study was performed. Two glycogen synthase-interacting proteins were identified in human skeletal muscle, glycogenin-1, and nebulin. The interaction with glycogenin was found to be mediated by the region of glycogenin which contains the 33 COOH-terminal amino acid residues. The regions in glycogen synthase containing both NH2- and COOH-terminal phosphorylation sites are not involved in the interaction. The core segment of glycogen synthase from Glu21 to Gly503 does not bind COOH-terminal fragment of glycogenin. However, this region of glycogen synthase binds full-length glycogenin indicating that glycogenin contains at least one additional interacting site for glycogen synthase besides the COOH-terminus. We demonstrate that the COOH-terminal fragment of glycogenin can be used as an effective high affinity reagent for the purification of glycogen synthase from skeletal muscle and liver.     

Trehalose synthase converts glycogen to trehalose

Trehalose (alpha,alpha-1,1-glucosyl-glucose) is essential for the growth of mycobacteria, and these organisms have three different pathways that can produce trehalose. One pathway involves the enzyme described in the present study, trehalose synthase (TreS), which interconverts trehalose and maltose. We show that TreS from Mycobacterium smegmatis, as well as recombinant TreS produced in Escherichia coli, has amylase activity in addition to the maltose <--> trehalose interconverting activity (referred to as MTase). Both activities were present in the enzyme purified to apparent homogeneity from extracts of Mycobacterium smegmatis, and also in the recombinant enzyme produced in E. coli from either the M. smegmatis or the Mycobacterium tuberculosis gene. Furthermore, when either purified or recombinant TreS was chromatographed on a Sephacryl S-200 column, both MTase and amylase activities were present in the same fractions across the peak, and the ratio of these two activities remained constant in these fractions. In addition, crystals of TreS also contained both amylase and MTase activities. TreS produced both radioactive maltose and radioactive trehalose when incubated with [(3)H]glycogen, and also converted maltooligosaccharides, such as maltoheptaose, to both maltose and trehalose. The amylase activity was stimulated by addition of Ca(2+), but this cation inhibited the MTase activity. In addition, MTase activity, but not amylase activity, was strongly inhibited, and in a competitive manner, by validoxylamine. On the other hand, amylase, but not MTase activity, was inhibited by the known transition-state amylase inhibitor, acarbose, suggesting the possibility of two different active sites. Our data suggest that TreS represents another pathway for the production of trehalose from glycogen, involving maltose as an intermediate. In addition, the wild-type organism or mutants blocked in other trehalose biosynthetic pathways, but still having active TreS, accumulate 10- to 20-fold more glycogen when grown in high concentrations (> or = 2% or more) of trehalose, but not in glucose or other sugars. Furthermore, trehalose mutants that are missing TreS do not accumulate glycogen in high concentrations of trehalose or other sugars. These data indicate that trehalose and TreS are both involved in the production of glycogen, and that the metabolism of trehalose and glycogen is interconnected.