Effects of prolonged intravenous infusions of adrenaline on glucose utilization, plasma metabolites, hormones and milk production in lactating sheep

Lactating ewes received continuous intravenous infusions of adrenaline (0.05 micrograms/kg liveweight) for 4 days. Prior to, during and after adrenaline infusions, milk yield and composition were monitored. Plasma concentrations of metabolites and hormones were measured each day and glucose biokinetics were measured in non-steady state at the start and end of adrenaline infusions. During adrenaline infusion, milk yield and content of solids-not-fat decreased and milk fat content was reduced on the first day of infusion. Plasma glucose was raised throughout the period of adrenaline infusion, plasma lactate increased over the first 4 h from the start of infusion and plasma non-esterified fatty acids increased for 2 h at the start of infusion and tended to increase during the first 2-3 h after withdrawal of adrenaline. Plasma growth hormone remained relatively stable except for a marked increase at 30 min after withdrawal of adrenaline. At the start and immediately after withdrawal of adrenaline infusion plasma insulin was increased approximately twofold. Glucose production, but not utilization, increased at the start of infusions. Immediately after withdrawal of adrenaline glucose utilization increased 2.5-fold with a smaller response in glucose production. There was essentially no change in glucose clearance during adrenaline infusion but a marked increase occurred after withdrawal of adrenaline.     

Effects of adrenaline on the dynamics of carbohydrate metabolism in rats treated chronically with adrenaline.

Following a subcutaneous injection of adrenaline (300 mug/kg), blood-glucose levels were lower in rats treated chronically with adrenaline (300 mug/kg twice a day for 28 days) than in control rats during at least 2.5 h after the injection. To explain this difference of response, the turnover rate of glucose was measured in control and adrenaline-treated rats during adrenaline infusion (0.75 mug/kg- minus 1 min- minus 1), with [U- minus 14C]glucose as tracer. It was found that the rate of appearance of glucose was greater in the control than in the adrenaline-treated group after a 120-min infusion of adrenaline. The rate of disappearance of glucose in the treated rats increased during the first 60 min of infusion and stayed at this elevated level for a subsequent 2 h, whereas in the control rats, it remained unchanged at the beginning of adrenaline infusion and significantly increased only during the second and third hours of infusion. In addition, the metabolic- clearance rate of glucose was not modified by adrenaline in the treated group, but in the control group, the initial clearance rate was significantly less than in the treated group, and decreased during the first hour of adrenaline infusion even though blood glucose reached values of 244 mg/100 ml. ,rom these data, it is suggested that rats adapt to a chronic exogenous supply of adrenaline by a reduced increase in glucose production in response to adrenaline infusion and a better glucose utilization, which possibly indicates a decrease in the inhibitory effect of adrenaline on insulin secretion.     

Effect of adrenaline on insulin secretion in rats treated chronically with adrenaline.

To determine whether rats could adapt to a chronic exogenous supply of adrenaline by a decrease in the well-known inhibitory effect of adrenaline on insulin secretion, plasma glucose and insulin levels were measured in unanesthetized control and adrenaline-treated rats (300 mug/kg twice a day for 28 days) during an adrenaline infusion (0.75 mug kg-1 min-1), after an acute glucose load (0.5 g/kg), and during the simultaneous administration of both agents. Chronic treatment with adrenaline did not modify the initial glucose levels but it greatly diminished the basal insulin values (21.57+/-2.48 vs. 44.69+/-3.3muU/ml, p less than 0.01). In the control rats, despite the elevated glucose concentrations, a significant drop in plasma insulin levels was observed within the first 15 min of adrenaline infusion, followed by a period of recovery. In the adrenaline-treated group, in which plasma glucose levels were lower than in control animals, plasma insulin levels did not drop as in control rats, but a significant increase was found after 30 min of infusion. During the intravenous glucose tolerance test, the plasma glucose and insulin responses showed similar patterns; however, during the concomitant adrenaline infusion, the treated rats showed a better glucose tolerance than their controls. These results indicate that rats chronically treated with adrenaline adapt to the diabetogenic effect of an infusion of adrenaline by have a lower inhibition of insulin release, although the lower basal insulin levels may indicate a greater sensitivity to endogenous insulin.     

Adrenaline responsiveness of glucose metabolism in insulin-resistant adipose tissue of rats fed a high-fat diet.

