Purification and characterisation of limit dextrinase from Pisum sativum L.

A limit dextrinase has been purified 2,700-fold from ungerminated peas by affinity chromatography. The enzyme hydrolyses (1→6)-α-D-glucosidic linkages in alpha-limit dextrins containing at least one α-(1→4)-linked D-glucose residue on either side of the susceptible linkage. The limit dextrinase also hydrolyses the polysaccharides amylopectin, amylopectin beta-limit dextrin, glycogen beta-limit dextrin, and pullulan, but has no activity towards glycogen.     

Caste specific differences in fat body glycogen metabolism of the bumblebee,Bombus terrestris

Bumblebee queens of Bombus terrestris store large amounts of glycogen in the fat body during the first days after eclosion. The accumulation of the reserves is complete prior to hibernation. Comparative studies on the glycogen metabolism in queens and workers show that the increased activity of UDP-glucose: glycogen 4-α-d-glucosyltransferase (EC 2.4.1.11) could account for glycogen accumulation in queens. The enzymatic activities are nearly the same in newly emerged bees, significant differences between castes are detected by day three after eclosion. The activity of glycogen phosphorylase (EC 2.4.1.1), in contrast, is not different between the castes. After injection of juvenile hormone into newly emerged queens the activity of UDP-glucose:glycogen 4-α-d-glucosyltransferase remains low and no glycogen is accumulated in the fat body. Since eggs are formed simultaneously, the lowered activity of the enzyme is thought to depend on the changed metabolism of the fat body related to induced oogenesis.     

Insulin-Stimulated Glycogen Synthesis in Cultured Hepatoma Cells: Differential Effects of Inhibitors of Insulin Signaling Molecules

Abstract

In rat HTC hepatoma cells overexpressing human insulin receptors, insulin stimulated glycogen synthesis by 55–70%. To study postreceptor signaling events leading to insulin-stimulated glycogen synthesis in these cells, we have employed pathway-specific chemical inhibitors such as LY294002, rapamycin and PD98059 to inhibit phosphatidylinositol-3-kinase (PI3K), p70 ribosomal S6 kinase and mitogen-activated protein kinase (MAPK) kinase/MAPK, respectively. LY294002 (50 μM) completely abolished insulin-stimulated glycogen synthesis whereas rapamycin (2–20 nM) partially inhibited it. Neither LY294002 nor rapamycin significantly affected the basal glycogen synthesis. However, PD98059 (100 μM) significantly inhibited the basal glycogen synthesis without affecting insulin-stimulated glycogen synthesis. In these cells, insulin at 100 nM decreased glycogen synthase kinase 3α (GSK3α) activity by 30–35%. LY294002, but neither rapamycin nor PD98059, abolished insulin-induced inactivation of GSK3α. These data suggest that insulin-stimulated glycogen synthesis in rat HTC hepatoma cells is mediated mainly by PI3K-dependent mechanism. In these cells, inactivation of GSK3α, downstream of PI3K, may play a role in insulin-stimulated glycogen synthesis.     

Regulation of glycogen metabolism in the adrenal gland. IV. The effect of insulin on glycogen synthetase, phosphorylase, and related metabolites

Previous studies have indicated that the glycogen content of adrenal glands of fasted rats can be depleted by insulin per se (Bindstein, E., Piras, R., and Piras, M. M., Endocrinology88, 223, 1971). In order to establish the mechanism of action of this hormone in the adrenal gland, the effect of insulin has been now investigated on glycogen synthetase (UDP-glucose: α-1,4 glucan α-4-glueosyl-transferase, EC 2.4.1.11), glycogen phosphorylase (α-1,4 glucan: orthophosphate glucosyl-transferase, EC 2.4.1.1) and metabolites related to these enzymes.Approximately 40% of total adrenal glycogen phosphorylase of fasted rats is in the active form, which increases to 75% 1 hr after insulin treatment (75 mU/100 g body wt). This conversion occurs without apparent large changes of 3′-5′ cyclic AMP. Concomitantly with the enzymatic change, the levels of glucose-6-P, UDP-glucose and P_i suffer alterations which favor an increased phosphorolytic activity during the first hour of insulin treatment. Glycogen synthetase, which did not change during this period, is converted to the glucose-6-P independent form during the 2–3 hr of treatment. This conversion is preceded by an increased glycogen synthetase phosphatase activity, which seems to follow an inverse relationship with the glycogen level.The results obtained suggest that the effect of insulin on the adrenal gland of fasted rats is glycogenolytic, that is, opposite to that described for this hormone in other normal tissues. The glycogen depletion, on the other hand, seems to set in motion the mechanism for glycogen synthetase activation, with the subsequent glycogen resynthesis.     

