Progressive weakening of the response of key enzymes of liver glycogen metabolism to permanently increased plasma epinephrine levels

In adult male rats anaesthetized with pentobarbital the intravenous infusion of 0.5 micrograms.kg-1.min-1 of epinephrine increased liver phosphorylase a activity within 5 min, whereas later a weakening of the hormone effect was observed. After increasing the infusion rate to 1.0 micrograms.kg-1.min-1 and extending the study to more parameters, the diminishing effect on phosphorylase was confirmed and a similar response was established for liver cAMP. Concomitantly, a decrease and recovery of liver glycogen synthase a activity was observed. In rats with permanent catheters in one of their tail arteries for obtaining blood samples, the plasma epinephrine levels were shown to be permanently increased (from cca 1 pmol.ml-1 before infusion of 1.0 micrograms.kg-1.min-1 to more than 30 pmol.ml-1 during infusion) and remained at steady levels throughout the infusion. Therefore, the weakening of the epinephrine effect should be ascribed to changes at (or beyond) the catecholamine receptor level. A hitherto undescribed decrease of total glycogen synthase activity was observed during the infusions.     

Fasting reduces the response of liver glycogen phosphorylase to physiological levels of epinephrine in rats

The effect of 24 h fasting on the response of rat liver glycogen phosphorylase activity to an i.v. bolus of 2.75, 5.50 or 22.00 nmol kg-1 of epinephrine was studied. Even the lowest dose increased activity of the a form of the enzyme in the liver of anesthetized, fed rats to approximately 70 - 80% of total enzyme activity two minutes after administration. Further increased epinephrine doses failed to potentiate the enzyme response significantly, but shortened the time necessary for attaining the response, and delayed the return of enzyme activity to control values. No activation of phosphorylase was demonstrable after 2.75 nmol kg-1 of the hormone injected to fasted rats, but after increasing the hormone dose to 5.50 nmol kg-1 the enzyme response was the same as in the corresponding fed group at 2 min, and after administering the highest dose both at 1 and 2 min. According to these results, an increased threshold to epinephrine should be added to the already described effects of fasting, i.e. decreased phosphorylase a and total enzyme activity and shortened response to catecholamines. The efficacy of the i.v. bolus of 5.50 nmol kg-1 of epinephrine in increasing plasma epinephrine level to the theoretical value of 27.5 pmol ml-1 was proven by measuring plasma epinephrine which increased during the first minute after hormone administration to 24.5 + 5.9 pmol ml-1, to decrease during an additional minute with a half life of cca 22.2 seconds.     

The role played by hormonal factors in the rapid activation of liver glycogen phosphorylase in traumatized rats

In adult male SPF rats anaesthetized with pentobarbital and subjected to traumatization in revolving Noble-Collip drums for 2 min (= 120 revolutions) maximal increases of liver glycogen phosphorylase activity were observed. In experiments on rats with permanent arterial catheters for blood sampling no posttraumatic increase of plasma norepinephrine and an only slight increase of plasma epinephrine was observed if the animals were traumatized under anaesthesia, in contrast to the considerable increases in the plasma level of both hormones in rats subjected to the injury without anaesthesia. Time and extent of the phosphorylase response of anaesthetized rats after trauma were compared with changes in enzyme activity after i.v. administration of exogenous epinephrine or glucagon. A nearly maximal response after 1 microgram kg-1 epinephrine was present within 1 min, whereas after 0.1 micrograms kg-1 of glucagon there was comparable phosphorylase activation 2 min after administration of the hormone. The plasma renin-angiotensin activity was not increased after injury for 2 min under anaesthesia so that only the increase in plasma vasopressin fitted in with the criteria for possible activators of phosphorylase. An additional role of glucagon also cannot be excluded on the basis of data obtained by the present authors. The increase of phosphorylase activity in this type of stress is ensured by several mechanisms. Moreover, the high effectivity of these hormonal factors in evoking the phosphorylase response even without major activation of the sympathicoadrenal system is underlined.     

Studies on the alpha-adrenergic activation of hepatic glucose output. I. Studies on the alpha-adrenergic activation of phosphorylase and gluconeogenesis and inactivation of glycogen synthase in isolated rat liver parenchymal cells.

