Glucose tolerance in ewes and susceptibility to pregnancy toxaemia

Intravenous glucose tolerance tests were undertaken on fed twin-pregnant ewes at about 120 days of gestation by injecting 0.4 g glucose per kilogram of live weight, then measuring glucose and insulin concentrations in plasma over the next 2 h. An insulin resistance index was calculated from the product of T1/2 for glucose disappearance and the plasma insulin concentrations integrated over time. Approximately 10 days later, the ewes were starved to induce ovine pregnancy toxaemia. During this period, the course of the hypoglycaemia and ketonaemia were followed by measuring metabolite concentrations in jugular blood samples obtained every 2-3 days. The existence of dehydration, acid-base imbalance and renal failure was also determined from packed cell volumes, serum CO2 content and serum concentrations of urea, creatinine and inorganic phosphate. Ewes that became recumbent and moribund with the disease were classified as susceptible whereas those asymptomatic after 10 days were classified as non-susceptible. Seven susceptible ewes had significantly higher insulin resistance indices (2043 +/- 670 s.d.) than did six non-susceptible ewes (1261 +/- 433 s.d.). It was concluded that poor control of glucose homeostasis may be an important predisposing factor in pathogenesis of the disease.     

Effect of metal ion catalyzed oxidation of rifamycin SV on cell viability and metabolic performance of isolated rat hepatocytes

The effect of rifamycin SV on metabolic performance and cell viability was studied using isolated hepatocytes from fed, starved and glutathione (GSH) depleted rats. The relationships between GSH depletion, nutritional status of the cells, glucose metabolism, lactate dehydrogenase (LDH) leakage and malondialdehyde (MDA) production in the presence of rifamycin SV and transition metal ions was investigated. Glucose metabolism was impaired in isolated hepatocytes from both fed and starved animals, the effect is dependent on the rifamycin SV concentration and is enhanced by copper (II). Oxygen consumption by isolated hepatocytes from starved rats was also increased by copper (II) and a partial inhibition due to catalase was observed. Cellular GSH levels which decrease with increasing the rifamycin SV concentration were almost depleted in the presence of copper (II). A correlation between GSH depletion and LDH leakage was observed in fed and starved cells. Catalase induced a slight inhibition of the impairment of gluconeogenesis, GSH depletion and LDH leakage in starved hepatocytes incubated with rifamycin SV, iron (II) and copper (II) salts. Lipid peroxidation measured as MDA production by isolated hepatocytes was also augmented by rifamycin SV and copper (II), especially in hepatic cells isolated from starved and GSH depleted rats. Higher cytotoxicity was observed in isolated hepatocytes from fasted animals when compared with fed or GSH depleted animals. It seems likely that in addition to GSH level, there are other factors which may have an influence on the susceptibility of hepatic cells towards xenobiotic induced cytotoxicity.     

Effects of medium-chain triglyceride feeding or glucose infusion on glucose kinetics in the newborn rat

Hypoglycaemia which develops in starved newborn rats (0.15 +/- 0.01 mg/ml) is reversed by feeding medium-chain triglycerides (0.66 +/- 0.05 mg/ml). Despite similar glycaemia (0.71 +/- 0.07 mg/ml) starved newborns infused with glucose (10.7 mg/min/kg) show a 30% higher glucose turnover rate than medium-chain triglyceride fed animals (14.1 +/- 0.6 versus 10.6 +/- 0.3 mg/min/kg, p less than 0.01). For a comparable [6-3H]glucose turnover rate (10.5 +/- 0.3 mg/min/kg), glucose-infused (5.25 mg/min/kg) newborns have a 30% lower glycaemia (0.50 +/- 0.03 mg/ml, p less than 0.01) than medium-chain triglyceride-fed newborns. Thus, medium chain triglyceride feeding leads to a 30% decreased capacity of the tissues to utilize glucose. For a similar glucose turnover rate, medium-chain triglyceride-fed newborns have a higher blood lactate concentration than glucose-infused newborns (0.26 +/- 0.03 versus 0.15 +/- 0.02 mg/ml). However, in medium-chain triglyceride-fed newborns, the increase of blood lactate is not only due to the Cori cycle, as glucose recycling is less increased than glucose production. Thus medium-chain triglyceride increases the release of gluconeogenic precursors which are not derived from blood glucose. In presence of a glucose infusion (15.25 mg/min/kg) producing hyperglycaemia (1.35 +/- 0.05 mg/ml), endogenous glucose production is suppressed by only 37%. If 3-mercaptopicolinate, an inhibitor or gluconeogenesis, is given concomitantly, hyperglycaemia is prevented (0.72 +/- 0.08 mg/ml) and endogenous glucose production is suppressed. Glucose infusion in the hypoglycaemic newborn rat might thus lead to a precarious glucose homeostasis.     