The effects of adrenaline (0.5 microM) and the combination of adrenaline and insulin (1.7nM) on [6-14C]glucose metabolism were assessed in epididymal fat-pads from rats fed either a low- or high-fat diet. The response of lipolysis to adrenaline was clearly diminished in fat-fed rats. Insulin added to adrenaline inhibited the lipolysis by 50% regardless of the diet. Glucose utilization in adipose tissue of fat-fed rats was markedly stimulated by adrenaline (glucose uptake was increased 3-fold and the production of CO2 and the glycerol moiety of acylglycerol was increased 4-fold). However, adipose tissue from fat-fed rats was resistant to the effect of insulin to produce a further increase in adrenaline-stimulated glucose uptake. The intracellular capacity of lipogenesis on the one hand, and the production of CO2 and the glycerol moiety of acylglycerol on the other, are of prime importance in the action of insulin and adrenaline on glucose utilization in this model.     

Metabolic interactions of glucose, acetoacetate and adrenaline in rat submaxillary gland in vitro.

1. The metabolic interactions between glucose, acetoacetate and adrenaline were studied in submaxillary-gland slices. 2. Acetoacetate (2.5 mM) inhibited glucose removal by 22% and entry of glucose carbon into the tricarboxylic acid cycle by 54%. 3. Acetoacetate caused an increase in (glucose 6-phosphate) together with an increase in (citrate), a finding that suggests that the phosphofructokinase step might be inhibited by the elevated (citrate). Support for this suggestion was obtained in experiments in which fluoracetate was used to elevate (citrate). 4. A further site of action of acetoacetate at the pyruvate dehydrogenase step was suggested by an increase in the lactate+pyruvate pool, and the finding that pyruvate removal and (3-14C)pyruvate oxidation were inhibited by acetoacetate. 5. Adrenaline, a stimulator of secretion by this tissue, increased glucose removal by 25%. Adrenaline increased glucose removal to the same extent when acetoacetate was also present in the incubation medium. In both cases the increase was accompanied by a fall in (glucose 6-phosphate). 6. Adrenaline also overcame the inhibition of pyruvate removal caused by acetoacetate. 7. The tissue (ATP) decreased by about 50% on addition of adrenaline, and a similar fall was observed in vivo after adrenergic stimulation by isoproterenol. 8. Omission of Ca-2+ from the medium prevented the fall in (glucose 6-phosphate) and (ATP) caused by adrenaline, although adrenaline was still able to stimulate glucose removal. The inhibitory effect of acetoacetate on gluocse removal was reversed by adrenaline, but there was no stimulation above the control rates. Inhibition of pyruvate removal by acetoacetate was not overcome by adrenaline in the absence of Ca-2+. 9. Dibutyryl cyclic AMP had no effect on glucose removal or on (ATP). 10. Possible mechanisms by which adrenaline can bring about its metabolic effects are discussed.     

The effect of glucose, insulin and adrenaline on glycerol metabolism in vitro in rat adipose tissue.

The uptake and utilization of [1-14C]glycerol was determined in pieces of rat epididymal fat-pads incubated in Krebs--Ringer bicarbonate buffer containing albumin. Insulin (200 muunits/ml), adrenaline (epinephrine; 0.5 mug/ml) and glucose (0, 5, 15 and 20 mM) were added to the medium. Changes in the specific radioactivity of the tracer during the incubation were taken into account in calculating the rate of glycerol utilization. Adrenaline decreased glycerol uptake, whereas insulin plus adrenaline increased it. The rate of incorporation of glycerol into glycerides was decreased by adrenaline and insulin, singly or together. Insulin increased the rate of formation of CO2 and fatty acids from glycerol. The formation of CO2 and fatty acids was further enhanced by insulin plus adrenaline. The decrease in glycerol uptake induced by adrenaline, the decrease in incorporation of glycerol into glycerides induced by insulin and insulin plus adrenaline and the synthesis of fatty acids were dependent on the presence of glucose in the medium. Thus insulin and adrenaline act on glycerol utilization in adipose tissue and some of their effects are mediated by action on glucose metabolism, but others are independent of this.     

Differential control of glycogenolysis and flow by arterial and portal acetylcholine in perfused rat liver.

