Insulin signaling in the yeast Saccharomyces cerevisiae. 1. Stimulation of glucose metabolism and Snf1 kinase by human insulin

Effects of human insulin on glucose metabolism in the yeast Saccharomyces cerevisiae were studied in this report. Under two conditions of growth limitation (glucose-grown cells during transition to stationary phase or spheroplasts during incubation in synthetic glucose medium), human insulin (10 and 1 microM, respectively) enhanced glycogen accumulation and glycogen synthase activity by 40-60% compared to control cells. Glycogen phosphorylase activity was also increased under the same conditions, but this stimulation was diminished by 35-45% in insulin-treated compared to control cells. Thus, under growth limitation, insulin causes glycogen phosphorylase and glycogen synthase to become more sensitive to inactivation and activation, respectively. In glucose-induced spheroplasts, insulin (1 microM), in addition to glycogen accumulation, led to about 2-fold increases of the rates of ethanol production and glucose oxidation compared to control cells, and the maximal concentration of hexose 6-phosphate was increased by 30-40%. In contrast, glucose transport as well as the levels of the allosteric regulators, fructose 2,6-bisphosphate and cAMP, were not altered at all. Snf1 kinase is assumed to be involved in the regulation of glycogen metabolism in yeast, although it does not seem to be modulated directly by the glucose concentration. Snf1 kinase activity was elevated 5-10-fold in response to insulin both during glucose induction of yeast spheroplasts and during transition to stationary phase of glucose-grown cells. We conclude that Saccharomyces cerevisiae and insulin-sensitive mammalian cells share some parts of the signaling cascades regulating oxidative and nonoxidative glucose metabolism in response to glucose and insulin.     

Protective effect of fructose 1,6-bisphosphate against carrageenan-induced inflammation

Administration of carrageenan (0.5 mg) to the plantar tissue of rats resulted in reversible inflammatory injury. This damage was monitored as changes in foot volume, using a plethysmometer. Administration of fructose 1,6-bisphosphate at different doses, orally or intraperitoneally, prevented the inflammatory action induced by the simultaneous injection of carrageenan in the rat paw. The effect was dose and time dependent. In contrast, fructose or fructose 6-phosphate afforded no significant protection. In order to extend the average half-life of the drug, we prepared liposomes of fructose 1,6-bisphosphate which, administered orally or intraperitoneally, showed a greater and more prolonged antiinflammatory action. The significance of these findings with respect to the mechanism of the antiinflammatory action of fructose 1,6-bisphosphate is discussed.     

Triosephosphate metabolism by mature boar spermatozoa

Boar sperm rapidly interconverted dihydroxyacetone phosphate and glyceraldehyde 3-phosphate, produced fructose-1,6-bisphosphate, approximately equilibrium concentrations of fructose 6-phosphate and glucose 6-phosphate but not glycerol or glycerol 3-phosphate. In the presence of 3-chloro-1-hydroxypropanone, an inhibitor of stage 2 of the glycolytic pathway, the triosephosphates were metabolized faster, produced less fructose-1,6-bisphosphate, fructose 6-phosphate and glucose 6-phosphate, but not glycerol or glycerol 3-phosphate. This suggests that these cells may have the capacity to convert glycolytic intermediates into a storage metabolite to conserve carbon atoms for the eventual synthesis of lactate.     

