Cyclic AMP-mediated activation of hepatic glycogenolysis by fructose.

Isolated livers from fed and fasted rats were perfused for 30 min with recirculating blood-buffer medium containing no added substrate and then switched to a flow-through perfusion using the same medium for an additional 5, 10 and 30 min. Continuous infusion of fructose for the final 5, 10 or 30 min resulted in activation of glycogen phosphorylase, an increase in the activity of protein kinase, elevated levels of tissue adenosine 3', 5'-monophosphate (cyclic AMP), and no consistent effect on glycogen synthase. Infusion of glucose under the same conditions resulted in activation of glycogen synthase, inactivation of glycogen phosphorylase, no change in protein kinase, and no consistent change in tissue cyclic AMP. These results demonstrate that while glucose promotes hepatic glycogen synthesis, fructose promotes activation of the enzymatic cascade responsible for glycogen breakdown.     

Glucose activation of liver glycogen synthase. Insulin-mediated restoration of glucose effect in diabetic rate is blocked by protein synthesis inhibitor

The loss of glucose regulation of glycogen synthase in perfused livers from diabetic rats was associated with a substantial reduction in synthase phosphatase activity. Treatment of diabetic rats with insulin alone resulted in total restoration of the glucose effect and synthase phosphatase activity, while simultaneous treatment with cycloheximide severely reduced the hormonal effect. Although treatment of normal rats with cycloheximide had no effect on glucose activation of synthase, it did result in severe depletion of liver glycogen increased liver glycogen phosphorylase activity, and elevation of liver adenosine 3′,5′-monosphosphate (cyclic AMP), but without elevation of liver protein kinase activity. Simultaneous treatment of alloxan-diabetic rats with insulin and cycloheximide resulted in reduction of total liver glycogen, increased phosphorylase activity, a reduction in the ability of insulin to lower hepatic cyclic AMP, and a further reduction of protein kinase activity.In summary, the effect of insulin treatment of diabetic rats to restore glucose regulation of hepatic glycogen synthase probably involves synthesis of new protein, and the data remain consistent with the hypothesis that the defect may be due to a diabetes-related deficiency in a specific synthase phosphatase and/or alteration of the synthase molecule itself.     

Glucose activation of liver glycogen synthase. Insulin-mediated restoration of glucose effect in diabetic rats is blocked by protein synthesis inhibitor.

The loss of glucose regulation of glycogen synthase in perfused livers from diabetic rats was associated with a substantial reduction in synthase phosphatase activity. Treatment of diabetic rats with insulin alone resulted in total restoration of the glucose effect and synthase phosphatase activity, while simultaneous treatment with cycloheximide severely reduced the hormonal effect. Although treatment of normal rats with cycloheximide had no effect on glucose activation of synthase, it did result in severe depletion of liver glycogen, increased liver glycogen phosphorylase activity, and elevation of liver adenosine 3',5'-monophosphate (cyclic AMP), but without elevation of liver protein kinase activity. Simultaneous treatment of alloxan-diabetic rats with insulin and cycloheximide resulted in reduction of total liver glycogen, increased phosphorylase activity, a reduction in the ability of insulin to lower hepatic cyclic AMP, and a further reduction of protein kinase activity. In summary, the effect of insulin treatment of diabetic rats to restore glucose regulation of hepatic glycogen synthase probably involves synthesis of new protein, and the data remain consistent with the hypothesis that the defect may be due to a diabetes-related deficiency in a specific synthase phosphatase and/or alteration of the synthase molecule itself.     

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.     

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.     

Activation of protein kinase and glycogen phosphorylase in isolated rat liver cells by glucagon and catecholamines.