The effects of acetylcholine on glucose and lactate balance and on perfusion flow were studied in isolated rat livers perfused simultaneously via the hepatic artery (100 mmHg, 25-35% of flow) and the portal vein (10 mmHg, 75-65% of flow) with a Krebs-Henseleit bicarbonate buffer containing 5 mM-glucose, 2 mM-lactate and 0.2 mM-pyruvate. Arterial acetylcholine (10 microM sinusoidal concentration) caused an increase in glucose and lactate output and a slight decrease in arterial and portal flow. These effects were accompanied by an output of noradrenaline and adrenaline into the hepatic vein. Portal acetylcholine elicited only minor increases in glucose and lactate output, a slight decrease in portal flow and a small increase in arterial flow, and no noradrenaline and adrenaline release. The metabolic and haemodynamic effects of arterial acetylcholine and the output of noradrenaline and adrenaline were strongly inhibited by the muscarinic antagonist atropine (10 microM). The acetylcholine-dependent alterations of metabolism and the output of noradrenaline were not influenced by the alpha 1-blocker prazosin (5 microM), whereas the output of adrenaline was increased. The acetylcholine-dependent metabolic alterations were not inhibited by the beta 2-antagonist butoxamine (10 microM), although the overflow of noradrenaline was nearly completely blocked and the output of adrenaline was slightly decreased. These results allow the conclusion that arterial, but not portal, acetylcholine caused sympathomimetic metabolic effects, without noradrenaline or adrenaline being involved in signal transduction.     

Progeny of high muscling sires have reduced muscle response to adrenaline in sheep

This study investigated the impact of variation in Australian sheep breeding values (ASBVs) for yearling eye muscle depth (YEMD) within Merino and Poll Dorset sires on intermediary metabolism of progeny. Specifically, the change in the blood concentrations of lactate, non-esterified fatty acids (NEFA) and glucose in response to administration of an exogenous dose of adrenaline was studied. The experiment used 20 Merino and Merino cross Poll Dorset mixed sex sheep. The sires were selected across a range of YEMD ASBVs. The sheep were fitted with indwelling jugular catheters and administered seven levels of adrenaline over a period of 4 days at 4 months of age (0.1, 0.2, 0.4, 0.6, 0.9, 1.2 and 1.6 μg/kg liveweight (LW)) and 16 months of age (0.1, 0.2, 0.6, 1.2, 1.8, 2.4 and 3.0 μg/kg LW). A total of 16 blood samples were collected between -30 min and 130 min relative to administration of the adrenaline challenge and were later measured for the plasma concentrations of lactate, NEFA and glucose. These data were then used to calculate the time to maximum substrate concentration, the maximum concentration and the area under curve (AUC) between 0 and 10 min, thus reflecting the substrate's response to exogenous adrenaline. Selection for muscling led to decreased muscle response due to adrenaline, as indicated by lower maximum concentrations and AUC for lactate. The muscles' response to adrenaline was more prominent at 16 months of age than at 4 months of age. Thus, animals selected for increased muscling have lower levels of glycogenolysis in situations where endogenous adrenaline levels are increased like pre-slaughter. This may minimise the risk of poor meat quality in these animals, as they will express higher muscle concentrations of glycogen at slaughter. Adipose tissue was more sensitive to adrenaline in young lambs from high YEMD sires. This shows that high muscled growing lambs utilise their adipose tissue deposits in times of stress to produce energy. This may explain the phenotypic leanness of these animals. Blood glucose levels that are indicative of liver response to adrenaline decreased with selection for muscling. This response may indicate a potential limiting of glucose that is available within animals selected for muscling, leanness and growth for brain function.     

Hormonal effects on the liver glucose metabolism in rainbow trout (Salmo gairdneri)

1. Glucagon, adrenaline and dibutyril cyclic AMP increased the release of glucose to the medium during incubation of liver slices from rainbow trout (Salmo gairdneri) while insulin had no effect. 2. Glycogen content decreased only slightly after cyclic AMP addition and even increased in the presence of glucagon and adrenaline. Consequently, the release of glucose was due mainly to gluconeogenesis. 3. This is corroborated by the reduction of glucose liberation in presence of alpha-cyanocinnamate, an inhibitor of gluconeogenesis.     