Epinephrine and the alpha-adrenergic agonist phenylephrine activated phosphorylase, glycogenolysis, and gluconeogenesis from lactate in a dose-dependent manner in isolated rat liver parenchymal cells. The half-maximally active dose of epinephrine was 10-7 M and of phenylephrine was 10(-6) M. These effects were blocked by alpha-adrenergic antagonists including phenoxybenzamine, but were largely unaffected by beta-adrenergic antagonists including propranolol. Epinephrine caused a transient 2-fold elevation of adenosine 3':5'-monophosphate (cAMP) which was abolished by propranolol and other beta blockers, but was unaffected by phenoxybenzamine and other alpha blockers. Phenoxybenzamine and propranolol were shown to be specific for their respective adrenergic receptors and to not affect the actions of glucagon or exogenous cAMP. Neither epinephrine (10-7 M), phenylephrine (10-5 M), nor glucagon (10-7 M) inactivated glycogen synthase in liver cells from fed rats. When the glycogen synthase activity ratio (-glucose 6-phosphate/+ glucose 6-phosphate) was increased from 0.09 to 0.66 by preincubation of such cells with 40 mM glucose, these agents substantially inactivated the enzyme. Incubation of hepatocytes from fed rats resulted in glycogen depletion which was correlated with an increase in the glycogen synthase activity ratio and a decrease in phosphorylase alpha activity. In hepatocytes from fasted animals, the glycogen synthase activity ratio was 0.32 +/- 0.03, and epinephrine, glucagon, and phenylephrine were able to lower this significantly. The effects of epinephrine and phenylephrine on the enzyme were blocked by phenoxybenzamine, but were largely unaffected by propranolol. Maximal phosphorylase activation in hepatocytes from fasted rats incubated with 10(-5) M phenylephrine preceded the maximal inactivation of glycogen synthase. Addition of glucose rapidly reduced, in a dose-dependent manner, both basal and phenylephrine-elevated phosphorylase alpha activity in hepatocytes prepared from fasted rats. Glucose also increased the glycogen synthase activity ratio, but this effect lagged behind the change in phosphorylase. Phenylephrine (10-5 M) and glucagon (5 x 10(-10) M) decreased by one-half the fall in phosphoryalse alpha activity seen with 10 mM glucose and markedly suppressed the elevation of glycogen synthase activity. The following conclusions are drawn from these findings. (a) The effects of epinephrine and phenylephrine on carbohydrate metabolism in rat liver parenchymal cells are mediated predominantly by alpha-adrenergic receptors. (b) Stimulation of these receptors by epinephrine or phenylephrine results in activation of phosphorylase and gluconeogenesis and inactivation of glycogen synthase by mechanisms not involving an increase in cellular cAMP. (c) Activation of beta-adrenergic receptors by epinephrine leads to the accumulation of cAMP, but this is associated with minimal activation of phosphorylase or inactivation of glycogen synthase...     

Regulation of synthase phosphatase and phosphorylase phosphatase in rat liver.

Using substrates purified from liver, the apparent Km values of synthase phosphatase ([UDPglucose--glycogen glucosyltransferase-D]phosphohydrolase, EC 3.1.3.42) and phosphorylase phosphatase (phosphorylase a phosphohydrolase, EC 3.1.3.17) were found to be 0.7 and 60 units/ml respectively. The maximal velocity of phosphorylase phosphatase was more than a 100 times that of synthase phosphatase. In adrenalectomized, fasted animals there was a complete loss of synthase phosphatase but only a slight decrease in phosphorylase phosphatase when activity was measured using endogenous substrates in a concentrated liver extract. When assayed under optimal conditions with purified substrates, both activities were present but had decreased to very low levels. Mixing experiments indicated that synthase D present in the extract of adrenalectomized fasted animals was altered such that it was no longer a substrate for synthase phosphatase from normal rats. Phosphorylase a substrate on the other hand was unaltered and readily converted. When glucose was given in vivo, no change in percent of synthase in the I form was seen in adrenalectomized rats but the percent of phosphorylase in the a form was reduced. Precipitation of protein from an extract of normal fed rats with ethanol produced a large activation of phosphorylase phosphatase activity with no corresponding increase in synthase phosphatase activity. Despite the low phosphorylase phosphatase present in extracts of adrenalectomized fasted animals, ethanol precipitation increased activity to the same high level as obtained in the normal fed rats. Synthase phosphatase and phosphorylase phosphatase activities were also decreased in normal fasted, diabetic fed and fasted, and adrenalectomized fed rats. Both enzymes recovered in the same manner temporally after oral glucose administration to adrenalectomized, fasted rats. These results suggest an integrated regulatory mechanism for the two phosphatase.     