In liver cells isolated from fed female rats, glucagon (290nM) increased adenosine 3':5'-monophosphate (cyclic AMP) content and decreased cyclic AMP binding 30 s after addition of hormones. Both returned to control values after 10 min. Glucagon also stimulated cyclic AMP-independent protein kinase activity at 30 s and decreased protein kinase activity assayed in the presence of 2 muM cyclic AMP at 1 min. Glucagon increased the levels of glycogen phosphorylase a, but there was no change in total glycogen phosphorylase activity. Glucagon increased glycogen phosphorylase a at concentrations considerably less than those required to affect cyclic AMP and protein kinase. The phosphodiesterase inhibitor, 1-methyl-3-isobutyl xanthine, potentiated the action of glucagon on all variables, but did not increase the maximuM activation of glycogen phosphorylase. Epinephrine (1muM) decreased cyclic AMP binding and increased glycogen phosphorylase a after a 1-min incubation with cells. Although 0.1 muM epinephrine stimulated phosphorylase a, a concentration of 10 muM was required to increase protein kinase activity. 1-Methyl-3-isobutyl xanthine (0.1 mM) potentiated the action of epinephrine on cyclic AMP and protein kinase. (-)-Propranolol (10muM) completely abolished the changes in cyclic AMP binding and protein kinase due to epinephrine (1muM) in the presence of 0.1mM 1-methyl-3-isobutyl xanthine, yet inhibited the increase in phosphorylase a by only 14 per cent. Phenylephrine (0.1muM) increased glycogen phosphorylase a, although concentrations as great as 10 muM failed to affect cyclic AMP binding or protein kinase in the absence of phosphodiesterase inhibitor. Isoproterenol (0.1muM) stimulated phosphorylase and decreased cyclic AMP binding, but only a concentration of 10muM increased protein kinase. 1-Methyl-3-isobutyl xanthine potentiated the action of isoproterenol on cyclic AMP binding and protein kinase, and propranolol reduced the augmentation of glucose release and glycogen phosphorylase activity due to isoproterenol. These data indicate that both alpha- and beta-adrenergic agents are capable of stimulating glycogenolysis and glycogen phosphorylase a in isolated rat liver cells. Low concentrations of glucagon and beta-adrenergic agonists stimulate glycogen phosphorylase without any detectable increase in cyclic AMP or protein kinase activity. The effects of alpha-adrenergic agents appear to be completely independent of changes in cyclic AMP protein kinase activity.     

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.     

Effects of the specific cAMP antagonist, (Rp)-adenosine cyclic 3',5'-phosphorothioate, on the cAMP-dependent protein kinase-induced activity of hepatic glycogen phosphorylase and glycogen synthase

The cAMP-dependent protein kinase-induced effects on phosphorylase and glycogen synthase activities and glucose production were studied in hepatocytes isolated from fed rats in the presence of the diastereomers of adenosine cyclic 3',5'-phosphorothioate, (Sp)-cAMPS and (Rp)-cAMPS. Incubation of hepatocytes with (Sp)-cAMPS or glucagon, both of which lead to cAMP-dependent protein kinase activation, resulted in a concentration-dependent increase in glycogen phosphorylase activity and a decrease in glycogen synthase activity. Incubation of hepatocytes with the cAMP-dependent protein kinase antagonist, (Rp)-cAMPS, in the absence of an agonist, had no significant effect on phosphorylase or glycogen synthase activities. Incubation of hepatocytes with a half-maximally inhibitory concentration of (Rp)-cAMPS shifted the agonist-induced activation curves for phosphorylase and the agonist-induced inhibition curves for glycogen synthase to 5-fold higher concentrations for both (Sp)-cAMPS and glucagon. Phosphorylase activity was very sensitive to the rapid, concentration-dependent inhibition by (Rp)-cAMPS of agonist-induced activation of cAMP-dependent protein kinase. The effects on phosphorylase activity were observable in 30 s and were concentration-dependent with half-maximal inhibition at 10 microM, similar to that observed for cAMP-dependent protein kinase. In contrast, glycogen synthase activity was less sensitive to (Rp)-cAMPS inhibition of agonist-induced activation of cAMP-dependent protein kinase. The effects on glycogen synthase activity lagged behind those on phosphorylase activity and the concentration dependence did not parallel the cAMP-dependent protein kinase effect, but was shifted to higher concentrations of (Rp)-cAMPS with half-maximal inhibition at 60 microM. Glucose (10 to 40 mM) increased the sensitivity of glycogen synthase to (Rp)-cAMPS inhibition of cAMP-dependent protein kinase over a narrow range of agonist concentration, but had no significant effect throughout most of the agonist-induced activation range. Thus, the diastereomers, (Sp)- and (Rp)-cAMPS, influence glycogen metabolism and the glycogenolytic enzymes through their modulation of cAMP-dependent protein kinase levels.     