Measurement of concentrations of metabolites in adipose tissue and effects of insulin, alloxan-diabetes and adrenaline

1. Methods are described for the extraction and assay of ATP, ADP, AMP, glucose 6-phosphate, l-glycerol 3-phosphate and citrate in rat epididymal adipose tissue incubated in vitro for 1hr. At this time of incubation rates of glucose uptake and outputs of glycerol, free fatty acids, lactate and pyruvate were shown to be constant. 2. In fat pads incubated in medium containing glucose (3mg./ml.) and albumin (20mg./ml.) the concentrations (in mmumoles/g. wet wt.) were: ATP, 70; ADP, 36; AMP, 9.0; glucose 6-phosphate, 3.0; l-glycerol 3-phosphate, 3.3; citrate, 8.1. 3. The volume of intracellular water calculated from ([(3)H]water space-[(14)C]sorbitol space), ([(14)C]urea space-inulin space) and (weight loss on drying-[(14)C]sorbitol space) was 1.4ml./100g. wet wt. of tissue. The intracellular volume was not changed by insulin, alloxan-diabetes or adrenaline. 4. When compared in terms of mumoles/ml. of intracellular water the concentration of ATP in adipose tissue was less than in heart and diaphragm muscles. The concentrations of ADP and AMP were greater both in absolute terms and relative to ATP. Insulin, alloxan-diabetes and adrenaline had no significant effects on the concentrations of the adenine nucleotides in adipose tissue. 5. The concentration of glucose 6-phosphate was increased by insulin and lowered by alloxan-diabetes and adrenaline. The concentration of l-glycerol 3-phosphate was increased by insulin, unchanged by alloxan-diabetes and lowered by adrenaline. The concentration of citrate was increased by adrenaline and alloxan-diabetes and unchanged by insulin. 6. The effect of glucose concentration in the medium on rates of glucose uptake in adipose tissue from normal rats and alloxan-diabetic rats was investigated. The K(u) of glucose uptake was 29-44mg./100ml. and the V(max.) was 0.77mg./g. wet wt. of tissue/hr. Insulin increased the V(max.) and alloxan-diabetes diminished it, but neither agent significantly altered the K(u). 7. The significance of these results in relation to control of metabolism of adipose tissue is discussed.     

Failure of adrenaline to induce hyperglycaemia after fructose injection in young mice.

In control animals a 2-fold increase in liver phosphorylase activity 10min after adrenaline treatment was associated with a 55% increase in plasma glucose (P less than 0.001); at 20 min plasma glucose was 247% of the control value (P less than 0.001). Liver phosphorylase activity was decreased by 74%, 20 min after fructose injection (P less than 0.001), and, although phosphorylase activity increased 5-fold within 5 min of adrenaline injection, no increases in plasma glucose concentration over that found in fructose-injected animals which did not receive adrenaline occurred at either 5, 10 or 20 min. The data confirm inactivation of liver phosphorylase after fructose injection and suggest inhibition of the adrenaline-activated enzyme by the decrease in Pi and elevation of fructose 1-phosphate concentrations produced by the injection of fructose. These findings may be causally related to the hypoglycaemia and the lack of response to glucagon seen in patients with hereditary fructose intolerance after fructose ingestion.     

Determinants and importance of stress hyperglycaemia in non-diabetic patients with myocardial infarction.

Determinants of plasma glucose concentrations were studied in patients on admission to hospital with confirmed acute myocardial infarction but without previous glucose intolerance as evidenced by raised concentrations of glycosylated haemoglobin (HbAlc). Mortality in hospital increased significantly with increasing plasma concentrations of glucose in patients with both normal (p less than 0.0001, n = 311) and borderline (p less than 0.02, n = 70) concentrations of HbAlc. There was a weak relation between plasma glucose concentrations and infarct size as estimated by peak aspartate transaminase activity in both HbAlc groups (rs = 0.26, n = 101 and rs = 0.41, n = 35 respectively). A correlation was found between adrenaline and plasma glucose concentrations (r = 0.47, n = 27) and cortisol and plasma glucose concentrations (r = 0.75, n = 19), but the relation of plasma noradrenaline and plasma glucose suggested a threshold effect. Concentrations of adrenaline, but not those of noradrenaline or cortisol, correlated with infarct size as measured both by peak aspartate transaminase activity and cumulative release of creatine kinase MB isoenzyme. Multiple regression analysis showed that concentrations of cortisol, adrenaline, and noradrenaline (but not the concentration of HbAlc, infarct size, or age) are the main determinants of plasma glucose concentration measured in non-diabetic patients when admitted to hospital after acute myocardial infarction.     