Postmaturity in the rat: glucose metabolism in the fetus and the neonate

The present study was designed to investigate glucose metabolism in the postmature fetus and newborn. In the fetus, the decreased hepatic glycogen content together with the decrease by the same percentage of total hepatic glycogen radioactivity from directly injected [6-3H]glucose demonstrate that fetal glycogenolysis occurs during prolonged gestation. Moreover, fetal glycogen synthesis as tested by in vivo [6-3H]glucose incorporation experiments is inhibited. In vivo experiments with [14C]lactate are consistent with gluconeogenesis, being inactive in the postmature fetus as well as in the normal-term fetus. During the first hr after delivery, our in vivo data about conversion of [14C]lactate to glucose show that the gluconeogenic pathway is not functioning in spite of very high phosphoenolpyruvate carboxykinase activity in the postmature. By 3 hr postpartum, the phosphoenolpyruvate carboxykinase activity, the blood lactate level, the percentage of conversion, and the rate of gluconeogenesis are very elevated in the postmatures as compared to the term neonates. By 6 hr postpartum, despite maintained phosphoenolpyruvate carboxykinase activity, gluconeogenic rate becomes very weak in postmatures kept fasting. This is the time characterized by a profound hypoglycemia. In contrast, fed postmature neonates exhibit normal blood glucose levels by 6 and 12 hr postpartum as a result of sustained rate of gluconeogenesis.     

Glycogen turnover in skeletal muscle is stimulated along with glucose uptake in vivo during contraction

We have shown previously that glycogen synthesis in the heart can be stimulated in vivo by epinephrine. Our aim in this study was to determine whether glycogen synthesis in skeletal muscle can be similarly affected during increased energy expenditure. Left sciatic nerves of anesthetized fasted rats were electrically stimulated to allow left hindlimb muscles to contract for 5, 10, and 20 min. Glycogen contents in the contracting muscles at the end of electrical stimulation were found to be approximately 40% less than resting muscles in the right hindlimbs in all three groups of rats. Accompanying the enhanced glycogenolysis was increased incorporation of the intravenously infused [3-(3)H]-glucose into glycogen. The rate of tritium incorporation into glycogen in the contracting muscle was found to be 34-fold greater than resting muscles. Glucose utilization was determined by the phosphorylation of the intravenously injected [14C]-2-deoxyglucose in the skeletal muscle. The rate of accumulation of [14C]-2-deoxyglucose-6-phosphate in the contracting muscles was found to be 28-fold greater than resting muscles. Glycogen synthesis and glucose uptake indexes, calculated by dividing the radioactivity in [3H]-glycogen and [14C]-2-DGP by the mean specific activity of their respective precursors in the plasma, were not found to be significantly different in the contracting muscle. In conclusion, our data indicate that: (i) glycogenesis and glycogenolysis can be stimulated concurrently in the skeletal muscle; and (ii) glucose utilization in the skeletal muscle during contraction may be mediated through glycogen turnover.     

The development of pre- and post-natal veins

There is little information on the metabolic response to ingested fructose in patients with cirrhosis. Glucose kinetics, plasma lipid and blood lactate levels, whole body substrate oxidation rates and energy expenditure were measured following ingestion of 75 g fructose, in 8 cirrhotic patients and 6 controls. Fasting plasma glucose levels and rates of glucose appearance (Ra) and disappearance (Rd) were similar. The basal rate of lipolysis was higher in cirrhotic patients (P < 0.05), but whole body lipid and carbohydrate oxidation rates and energy expenditure were similar. After fructose ingestion, plasma fructose levels were much higher in cirrhotic patients (P < 0.001) and the incremental area under the plasma glucose curve was twice that of controls (P < 0.05). The increase in glucose in patients with cirrhosis was due to an increase in glucose Ra and an initial reduction in glucose Rd. Plasma non-esterified fatty acid levels fell to similar low levels in both groups. Glycerol levels fell in controls (P < 0.05) but not in cirrhotic patients. Blood lactate levels, fasting and after oral fructose, were similar in cirrhotics and controls. The time course of suppression of lipid oxidation and stimulation of carbohydrate oxidation was more closely related to fructose levels than to serum fatty acid levels in both groups. The percent suppression and total quantity of lipid oxidized in 4 h after fructose were not significantly different, but the suppressed lipid oxidation rates and elevated carbohydrate oxidation rates were sustained for longer in the cirrhotics. The data suggest that fructose uptake and metabolism inhibits oxidation of intracellular lipid. There was a smaller increase in energy expenditure after fructose in cirrhotics (P < 0.001), but normal overall storage of fructose; the likely explanation is reduced first pass hepatic fructose uptake in cirrhotics making more fructose available to the periphery for incorporation into muscle glycogen. The energy cost of storing fructose as muscle glycogen is less than that of storing it as liver glycogen. Preferential incorporation of fructose carbon into muscle glycogen, with lower rates of hepatic glycogen and triglyceride synthesis, would therefore result in less energy expenditure after a fructose load in cirrhotics.     