The fine structure of the branched α-D-glucan from the blue-green alga Anacystis nidulans: comparison with other bacterial glycogens and phytoglycogen

The fine structure of the glycogen from the blue-green alga Anacystis nidulans has been examined. After selective hydrolysis of all (1→6)-α-D linkages by a bacterial isoamylase, the resulting mixture of linear chains was subjected to gel-permeation chromatography. For purposes of comparison, the glycogens from Escherichia coli and Arthrobacter sp., amylopectin, phytoglycogen from sweet corn, and shell-fish glycogen were treated similarly. The profiles of the unit chains of A. nidulans glycogen and phytoglycogen were closely similar. There was no close resemblance in the size distribution of unit chains for A. nidulans glycogen, other bacterial glycogens, and amylopectin.     

Two pathways from glycogen to glucose-6-phosphate in sea urchin eggs with special reference to the difference between the species in the contribution ratio of each pathway

In the unfertilized eggs of the sea urchins, Anthocidaris crassispina, Pseudocentrotus depressus, Hemicentrotus pulcherrimus, Mespilia globulus, Temnopleurus toreumaticus, Toxopeneustes pileolus, and Clypeaster japonicus, the activities of phosphorylase [EC 2.4.1.1], phosphoglucomutase [EC 2.7.5.1], exo-l,4-α-glucosidase [EC 3.2.1.3], and hexokinase [EC 2.7.1.1] are very similar. In all species, only phosphorylase activity is higher in fertilized eggs than in unfertilized eggs. The concentrations of glycogen, glucose, GIP, G6P, ATP, ADP, and Pi; the products and substrates in reactions catalyzed by these enzymes, were measured in these eggs. Based on the concentrations of these compounds in the eggs, it is assumed that G6P is produced by the combined action of glucosidase and hexokinase in all species examined, and that it is also produced in the reaction catalyzed by phosphorylase and phosphoglucomutase in all species except A crassispina and P depressus. Glycogen was found both in supernatant and in precipitate fractions, which were obtained by adding perchloric acid. Glycogen in the precipitate seems to be protein-bound. Whole glycogen level in the eggs is almost the same in all species examined, but the level of acid-soluble glycogen, as well as GIP, is markedly lower in the eggs of A crassispina and P depressus than in the eggs of other species examined. Protein-bound glycogen is utilized by glucosidase activity but not by phosphorylase activity, in contrast to acid-soluble glycogen, which is utilized by both enzyme activities. Hence, it is assumed that the failure of G6P production by phosphorylase and phosphoglucomutase-in A crassispina and P depressus eggs is due to a low level of acid-soluble glycogen in these eggs.     

Insulin action in intact mouse diaphragm I.

Summary The incubation of intact mouse diaphragms with insulin caused a dose and time dependent increase in the independent activity of glycogen synthase in tissue extracts. 2-deoxyglucose (2–10 mm) alone markedly stimulated the conversion of glycogen synthase to the independent activity under conditions in which tissue ATP concentrations were not affected. The incubation of diaphragms with both insulin and 2-deoxyglucose resulted in a greater than additive effect. Insulin stimulated the uptake of 2-deoxyglucose into mouse diaphragms, accumulating as 2-deoxyglucose-6-phosphate. The accumulation of 2-deoxyglucose-6-phosphate correlated well with the increase in the independent activity of glycogen synthase and with the activation of glycogen synthase phosphatase in tissue extracts. The uptake of 3-0-methyl glucose was also markedly stimulated by insulin, without affecting the activity of glycogen synthase. Both glucose-6-phosphate and 2-deoxyglucose-6-phosphate stimulated the activation of endogenous glycogen synthase phosphatase activity in muscle homogenates. We conclude that insulin, in addition to its effects in the absence of exogenous sugars, increases the independent activity of glycogen synthase through increased sugar transport resulting in increased concentrations of sugar-phosphates which promote the activity of glycogen synthase phosphatase.Abbreviations GS Glycogen synthase - GS-I Glycogen synthase activity independent of G6P - GS-D Glycogen synthase activity dependent on G6P - G6P Glucose-6-phosphate - ATP Adenosine triphosphate - EDTA Ethylene diamine tetracetic acid - Mops Morpholinopropane sulfonic acid - 2DG 2-Deoxy glucose - 3-0-MG 3-0-Methyl glucose - tricine N-tris(Hydroxymethyl)methyl glycine Enzymes: Glycogen Synthase — UDPGlucose — Glycogen Glucosyl — Transferase (EC 2.4.1.11) J. Larner is an established investigator of the American Diabetes Association.     