Effect of prostaglandin E1 administration on the heart glycogen synthase and phosphorylase systems

The effects of intravenous administration of PGE₁ on the glycogen synthase and phosphorylase system in rat heart were studied.Unlike the consistent effects of PGE₁ on glycogen synthase in liver, the response in heart was variable. A significant decrease in the per cent synthase occurred in fasted intact rats while a significant increase was seen in adrenalectomized hydrocortisone treated fasted rats. No significant effect was seen on the synthase system in either fed intact or fasted adrenalectomized rats.Phosphorylase activity was increased significantly following PGE₁ administration in fed intact rats and slightly increased in adrenalectomized fasted rats. The phosphorylase system was not affected in fasted intact and fasted adrenalectomized rats given glucocorticoid replacement. With our present state of knowledge an adequate explanation for the response of these heart enzymes to PGE₁ under the various conditions of this study does not appear possible.     

Lack of effect of somatostatin on the stimulation of hepatic glycogenolysis by epinephrine in isolated canine hepatocytes

The effects of somatostatin on epinephrine's ability to stimulate glucose output have been examined in hepatocytes isolated from dogs fasted overnight. Half-maximal stimulation of phosphorylase a activity and glucose output occurred at an epinephrine concentration of approx. 5 X 10(-9) M. Somatostatin at 10, 100 or 1000 ng/ml had no effect on the ability of a maximal (1 X 10(-7) M) and a submaximal (1 X 10(-8) M) dose of epinephrine to activate phosphorylase at 2 min, or to stimulate glucose output over 20 min. Since the doses of somatostatin used in the present study are up to 50-fold higher than the blood concentrations commonly found when somatostatin is used in vivo to inhibit pancreatic hormone secretion, it seems unlikely that use of somatostatin in this way would affect stimulation of hepatic glycogenolysis by epinephrine in vivo.     

Hepatic glycogen breakdown is implicated in the maintenance of plasma mannose concentration

D-mannose is an essential monosaccharide constituent of glycoproteins and glycolipids. However, it is unknown how plasma mannose is supplied. The aim of this study was to explore the source of plasma mannose. Oral administration of glucose resulted in a significant decrease of plasma mannose concentration after 20 min in fasted normal rats. However, in fasted type 2 diabetes model rats, plasma mannose concentrations that were higher compared with normal rats did not change after the administration of glucose. When insulin was administered intravenously to fed rats, it took longer for plasma mannose concentrations to decrease significantly in diabetic rats than in normal rats (20 and 5 min, respectively). Intravenous administration of epinephrine to fed normal rats increased the plasma mannose concentration, but this effect was negated by fasting or by administration of a glycogen phosphorylase inhibitor. Epinephrine increased mannose output from the perfused liver of fed rats, but this effect was negated in the presence of a glucose-6-phosphatase inhibitor. Epinephrine also increased the hepatic levels of hexose 6-phosphates, including mannose 6-phosphate. When either lactate alone or lactate plus alanine were administered as gluconeogenic substrates to fasted rats, the concentration of plasma mannose did not increase. When lactate was used to perfuse the liver of fasted rats, a decrease, rather than an increase, in mannose output was observed. These findings indicate that hepatic glycogen is a source of plasma mannose.     

Regulation of glycogenolysis in human muscle in response to epinephrine infusion

The regulation of glycogenolysis in human muscle during epinephrine infusion has been investigated. The content of cAMP in resting muscle was 2.7 +/- 0.7 (SD) mumol . kg dry muscle-1 and increased threefold during the first 5 min of infusion. Total glycogen phosphorylase and glycogen synthase activities were unchanged during the infusion. The proportion of phosphorylase in the a form in the basal state was estimated to be at least 22.5% and during infusion 80-90%. During infusion, synthase I activity decreased. The muscle glycogen content was 340 mmol . kg dry wt-1 and decreased during the first 2 min of infusion at a rate of 11.0 mmol glycosyl units . kg dry wt-1 . min-1. Prolonged infusion resulted in a much lower glycogenolytic rate, even though most of the phosphorylase was still in the a form. Accumulation of hexose monophosphates and lactate followed the changes in glycogen. It was concluded that despite the almost total transformation of phosphorylase to the a form, the in vivo activity was maintained at a low level. It is suggested that this may be due to a low concentration of inorganic phosphate at the active site of the enzyme.     

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. Continous 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′-monphosphate (cylic 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.     

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.     