Significant amounts of glycogen are synthesized from 3-carbon compounds in astroglial primary cultures from mice with participation of the mitochondrial phosphoenolpyruvate carboxykinase isoenzyme

The incorporation was studied of the gluconeogenic substrates lactate, alanine, aspartate and glutamate into glycogen of astroglial primary cultures derived from mouse brain. The incorporation was inhibited by 3-mercaptopicolinate, an inhibitor of one of the characteristic gluconeogenic enzymes, phosphoenolpyruvate carboxykinase. Only the mitochondrial isoenzyme of phosphoenolpyruvate carboxykinase was detectable in the astroglial primary cultures. After the incubation of glucose-starved cells with medium containing a mixture of [6-3H]glucose and [U-14C]glucose, the newly synthesized glycogen showed a 3H/14C ratio which was approximately 15% less than the isotope ratio for the medium. The decrease of the isotope ratio was not significantly inhibited by 3-mercaptopicolinate, indicating a cycling of approximately 15% of the glucose to the level of the triose phosphates before its incorporation into astroglial glycogen. During the initial phase of glycogen resynthesis, the contribution of the gluconeogenic substrates appeared to be higher. This was in agreement with the accumulation of fructose 2,6-bisphosphate during refeeding. A participation of gluconeogenic substrates in glycogen metabolism was also detectable when the glycogen content was not changing significantly.     

Rat liver messenger ribonucleic acid and enzyme activity of 6-phosphofructo 2-kinase/fructose 2,6-bisphosphatase impairment during the late period of pregnancy

Fructose 2,6-bisphosphate concentration, 6-phosphofructo 2-kinase/fructose 2,6-bisphosphatase (PFK-2/FBPase2) activity, and messenger RNA decreased in maternal rat liver during the last days of gestation, and the recovery started after delivery. Phospho(enol)pyruvate carboxykinase activity and messenger RNA increased in contrast to PFK-2 changes. Measurement of the glycolytic capacity in isolated hepatocytes prepared from rats 1 h after parturition showed a low glucose consumption and an impaired capacity to metabolize glucose. These results stress the relevance of the PFK-2/fructose 2,6-bisphosphate system in the control of the glycolytic flux in liver, and these changes are intended to prevent glucose consumption by maternal liver and contribute to allow gluconeogenesis to proceed at the end of gestation. The physiological basis of this adaptation may lay on the diversion of glucose from maternal to fetal metabolism.     

Glucose turnover in the post-absorptive rat and the effects of halothane anaesthesia

1. Rates and rate coefficients of glucose utilization and replacement in post-absorptive rats, either conscious or under halothane anaesthesia, were determined in a thermoneutral environment by using [5-3H]- and [U-14C]glucose. Label was not injected into rats under halothane until about 0.5h after anaesthesia was initiated. 2. Comparison with the results for 24h-starved rats in the preceding paper [Heath et al. (1977) Biochem. J. 162, 643-651] showed that insulin concentrations were considerably higher but rate coefficients for glucose utilization were little altered in post-absorptive rats. Sensitivity to insulin was thus considerably increased by a 24h period of starvation in the rat. 3. Fractional recycling of glucose carbon in post-absorptive rats was under one-half of that in starved rats, reflecting the larger contribution of liver glycogenolysis to glucose production in the former. 4. In post-absorptive rats halothane decreased the mean rate of glucose utilization by about 17%. This decrease was associated with an increase in mean plasma insulin concentration, showing that halothane decreased sensitivity to insulin. 5. Recycling was slightly increased by halothane, indicating that the contribution of liver glycogen to the total glucogenic rate was decreased, probably because liver glycogen concentration were about 40% lower throughout the rate determinations in halothane. 6. Comparison of our results with earlier work shows that during and shortly after induction of halothane anaesthesia glucose turnover must have been greatly increased whereas from about 0.5h after induction it was decreased.     

