Interaction between glycogen and glycogen phosphorylase of Tetrahymena

The glycogen phosphorylase of Tetrahymena pyriformis complexes with glycogen as judged by its elution pattern from columns of Sepharose 6B. Complex formation does not occur with starch, amylose, or amylopectin, and neither do these polyglucans serve as primers for the enzyme. To study the association between the phosphorylase and glycogen particles in situ, Tetrahymena were grown under differing physiological conditions, phosphorylase was isolated and chromatographed on a Sepharose 6B column. Phosphorylase activity isolated from cells grown in the absence of glucose was only partially associated with glycogen, while in cells exposed to glucose for 30 min or more all the phosphorylase activity was associated with glycogen. The effects of culture age and anaerobiosis on the relative amounts of free and glycogen-bound enzyme in the cells were also studied. It was concluded from the in vivo experiments that there was no simple relation between the fraction of enzyme bound to glycogen and between cell glycogen content.     

Affinity glycogen synthetase to crosslinked glycogen.

The affinity of yeast glycogen synthetase to glycogen modified by crosslinking has been studied under various experimental conditions. It was found that the higher the degree of crosslinking, the lower the affinity of glycogen synthetase to glycogen. The amount of glycogen synthetase adsorbed from the solution depends on the amount of crosslinked glycogen added and is inversely proportional to the concentration of the soluble glycogen. The stability of the complex formed between yeast glycogen synthetase and the crosslinked glycogen was found to be maximal at neutral pH range. The presence of glucose 6-phosphate, uridine 5′-di-phosphate, and uridine 5′-diphosphate glucose enhanced the stability of the complex.     

The interaction of muscle glycogen phosphorylase b with glycogen

Interaction of muscle glycogen phosphorylase b (EC 2.4.1.1) with glycogen was studied by sedimentation, stopped-flow and temperature-jump methods. The equilibrium enzyme concentration was determined by sedimentation in an analytical ultracentrifuge equipped with absorption optics and a photoelectric scanning system. The maximum adsorption capacity of pig liver glycogen is 3.64 mumol dimeric glycogen phosphorylase b per g glycogen, which corresponds to 20 dimeric enzyme molecules per average glycogen molecule of Mr 5.5 X 10(6). Microscopic dissociation constants were determined for the enzyme-glycogen complex within the temperature range from 12.7 to 30.0 degrees C. Enzyme-glycogen complexing is accompanied by increasing light scattering and its increment depends linearly on the concentration of the binding sites on a glycogen particle that are occupied by the enzyme. Complex formation and relaxation kinetics are in accordance with the proposed bimolecular reaction scheme. The monomolecular dissociation rate constant of the complex increases as the temperature increases from 12.7 to 30.0 degrees C, whereas the bimolecular rate constant changes slightly and is about 10(8) M-1 X S-1. These data point to the possibility of diffusional control of the complex formation.     

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.     

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.     

Regulation of glycogen synthesis in human skeletal muscle: does cellular glycogen control glycogen synthase phosphatase activity?

Contrary to the accepted feedback control mechanism of glycogen biosynthesis in skeletal muscle, evidence is presented here leading to the conclusion that glycogen does not control the activity of glycogen synthase phosphatase in intact human skeletal muscle tissue.     

Kinetics of the reaction between muscle glycogen phosphorylase B and glycogen

Kinetics of glycogen binding by glycogen phosphorylase b has been studied by stopped flow and temperature jump methods. This reaction is followed by increase in light scattering whose amplitude depends upon the enzyme binding sites concentration of glycogen particles occupied by the enzyme. It has been shown that the complex formation has the first order with respect to enzyme and glycogen concentrations. Relaxation kinetics is compatible with proposed bimolecular reaction scheme. Microscopic rate constants of the forward and reverse reactions of glycogen binding by glycogen phosphorylase b are determined in temperature range from 12,7 to 30 degrees C. The possibility of diffusional control of the binding rate is discussed.     

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.     

Schistosoma haematobium: histochemistry of glycogen, glycogen phosphorylase a and glycogen branching enzyme in niridazole-treated females.

The body posterior to the ovary of Schistosoma haematobium females was investigated. Glycogen, glycogen phosphorylase a (EC 2.4.1.1) and glycogen branching enzyme (EC 2.4.1.18) activities were detected in the subtegumental muscle system, parenchyma and mature vitelline cells, whereas no activities were detected in the tegument and immature vitelline cells of the parasite. Administration of a single niridazole dose of 250 mg kg-1 to the pouched mouse (Saccostomus camestris) produced the following changes in S. haematobium females: a relatively rapid depletion of glycogen stores due to disruption of the absorptive surface of the parasite, and to an increase in the activity of glycogen phosphorylase a; a reduction in the phosphorylase a to phosphorylase b-conversion capacity of glycogen phosphorylase phosphatase (EC 3.1.3.17); a decrease in glycogen branching enzyme activity; and a relatively rapid degeneration of parasite cells possibly due to their loss of endogenous energy reserves.     

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.     

Determination of glycogen and enzymes of glycogen metabolism in human hair follicles

The skin epithelium and its organelles use glycogen as well as glucose as source of energy. Therefore the characterisation of glycogen metabolism and the enzymes involved is important in the study of mechanisms regulating the normal or abnormal differentiation of skin organelles such as sebaceous glands and hair follicles.The present paper describes fluorimetric methods for the determination of glycogen and for the measurements of phosphorylase and phosphorylase kinase activity in one and the same lysate of minute tissue samples. The methods were tested for their suitability on freshly isolated human hair follicles and cultured hair follicle cells. The possible use of these techniques for studies on the pathophysiology of acne and hirsutism is discussed.     

Control of glycogen deposition

Traditionally, glycogen synthase (GS) has been considered to catalyze the key step of glycogen synthesis and to exercise most of the control over this metabolic pathway. However, recent advances have shown that other factors must be considered. Moreover, the control of glycogen deposition does not follow identical mechanisms in muscle and liver. Glucose must be phosphorylated to promote activation of GS. Glucose-6-phosphate (Glc-6-P) binds to GS, causing the allosteric activation of the enzyme probably through a conformational rearrangement that simultaneously converts it into a better substrate for protein phosphatases, which can then lead to the covalent activation of GS. The potency of Glc-6-P for activation of liver GS is determined by its source, since Glc-6-P arising from the catalytic action of glucokinase (GK) is much more effective in mediating the activation of the enzyme than the same metabolite produced by hexokinase I (HK I). As a result, hepatic glycogen deposition from glucose is subject to a system of control in which the 'controller', GS, is in turn controlled by GK. In contrast, in skeletal muscle, the control of glycogen synthesis is shared between glucose transport and GS. The characteristics of the two pairs of isoenzymes, liver GS/GK and muscle GS/HK I, and the relationships that they establish are tailored to suit specific metabolic roles of the tissues in which they are expressed. The key enzymes in glycogen metabolism change their intracellular localization in response to glucose. The changes in the intracellular distribution of liver GS and GK triggered by glucose correlate with stimulation of glycogen synthesis. The translocation of GS, which constitutes an additional mechanism of control, causes the orderly deposition of hepatic glycogen and probably represents a functional advantage in the metabolism of the polysaccharide.