Tissue glucose utilization during epinephrine-induced hyperglycemia

The aim of this study was to investigate glucose utilization by individual tissues during epinephrine infusion. First, the applicability of the 2-deoxyglucose (2-DG) tracer technique during in vivo hyperglycemia was investigated in model systems in vitro. Epitrochlearis muscle and spleen cells were incubated with 1.25-20 mM glucose. The discrimination against 2-[14C]DG in glucose metabolic pathways, expressed by the lumped constant, remained unchanged over this wide range of glucose concentrations. It was concluded that in vivo hyperglycemia does not preclude the application of the 2-DG method. In a series of in vivo experiments, chronically catheterized conscious rats fasted for 24 h and were infused with epinephrine (0.2 microgram.kg-1.min-1), which produced a two-fold increase in plasma glucose concentration. 2-[14C]DG was injected 30 min after starting the epinephrine infusion and glucose utilization rates of individual tissues were calculated based on the concentration of phosphorylated 2-DG in samples excised at 70 min. The epinephrine infusion increased glucose utilization rates by 40-160% in hindlimb muscles, skin, ileum, liver, spleen, lung, epididymal fat, and kidney, although no change was found in the brain. Mass action of the increased plasma glucose is likely to play an important role in the enhanced rate of glucose utilization.     

Effect of acetylcholine on glycogen phosphorylase activity and cyclic nucleotide content in isolated perfused rat hearts.

Acetylcholine (1muM) increased cyclid GMP content in paced perfused rat hearts within 15 sec., with peak content occurring at 1 min. No effect of acetylcholine on cyclic AMP content, phosphorylase activity or glycogen synthase was observed. Epinephrine (1muM) infusion increased both cyclic AMP content and phosphorylase, but did not alter cyclic GMP content or glycogen synthase activity. When acetylcholine was infused during the second min. of a 2 min. infusion of epinephrine, the cholinergic agent increased cyclic GMP and reduced the stimulated phosphorylase activity and elevated cyclic AMP.     

Regulation of glycogen synthase activity in the isolated mouse soleus muscle effect of insulin,epinephrine, glucose and anti-insulin receptor antibodies

The effects of insulin, epinephrine, glucose and anti-insulin receptor antibodies on enzymes involved in the regulation of glycogen synthesis were investigared in the isolated mouse soleus muscle. Insulin maximally increased the percentage of glycogen synthase active form after 15 min in the absence of glucose in the extracellular medium; half-maximal and maximal effects were obtained with 1.5 and 33 nM insulin, respectively. The basal percentage of glycogen phosphorylase active form was not altered by insulin. Antibodies to the insulin receptor had similar effects to those of insulin on both enzymes. The percentage of glycogen synthase active form was maximally decreased and that of phosphorylase maximally increased after a 2 min exposure to epinephrine in the absence of extracellular glucose. Glucose alone had no effect on muscle glycogen synthase. When muscles were incubated with insulin (33 nM) plus glucose (20 mM) for 5–10 min, the increase in the percentage of glycogen synthase active form was greater than with insulin alone. This enhancing effect of glucose on insulin activation of glycogen synthase disappeared after 20 min. The results suggest the existence of two mechanisms whereby insulin activates muscle glycogen synthase. The main effect is operative in the absence of extracellular glucose and occurs at insulin concentrations close to the physiological range. The other effect requires glucose and may result from the stimulation by insulin of glucose transport and/or metabolism.     

Regulation of glycogen synthase activity in the isolated mouse soleus muscle. Effect of insulin, epinephrine, glucose and anti-insulin receptor antibodies

The effects of insulin, epinephrine, glucose and anti-insulin receptor antibodies on enzymes involved in the regulation of glycogen synthesis were investigated in the isolated mouse soleus muscle. Insulin maximally increased the percentage of glycogen synthase active form after 15 min in the absence of glucose in the extracellular medium; half-maximal and maximal effects were obtained with 1.5 and 33 mM insulin, respectively. The basal percentage of glycogen phosphorylase active form was not altered by insulin. Antibodies to the insulin receptor had similar effects to those of insulin on both enzymes. The percentage of glycogen synthase active form was maximally decreased and that of phosphorylase maximally increased after a 2 min exposure to epinephrine in the absence of extracellular glucose. Glucose alone had no effect on muscle glycogen synthase. When muscles were incubated with insulin (33 nM) plus glucose (20 mM) for 5-10 min, the increase in the percentage of glycogen synthase active form was greater than with insulin alone. This enhancing effect of glucose on insulin activation of glycogen synthase disappeared after 20 min. The results suggest the existence of two mechanisms whereby insulin activates muscle glycogen synthase. The main effect is operative in the absence of extracellular glucose and occurs at insulin concentrations close to the physiological range. The other effect requires glucose and may result from the stimulation by insulin of glucose transport and/or metabolism.     

Insulin stimulation of heart glycogen synthase D phosphatase (protein phosphatase).