The effect of elevation of maternal plasma catecholamines on the fetus and placenta of the pregnant sheep

To study the effects of reduced uterine blood flow on fetal and placental metabolism, adrenaline has been infused at physiological doses (0.5 microgram/min per kg) into the circulation of the pregnant sheep. This gives a reduction of about one third of uterine blood flow at days 120-143 of pregnancy, but causes no significant change in umbilical blood flow. In contrast to the effects of constricting the uterine artery to reduce blood flow to a similar degree, placental oxygen consumption was reduced and that, together with a large increase in lactate production, indicated the placenta became hypoxic. The fetal blood gas status and hence oxygen consumption was not affected significantly. A consistent arterio-venous difference for glucose across the umbilical or uterine circulations was not detected unless the uterine blood flow was comparatively high. Glucose balance across the uterus showed a close linear relationship with uterine blood flow and more particularly with the supply of glucose to the uterus. There was clear evidence for glucose uptake by the placenta and fetus and also glucose output by both. The latter was more common when uterine blood flow was comparatively low or reduced by adrenaline infusion. The results are consistent with the concept that glucose supply has to be maintained to the placenta even at the expense of fetal stores, although lactate can substitute if there is enhanced output because of fetal hypoxia. They indicate that placental mobilisation of glycogen can lead to a net output of glucose to the mother. The manner of communicating to the fetus changes in placental state that occur during maternal adrenaline infusion is not clear. However towards the end of the 60 min infusion, elevation of fetal plasma adrenaline, probably resulting from a breakdown of the placental permeability barrier, may be an important signal.     

Effect of adrenaline on glucose transport in red cells of Rana balcanica

The characteristics of 3-O-methyl-D-glucose (3-OMG) uptake by frog erythrocytes were studied. 3-OMG transport was increased by adrenaline. Although the transport is inhibited by phloretin, the lack of saturation kinetics suggests that a glucose transporter doesn't exist or that its affinity for glucose is extremely low. Frog Rana balcanica red cells suspended in an isotonic medium containing adrenaline enlarge rapidly to reach a new pH-dependent steady state volume. At pH 8.0, the cells swell less than at pH 7.3. This is explained by a differential pH effect on the two pathways controlling the movement of the cations: as pH becomes more acidic K+ loss decreases. On the contrary as pH becomes more acidic Na+ uptake increases. The increase in glucose transport after osmotic swelling and the inhibition of swelling-induced glucose transport by phloretin suggest that the glucose transport pathway in Rana balcanica erythrocytes may is a volume-activated channel.     

Glucose, Insulin, and Adrenaline Effects on Some Aspects of Fish Feeding Behavior

Effects of glucose, insulin, and adrenaline on the feeding latent time and the ration in 3 species of fresh-water teleost fish were studied. There has been shown a significant and uniform effect of glucose (an increase of the feeding latent period, a decrease of the ration) and of adrenaline (an increase of the feeding latent period) at initial stages of exotrophia in fish. The insulin effect on the fish feeding reaction rate is not uniform: apart from a statistically significant decrease of the feeding latent period, there were recorded opposite effects.     

Effects of oxytocin delivery on counter-regulatory hormone response in insulin-dependent (type 1) diabetic subjects

In insulin-dependent (type 1) diabetic subjects (n = 7) with intact hormone response to hypoglycaemia, oxytocin infusion (0.2 mU/min over 60 min) produced significant rises in basal plasma glucagon and adrenaline levels, while it reduced basal plasma cortisol levels. During insulin-induced hypoglycaemia, oxytocin potentiated the increases in plasma glucagon and adrenaline, while an inhibitory effect on plasma cortisol levels was still present. In insulin-dependent (type 1) diabetic subjects (n = 7) with blunted counter-regulatory hormone response to hypoglycaemia, the same dose of oxytocin (0.2 mU/min over 60 min) increased basal plasma glucose and glucagon concentrations and lowered basal plasma cortisol concentration. In the same group of patients, oxytocin delivery (0.2 mU/min), simultaneously to an insulin-induced hypoglycaemia, produced a significant elevation of plasma glucagon and adrenaline concentrations thus enhancing glucose recovery from hypoglycaemia. In conclusion, in insulin-dependent (type 1) diabetic patients, oxytocin delivery enhances plasma glucagon and adrenaline levels in basal conditions and during insulin-induced hypoglycaemia.     