The role of glucose 6-phosphate in mediating the effects of glucokinase overexpression on hepatic glucose metabolism

Pharmacological activation or overexpression of glucokinase in hepatocytes stimulates glucose phosphorylation, glycolysis and glycogen synthesis. We used an inhibitor of glucose 6-phosphate (Glc6P) hydrolysis, namely the chlorogenic derivative, 1-[2-(4-chloro-phenyl)-cyclopropylmethoxy]-3, 4-dihydroxy-5-(3-imidazo[4,5-b]pyridin-1-yl-3-phenyl-acryloyloxy)-cyclohexanecarboxylic acid (also known as S4048), to determine the contribution of Glc6P concentration, as distinct from glucokinase protein or activity, to the control of glycolysis and glycogen synthesis by glucokinase overexpression. The validity of S4048 for testing the role of Glc6P was supported by its lack of effect on glucokinase binding and its nuclear/cytoplasmic distribution. The stimulation of glycolysis by glucokinase overexpression correlated strongly with glucose phosphorylation, whereas glycogen synthesis correlated strongly with Glc6P concentration. Metabolic control analysis was used to determine the sensitivity of glycogenic flux to glucokinase or Glc6P at varying glucose concentrations (5-20 mm). The concentration control coefficient of glucokinase on Glc6P (1.4-1.7) was relatively independent of glucose concentration, whereas the flux control coefficients of Glc6P (2.4-1.0) and glucokinase (3.7-1.8) on glycogen synthesis decreased with glucose concentration. The high sensitivity of glycogenic flux to Glc6P at low glucose concentration is consistent with covalent modification by Glc6P of both phosphorylase and glycogen synthase. The high control strength of glucokinase on glycogenic flux is explained by its concentration control coefficient on Glc6P and the high control strength of Glc6P on glycogen synthesis. It is suggested that the regulatory strength of pharmacological glucokinase activators on glycogen metabolism can be predicted from their effect on the Glc6P content.     

Studies on the Amylolytic System of the Black-koji Molds

Saccharogenic and dextrinogenic amylase fractions were prepared from Black-koji amylase system and their actions investigated with a number of different substrates.

It was found that saccharogenic amylase fraction completely hydrolyzes glutinous rice starch and glycogen to glucose, without leaving any limit dextrin. On the other hand, this enzyme fraction converts potato starch to an extent of about 90% theoretical glucose, the remainder being left as limit dextrin, which is colored purple by iodine. The complete hydrolysis of the branched substrates except potato starch shows that the saccharogenic amylase fraction is capable of hydrolyzing the l,6-α-d-glucosidic linkage besides the 1,4-linkage, while the branched fraction of potato starch may contain some sort of anomaly to the enzyme. Dextrinogenic amylase fraction hydrolyzes starch and glycogen just as malt α-amylase.     

Anti-inflammatory activity of the epimers of N-propyl 20ξ-dihydroprednisolonamide

The epimers of a steroid carboxamide, N-propyl 20α- and 20β -dihydroprednisolonamide, were evaluated for their local and systemic effects on granuloma formation, pituitary-adrenal function and liver glycogen content in rats. When the carboxamides were administered locally, the 20β-epimer exhibited greater activity than the 20α-epimer in suppressing cotton pellet granuloma formation. Neither epimer had suppressive effects on thymus weight and plasma corticosterone levels at the dose level used. When the carboxamides were administered systemically, they were pharmacologically inactive. Furthermore, in acute pharmacological studies, the carboxamides neither increased tyrosine aminotransferase activity and glycogen deposition in the liver nor decreased plasma corticosterone levels and relative thymus weight.     