Metabolism of glucose in hyper- and hypo-thyroid rats in vivo. Glucose-turnover values and futile-cycle activities obtained with 14C- and 3H-labelled glucose.

1. A trace amount of glucose labelled with 14C uniformly and with 3H at position 2, 3 or 6 was injected intravenously into starved rats to measure the turnover rate of blood glucose. 2. Reliable estimates were made based on the semilogarithmic plot of specific radioactivity of the glucose contained in whole blood samples taken from the tail vein. 3. Glucose turned over more rapidly in hyperthyroid and more slowly in hypothyroid than in euthyroid rats. The percentage contribution of glucose recycling (determined from the difference in replacement rates between [U-14C]glucose and [6-3H]glucose) to the glucose utilization increased on induction of hyperthyroidism. 4. Futile cycles between glucose and glucose 6-phosphate (determined from the difference between replacement rates of [2-3H]glucose and [6-3H]glucose) were activated and inactivated by induction of hyperthyroid and hypothyroid states respectively. 5. The hepatic content of glycogen was much lower in hyper- and hypo-thyroid than in euthyroid rats. The enhanced glucose production in hyperthyroid rats resulted from not only activationof hepatic gluconeogenesis but also diversion of the final product of gluconeogenesis from liver glycogen to blood glucose. In hypothyroidism, the inhibition of gluconeogensis led to suppression of both glucose production and glycogenesis in the liver.     

Effects of maternal fasting on hepatic gluconeogenesis and glucose metabolism in fetal lambs.

In unstressed, normoglycaemic fetal lambs, the liver produces little glucose, and gluconeogenesis is insignificant. Indirect measurements have suggested that the fetus may produce glucose endogenously during hypoglycaemia induced by prolonged maternal starvation. In eight fetal lambs we directly measured total and radiolabelled substrate concentration differences across the liver to determine whether the fetal liver produces glucose after four days of fasting-induced hypoglycaemia. Simultaneously we measured umbilical glucose uptake and fetal glucose utilization. Glucose concentrations in ewes (1.78 +/- 0.44 mmol.-1) and fetuses (0.61 +/- 0.17 mmol.l-1) were decreased. Fetal glucose utilization rate (21.7 +/- 8.9 mumol.min-1.kg-1) was not significantly different from umbilical glucose uptake (17.2 +/- 8.9 mumol.min-1.kg-1). Hepatic glucose production (8.9 +/- 17.2 mumol.min-1.100 g-1) and gluconeogenesis (6.1 +/- 4.4 mumol.min-1.100 g-1) were present, but could account for only 13% and 8% of fetal glucose requirements, respectively. To determine whether glucose output by the fetal liver was limited by substrate availability, we infused lactate, acetate, and acetone into the umbilical veins of four fasted animals, increasing hepatic substrate delivery. Hepatic glucose output did not increase during infusion of gluconeogenic substrates, indicating that substrate availability did not limit gluconeogenesis. We conclude that the gluconeogenic pathway is intact in late-gestation fetal lambs and that the fetal liver is capable of gluconeogenesis. However, the primary change in fetal metabolism during maternal starvation is the reduction in fetal glucose utilization, obviating the need for substantial hepatic glucose production. The factors stimulating this modest increase in fetal hepatic glucose production remain to be elucidated.     

