Glycogen synthesis from glucose and fructose in hepatocytes from diabetic rats

In rat hepatocytes, the basal glycogen synthase activation state is decreased in the fed and diabetic states, whereas glycogen phosphorylase a activity decreases only in diabetes. Diabetes practically abolishes the time- and dose-dependent activation of glycogen synthase to glucose especially in the fed state. Fructose, however, is still able to activate this enzyme. Glycogen phosphorylase response to both sugars is operative in all cases. Cell incubation with the combination of 20 mM glucose plus 3 mM fructose produces a great activation of glycogen synthase and a potentiated glycogen deposition in both normal and diabetic conditions. Using radiolabeled sugars, we demonstrate that this enhanced glycogen synthesis is achieved from both glucose and fructose even in the diabetic state. Therefore, the presence of fructose plays a permissive role in glycogen synthesis from glucose in diabetic animals. Glucose and fructose increase the intracellular concentration of glucose 6-phosphate and fructose reduces the concentration of ATP. There is a close correlation between the ratio of the intracellular concentrations of glucose 6-phosphate and ATP (G6-P/ATP) and the activation state of glycogen synthase in hepatocytes from both normal and diabetic animals. However, for any given value of the G6-P/ATP ratio, the activation state of glycogen synthase in diabetic animals is always lower than that of normal animals. This suggests that the system that activates glycogen synthase (synthase phosphatase activity) is impaired in the diabetic state. The permissive effect of fructose is probably exerted through its capacity to increase the G6-P/ATP ratio which may partially increase synthase phosphatase activity, rendering glycogen synthase active.     

Synergism of glucose and fructose in net glycogen synthesis in perfused rat livers

Synergism of glucose and fructose in net glycogen synthesis was studied in perfused livers from 24-h fasted rats. With either glucose or fructose alone, net glycogen deposition did not occur (p greater than 0.10 for each), whereas the addition of both together resulted in significant glycogen accumulation (net glycogen accumulation was 0.21 +/- 0.03 mumol of glucose/g of liver/min at 2 mM fructose and 30 mM glucose, p less than 0.001). To better understand this synergism, intermediary substrate levels were compared at steady state with various glucose levels in the absence and in the presence of 2 mM fructose. Independent of fructose, hepatic glucose and glucose 6-phosphate increased proportionally when glucose level in the medium was raised (r = 0.86, p less than 0.001). Unlike glucose 6-phosphate, UDP-glucose did not consistently increase with glucose (p greater than 0.10); in fact, there was a small decrease at a very high glucose level (30 mM), a result consistent with the well-established activation of glycogen synthase by glucose. With elevated glucose, the level of glucose 6-phosphate was strongly correlated with glycogen content (r = 0.71, p less than 0.01, slope = 32). Adding fructose increased the "efficiency" of glucose 6-phosphate to glycogen conversion: the effect of a given increment in glucose 6-phosphate upon glycogen accumulation was increased 2.6-fold (r = 0.73, p less than 0.01, slope = 86). A kinetic modeling approach was used to investigate the mechanisms by which fructose synergized glycogen accumulation when glucose was elevated. Based on steady-state hepatic substrate levels, net hepatic glucose output, and net glycogen synthesis rate, the model estimated the rate constants of major enzymes and individual fluxes in the glycogen metabolic pathway. Modeling analysis is consistent with the following scenario: glycogen synthase is activated by glucose, whereas glucose-6-phosphatase was inhibited. In addition, the model supports the hypothesis that fructose synergizes net glycogen accumulation due to suppression of phosphorylase. Overall, our analysis suggests that glucose enhances the metabolic flux to glycogen by inducing a build up of glucose 6-phosphate via combined effects of mass action and glucose-6-phosphatase inhibition and activating glycogen synthase and that fructose enhances glycogen accumulation by retaining glycogen via phosphorylase inhibition.     