Synthesis of glycogen from fructose in the presence of elevated levels of glycogen phosphorylase a in rat hepatocytes

Incubation of hepatocytes with glucose promoted the increase in the glycogen synthase (-glucose 6-phosphate/+glucose 6-phosphate) activity ratio, the decrease in the levels of phosphorylase a and a marked increase in the intracellular glycogen level. Incubation with fructose alone promoted the simultaneous activation of glycogen synthase and increase in the levels of phosphorylase a. Strikingly, glycogen deposition occurred in spite of the elevated levels of phosphorylase a. When glucose and fructose were added to the media the activation of glycogen synthase was always higher than when the hexoses were added separately. On the other hand the effects on glycogen phosphorylase were a function of the relative concentrations of both sugars. Inactivation of glycogen phosphorylase occurred when the fructose to glucose ratio was low while activation took place when the ratio was high. The simultaneous presence of glucose and fructose resulted, in all cases, in an enhancement in the deposition of glycogen. The effects described were not limited to fructose as D-glyceraldehyde, dihydroxyacetone, L-sorbose, D-tagatose and sorbitol, compounds metabolically related to fructose, provoked the same behaviour.     

Regulation of glycogen metabolism in astrocytoma and neuroblastoma cells in culture.

The regulation of glycogen metabolism in C-6 astrocytoma and C-1300 neuroblastoma cells in culture has been investigated. Two modes of control of glycogen metabolism appear to be operative. The regulation of intracellular glycogen concentrations and the predominant forms of glycogen phosphorylase and glycogen synthase vary with (a) the available energy supply, and (b) altered intracellular concentration of cyclic adenosine 3':5'-monophosphate (cyclic AMP). Both cell lines respond to glucose in the medium; when glucose levels are high, glycogen is synthesized, glycogen phosphorylase a decreases, and glycogen synthase a increases. When glucose in the medium decreases to a critical level, the phosphorylase a increases and glycogen concentrations in the cells decrease in aprallel with the medium glucose. The critical glucose concentration is 2.5 mM for the astrocytoma cells and 4 mM for the neuroblastoma cells. Insulin promotes the conversion of phosphorylase to the b form and synthase to the a form in both cell lines. All of these changes occur without alteration in the intracellular cyclic AMP concentrations. When cyclic AMP concentrations are increased in either cell line, phosphorylase a is increased, synthase a is decreased, and glycogen concentrations decrease. Isobutyl methylxanthine is effective in promoting glycogenolysis in both cell lines. Norepinephrine is effective with the astrocytoma cells, and prostaglandin E1 is effective with the neuroblastoma cells.     

Intracellular mechanism of action of sympathetic hepatic nerves on glucose and lactate balance in perfused rat liver

In rat liver perfused in situ stimulation of the nerve plexus around the hepatic artery and the portal vein caused an increase in glucose output and a shift from lactate uptake to output. The effects of nerve stimulation on some key enzymes, metabolites and effectors of carbohydrate metabolism were determined and compared to the actions of glucagon, which led to an increase not only of glucose output but also of lactate uptake. 1. Nerve stimulation caused an enhancement of the activity of glycogen phosphorylase a to 300% and a decrease of the activity of glycogen synthase I to 40%, while it left the activity of pyruvate kinase unaltered. Glucagon, similarly to nerve action, led to a strong increase of glycogen phosphorylase and to a decrease of glycogen synthase; yet in contrast to the nerve effect it lowered pyruvate kinase activity clearly. 2. Nerve stimulation increased the levels of glucose 6-phosphate and of fructose 6-phosphate to 200% and 170%, respectively; glucagon enhanced the levels to about 400% and 230%, respectively. The levels of ATP and ADP were not altered, those of AMP were increased slightly by nerve stimulation. 3. Nerve stimulation enhanced the levels of the effectors fructose 2,6-bisphosphate and cyclic AMP only slightly to 140% and 125%, respectively; glucagon lowered the level of fructose 2,6-bisphosphate to 15% and increased the level of cyclic AMP to 300%. 4. In calcium-free perfusions the metabolic responses to nerve stimulation showed normal kinetics, if calcium was re-added 3 min before, but delayed kinetics, if it was re-added 2 min after the onset of the stimulus. The delay may be due to the time required to refill intracellular calcium stores. The hemodynamic alterations dependent on extracellular calcium were normal in both cases. The activation of glycogen phosphorylase, the inhibition of glycogen synthase and the increase of glucose 6-phosphate can well explain the enhancement of glucose output following nerve stimulation. The unaltered activity of pyruvate kinase and the marginal increase of fructose 2,6-bisphosphate cannot be the cause of the nerve-stimulation-dependent shift from lactate uptake to output. The very slight increase of the level of cyclic AMP after nerve stimulation cannot elicit the observed activation of glycogen phosphorylase.(ABSTRACT TRUNCATED AT 400 WORDS)     