Development of gluconeogenesis from different substrates in newborn rabbit hepatocytes

The rates of glucose production from various substrates entering gluconeogenesis at different steps were investigated in hepatocytes isolated from term-fetus and newborn rabbits fasted during the first 2 days of life. The data were compared to the rate of glucose production measured in hepatocytes from young rabbits (50-60 days) starved for 48 h. The net production of glucose from substrates (lactate, pyruvate, propionate, alanine) entering gluconeogenesis below phosphoenolpyruvate was very low at birth and increased during the first day of life, in relation with an increased cytosolic phosphoenolpyruvate carboxykinase activity. The net production of glucose from precursors entering gluconeogenesis at the level of triose phosphates (dihydroxyacetone, fructose) was low at birth but a maximal capacity for gluconeogenesis was reached within 6 h after birth. This enhanced gluconeogenic capacity was associated with a fall in hepatic fructose 2,6-bisphosphate concentration and a reduced glycolytic flux. In contrast, a high glucose production from galactose was already present at birth and did not rise at 24 or 48 h after delivery. These results suggest that the development of gluconeogenic capacity in hepatocytes isolated from newborn rabbit is dependent upon two factors, a decrease in the F2,6-P2 concentration which reduces the glycolytic flux and an increase in the activity of cytosolic phosphoenolpyruvate carboxykinase.     

Endurance vs. strength training: comparison of cardiac structures using normal predicted values

The importance of metabolic feedback regulation vs. feedforward regulation of hepatic glucose production (HGP) during exercise was investigated in rats by infusing glucose intravenously from the onset of running. Glucose infusion equaled the average exercise-induced increase from basal to steady state in HGP found in saline-infused control rats. Rats were studied at two work loads, running at 21 (series I) or 18 m/min (series II) for 35 min. Glucose turnover was measured by means of an intravenous [3H]glucose infusion. HGP was suppressed by glucose infusion corresponding to the infused amount of glucose in both series, except for late in exercise in series I, where HGP plus infused glucose tended to exceed HGP in saline-infused rats (P less than 0.10). Muscle glycogenolysis and fat metabolism were similar in both groups in the two series. Plasma glucose was never elevated, whereas insulin was, in glucose- vs. saline-infused rats of both series. Plasma catecholamines were lower in glucose- compared with saline-infused rats in series II. In conclusion, HGP is very sensitive to metabolic feedback inhibition at low exercise intensities. Feedforward control of HGP may play a role at higher work loads (series I). Exogenously supplied glucose, in moderate amounts, may replace HGP specifically without concomitant changes in mobilization of other substrates.     

Glucose metabolism in the basal state and during a two-hour glucose infusion in low insulin responders and control subjects

Glucose metabolism was studied in eight low insulin responders to glucose and eight controls using a primed-constant tracer infusion technique. The tracer was 3-3H-glucose. The former group demonstrated a lower IVGTT than the controls, although the K-values were well within the normal range. They also attained higher blood glucose levels during iv administration of high and low glucose loads. Glucose turnover studies revealed normal hepatic glucose production, normal total glucose uptake and normal metabolic clearance of glucose in the low responders as a group. The findings suggest normal sensitivity to insulin in these subjects, and imply that the low insulin response is the sole mediator of the observed lowering in IVGTT.     

Interactions between insulin and thyroid hormone in the control of lipogenesis.

1. The effects of intragastric glucose feeding and L-tri-iodothyronine (T3) administration on rates of hepatic and brown-fat lipogenesis in vivo were examined in fed and 48 h-starved rats. 2. T3 treatment increased hepatic lipogenesis in the fed but not the starved animals. Brown-fat lipogenesis was unaffected or slightly decreased by T3 treatment of fed or starved rats. 3. Intragastric glucose feeding increased hepatic lipogenesis in control or T3-treated fed rats, but did not increase hepatic lipogenesis in starved control rats. Glucose feeding increased hepatic lipogenesis if the starved rats were treated with T3. Glucose feeding increased rates of brown-fat lipogenesis in all experimental groups. The effects of glucose feeding on liver and brown-fat lipogenesis were mimicked by insulin injection. 4. The increase in hepatic lipogenesis in T3-treated 48 h-starved rats after intragastric glucose feeding was prevented by short-term insulin deficiency, but not by (-)-hydroxycitrate, an inhibitor of ATP citrate lyase. The increase in lipogenesis in brown adipose tissue in response to glucose feeding was inhibited by both short-term insulin deficiency and (-)-hydroxycitrate. 5. The results tend to preclude pyruvate kinase and acetyl-CoA carboxylase as the sites of interaction of insulin and T3 in the regulation of hepatic lipogenesis in 48 h-starved rats. Other potential sites of interaction are discussed.     