Liver glycogen metabolism in endotoxin shock. I. Endotoxin administration decreases glycogen synthase activities in dog livers

The effects of E. coli endotoxin administration on hepatic glycogen content and glycogen synthase activities in dogs were studied. Liver glycogen content was decreased by 80% 2 hr after endotoxin injection. When enzyme preparations were preincubated at 25 degrees C for 3 hr prior to their assays, 75% of total glycogen synthase was in I form in control dogs. Under such conditions, endotoxin administration decreased the percentage I activity from 75 to 37%; decreased the Vmax and Km for UDP-glucose for total glycogen synthase by 62.2 and 35.3%, respectively; decreased the Vmax and Km for UDP-glucose for glycogen synthase I by 75.6 and 15.6%, respectively; increased the A0.5 for glucose-6-P for the activation of glycogen synthase D by 126% at high (10 mM) and by 18-fold at low (1 mM) UDP-glucose concentration; increased the percentage D activity from 24 to 72%; decreased the I50 for ATP for the inhibition of total glycogen synthase by 49.7%; decreased the I50 for ATP for the inhibition of glycogen synthase I by 26.4%; and decreased the percentage I activity from 78 to 33% at ATP concentrations below 6 mM. When enzyme preparations were not preincubated prior to their assays, 90% of total glycogen synthase was in D form in control dogs. Under such conditions, endotoxin administration decreased the Vmax and Km for UDP-glucose for total glycogen synthase by 47.1 and 33.3%, respectively, and increased the A0.5 for glucose-6-P for the activation of glycogen synthase D by 24.2% at high (10 mM) and by 106% at low (1 mM) UDP-glucose concentration. From these results, it is clear that endotoxin administration greatly impaired hepatic glycogenesis by decreasing the activity of glycogen synthase; this impairment is at least in part responsible for the depletion of liver glycogen content in endotoxin shock. Kinetic analyses revealed that the decrease in the activity of glycogen synthase in endotoxic shock is a result of a decrease in the interconversion of this enzyme from inactive to active form and an increase in the interconversion from active to inactive form.     

Evidence for a functional glycogen metabolism in mature mammalian spermatozoa

The glycogen content in fresh raw dog spermatozoa was 0.22+/-0.03 micromol/mg protein. This matched with the presence of a glycogen-like staining in the head and midpiece. Glycogen levels lowered to 0.05 micromol/mg protein after incubation for 60 min without sugars. Addition of either 10 mM fructose or 10 mM glucose increased glycogen content to 0.70 micromol/mg protein. On the other hand, glycogen synthase activity ratio of fresh dog sperm (0.35+/-0.07, measured in the absence and the presence of glucose 6-P) increased to 0.55 with 10 mM fructose for 20 min, whereas glucose had a smaller effect. Spermatozoa extracts had also a protein of about 100 Kd, which reacted against a rat liver glycogen synthase antibody. This was located in sperm head and midpiece. Furthermore, glycogen phosphorylase activity ratio measured in presence and absence of AMP (0.25+/-0.03 in fresh samples) decreased to 0.15 by 10 mM glucose for 20 min, whereas fructose was less potent in this regard. The maximal effect of glucose and fructose were observed from 10-20 mM onwards. This work is the first indication for a functional glycogen metabolism in mammal spermatozoa, which could play an important role in regulating sperm survival in vivo.     

Fructose effect to suppress hepatic glycogen degradation

The effect of fructose on glycogen degradation was examined by measuring the flux of 14C from prelabeled glycogen in perfused rat livers. During 2-h refeeding of 24-h-fasted rats, newly synthesized hepatic glycogen was labeled by intraperitoneal injection of [U-14C] galactose (0.1 mg and 0.02 microCi/g of body weight). The livers of refed rats were then perfused in a nonrecirculating fashion for an initial 30 min with glucose alone (10 mM) for the following 60 min with glucose (10 mM) without (n = 5) or with fructose (1, 2, or 10 mM; n = 5 for each). When livers were exposed to fructose, release of label into the perfusate immediately declined and remained markedly suppressed through the end of perfusion (p less than 0.05). The suppression was dose-dependent; at steady state (50-70 min), label release was suppressed 45, 64, and 72% by 1, 2, and 10 mM fructose, respectively (p less than 0.0001). Suppression was not accompanied by significant changes in the activities of glycogen synthase or phosphorylase assessed in vitro. These results suggest the existence of allosteric inhibition of phosphorylase in the presence of fructose. Fructose 1-phosphate (Fru-1-P) accumulated in proportion to fructose (0.11 +/- 0.01 without fructose, 0.86 +/- 0.03, 1.81 +/- 0.18, and 8.23 +/- 0.60 mumol/g of liver with 1, 2, and 10 mM fructose, respectively; p less than 0.0001). Maximum inhibition of label release was 82%; the Fru-1-P concentration for half inhibition was 0.57 mumol/g of liver, well within the concentration of Fru-1-P attained during refeeding. We conclude that fructose enhances net glycogen accumulation in liver by suppressing glycogenolysis and that the suppression is presumably caused by allosteric inhibition of phosphorylase by Fru-1-P.     