Anaphylaxis and plasma catecholamines

The concentrations of plasma catecholamines, cyclic AMP glucose, lactate and glycerol were measured in a high IgE-producing strain of Hooded-Lister rats. Immobilization caused an increase in the levels of plasma catecholamines, especially adrenalin. In rats immunized against egg albumin the rise was higher than in non-sensitized controls, possibly indicating a relationship between sympatho-adrenal activity and serum IgE levels. Anaphylaxis caused by egg albumin induced a rapid and huge increase of plasma catecholamines especially adrenaline. The increase of plasma catecholamines was more rapid and pronounced in awake than in anesthetized rats. The plasma levels of adrenaline following anaphylaxis were larger than those obtained following administration of 5 μg adrenaline i.v. Plasma cyclic AMP, glucose and lactate levels were markedly enhanced already before the injection of antigen. On the other hand, glycerol levels were initially low but increased in parallel to the rise in plasma catecholamines. Administration of dextran to Sprague-Dawley rats induced an anaphylactoid reaction and high plasma levels of adrenaline and noradrenaline. The results indicate a massive sympatho-adrenal activation in anaphylactic and anaphylactoid shock and the use of exogenous adrenaline may cause little additional activation of adrenoceptors.     

Comparison of metabolic effect of ammonia and adrenaline infusions in sheep.

Intravenous infusions of ammonium chloride (62.3 mumol.kg-1.min-1) for 30 min caused a significant increase in blood glucose, lactate, pyruvate and free fatty acid (FFA) levels. A similar effect was also observed during infusion of adrenaline. Propanolol--a beta-receptor blocking agent--completely prevented the rise of blood pyruvate and lactate after adrenaline when 8.3 microgram.kg-1.min-1 of propranolol were infused, but not after NH4Cl administration. Lipolytic actions of adrenaline were completely prevented but that of NH4Cl was only significantly diminished by blockade of beta-receptors with propranolol. It was concluded that the influence of ammonium ions on blood lactate and pyruvate and FFA was not entirely mediated by adrenaline.     

Metabolic effects and secretory properties of a radiation-induced transplantable rat insulinoma

The metabolic effects and secretory properties of a radiation-induced transplantable insulinoma were examined in 16-17 week old NEDH rats. Subcutaneous subscapular implantation of tumour fragments resulted in hyperphagia, increased body weight gain, marked hyperinsulinaemia and severe hypoglycaemia, with the resulting death of the recipient by 27 days. Ultimate tumour size was 2.1 +/- 0.4 g (mean +/- SEM). At 3 days after transplantation, plasma glucose and insulin responses to intraperitoneal glucose, insulin, arginine and adrenaline were similar to control rats. At 20 days, plasma glucose concentrations of insulinoma-bearing rats remained low throughout glucose tolerance tests, and insulin responsiveness to glucose stimulation was absent. 2-Deoxy-D-glucose produced only a small rise of glucose concentrations in tumour-bearing rats. Insulin sensitivity was not appreciably impaired at 20 days despite severe hyperinsulinaemia and hypoglycaemia. The ability of adrenaline and propranolol to suppress plasma insulin and raise plasma glucose concentrations was also retained. At 20 days, glucagon evoked a marked plasma insulin response with no change in plasma glucose concentrations. In contrast, arginine and glibenclamide failed to stimulate insulin above high basal concentrations.     

Regulation of liver and brain hexose monophosphate dehydrogenases by insulin and dietary intake in the female rat

Summary Liver glucose 6-phosphate dehydrogenase and phosphogluconate dehydrogenase activities were significantly decreased in both diabetic and fasted rats. Treatment of diabetic rats with insulin resulted in liver glucose 6-phosphate dehydrogenase and phosphogluconate dehydrogenase activities that were significantly greater than controls. Insulin promoted an increase in food consumption that was blocked by adrenaline. Insulin, when administered together with adrenaline, restored hepatic glucose 6-phosphate dehydrogenase and phosphogluconate dehydrogenas activities of diabetic animals to control values, without altering food consumption. Brain glucose 6-phosphate dehydrogenase and phosphogluconate dehydrogenase activities were not significantly altered by either dietary restriction, diabetes or insulin treatment. These results demonstrate a dissociation between the action of insulin on hepatic glucose 6-phosphate dehydrogenase activity and its action to increase food intake.Abbreviations NADP⁺ oxidoreductase, EC 1.1.1.49 Glucose 6-P dehydrogenase, GPD, D-glucose-6-phosphate - NADP⁺ 2-oxidoreductase (decarboxylating), EC 1.1.1.44 phosphogluconate dehydrogenase, PGD, 6-phospho-D-gluconate