Dietary fat type alters glucose metabolism in isolated rat hepatocytes

Dietary fat type can influence the regulation of carbohydrate metabolism in multiple tissue types. The influence of feeding high-fat (40% of kilocalories) diets containing either menhaden oil (MO) or coconut oil (CO) on hepatic glycogenolytic and gluconeogenic capacities was studied in isolated rat hepatocytes. Estimates of both glycogenolytic and gluconeogenic capacities were performed on hepatocytes isolated from fed and fasted animals, respectively. In MO-fed animals, both basal and hormone-stimulated rates of glucose production were significantly greater than those in CO-fed animals. However, both groups displayed a similar maximal increase in glucose production above basal for glucagon and epinephrine (2.3- and 1.9-fold, respectively). Basal rates of adenosine 3′,5′-cyclic phosphate (cAMP) production were not different between groups whereas glucagon-stimulated cAMP production was increased twofold in the MO-fed group. In both MO and CO groups, the addition of 10 nM insulin reduced glucose production in fed animals to similar absolute rates. In animals fasted for 24 hours, gluconeogenic capacity was estimated using 10 mM pyruvate, lactate, or glycerol. Glucose production from all substrates was significantly greater in CO-fed animals. In addition to increased gluconeogenic rates, maximal phosphoenolpyruvate carboxykinase (PEPCK) activity was increased in the CO-fed group. Insulin reduced glucose production in both dietary groups, but the absolute rate of glucose production was 28% greater in the CO-fed group relative to the MO-fed group. In summary, dietary fat type can markedly influence the regulation of hepatic glucose metabolism in multiple metabolic pathways. MO feeding promoted glycogenolysis and sensitivity to insulin whereas CO feeding favored gluconeogenesis and reduced insulin sensitivity.     

Glycogen synthesis in the perfused liver of streptozotocin-diabetic rats.

1. Net glycogen accumulation was measured in sequentially removed samples during perfusion of the liver of starved streptozotocin-diabetic rats, and shown to be significantly impaired, compared with rates in normal (starved) rats. 2. In perfusions of normal livers with glucose plus C3 substrates, there was an increase in the proportion of glycogen synthetase 'a', compared with that in the absence of substrates. This response to substrates, followed in sequential synthesis and enzymic sensitivity in the perfused liver of diabetic rats were reversed by pretreatment in vivo with glucose plus fructose, or insulin. Glucose alone did not produce this effect. 4. Glucose, fructose, insulin or cortisol added to e perfusion medium (in the absence of pretreatment in vivo) did not stimulate glycogen synthesis in diabetic rats. 5. In intact diabetic rats, there was a decline in rates of net hepatic glycogen accumulation, and the response of glycogen synthetase to substrates. The most rapid rates of synthesis were obtained after fructose administration. 6. These results demonstrate that there is a marked inherent impairment in hepatic glycogen synthesis in starved diabetic rats, which can be rapidly reversed in vivo but no in perfusion. Thus hepatic glycogen synthesis does not appear to be sensitive to either the short-term direct action of insulin (added alone to perfusions) of to long-term insulin deprivation in vivo. The regulatory roles of substrates, insulin and glycogen synthetase in hepatic glycogen accumulation are discussed.     