The control of glycogen metabolism in yeast. 1. Interconversion in vivo of glycogen synthase and glycogen phosphorylase induced by glucose, a nitrogen source or uncouplers

The addition of glucose to a suspension of yeast initiated glycogen synthesis and ethanol formation. Other effects of the glucose addition were a transient rise in the concentration of cyclic AMP and a more prolonged increase in the concentration of hexose 6-monophosphate and of fructose 2,6-bisphosphate. The activity of glycogen synthase increased about 4-fold and that of glycogen phosphorylase decreased 3-5-fold. These changes could be reversed by the removal of glucose from the medium and induced again by a new addition of the sugar. These effects of glucose were also obtained with glucose derivatives known to form the corresponding 6-phosphoester. Similar changes in glycogen synthase and glycogen phosphorylase activity were induced by glucose in a thermosensitive mutant deficient in adenylate cyclase (cdc35) when incubated at the permissive temperature of 26 degrees C, but were much more pronounced at the nonpermissive temperature of 35 degrees C. Under the latter condition, glycogen synthase was nearly fully activated and glycogen phosphorylase fully inactivated. Such large effects of glucose were, however, not seen in another adenylate-cyclase-deficient mutant (cyr1), able to incorporate exogenous cyclic AMP. When a nitrogen source or uncouplers were added to the incubation medium after glucose, they had effects on glycogen metabolism and on the activity of glycogen synthase and glycogen phosphorylase which were directly opposite to those of glucose. By contrast, like glucose, these agents also caused, under most experimental conditions, a detectable rise in cyclic AMP concentration and a series of cyclic-AMP-dependent effects such as an activation of phosphofructokinase 2 and of trehalase and an increase in the concentration of fructose 2,6-bisphosphate and in the rate of glycolysis. Under all experimental conditions, the rate of glycolysis was proportional to the concentration of fructose 2,6-bisphosphate. Uncouplers, but not a nitrogen source, also induced an activation of glycogen phosphorylase and an inactivation of glycogen synthase when added to the cdc35 mutant incubated at the restrictive temperature of 35 degrees C without affecting cyclic AMP concentration.     

Regulation of liver glycogen synthase phosphatase activity by ATP-Mg

The kinetics of a synthase phosphatase reaction inhibited by ATP-Mg in a liver glycogen particle preparation were complex. In the presence of a physiological concentration of ATP-Mg, synthase phosphatase activity in the glycogen particle follows a biphasic course. Initially, the reaction was inhibited but later the reaction rate accelerated. The reaction was inhibited but the rate was constant in the presence of ATP-Mg with the addition of a physiological concentration of glucose 6-phosphate (Glc 6-P). Therefore, in most subsequent experiments Glc 6-P was added. The concentration of ATP-Mg at which 50% maximal inhibition (I0.5) occurred was approximately 0.1 mM in preparations obtained from rats given glucagon prior to being killed. In preparations from animals given glucose, the I0.5 was increased to 2.0 mM. The maximum inhibition was little changed in preparations from glucose- or glucagon-treated animals. Thus, administration of glucose in vivo reduced the sensitivity of the synthase phosphatase to ATP-Mg inhibition. Complexes of ATP with paramagnetic ions such as Co2+ and Mn2+ were less inhibitory than complexes with diamagnetic ions, including Ca2+ and Mg2+. Magnesium complexes of adenosine tetraphosphate and 5'-adenylimidodiphosphate also were inhibitory. Inhibition was independent of phosphorylase a and not a nonspecific, polyvalent anion effect. The best explanation for the distinctive effects of ATP-Mg in preparations from glucagon- and glucose-treated animals is that the respective treatments promote and stabilize different forms of synthase D or possibly synthase phosphatase with different affinities for ATP-Mg. These forms are interconvertible, as previously suggested, in studies employing EDTA (20).     