The contribution of "cure by dapsone monotherapy'' to the reduction of prevalence of leprosy in the State of Orissa, India, 1983-1993

The activity of phosphofructokinase-2, fructose, 1,6-bisphosphatase, glucokinase, and also the level of fructose 2,6-bisphosphate and glycogen were examined in the liver of normal, and streptozotocin-diabetic rats. It was shown that the activity of phosphofructokinase-2 was decreased in the liver of diabetic rats. Besides that the activity determined at pH 6.6 (the "active" or unphosphorylated enzyme form) was 3-fold reduced whereas the "total" enzyme activity as measured at pH 8.5 was lowered 1,7-fold. The phosphofructokinase-2 activity assay at two pH values allows to estimate a degree of phosphorylation of bifunctional enzyme which is markedly enhanced in diabetes. The fall of the bifunctional enzyme k in case activity is accompanied by the lowered fructose 2.6-bisphosphate level, increased fructose 1,6-bisphosphatase activity that in turn favours the liver tissue glycolysis inhibition and gluconeogenesis enhanced in diabetes.     

The Arg-Gly-Asp motif in the cell adhesion molecule L1 promotes neurite outgrowth via interaction with the alphavbeta3 integrin

This review focuses on the mechanisms of control of heart glycolysis under conditions of normal and reduced oxygen supply. The kinetic properties and the biochemical characteristics of control steps (glucose transporters, hexokinase, glycogen phosphorylase and phosphofructokinases) in the heart are reviewed in the light of recent findings and are considered together to explain the control of glycolysis by substrate supply and availability, energy demand, oxygen deprivation and hormones. The role of fructose 2,6-bisphosphate in the control of glycolysis is analysed in detail. This regulator participates in the stimulation of heart glycolysis in response to glucose, workload, insulin and adrenaline, and it decreases the glycolytic flux when alternative fuels are oxidized. Fructose 2,6-bisphosphate integrates information from various metabolic and signalling pathways and acts as a glycolytic signal. Moreover, a hierarchy in the control of glycolysis occurs and is evidenced in the presence of adrenaline or cyclic AMP, which relieve the inhibition of glycolysis by alternative fuels and stimulate fatty acid oxidation. Insulin and glucose also stimulate glycolysis, but inhibit fatty acid oxidation. The mechanisms of control underlying this fuel selection are discussed. Finally, the study of the metabolic adaptation of glucose metabolism to oxygen deprivation revealed the implication of nitric oxide and cyclic GMP in the control of heart glucose metabolism.     

The effects of insulin on transport and metabolism of glucose in skeletal muscle from hyperthyroid and hypothyroid rats

The effects of insulin on the rates of glucose disposal were studied in soleus muscles isolated from hyper- or hypothyroid rats. Treatment with triiodothyronine for 5 or 10 days decreased the sensitivity of glycogen synthesis but increased the sensitivity of lactate formation to insulin. The sensitivity of 3-O methylglucose to insulin was increased only after 10 days of treatment and was accompanied by an increase in the sensitivity of 2-deoxyglucose phosphorylation; however, 2-deoxyglucose and glucose 6-phosphate in response to insulin remained unaltered. In hypothyroidism, insulin-stimulated rates of 3-O-methylglucose transport and 2-deoxyglucose phosphorylation were decreased; however, at basal levels of insulin, 3-O-methylglucose transport was increased, while 2-deoxyglucose phosphorylation was normal. In these muscles, the sensitivity of lactate formation to insulin was decreased; this defect was improved after incubation of the muscles with prostaglandin E2. The results suggest: (a) in hyperthyroidism, insulin-stimulated rates of glucose utilization in muscle to form lactate are increased mainly because of a decrease in glycogen synthesis; when hyperthyroidism progresses in severity, increases in the sensitivity of glucose transport to insulin and in the activity of hexokinase may also be involved; (b) in hypothyroidism, the decrease in insulin-stimulated rates of glucose utilization is caused by decreased rates of glycolysis; (c) prostaglandins may be involved in the changes in sensitivity of glucose utilization to insulin observed in muscle in altered thyroid states.     

