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.     

Enzymatic microdetermination of glycogen.

A method for the determination of isolated glycogen was developed. Glucose was released from glycogen with an amyloglucosidase from Rhizopus. The released glucose was determined with glucose oxidase and peroxidase utilizing diammonium 2,2′-azino-di-[3-ethyl-benzthiazoline sulfonate (6)] (ABTS) as a chromogenic substrate. The ABTS method was found to be three times as sensitive as the older o-dianisidine method. For rabbit liver glycogen, the results obtained with amyloglucosidase correlated highly with those obtained by acid hydrolysis.     

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.     

Biosynthesis of glycogen in Neurospora crassa. Kinetic mechanism of UDP-glucose: glycogen 4-alpha-glucosyltransferase.

The kinetic mechanism of glycogen synthase [UDP-glucose: glycogen 4-alpha-glucosyltransferase, EC 2.4.1.11], glucose-6-P-dependent form, from Neurospora crassa has been investigated by initial velocity experiments and studies with inhibitors in the presence of sufficient levels of glucose-6-P. The rate equation was different from those of common two-substrate systems because one of the substrates, glycogen, is also a product. The reaction rates were determined by varying the concentration of one of the substrates while keeping that of the other constant. Double-reciprocal plots of initial velocity measurements were linear and showed converging line patterns. UDP was found to act competitively when the substrate UDP-glucose was varied, but noncompetitively when glycogen was varied. On the basis of these results, it is concluded that glycogen synthase, glucose-6-P-dependent form, from N. crassa has a rapid equilibrium random Bi-Bi mechanism. Rate constant and dissociation constants for each step of this mechanism were estimated.     

Coordinate regulation of glycogen metabolism in the yeast Saccharomyces cerevisiae. Induction of glycogen branching enzyme.

The yeast glycogen branching enzyme (EC 2.4.1.18) is shown to be induced in batch culture simultaneously with the onset of intracellular glycogen accumulation. The branching enzyme structural gene (GLC3) has been cloned. Its predicted amino acid sequence is very similar to procaryotic branching enzymes. Northern analysis indicates that GLC3 mRNA abundance increases in late exponential growth phase coincident with glycogen accumulation. Disruption of the branching enzyme structural gene establishes that branching enzyme activity is an absolute requirement for maximal glycogen synthesis.     

Intracellular localization and size of glycogen particles in glycogen synthesized under histochemical conditions.

During the investigation of the histochemical synthesis of glycogen particles from glucose 1-phosphate by the phosphorylase-branching glycosyltransferase system in various tissue cells, it was observed that focal synthesis localized in a certain area of the cytoplasm occurred in some cells. This differed from the usual synthesis in which particles of similar size were synthesized within the cytoplasm. Otherwise, cytoplasmic particles of various size were also synthesized in other cells under the same histochemical condition. The possible significance of the presence of these patterns in glycogen synthesis is discussed.     

Studies on glycogen synthesis in pigeon liver homogenates. Incorporation of hexose into glycogen

Liver homogenates of avian species, but not of mammals, form glycogen from glucose, mannose, fructose and galactose. Incorporation of labelled glucose, fructose and mannose, but not of labelled galactose, into glycogen is diluted isotopically by unlabelled glucose. Except for fructose, glycogen formation from other substrates by pigeon liver homogenates compares favourably with that from the same substrates in pigeon liver slices. Optimum conditions for glycogen synthesis from glucose by pigeon liver homogenate are: medium of incubation, 0.175m-sucrose-45mm-potassium chloride-15mm-glycylglycine buffer, pH7.5; concentration of substrate, 15mm; concentration of tissue, less than 120mg./ml.; temperature of incubation, 37-43 degrees ; atmosphere, oxygen. Uncouplers of oxidative phosphorylation, Ca(2+), EDTA, PP(i), 2-deoxyglucose 6-phosphate and microsomal fraction of rat liver are inhibitory to glycogen synthesis from glucose. Starvation of pigeons for 24 and 48hr. leads to a slight stimulation of glycogen synthesis in their liver homogenates as compared with fed controls. Pigeon liver homogenates can be separated into subcellular fractions that on reconstitution can synthesize glycogen. All the enzymes of the glycogen pathway except soluble high-K(m) glucokinase are present in pigeon liver.     

Particulate glycogen of mammalian liver: specificity in binding phosphorylase and glycogen synthase.