Glucose 6-phosphate plays a central role in the regulation of glycogen synthesis in a glycogen-storing liver cell line

Two substrains of the epithelial liver cell line C1I, one storing large amounts of glycogen, the other one being very poor in glycogen were used as a model for studying glycogen synthesis. The glycogen content of glycogen-rich cells doubled during the proliferative phase and remained high in plateau phase although glycogen synthase I activity was not significantly altered during growth cycle and was too low to account for the increase in glycogen. However, the activity of the glucose 6-phosphate (Glc6-P)-dependent synthase rose continuously during growth cycle, and intracellular Glc6-P-concentration increased about 10-fold in log phase cells to 0.72 mumol g-1 wet weight. A0.5 of synthase for Glc6-P was 0.79 mM. It was also found that in contrast to the enzyme from normal liver, glycogen phosphorylase a from C1I cells was inhibited by Glc6-P, the apparent Ki being 0.45 mM. It was concluded that glycogen accumulation in C1I cells was due to stimulation of synthase and inhibition of phosphorylase by Glc6-P. Findings from the glycogen-poor cell line which revealed similar specific activities of synthase and phosphorylase but only low Glc6-P (0.056 mumol g-1 wet weight) supported this conclusion. Addition of glucose to starved cells resulted in a transient activation of synthase in both cell lines. Net glycogen synthesis, was, however, only observed in the cells with a high Glc6-P-content. Thus, modulation of synthase and phosphorylase by Glc6-P and not activation/inactivation of the enzymes seems to play a predominant role in glycogen accumulation in this cell line.     

Glycogen synthesis by rat hepatocytes.

1. Hepatocytes from starved rats or fed rats whose glycogen content was previously depleted by phlorrhizin or by glucagon injections, form glycogen at rapid rates when incubated with 10mM-glucose, gluconeogenic precursors (lactate, glycerol, fructose etc.) and glutamine. There is a net synthesis of glucose and glycogen. 14C from all three types of substrate is incorporated into glycogen, but the incorporation from glucose represents exchange of carbon atoms, rather than net incorporation. 14C incorporation does not serve to measure net glycogen synthesis from any one substrate. 2. With glucose as sole substrate net glucose uptake and glycogen deposition commences at concentrations of about 12--15mM. Glycogen synthesis increases with glucose concentrations attaining maximal values at 50--60mM, when it is similar to that obtained in the presence of 10mM glucose and lactate plus glutamine. 3. The activities of the active (a) and total (a+b) forms of glycogen synthase and phosphorylase were monitored concomitant with glycogen synthesis. Total synthase was not constant during a 1 h incubation period. Total and active synthase activity increased in parallel with glycogen synthesis. 4. Glycogen phosphorylase was assayed in two directions, by conversion of glycose 1-phosphate into glycogen and by the phosphorylation of glycogen. Total phosphorylase was assyed in the presence of AMP or after conversion into the phosphorylated form by phosphorylase kinase. Results obtained by the various methods were compared. Although the rates measured by the procedures differ, the pattern of change during incubation was much the same. Total phosphorylase was not constant. 5. The amounts of active and total phosphorylase were highest in the washed cell pellet. Incubation in an oxygenated medium, with or without substrates, caused a prompt and pronounced decline in the assayed amounts of active and total enzyme. There was no correlation between phosphorylase activity and glycogen synthesis from gluconeogenic substrates. With fructose, active and total phosphorylase activities increased during glycogen syntheses. 6. In glycogen synthesis from glucose as sole substrate there was a decline in phosphorylase activities with increased glucose concentration and increased rates of glycogen deposition. The decrease was marked in cells from fed rats. 7. To determine whether phosphorolysis and glycogen synthesis occur concurrently, glycogen was prelabelled with [2-3H,1-14C]-galactose. During subsequent glycogen deposition there was no loss of activity from glycogen in spite of high amounts of assayable active phosphorylase.     

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.     

Phosphorylation of heart glycogen synthase by cAMP-dependent protein kinase. Regulatory effects of ATP