Fasting does not impair insulin-stimulated glucose uptake but alters intracellular glucose metabolism in conscious rats

Effects of 24-h and 48-h fasting on maximal insulin-stimulated whole-body and muscle glucose uptake, glycogen synthesis, and glycolysis were studied in conscious rats by combining the glucose clamp technique with tracer methods. Fasting decreased body weight and basal plasma glucose, plasma insulin, hepatic glucose output, and glucose clearance (P < 0.05 for all). However, maximal insulin-stimulated whole-body glucose uptake, normalized to body weight, was almost identical in fed, 24-h fasted, and 48-h fasted rats (191 +/- 8, 185 +/- 14, and 182 +/- 5 mumol.kg-1.min-1, respectively; P > 0.7). Similarly, rates of insulin-stimulated glucose uptake by four different skeletal muscles, estimated by the 2-deoxyglucose injection technique, were not different among the three groups. In contrast to glucose uptake, insulin-stimulated whole-body glycolysis was decreased significantly after fasting (36% after 48 h fasting; P < 0.05), whereas insulin-stimulated whole-body glycogen synthesis was increased (44% after 48 h fasting; P < 0.05). In fed rats, glycolysis was the major pathway for glucose metabolism during hyperinsulinemia, accounting for 60 +/- 5% of glucose uptake. This fraction was decreased significantly by fasting (P < 0.01), so that after a 48-h fast, glycolysis accounted for only 40 +/- 3% of insulin-stimulated glucose uptake and glycogen synthesis became predominant pathway, accounting for 60 +/- 3% of whole-body glucose utilization. Whole-body patterns of glucose metabolism during hyperinsulinemia were paralleled by glucose metabolism in individual muscles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human muscle glycogen metabolism during exercise. Effect of carbohydrate supplementation

Carbohydrate (CHO) ingestion during exercise, in the form of CHO-electrolyte beverages, leads to performance benefits during prolonged submaximal and variable intensity exercise. However, the mechanism underlying this ergogenic effect is less clear. Euglycaemia and oxidation of blood glucose at high rates late in exercise and a decreased rate of muscle glycogen utilisation (i.e. glycogen 'sparing') have been proposed as possible mechanisms underlying the ergogenic effect of CHO ingestion. The prevalence of one or the other mechanism depends on factors such as the type and intensity of exercise, amount, type and timing of CHO ingestion, and pre-exercise nutritional and training status of study participants. The type and intensity of exercise and the effect of these on blood glucose, plasma insulin and catecholamine levels, may play a major role in determining the rate of muscle glycogen utilisation when CHO is ingested during exercise. The ingestion of CHO (except fructose) at a rate of > 45 g/h, accompanied by a significant increase in plasma insulin levels, could lead to decreased muscle glycogen utilisation (particularly in type I fibres) during exercise. Endurance training and alterations in pre-exercise muscle glycogen levels do not seem to affect exogenous glucose oxidation during submaximal exercise. Thus, at least during low intensity or intermittent exercise, CHO ingestion could result in reduced muscle glycogen utilisation in well trained individuals with high resting muscle glycogen levels. Further research needs to concentrate on factors that regulate glucose uptake and energy metabolism in different types of muscle fibres during exercise with and without CHO ingestion.     