The concentrations of glucose 1,6-bisphosphate and other regulatory metabolites, and the activities of enzymes of the glycogen metabolism in the perfused rabbit psoas muscle

The following parameters were determined in the rabbit psoas muscle after perfusion in the presence of either insulin, propranolol, or isoproterenol: Concentrations of cyclic AMP, glucose 1,6-bisphosphate, fructose 2,6-bisphosphate, glucose-1-phosphate, glucose 6-phosphate, and fructose-1,6-bisphosphate. Maximum and "regulatory" activities of the enzymes glycogen phosphorylase, glycogen synthase, phosphofructokinase, and histone-phosphorylating protein kinase.     

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.     

Liver glycogen metabolism during intestinal perfusion in the rat.

The effects of metabolic constituents on glycogen metabolism in the liver can be studied by perfusing the small intestine with those constituents capable of being absorbed across the gut mucosa. Perfusion of the gut with glucose to give concentrations of approx. 20 mM in the portal vein produced a 5-fold increase in liver glycogen after 60 min. The rate of synthesis over the 15–30 min period of perfusion of 1.24 μmol/min/g liver fell to 0.34 in the 30–60 min period. This stimulation was accompanied by a transient activation of glycogen synthase which occurred in the first 30 min period of perfusion but which had disappeared by 60 min. Glucose perfusion had no effect on total and active phosphorylase at the time intervals studied. While the pattern of insulin secretion during perfusion could not be ascertained, the activation of glycogen synthase and increase in glycogen synthesis correlated with the production of gastric inhibitory polypeptide (GIP), a potent stimulator of insulin secretion. Perfusion of the gut with fructose did not stimulate glycogen synthesis or activate glycogen synthase or stimulate GIP secretion, but instead it produced a marked activation of phosphorylase after 30 min of perfusion.     

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.     

Altered liver glycogen metabolism in fed genetically obese mice.

The cyclic AMP and glycogen concentrations and the activities of phosphorylase kinase, phosphorylase a and glycogen synthase a were not different in livers from lean or ob/ob mice despite increased plasma glucose and insulin in the obese group. The liver water content was decreased by 10% in the obese mice. In hepatocytes isolated from lean mice and incubated with increasing glucose concentrations (14-112 mM), a sequential inactivation of phosphorylase and activation of glycogen synthase was observed. In hepatocytes from obese mice the inactivation of phosphorylase was not followed by an activation of synthase. The inactivation of phosphorylase occurred more rapidly and was followed by an activation of synthase in hepatocytes isolated from both groups of mice when in the incubation medium Na+ was replaced by K+ or when Ca2+ was omitted and 2.5 mM-EGTA included. The inactivation of phosphorylase and activation of synthase were not different in broken-liver-cell preparations from lean and obese animals. The re-activation of phosphorylase in liver filtrates in the presence of 0.1 microM-cyclic AMP and MgATP was inhibited by about 70% by EGTA and stimulated by Ca2+ and was always greater in preparations from ob/ob mice. The apparent paradox between the impairment of glycogen metabolism in isolated liver preparations and the situation in vivo in obese mice is discussed.     

Effect of fructose 1-phosphate on the activation of liver glycogen synthase.