Role of liver nerves and adrenal medulla in glucose turnover of running rats

Sympathetic control of glucose turnover was studied in rats running 35 min at 21 m X min-1 on the level. The rats were surgically liver denervated, adrenodemedullated, or sham operated. Glucose turnover was measured by primed constant infusion of [3-3H]glucose. At rest, the three groups had identical turnover rates and concentrations of glucose in plasma. During running, glucose production always rose rapidly to steady levels. The increase was not influenced by liver denervation but was halved by adrenodemedullation. Similarly, hepatic glycogen depletion was identical in denervated and control rats but reduced after adrenodemedullation. Early in exercise, glucose uptake rose identically in all groups and, in adrenodemedullated rats, matched glucose production. Accordingly, plasma glucose concentration increased in liver-denervated and control rats but was constant in adrenodemedullated rats. Compensatory changes in hormone or substrate levels explaining the lack of effect of liver denervation were not found. In rats with intact adrenals, the plasma epinephrine concentration was increased after 2.5 min of running. It is concluded that, in rats carrying out exercise of moderate intensity and duration, hepatic glycogenolysis and glucose production are not influenced by the autonomic liver nerves but are enhanced by circulating epinephrine.     

Stimulation by glucose of gluconeogenesis in hepatocytes isolated from starved rats.

Control properties of the gluconeogenic pathway in hepatocytes isolated from starved rats were studied in the presence of glucose. The following observations were made. (1) Glucose stimulated the rate of glucose production from 20 mM-glycerol, from a mixture of 20 mM-lactate and 2 mM-pyruvate, or from pyruvate alone; no stimulation was observed with 20 mM-alanine or 20 mM-dihydroxyacetone. Maximal stimulation was obtained between 2 and 5 mM-glucose, depending on the conditions. At concentrations above 6 mM, gluconeogenesis declined again, so that at 10 mM-glucose the glucose production rate became equal to that in its absence. (2) With glycerol, stimulation of gluconeogenesis by glucose was accompanied by oxidation of cytosolic NADH and reduction of mitochondrial NAD+ and was insensitive to the transaminase inhibitor amino-oxyacetate; this indicated that glucose accelerated the rate of transport of cytosolic reducing equivalents to the mitochondria via the glycerol 1-phosphate shuttle. (3) With lactate plus pyruvate (10:1) as substrates, stimulation of gluconeogenesis by glucose was almost additive to that obtained with glucagon. From an analysis of the effect of glucose on the curves relating gluconeogenic flux and the steady-state intracellular concentrations of gluconeogenic intermediates under various conditions, in the absence and presence of glucagon, it was concluded that addition of glucose stimulated both phosphoenolpyruvate carboxykinase and pyruvate carboxylase activity.     

The utilization of glucose for the synthesis of milk components in the fed and starved lactating goat in vivo.

1. [U-14C]Glucose and [3-3H]glucose were infused into fed and starved lactating goats in order to study glucose metabolism in the mammary gland. 2. Glucose carbon was oxidized and metabolizet to milk lactose, citrate and triacylglycerol in the lactating goat udder. 3. Recycling of glucose carbon in the lactating animal accounted for 10-20% of the total glucose turnover in the whole animal. Recycling of glucose 6-phosphate in the udder accounted for about 25% of the glucose 6-phosphate metabolized. 4. Flux of glucose 6-phosphate through the pentose phosphate pathway was sufficient to account for 34% of the NADPH required for fatty acid synthesis in the gland in the fed animal. 5. Net metabolism of glucose 6-phosphate via the pentose phosphate pathway accounted for 17.8 and 1.2% of the glucose phosphorylated by the mammary gland in the fed and starved animal respectively. Metabolism of glucose 6-phosphate via the pentose phosphate pathway was sufficient to account for all the CO2 produced from glucose in the fed animal, but only 17% of the CO2 produced from glucose in the starved animal.     

Metabolism of glucose in hyper- and hypo-thyroid rats in vivo. Relation of catecholamine actions to thyroid activity in controlling glucose turnover.