Daytime restricted feeding modifies the daily variations of liver gluconeogenesis: Adaptations in biochemical and endocrine regulators

Daytime restricted feeding (DRF) promotes circadian adaptations in the metabolic processing of nutrients. We explored the hepatic gluconeogenic response in DRF rats by the temporal profiles of the following: (1) the activity of glucose 6-phosphatase (G6Pase) and phosphoenolpyruvate carboxykinase (PEPCK), as well as the periportal and pericentral distribution of PEPCK; (2) conversion of alanine to glucose; (3) glycemia and liver glycogen content; (4) presence of glycogen synthase (GYS) and its phosphorylated form (at Ser641, pGYS); (5) circulating levels of corticosterone, glucagon and insulin; (6) glucose-tolerance test; and (7) sirtuin 1 (SIRT1) and peroxisome proliferator-activated receptor-coactivator 1α (PGC-1α). The results showed that DRF promoted: (1) a phase shift in G6Pase activity and an increase in PEPCK activity as well as a change of PEPCK from periportal to pericentral hepatocytes, (2) a net conversion of alanine to circulating glucose, (3) a decrease in glycemic values and a phase shift in the liver glycogen content, (4) a phase shift in GYS and an increase of pGYS, (5) an increase in the daily levels of corticosterone and glucagon, but a reduction in the levels of insulin, (6) normal glucose homeostasis in all groups and (7) an enhanced presence of SIRT1 and PGC-1α. It is proposed that the increased gluconeogenic in DRF group promotes synthesis of hepatic glycogen and the production of glucose. These results could be a modulation of the gluconeogenic process due to rheostatic adaptations in the endocrine, metabolic and timing regulation of liver and could be associated with the physiology of the food entrained oscillator.     

Hexose phosphates as regulators of hepatic glycogen synthase phosphatases

The activity of glycogen synthase phosphatase from smooth endoplasmic reticulum of liver was stimulated markedly by galactose-6- and fructose-6-phosphates and to a lesser extent by glucose-1- and 2-deoxyglucose-6-phosphates. The synthase phosphatase of liver cytosol showed strong activation by glucose-1-, glucose-6- and fructose-6-phosphates and smaller activation by galactose-6- and 2-deoxyglucose-6-phosphates. Kinetic analysis showed that the activators did not affect the Km for glycogen synthase D, for either enzyme. The mechanism of activation of the two phosphatases by hexose phosphates appears to be by combination of the activator at a specific activator site on the enzyme rather than by substrate modulation. It is concluded that certain hexose phosphates, particularly fructose-6-phosphate and glucose-1-phosphate, can function as regulators of hepatic synthase phosphatase activity, and that this may explain the ability of elevated blood glucose to increase both glycogen synthase I activity and glycogen synthesis in the liver.     

Role of nuclear glycogen synthase and cytoplasmic UDP glucose pyrophosphorylase in the biosynthesis of nuclear glycogen in HD33 Ehrlich-Lettre ascites tumor cells

Biochemical and autoradiographic evidence show both glycogen synthesis and the presence of glycogen synthase (UDP glucose [UDPG]: glycogen 4-alpha-D-glucosyltransferase; EC 2.4.1.11) in isolated nuclei of Ehrlich-Lettré mouse ascites tumor cells of the mutant subline HD33. 5 d after tumor transplantation, glycogen (average 5-7 pg/cell) is stored mainly in the cell nuclei. The activity of glycogen synthase in isolated nuclei is 14.5 mU/mg protein. At least half of the total cellular glycogen synthase activity is present in the nuclei. The nuclear glycogen synthase activity exists almost exclusively in its b form. The Km value for (a + b) glycogen synthase is 1 x 10(-3) M UDPG, the activation constant is 5 x 10(-3) M glucose-6-phosphate (Glc-6-P). Light and electron microscopic autoradiographs of isolated nuclei incubated with UDP-[1-3H]glucose show the highest activity of glycogen synthesis not only in the periphery of glycogen deposits but also in interchromatin regions unrelated to detectable glycogen particles. Together with earlier findings on nuclear glycogen synthesis in intact HD33 ascites tumor cells (Zimmermann, H.-P., V. Granzow, and C. Granzow. 1976. J. Ultrastruct. Res. 54:115-123), the results of tests on isolated nuclei suggest a predominantly appositional mode of nuclear glycogen deposition, without participation of the nuclear membrane system. In intact cells, synthesis of UDPG for nuclear glycogen synthesis depends on the activity of the exclusively cytoplasmic UDPG pyrophosphorylase (UTP: alpha-D-glucose-1-phosphate uridylyltransferase; EC 2.7.7.9). However, we conclude that glycogen synthesis is not exclusively a cytoplasmic function and that the mammalian cell nucleus is capable of synthesizing glycogen.     