The activation (dephosphorylation) of glycogen synthase and the inactivation (dephosphorylation) of phosphorylase in rat liver extracts on the administration of fructose were examined. The lag in the conversion of synthase b into a was cancelled, owing to the accumulation of fructose 1-phosphate. A decrease in the rate of dephosphorylation of phosphorylase a was also observed. The latency re-appeared in gel-filtered liver extracts. Similar latency was demonstrated in extracts from glucagon-treated rats. Addition of fructose 1-phosphate to the extract was able to abolish the latency, and the activation of glycogen synthase and the inactivation of phosphorylase occurred simultaneously. Fructose 1-phosphate increased the activity of glycogen synthase b measured in the presence of 0.2-0.4 mM-glucose 6-phosphate. According to kinetic investigations, fructose 1-phosphate increased the affinity of synthase b for its substrate, UDP-glucose. The accumulation of fructose 1-phosphate resulted in glycogen synthesis in the liver by inducing the enzymic activity of glycogen synthase b in the presence of glucose 6-phosphate in vivo and by promoting the activation of glycogen synthase.     

Non-hormonal and hormonal control of glycogen metabolism in isolated sheep liver cells

1. Control of glycogen metabolism by various substrates and hormones was studied in ruminant liver using isolated hepatocytes from fed sheep. 2. In these cells glucose appeared uneffective to stimulate glycogen synthesis whereas fructose and propionate activated glycogen synthase owing to (i) a decrease in phosphorylase a activity and (ii) changes in the intracellular concentrations of glucose 6-phosphate and adenine nucleotides. 3. The activation of hepatic glycogenolysis by glucagon and alpha 1-adrenergic agents was associated with increased phosphorylase a and decreased glycogen synthase activities. 4. The simultaneous changes in these two enzyme activities suggest that in sheep liver, activation of phosphorylase a is not a prerequisite step for synthase inactivation. 5. In sheep hepatocytes, in the presence of propionate and after a lag period, insulin activated glycogen synthase without affecting phosphorylase a. 6. This latter result suggests that the direct activation of glycogen synthase by insulin is mediated by a glycogen synthase-specific kinase or phosphatase. Insulin also antagonized glucagon effect on glycogen synthesis by counteracting the rise of cAMP.     

Activation of phosphoprotein phosphatases by growth hormone sequences with insulin-like activity

The N-terminal part sequences of pituitary growth hormone, N-acetyl-hGH 7–13 and hGH 6–13, promoted conversion of glycogen synthase b to glycogen synthase a in skeletal muscle and adipose tissue when injected intravenously. The peptides also caused conversion of phosphorylase a to phosphorylase b in liver and adipose tissue, but not in muscle, where the peptides antagonised activation of phosphorylase. Synthase phosphatase activity in muscle and phosphorylase phosphatase activity in liver increased after injection of peptide, with time courses of change similar to those seen for muscle synthase and liver phosphorylase activities. Injection of peptide also decreased both the cyclic AMP dependent and independent synthase kinase activities in muscle. These results show that the insulin-like activities of these peptides on glycogen synthase and phosphorylase involve both increases in protein phosphatase activities and inhibition of protein kinase activities. These results are discussed in relation to the insulin-like activities of growth hormone.     

The glycogenic action of protein targeting to glycogen in hepatocytes involves multiple mechanisms including phosphorylase inactivation and glycogen synthase translocation

Expression of the glycogen-targeting protein PTG promotes glycogen synthase activation and glycogen storage in various cell types. In this study, we tested the contribution of phosphorylase inactivation to the glycogenic action of PTG in hepatocytes by using a selective inhibitor of phosphorylase (CP-91149) that causes dephosphorylation of phosphorylase a and sequential activation of glycogen synthase. Similar to CP-91194, graded expression of PTG caused a concentration-dependent inactivation of phosphorylase and activation of glycogen synthase. The latter was partially counter-acted by the expression of muscle phosphorylase and was not additive with the activation by CP-91149, indicating that it is in part secondary to the inactivation of phosphorylase. PTG expression caused greater stimulation of glycogen synthesis and translocation of glycogen synthase than CP-91149, and the translocation of synthase could not be explained by accumulation of glycogen, supporting an additional role for glycogen synthase translocation in the glycogenic action of PTG. The effects of PTG expression on glycogen synthase and glycogen synthesis were additive with the effects of glucokinase expression, confirming the complementary roles of depletion of phosphorylase a (a negative modulator) and elevated glucose 6-phosphate (a positive modulator) in potentiating the activation of glycogen synthase. PTG expression mimicked the inactivation of phosphorylase caused by high glucose and counteracted the activation caused by glucagon. The latter suggests a possible additional role for PTG on phosphorylase kinase inactivation.