1. In euthyroid rats, treatment with reserpine of 6-hydroxydopamine, which deprived neuronal terminals of catecholamines, resulted in increases in rates and rate coefficients for blood glucose turnover in the starved states as determined by decay of [U-14C,6-3H]-glucose. Conversely, the injection of adrenaline or noradrenaline into starved euthyroid rats caused a marked decrease in rate coeeficients for glucose turnover. There was no change in the percentage glucose recycling under these conditions. 2. Adrenaline and noradrenaline caused more pronounced hyperglycaemia in hyperthyroid than in euthyroid rats owing to the greater activation of hepatic glucose production. 3. The increase in glucose turnover characteristics of hyperthyroidism was observed even after treatment with an alpha- or beta-adrenergic antagonist, showing the insignificant role of the balance between alpha- and beta-adrenergic receptors in the thyroid-dependent metabolic changes. 4. Rate coefficients for glucose turnover were not affected by reserpine treatment or catecholamine injections when rats had been rendered hyperthyroid. 5. Thus catecholamines are direct determinants of glucose-turnover rates in the starved state, and depend to some extent on the prevailing thyroid state.     

Studies on gluconeogenesis and protein synthesis in isolated hepatocytes.

Glucose production was studied in isolated hepatocytes using various substrates and with increasing substrate concentrations (0-10 mM). Fructose was the best gluconeogenic substrate while other substrates studied stimulated net glucose production in the following decreasing order: lactate, pyruvate, glycerol, galactose, alanine, and succinate. Studies on oxygen consumption showed that endogenous respiration was linear for 60 min and was not altered by extracellular calcium. Studies on the incorporation of 14C-leucine into protein was linear for only 3-4 hr in cells containing low glycogen. However, cells containing high glycogen incorporated 14C-leucine into protein linearly for 8-10 hr. About 3 mg of protein per g per hr was synthesized by isolated cells when incubated for 4 hr with amino acids mixture, glucose, lactate, and insulin.     

Regulation of glucose production in rainbow trout: role of epinephrine in vivo and in isolated hepatocytes

The rate of hepatic glucose production (R(a) glucose) of rainbow trout (Oncorhynchus mykiss) was measured in vivo by continuous infusion of [6-(3)H]glucose and in vitro on isolated hepatocytes to examine the role of epinephrine (Epi) in its regulation. By elevating Epi concentration and/or blocking beta-adrenoreceptors with propranolol (Prop), our goals were to investigate the mechanism for Epi-induced hyperglycemia to determine the possible role played by basal Epi concentration in maintaining resting R(a) glucose and to assess indirect effects of Epi in the intact animal. In vivo infusion of Epi caused hyperglycemia (3.75 +/- 0.16 to 8.75 +/- 0.54 mM) and a twofold increase in R(a) glucose (6.57 +/- 0.79 to 13.30 +/- 1.78 micromol. kg(-1). min(-1), n = 7), whereas Prop infusion decreased R(a) from 7.65 +/- 0.92 to 4.10 +/- 0.56 micromol. kg(-1). min(-1) (n = 10). Isolated hepatocytes increased glucose production when treated with Epi, and this response was abolished in the presence of Prop. We conclude that Epi-induced trout hyperglycemia is entirely caused by an increase in R(a) glucose, because the decrease in the rate of glucose disappearance normally seen in mammals does not occur in trout. Basal circulating levels of Epi are involved in maintaining resting R(a) glucose. Epi stimulates in vitro glucose production in a dose-dependent manner, and its effects are mainly mediated by beta-adrenoreceptors. Isolated trout hepatocytes produce glucose at one-half the basal rate measured in vivo, even when diet, temperature, and body size are standardized, and basal circulating Epi is responsible for part of this discrepancy. The relative increase in R(a) glucose after Epi stimulation is similar in vivo and in vitro, suggesting that indirect in vivo effects of Epi, such as changes in hepatic blood flow or in other circulating hormones, do not play an important role in the regulation of glucose production in trout.     