Dextran strongly increases the Michaelis constants of oxidative phosphorylation and of mitochondrial creatine kinase in heart mitochondria

A minimal model of glycogen metabolism in muscle tissue is analyzed in accordance with metabolic control analysis. The model contains two branch points. Rather than contributing to complexity of the analysis, this branching allows expression of the control coefficients in a simplified form. Glucose 6-phosphate is the metabolite at the first branch point, and the analysis is simplified further by the fact that glucose 6-phosphate is the substrate for enzymes which catalyze near-equilibrium reactions. Control of the concentration of glucose 6-phosphate is of interest because of its pivotal location in the metabolic system, but also because it interacts with an allosteric site on glycogen synthase to stimulate glycogen synthase activity. It is shown that the control which the transporter and enzymes involved in glycogen synthesis exert on glycolytic flux is proportional to the control which these components exert on glucose 6-phosphate concentration. Thus, glycolysis plays a major role in control of glucose 6-phosphate concentration. It is concluded that control of glycogen synthesis is not a rigid parameter of any component of this metabolic system. Rather the distribution of control is flexible and shifts from one portion of the system to another in response to shifts in the physiological state. An important element in determining the distribution of control of glycogen synthesis is the change in the sensitivity of the allosteric site of glycogen synthase to glucose 6-phosphate which is brought about by conversion of glycogen synthase to the dephosphorylated, glucose 6-phosphate-independent, state.     

Non-insulin and non-exercise related increase of glucose utilization in rats and mice

The effects of high-energy phosphate contents in muscles on glucose tolerance and glucose uptake into tissues were studied in rats and mice. Enhanced glucose tolerance associated with depleted high-energy phosphates and elevated glycogen content in muscles and liver was observed in animals fed creatine analogue beta-guanidinopropionic acid (beta-GPA). Distribution of infused 2-[1-14C]deoxy-D-glucose in tissues especially in the soleus muscle, kidney, and brain was greater in mice fed beta-GPA than controls. The glucose uptake was decreased when the contents of ATP and glycogen were normalized following creatine supplementation. Plasma insulin in animals at rest was lower and its concentration after intraperitoneal glucose infusion tended to be less in animals fed beta-GPA than controls (p > 0.05), although the pattern of insulin response to glucose loading was similar to the control. The daily voluntary activity in beta-GPA fed mice was also less than controls. These results suggest that improved glucose tolerance is not related to elevated insulin concentration and/or decreased glycogen following exercise. Such improvement may be due to an increased mitochondrial energy metabolism caused by depletion of high-energy phosphates.     

Long-term effects of perindopril on metabolic parameters and the heart in the spontaneously hypertensive/NIH-corpulent rat with non-insulin-dependent diabetes mellitus and hypertension

The spontaneously hypertensive/NIH-corpulent (SHR/N-cp) rat is a genetic model that exhibits both non-insulin-dependent diabetes mellitus (NIDDM) and hypertension. To determine the impact of long-term treatment with the long-acting angiotensin-converting enzyme (ACE) inhibitor perindopril (PE) on the glucose metabolism, lipid levels, and heart in this model, studies were performed in three groups of SHR/N-cp rats maintained on a diet containing 54% carbohydrate with 18% sucrose and 36% starch. One group of obese rats received PE (0.5 to 1.0 mg/kg body weight/d) for 3 to 4 months, a second group of obese rats received no treatment, and a third group of lean rats were used as controls. The mean systolic blood pressure (SBP) increased gradually in both untreated obese and lean rats, with lean animals showing slightly higher levels compared with untreated obese rats. By contrast, SBP was reduced to normal levels in PE-treated obese rats throughout the treatment period. Compared with lean rats, obese rats showed significantly higher body weight and fasting serum levels of glucose, insulin, total cholesterol (TC), and triglyceride (TG). However, no significant differences were observed in these metabolic parameters between PE-treated and untreated obese rats. Plasma renin activity measured at the end of the treatment period was significantly higher in PE-treated rats compared with untreated obese and untreated lean rats. The mean heart weight and left ventricular weight, expressed in absolute terms or indexed to body weight, were significantly lower in PE-treated versus untreated obese and untreated lean rats. To further determine whether glucose metabolism is directly affected by PE treatment, in vitro glycogen synthesis was evaluated in isolated soleus muscles obtained from three additional groups of animals. The basal rate of muscle glycogen synthesis was significantly lower in obese compared with lean rats (P < .05), but did not differ between PE-treated and untreated obese rats. Maximal insulin-stimulated glycogen synthesis increased threefold in PE-treated obese rats, but this increase did not differ from the increases observed in untreated obese and lean rats. In conclusion, the present study shows that long-term PE treatment in obese SHR/N-cp rats with NIDDM and hypertension effectively controlled systemic arterial pressure and resulted in a significant reduction in left ventricular weight. However, these favorable effects of PE were not associated with significant improvement in glucose tolerance, hyperinsulinemia, and hyperlipidemia in this model. PE also had no direct stimulatory effects on either basal or insulin-mediated glycogen synthesis in the isolated soleus muscle of obese rats, perhaps because of the severe insulin-resistant state of the animals. Our results support the clinical observations that antihypertensive therapy with ACE inhibitors has neutral effects on glucose metabolism and insulin sensitivity in patients with combined hypertension and NIDDM.     