Glycogen synthase I, purified from bovine heart, had a specific activity of 33 units/mg and gave a single band on sodium dodecyl sulfate gel electrophoresis with a subunit molecular weight of 86,000. The enzyme was phosphorylated with cAMP-dependent protein kinase catalytic subunit, also isolated from heart. With 10 microM ATP, only one phosphate group was incorporated per subunit of glycogen synthase. The phosphorylation decreased the per cent of glycogen synthase I from 0.95 to 0.50 when activity was determined by assays with Na2SO4 and glucose 6-phosphate. Glycogen synthase containing one phosphate per subunit was designated GS-1. One additional phosphate was incorporated per synthase subunit when ATP was increased to 0.5 mM and the percent glycogen synthase I decreased from 0.50 to < 0.05. This enzyme form was designated GS-1,2. Conversion of GS-1 to Gs-1,2 gave cooperative kinetics with ATP concentration and a half-maximal stimulation at approximately 40 microM. Phosphorylation of GS-1 could also be achieved by adding other non-substrate nucleotide triphosphates such as ITP and UTP along with 10 microM ATP. Glucose-6-P and Na2SO4 were without effect on this phosphorylation reaction. Two separate peptides were obtained after CNBr cleavage of 32P-labeled GS-1,2 and only one from GS-1. Both enzyme forms contained a single phosphorylated peptide in common. Thus, heart glycogen synthase may be phosphorylated specifically in either of two different sites using appropriate concentrations of ATP. ATP acts as a substrate for the protein kinase and also affects the availability of a second site to phosphorylation by cAMP-dependent protein kinase.     

Frog liver glycogen synthase. In vitro and in vivo interconversions between I and D forms.

1. Frog liver has enzymatic systems able to interconvert glycogen synthase. 2. D to I conversion is achieved in vitro by incubation at 30 degrees C. ATP, ADP, inorganic phosphate and glycogen are inhibitors of this conversion, whereas glucose-6-P and Mg2+ stimulate it. 3. I to D conversion in vitro depends on ATP-Mg2+. Cyclic-AMP activates this conversion, while glucose-6-P inhibits it. 4. Injection of glucose, ribose, mannose, fructose, galactose, and cortisone into frogs increase liver percentage of I activity. 5. Glucagon and adrenaline decrease percentage of I activity.     

Lithium's effects on rat liver glucose metabolism in vivo

Oral administration of lithium carbonate to fed-healthy rats strongly decreased liver glycogen content, despite the simultaneous activation of glycogen synthase and the inactivation of glycogen phosphorylase. The effect seemed to be related to a decrease in glucose 6-phosphate concentration and to a decrease in glucokinase activity. Moreover, in these animals lithium markedly decreased liver fructose 2,6-bisphosphate, which could be a consequence of the fall in glucose 6-phosphate and of the inactivation of 6-phosphofructo-2-kinase. Liver pyruvate kinase activity and blood insulin also decreased after lithium administration. Lower doses of lithium carbonate had less intense effects. Lithium administration to starved-healthy and fed-streptozotocin-diabetic rats caused a slight increase in blood insulin, which was simultaneous with increases in liver glycogen, glucose 6-phosphate, and fructose 2, 6-phosphate. Glucokinase, 6-phosphofructo-2-kinase, and pyruvate kinase activities also increased after lithium administration in starved-healthy and fed-diabetic rats. Lithium treatment activated glycogen synthase and inactivated glycogen phosphorylase in a manner similar to that observed in fed-healthy rats. Glycemia was not modified in any group of animals. These results indicate that lithium acts on liver glycogen metabolism in vivo in at least two different ways: one related to changes in insulinemia, and the other related to the direct action of lithium on the activity of some key enzymes of liver glucose metabolism.     

Glycogen synthase activation by sugars in isolated hepatocytes

We have investigated the activation by sugars of glycogen synthase in relation to (i) phosphorylase a activity and (ii) changes in the intracellular concentration of glucose 6-phosphate and adenine nucleotides. All the sugars tested in this work present the common denominator of activating glycogen synthase. On the other hand, phosphorylase a activity is decreased by mannose and glucose, unchanged by galactose and xylitol, and increased by tagatose, glyceraldehyde, and fructose. Dihydroxyacetone exerts a biphasic effect on phosphorylase. These findings provide additional evidence proving that glycogen synthase can be activated regardless of the levels of phosphorylase a, clearly establishing that a nonsequential mechanism for the activation of glycogen synthase occurs in liver cells. The glycogen synthase activation state is related to the concentrations of glucose 6-phosphate and adenine nucleotides. In this respect, tagatose, glyceraldehyde, and fructose deplete ATP and increase AMP contents, whereas glucose, mannose, galactose, xylitol, and dihydroxyacetone do not alter the concentration of these nucleotides. In addition, all these sugars, except glyceraldehyde, increase the intracellular content of glucose 6-phosphate. The activation of glycogen synthase by sugars is reflected in decreases on both kinetic constants of the enzyme, M0.5 (for glucose 6-phosphate) and S0.5 (for UDP-glucose). We propose that hepatocyte glycogen synthase is activated by monosaccharides by a mechanism triggered by changes in glucose 6-phosphate and adenine nucleotide concentrations which have been described to modify glycogen synthase phosphatase activity. This mechanism represents a metabolite control of the sugar-induced activation of hepatocyte glycogen synthase.     