The glycogen particle - glycogen metabolizing enzyme complex was investigated to gain some understanding of its physiological significance. Fractionations of populations of particles from mouse liver were carried out utilising open column and high performance liquid chromatography, and based either on the molecular weight of the particles or the hydrophobic interactions of the glycogen-associated proteins. The activities of glycogen phosphorylase and glycogen synthase were measured in these fractions. Fractionations were of tissue in different stages of glycogen deposition or mobilization. In animals fed ad libitum, glycogen synthase was associated with the whole spectrum of molecular weights, while the glycogen phosphorylase distribution was skewed in favour of the lower molecular weight species. Under conditions of glycogen mobilization, the phosphorylase distribution changed to include all molecular weights. The hydrophobic interaction separations demonstrated that glycogen synthase binds to a specific subpopulation of particles that is a minor proportion of the total. In general, there was a direct relationship of the total amount of phosphorylase and synthase bound during periods of mobilization and deposition, respectively. Two notable exceptions were the large amounts of glucose-6-P dependent synthase present during the early period of glycogen mobilization and the high amounts of active phosphorylase appearing shortly after food withdrawal, in spite of interim glycogen deposition from presumably already ingested food.     

Biosynthesis of glycogen in Neurospora crassa. Purification and properties of the UDPglucose:glycogen 4-alpha-glucosyltransferase.

The Neurospora crassa glycogen synthase (UDPglucose:glycogen 4-alpha-glucosyltransferase, EC 2.4.1.11) was purified to electrophoretic homogeneity by a procedure involving ultracentrifugation, DEAE-cellulose column chromatography, (NH4)2SO4 fractionation and 3-aminopropyl-Sepharose column chromatography. The final purified enzyme preparation was almost entirely dependent on glucose-6-P and had a specific activity of 6.9 units per mg of protein. The subunit molecular weight of the glycogen synthase was determined by electrophoresis in sodium dodecyl sulfate-polyacrylamide gel to be 88 000--90 000. The native enzyme was shown to have a molecular weight of 270 000 as determined by sucrose density gradient centrifugation. Thus, the glucose-6-P-dependent form of the N. crassa glycogen synthase can exist as trimer of the subunit. Limited proteolysis with trypsin or chymotrypsin converted the glucose-6-P-dependent form of the enzyme into an apparent glucose-6-P-independent form. The enzyme was shown to catalyze transfer of glucose from UDPglucose to glycogen as well as to its phosphorylase limit dextrin, but not to its beta-amylase limit dextrin. Moreover, glucose, maltose and maltotriose were not active as acceptors.     

Two pools of glycogen in Saccharomyces.

The effect of different extraction procedures on the yields of water-soluble and water-insoluble glycogen fractions from a number of Saccharomyces strains was studied by using a specific method for glycogen determination. The similarity of the yields obtained by the different procedures showed that neither form of glycogen is an artifact, and variations in the relative amounts of glycogen in the two fractions during cell growth and in different yeast strains suggest that they represent different pools of storage material with specific roles in cell development and differentiation. A proportion of the water-insoluble glycogen fraction, solubilized by mechanical agitation, was shown to be strongly associated with a beta-glucan-like polysaccharide that may be a cell wall component.     

Amylin activates glycogen phosphorylase and inactivates glycogen synthase via a cAMP-independent mechanism.

Although the novel pancreatic peptide amylin has been shown to induce insulin resistance and decrease glucose uptake, the mechanism of amylin's actions is unknown. The following study evaluated the effect of amylin on glycogen metabolism in isolated soleus muscles in the presence and absence of insulin (200 microU/ml). Total glycogen, glycogen phosphorylase and glycogen synthases activities, and cAMP levels were measured. Total glycogen levels were significantly decreased by amylin (100 nM) in fed or fasted muscles under conditions of insulin stimulation. Amylin (100 nM) activated glycogen phosphorylase by as much as 100% and decreased glycogen synthase activity by over 60%, depending on the metabolic state of the muscles. These effects where comparable to those of the beta adrenergic agonist isoproterenol. A lower concentration of amylin (1 nM) did not significantly affect glycogen levels, glycogen phosphorylase, or glycogen synthase activity. Cyclic AMP levels were increased two-fold by isoproterenol but were unaffected by amylin. In conclusion, amylin induces glycogenolysis by decreasing glycogen synthesis and increasing breakdown. The effect of amylin on enzyme activity is consistent with a phosphorylation-dependent mechanism. It is likely that these events are mediated via a cAMP independent protein kinase.