Insulin rapidly produced an increase in per cent of total heart glycogen synthase in the I form in fed rats. In fasted rats the response was diminished and delayed. In diabetic animals there was no response over the 15-min time period studied. Since synthase phosphatase activity is necessary for synthase D to I conversion, the phosphatase activity was determined in extracts from these groups of animals. In the fasted and diabetic rats phosphatase activity was less than one-half of that in fed animals. Administration of insulin to fasting animals increased synthase phosphatase activity to a level approaching that of fed animals by 15 min. In diabetic animals insulin also stimulated an increase in synthase phosphatase activity but 30 min were required for full activation. Insulin had no effect in normal fed animals. Insulin activation of synthase phosphatase activity in heart extracts from fasted animals was still present after Sephadex G-25 chromatography and ammonium sulfate precipitation. Thus insulin had induced a stable modification of the phosphatase itself or of its substrate synthase D rendering the latter a more favorable substrate for the reaction. A difference in sensitivity of the reaction to glycogen inhibition was present between fed and fasted animals. Increasing concentrations of glycogen had only a slight inhibitory effect in extracts from fed animals but considerably reduced activity in extracts from fasted animals. Insulin administration reduced the sensitivity of the phosphatase reaction to glycogen inhibition. This could explain, at least in part, the increased phosphatase activity noted in the insulin-treated, fasted rats since glycogen was routinely added to the homogenizing buffer.     

The effect of ischemia on glycogen phosphorylase activity in rat liver: a quantitative histochemical study

The effects of ischemia in vitro for 0-60 min at 37 degrees C on glycogen phosphorylase activity in rat liver have been studied under different feeding conditions. Glycogen phosphorylase activity was demonstrated with a recently developed quantitative histochemical method using a semipermeable membrane and the PAS-reaction. The cytophotometrically measured glycogen phosphorylase activity in livers from 24 h-fasted rats was approximately five times the activity in livers from normally fed rats. The activity in periportal areas was about 1.5 times higher than the activity in pericentral areas in livers from starved rats, but more or less evenly distributed in livers from fed rats. Enzyme activity in pericentral areas of livers from 24 h-fasted rats started to decrease after 20 min of ischemia. After 50-60 min of ischemia, the activity was decreased to approximately 25% of the control activity. Livers from normally fed rats showed unchanged activity in periportal and pericentral areas after 10-60 min of ischemia. It has been assumed that the activation of the enzyme was disturbed by ischemia, possibly as a consequence of plasma membrane damage.     

Liver glycogen metabolism during short-term insulin-induced hypoglycemia in fed rats

The activities of glycogen phosphorylase and synthase during infusions of glucagon, isoproterenol, or cyanide in isolated liver of fed rats submitted to short-term insulin-induced hypoglycemia (IIH) was investigated. A condition of hyperinsulinemia/hypoglycemia was obtained with an intraperitoneal injection of regular insulin (1.0 U kg(-1)). The control group received ip saline. The experiments were carried out 60 min after insulin (IIH group) or saline (COG group) injection. The rats were anesthetized and after laparotomy, blood was collected from the vena cava for glucose and insulin measurements. The liver was then infused with glucagon (1 nM), isoproterenol (2 microM), or cyanide (0.5 mM) during 20 min and a sample of the organ was collected for determination of the activities of glycogen phosphorylase and synthase 5 min after starting and 10 min after stopping the infusions. The infusions of cyanide, glucagons, and isoproterenol did not change the activities of glycogen synthase and glycogen phosphorylase. However, glycogen catabolism was decreased during the infusions of glucagon and isoproterenol in IIH rats, being more intense with isoproterenol (p < 0.05), than glucagon. It was concluded that short-term IIH promoted changes in the liver responsiveness of glycogen degradation induced by glucagon and isoproterenol without a change in the activities of glycogen phosphorylase and synthase.     

Effect of sodium fluoride on cyclic AMP production in rat hepatocytes.

The effect of NaF on cAMP production was studied in hepatocytes isolated from fed and fasted rats. A four-six fold increase in hepatocyte cAMP production was observed in the presence of 10-20 mM NaF in cells isolated from either fed or fasted rats. The maximal stimulation of cAMP production was observed after a 10 min incubation in the presence of 1 mM theophylline. However, as little as 0.05-0.15 mM NaF induced a significant increase in cAMP production. It was also found that NaF would alter the production of glucose in isolated rat hepatocytes. When hepatocytes from fed rats were incubated with 0.05-5 mM NaF there was an increase in amount of glucose released from endogenous sources. Also NaF resulted in a decrease in lactate and pyruvate production. Similarly NaF stimulated glucose production in hepatocytes from fasted rats. The maximal stimulation was observed with about 0.15-0.25 mM NaF. At NaF concentrations greater than 1.5 mM a decrease in glucose production was observed. It is concluded that NaF increases the level of cAMP and alters glucose metabolism in intact hepatocytes.