Interconversion between multiple glucose 6-phosphate-dependent forms of glycogen synthase in intact adipose tissue.

We have tested the hypothesis that interconversion between multiple glucose-6-P-dependent forms of glycogen synthase helps regulate glycogen synthesis in adipose tissue. Our results indicate that interconversion of glycogen synthase in adipose tissue involves primarily dependent forms and that these interconversions were measured better by monitoring the activation constant (A0.5) for glucose-6-P than measuring the -: + glucose-6-P activity ratio. Insulin decreased and epinephrine increased the A0.5 for glucose-6-P without significant change in the activity ratio. Insulin consistently decreased the A0.5 in either the presence or absence of glucose, indicating that the insulin-promoted interconversion did not require increased hexose transport. Isoproterenol increased the A0.5 for glucose-6-P, while methoxamine was without effect, indicating beta receptors mediate adrenergic control of interconversion between glucose-6-P-dependent forms. The changes in the A0.5 produced by incubations with insulin or epinephrine were mutually reversible. We conclude that 1) glycogen synthesis in adipose tissue is catalyzed by multiple glucose-6-P-dependent forms of glycogen synthase, 2) hormones regulate glycogen metabolism by promoting reversible interconversions between these forms, and 3) there is no evidence that a glucose-6-P-independent form of glycogen synthase exists in intact adipose tissue.     

Influence of some mononucleotides and their corresponding nucleosides on the metabolism of carbohydrates in the isolated rat diaphragm muscle.

1. The influence of ATP on glucose metabolism was studied in the isolated rat diaphragm; it was shown that ATP increases the oxidation of glucose and the aerobic conversion of glucose into lactate, whereas it decreases glycogen synthesis. There was no influence of ATP on the anaerobic formation of lactate from glucose. 2. A maximum effect of ATP on the oxidation of glucose (about 160% increase) was obtained in the presence of 10mm-ATP; in the presence of 2mm-ATP the effect was about 65%, and was approximately constant from 10 to 90min. incubation period. 3. In a phosphate-free tris-buffered medium the oxidation of glucose was considerably decreased, but the percentage stimulation by ATP was about the same as in a phosphate-buffered medium. 4. ATP was shown to increase the oxidation of fructose, glucose 6-phosphate, glucose 1-phosphate, fructose 1,6-diphosphate and, to a much smaller extent, pyruvate. 5. ADP stimulated the oxidation of glucose to the same extent as ATP at a concentration of 2mm and the effect with AMP was only slightly less; IMP and adenosine had only a small stimulatory effect at this concentration, whereas inosine had no effect.     

Role of AMP on the activation of glycogen synthase and phosphorylase by adenosine, fructose, and glutamine in rat hepatocytes

The mechanism for glycogen synthesis stimulation produced by adenosine, fructose, and glutamine has been investigated. We have analyzed the relationship between adenine nucleotides and glycogen metabolism rate-limiting enzymes upon hepatocyte incubation with these three compounds. In isolated hepatocytes, inhibition of AMP deaminase with erythro-9-(2-hydroxyl-3nonyl)adenine further increases the accumulation of AMP and the activation of glycogen synthase and phosphorylase by fructose. This ketose does not increase cyclic AMP or the activity of cyclic AMP-dependent protein kinase. Adenosine raises AMP and ATP concentration. This nucleotide also activates glycogen synthase and phosphorylase by covalent modification. The correlation coefficient between AMP and glycogen synthase activity is 0.974. Nitrobenzylthioinosine, a transport inhibitor of adenosine, blocks (by 50%) the effect of the nucleoside on AMP formation and glycogen synthase but not on phosphorylase. 2-Chloroadenosine and N6-phenylisopropyladenosine, nonmetabolizable analogues of adenosine, activate phosphorylase (6-fold) without increasing the concentration of adenine nucleotides or the activity of glycogen synthase. Cyclic AMP is not increased by adenosine in hepatocytes from starved rats but is in cells from fed animals. [Ethylenebis (oxyethylenenitrilo)]tetraacetic acid (EGTA) blocks by 60% the activation of phosphorylase by adenosine but not that of glycogen synthase. Glutamine also increases AMP concentration and glycogen synthase and phosphorylase activities, and these effects are blocked by 6-mercaptopurine, a purine synthesis inhibitor. Neither adenosine nor glutamine increases glucose 6-phosphate. It is proposed that the observed efficient glycogen synthesis from fructose, adenosine, and glutamine is due to the generation of AMP that activates glycogen synthase probably through increases in synthase phosphatase activity. It is also concluded that the activation of phosphorylase by the above-mentioned compounds can be triggered by metabolic changes.     