TreX from Sulfolobus solfataricus ATCC 35092 Displays Isoamylase and 4-α-Glucanotransferase Activities

A treX in the trehalose biosynthesis gene cluster of Sulfolobus solfataricus ATCC 35092 has been reported to produce TreX, which hydrolyzes the α-1,6-branch portion of amylopectin and glycogen. TreX exhibited 4-α-D-glucan transferase activity, catalyzing the transfer of α-1,4-glucan oligosaccharides from one molecule to another in the case of linear maltooligosaccharides (G3–G7), and it produced cyclic glucans from amylopectin and amylose like 4-α-glucanotransferase. These results suggest that TreX is a novel isoamylase possessing the properties of 4-α-glucanotransferase.     

Epinephrine control of glycogen metabolism in glycogen-associated protein phosphatase PP1G/R(GL) knockout mice

The glycogen-associated protein phosphatase (PP1G/ R(GL))may play a central role in the hormonal control of glycogen metabolism in the skeletal muscle. Here, we investigated the in vivo epinephrine effect of glycogen metabolism in the skeletal muscle of the wild-type and R(GL) knockout mice. The administration of epinephrine increased blood glucose levels from 200 +/- +/- 20 to 325 +/- 20 mg/dl in both wild-type and knockout mice. Epinephrine decreased the glycogen synthase -/+ G6P ratio from 0.24 +/- 0.04 to 0.10 +/- 0.02 in the wild-type, and from 0.17 +/- 0.02 to 0.06 +/- 0.01 in the knockout mice. Conversely, the glycogen phosphorylase activity ratio increased from 0.21 +/- 0.04 to 0.65 +/- 0.07 and from 0.30 +/- 0.04 to 0.81 +/- 0.06 in the epinephrine treated wild-type and knockout mice respectively. The glycogen content of the knockout mice was substantially lower (27 percent) than that of both wild-type mice; and epinephrine decreased glycogen content in the wild-type and knockout mice. Also, in Western blot analysis there was no compensation of the other glycogen targeting components PTG/R5 and R6 in the knockout mice compared with the wild-type. Therefore, R(GL) is not required for the epinephrine stimulation of glycogen metabolism, and rather another phosphatase and/or regulatory subunit appears to be involved.     

Structure-Function Analysis of PPP1R3D,a Protein Phosphatase 1 Targeting Subunit,Reveals a Binding Motif for 14-3-3 Proteins which Regulates its Glycogenic Properties

Protein phosphatase 1 (PP1) is one of the major protein phosphatases in eukaryotic cells. It plays a key role in regulating glycogen synthesis, by dephosphorylating crucial enzymes involved in glycogen homeostasis such as glycogen synthase (GS) and glycogen phosphorylase (GP). To play this role, PP1 binds to specific glycogen targeting subunits that, on one hand recognize the substrates to be dephosphorylated and on the other hand recruit PP1 to glycogen particles. In this work we have analyzed the functionality of the different protein binding domains of one of these glycogen targeting subunits, namely PPP1R3D (R6) and studied how binding properties of different domains affect its glycogenic properties. We have found that the PP1 binding domain of R6 comprises a conserved RVXF motif (R₁₀₂VRF) located at the N-terminus of the protein. We have also identified a region located at the C-terminus of R6 (W₂₆₇DNND) that is involved in binding to the PP1 glycogenic substrates. Our results indicate that although binding to PP1 and glycogenic substrates are independent processes, impairment of any of them results in lack of glycogenic activity of R6. In addition, we have characterized a novel site of regulation in R6 that is involved in binding to 14-3-3 proteins (RARS₇₄LP). We present evidence indicating that when binding of R6 to 14-3-3 proteins is prevented, R6 displays hyper-glycogenic activity although is rapidly degraded by the lysosomal pathway. These results define binding to 14-3-3 proteins as an additional pathway in the control of the glycogenic properties of R6.     