Localization of ATP-gated P2X2 receptor immunoreactivity in the rat hypothalamus

In normoxic conditions, myocardial glucose utilization is inhibited when alternative oxidizable substrates are available. In this work we show that this inhibition is relieved in the presence of cAMP, and we studied the mechanism of this effect. Working rat hearts were perfused with 5.5 mM glucose alone (controls) or together with 5 mM lactate, 5 mM beta-hydroxybutyrate, or 1 mM palmitate. The effects of 0.1 mM chlorophenylthio-cAMP (CPT-cAMP), a cAMP analogue, were studied in each group. Glucose uptake, flux through 6-phosphofructo-1-kinase, and pyruvate dehydrogenase activity were inhibited in hearts perfused with alternative substrates, and addition of CPT-cAMP completely relieved the inhibition. The mechanism by which CPT-cAMP induced a preferential utilization of glucose was related to an increased glucose uptake and glycolysis, and to an activation of phosphorylase, pyruvate dehydrogenase, and 6-phosphofructo-2-kinase, the enzyme responsible for the synthesis of fructose 2,6-bisphosphate, the well-known stimulator of 6-phosphofructo-1-kinase. In vitro phosphorylation of 6-phosphofructo-2-kinase by cAMP-dependent protein kinase increased the Vmax of the enzyme and decreased its sensitivity to the inhibitor citrate. Therefore, in hearts perfused with various oxidizable substrates, cAMP induces a preferential utilization of glucose by a concerted stimulation of glucose transport, glycolysis, glycogen breakdown, and glucose oxidation.     

The role of glucose 6-phosphate in the control of glycogen synthase

Elevated blood glucose concentrations result in increased intracellular levels of glucose 6-phosphate in liver, skeletal muscle, and adipose tissue. In liver, blood glucose concentrations are the main factor in control of the synthesis of glycogen; insulin has only a potentiating effect. In skeletal muscle and adipocytes, glucose alone has little effect on the activity of glycogen synthase, the limiting enzyme in glycogen synthesis. However, insulin released as a result of elevated blood glucose stimulates the translocation of specific glucose transporters to the cell membrane, increases the uptake of glucose, and causes the covalent, dephosphorylation-mediated activation of glycogen synthase. We present evidence that elevated intracellular contents of glucose 6-phosphate provoke the activation of glycogen synthase in liver, muscle, and adipose tissue. In addition, glucose 6-phosphate may inhibit the phosphorylation of glycogen synthase by cyclic AMP-stimulated protein kinase. We show that the stimulated glucose uptake and phosphorylation appear to play a major role in the control by insulin of the enzymes involved in glycogen synthesis.