The effects of insulin and glucose on the induction and intracellular translocation of delta-aminolevulinic acid synthase

The administration of insulin and glucose to young Sprague-Dawley rats (125-150 g) resulted in changes in the intracellular distribution and in the turnover rates of delta-aminolevulinic acid synthase (ALAS) activity in the mitochondria and the cytosol. When starved, allylisopropylacetamide (AIA)-induced rats were injected with either insulin or glucose, the percentage of the total ALAS activity found in the cytosol increased from 27% in control animals to 33-40% in insulin-treated and 50% in glucose-treated rats. Similar increases of the ALAS activity in the cytosol were observed after insulin treatment of noninduced, starved animals. Glucose administration also repressed 25-40% of the AIA induction of ALAS as previously reported; however, this effect apparently was not a result of elevated insulin levels, since there was no observed repression of AIA induction after insulin administration. The effects of insulin and glucose on the turnover rates of ALAS activity in the mitochondria and in the cytosol were investigated by observing changes in the half-lives of ALAS activity in the two intracellular compartments. Administration of both insulin and glucose resulted in an increased half-life of ALAS activity in the cytosol from 20.8 to over 100 min, while the mitochondrial half-life was not significantly changed. When insulin was given to either fed, AIA-induced or to starved, noninduced rats, the half-life of the cytosolic ALAS increased from about 14 to 40 min. In contrast to the starved, induced animals, the mitochondrial ALAS half-life in starved, noninduced animals decreased 50%. These results suggest that insulin and glucose treatment may inhibit the translocation of ALAS from the cytosol into the mitochondrial matrix.     

Effects of fructose on hepatic glucose metabolism in humans

Hepatic and extrahepatic insulin sensitivity was assessed in six healthy humans from the insulin infusion required to maintain an 8 mmol/l glucose concentration during hyperglycemic pancreatic clamp with or without infusion of 16.7 micromol. kg(-1). min(-1) fructose. Glucose rate of disappearance (GR(d)), net endogenous glucose production (NEGP), total glucose output (TGO), and glucose cycling (GC) were measured with [6,6-(2)H(2)]- and [2-(2)H(1)]glucose. Hepatic glycogen synthesis was estimated from uridine diphosphoglucose (UDPG) kinetics as assessed with [1-(13)C]galactose and acetaminophen. Fructose infusion increased insulin requirements 2.3-fold to maintain blood glucose. Fructose infusion doubled UDPG turnover, but there was no effect on TGO, GC, NEGP, or GR(d) under hyperglycemic pancreatic clamp protocol conditions. When insulin concentrations were matched during a second hyperglycemic pancreatic clamp protocol, fructose administration was associated with an 11.1 micromol. kg(-1). min(-1) increase in TGO, a 7.8 micromol. kg(-1). min(-1) increase in NEGP, a 2.2 micromol. kg(-1). min(-1) increase in GC, and a 7.2 micromol. kg(-1). min(-1) decrease in GR(d) (P < 0. 05). These results indicate that fructose infusion induces hepatic and extrahepatic insulin resistance in humans.     

Carbohydrate metabolism of hepatocytes from starved Japanese quail

Hepatocytes were isolated from livers of mature male and female starved Japanese quail (Coturnix coturnix japonica). The hepatocytes take up lactate and dihydroxyacetone extensively, and have a very high rate of glucose synthesis from these substrates. Fructose uptake and incorporation into glucose is much less. Pyruvate and alanine are taken up extensively, but form little glucose. There is negligible lipogenesis in cells of starved quail. Alanine increases up to 10-fold incorporation of ³HOH and ¹⁴C from several substrates into fatty acids, but it remains insignificant as compared to lipogenesis by cells of fed quail. There is little utilization of glucose, even in the presence of alanine, in marked contrast to hepatocytes from fed quail. However, glucose is phosphorylated at high rates, but most of the glucose 6-phosphate is recycled to glucose. There is a marked difference in the metabolism of polyols between the sexes. Glycerol, xylitol, and sorbitol are converted nearly quantitatively into glucose by hepatocytes of starved female quail. In cells of starved males, the uptake of polyols is higher, but conversion to glucose less efficient. In cells of starved male quail, alanine markedly stimulates the uptake of glycerol and xylitol and their conversion to glucose, but has no effect on sorbitol metabolism. In cells of female quail, alanine is without a significant effect on polyol metabolism.