A novel coenzymatic function of pyridoxal 5'-phosphate

Pyridoxal 5′-phosphate, the vitamin B₆ derivative, acts as the coenzyme of many enzymes involved in amino acid metabolism. Exceptionally, this compound was found covalently bound to glycogen phosphorylase, the key enzyme in the regulation of glycogen metabolism. Although it is essential for the function of phosphorylase, its direct role has remained an enigma. We have recently found that the glucose moiety of pyridoxal (5′)diphospho (1)-α-D -glucose, a conjugate of pyridoxal 5′-phosphate and glucose 1-phosphate through a pyrophosphate linkage, is transferred to the nonreducing end of glycogen, forming a new α-1,4-glucosidic linkage. This finding emphasizes the importance of the direct phosphate-phosphate interaction between the coenzyme and the substrate in the phosphorylase catalytic reaction. We have proposed a catalytic mechanism for phosphorylase in which the phosphate group of pyridoxal 5′-phosphate acts as an electrophile to the phosphate group of glucose 1-phosphate. This appears to represent the first instance of the direct involvement of a phosphate group in catalysis by enzymes.     

Oligomeric and functional properties of a debranching enzyme (TreX) from the archaeon Sulfolobus solfataricus P2

A gene, treX, encoding a debranching enzyme previously cloned from the trehalose biosynthesis gene cluster of Sulfolobus solfataricus P2 was expressed in Escherichia coli as a His-tagged protein and the biochemical properties were studied. The specific activity of the S. solfataricus debranching enzyme (TreX) was highest at 75°C and pH 5.5. The enzyme exhibited hydrolysing activity toward α-1,6-glycosidic linkages of amylopectin, glycogen, pullulan, and other branched substrates, and glycogen was the preferred substrate. TreX has a high specificity for hydrolysis of maltohexaosyl α-1,6-β-cyclodextrin, indicating the high preference for side chains consisting of 6 glucose residues or more. The enzyme also exhibited 4-α-sulfoxide-glucan transferase activity, catalysing transfer of α-1,4-glucan oligosaccharides from one chain to another. Dimethyl sulfoxide (10%, v/v) increased the hydrolytic activity of TreX. Gel permeation chromatography and sedimentation equilibrium analytical ultracentrifugation revealed that the enzyme exists mostly as a dimer at pH 7.0, and as a mixture of dimers and tetramers at pH 5.5. Interestingly, TreX existed as a tetramer in the presence of DMSO at pH 5.5–6.5. The tetramer showed a 4-fold higher catalytic efficiency than the dimer. The enzyme catalysed not only intermolecular trans-glycosylation of malto-oligosaccharides (disproportionation) to produce linear α-1,4-glucans, but also intramolecular trans-glycosylation of glycogen. The results presented in this study indicated that TreX may be associated with glycogen metabolism by selective cleavage of the outer side chain.     

Glucose phosphorylation is not rate limiting for accumulation of glycogen from glucose in perfused livers from fasted rats

Incorporation of Glc and Fru into glycogen was measured in perfused livers from 24-h fasted rats using [6-3H]Glc and [U-14C]Fru. For the initial 20 min, livers were perfused with low Glc (2 mM) to deplete hepatic glycogen and were perfused for the following 30 min with various combinations of Glc and Fru. With constant Fru (2 mM), increasing perfusate Glc increased the relative contribution of Glc carbons to glycogen (7.2 +/- 0.4, 34.9 +/- 2.8, and 59.1 +/- 2.7% at 2, 10, and 20 mM Glc, respectively; n = 5 for each). During perfusion with substrate levels seen during refeeding (10 mM Glc, 1.8 mumol/g/min gluconeogenic flux from 2 mM Fru), Fru provided 54.7 +/- 2.7% of the carbons for glycogen, while Glc provided only 34.9 +/- 2.8%, consistent with in vivo estimations. However, the estimated rate of Glc phosphorylation was at least 1.10 +/- 0.11 mumol/g/min, which exceeded by at least 4-fold the glycogen accumulation rate (0.28 +/- 0.04 mumol of glucose/g/min). The total rate of glucose 6-phosphate supply via Glc phosphorylation and gluconeogenesis (2.9 mumol/g/min) exceeded reported in vivo rates of glycogen accumulation during refeeding. Thus, in perfused livers of 24-h fasted rats there is an apparent redundancy in glucose 6-phosphate supply. These results suggest that the rate-limiting step for hepatic glycogen accumulation during refeeding is located between glucose 6-phosphate and glycogen, rather than at the step of Glc phosphorylation or in the gluconeogenic pathway.