Mechanism of muscle glycogen autoregulation in humans

To examine the mechanism by which muscle glycogen limits its own synthesis, muscle glycogen and glucose 6-phosphate (G-6-P) concentrations were measured in seven healthy volunteers during a euglycemic ( approximately 5.5 mM)-hyperinsulinemic ( approximately 450 pM) clamp using (13)C/(31)P nuclear magnetic resonance spectroscopy before and after a muscle glycogen loading protocol. Rates of glycogen synthase (V(syn)) and phosphorylase (V(phos)) flux were estimated during a [1-(13)C]glucose (pulse)-unlabeled glucose (chase) infusion. The muscle glycogen loading protocol resulted in a 65% increase in muscle glycogen content that was associated with a twofold increase in fasting plasma lactate concentrations (P < 0.05 vs. basal) and an approximately 30% decrease in plasma free fatty acid concentrations (P < 0.001 vs. basal). Muscle glycogen loading resulted in an approximately 30% decrease in the insulin-stimulated rate of net muscle glycogen synthesis (P < 0.05 vs. basal), which was associated with a twofold increase in intramuscular G-6-P concentration (P < 0.05 vs. basal). Muscle glycogen loading also resulted in an approximately 30% increase in whole body glucose oxidation rates (P < 0.05 vs. basal), whereas there was no effect on insulin-stimulated rates of whole body glucose uptake ( approximately 10.5 mg. kg body wt(-1). min(-1) for both clamps) or glycogen turnover (V(syn)/V(phos) was approximately 23% for both clamps). In conclusion, these data are consistent with the hypothesis that glycogen limits its own synthesis through feedback inhibition of glycogen synthase activity, as reflected by an accumulation of intramuscular G-6-P, which is then shunted into aerobic and anaerobic glycolysis.     

Control of glycogen metabolism by gluconeogenic and ketogenic substrates in isolated hepatocytes from fed rats.

1. This study was conducted to examine the effects of gluconeogenic and ketogenic substrates on the activities of the glycogen-metabolizing enzymes and on glycogenolysis in isolated hepatocytes from fed rats. 2. Gluconeogenic substrates like fructose, dihydroxyacetone or lactate turned out to stimulate the glucose-induced activation of glycogen synthase and this effect may be linked, to some extent, to the increase of the cellular glucose 6-phosphate concentration. 3. The effect of fructose was accompanied by the onset of glycogen synthesis. 4. Energetic substrates like fatty acids were also potent activators of glycogen synthase, especially in the presence of glucose. 5. When fatty acids were added alone or together with a physiological concentration of glucose, they induced or potentiated the inhibition of glycogen phosphorylase-a. 6. This inhibitory effect was mediated by a decrease of lactate release. 7. The stimulatory effect of amino acids on glycogen synthase seemed to be direct, non mediated by an inhibition of the phosphorylase-a activity although hepatic glycogenolysis markedly decreased. 8. Moreover, the amino acid action could be linked to their capacities to induce cell swelling and/or to limit proteolysis.     

Activation of hepatocyte glycogen synthase by metabolic inhibitors

Incubation of isolated rat hepatocytes with metabolic inhibitors causes an increase in the -glucose 6-P/+glucose 6-P activity ratio of glycogen synthase after decreasing ATP and increasing AMP levels. Concomitantly, the activity of phosphorylase is increased six-fold by the same treatment. This activation of both enzymes remains after gel filtration of the hepatocyte extracts. Addition of metabolic inhibitors to cells pretreated with an inhibitor of AMP-deaminase results in an accumulation of AMP and, simultaneously, in a further increase in the activation state of glycogen synthase. The correlation coefficient between the intracellular concentration of AMP and glycogen synthase activity is r = 0.93. It is proposed that the covalent activation of glycogen synthase by metabolic inhibitors can be triggered by changes in the level of the intracellular concentrations of adenine nucleotides.