Alterations of glucose metabolism during perfusion of rat lung with paraquat.

Isolated perfused rat lungs were used to investigate effects of paraquat on lung glucose metabolism. Lungs were ventilated with 5% CO2 in air and perfused with Krebs-Ringer bicarbonate buffer, pH 7.4, containing albumin and 5.5 mM radiolabeled D-glucose. Control lung glucose utilization, estimated from rate of 3H2O production from [5-3H]glucose, was 44 mumol/h-g dry wt. Pentose cycle activity, based on 14CO2 specific yields at the end of perfusions with [1-14C]- and [6-14C]glucose, was 14% of glucose utilization. During perfusion with 1.5 mM paraquat, glucose utilization increased 28%, 14CO2 production via the pentose cycle increased 182% (P less than 0.005), CO2 production via mitochondrial metabolism increased 39% (P less than 0.02), and the rate of lactate production increased 28% (P less than 0.05). Pyruvate production and the lactate-to-pyruvate ratio were not significantly altered. The data indicate that interaction of paraquat with the lung results in increased turnover of cytoplasmic NADPH and increased mitochondrial metabolism, but no significant change in cytoplasmic redox state. The findings are compatible with intracellular enzymatic reduction of paraquat by an NADPH-requiring reductase.     

Lactate metabolism in the isolated perfused rat kidney: relations to renal function and gluconeogenesis.

In the intact dog, decreases in both glomerular filtration rate and net renal Na+ reabsorption due to raised ureteral pressure were not associated with a decrease in renal lactate oxidation rate, although total renal CO2 production decreased in proportion to the changes in net renal reabsorption of Na+ and glomerular filtration rate. 2. In order to determine whether, in the absence of other added substrates, the metabolism of lactate supports only the 'basal' renal metabolism or can enhance renal function as well, the rate of lactate utilization and decarboxylation by the isolated perfused rat kidney have been quantified in relation to renal function and one measure of renal basal metabolism, glucose production. 3. The perfusate was Krebs-Ringer bicarbonate (pH 7-35-7-48) with Fraction V bovine serum albumin, 6g/100 ml. L-(+)-lactate was added to raise the lactate concentration from endogenous levels to 2-5, 5-0 or 10 mM. 4. We determined: net lactate utilization rate, lactate decarboxylation rate (14CO2 produced from L-(+)-[U-14C]lactate), net glucose production rate, and net re-absorptive rate of Na+. 5. The apparent Km and Vmax for lactate oxidation were 2-1 mM and 1-29 mumole.g-1.min-1 respectively. There was no apparent maximum for total lactate utilization rate due to continuing increases in glucose production rate as lactate concentration was raised. At ca. 10 mM lactate, glucose production accounted for about half of the total lactate utilized. Therefore the basal energy requirements of the kidney need not be constant since glucose production increases as lactate concentration is raised. 6. Both lactate oxidation rate and lactate utilization rate were significantly correlated with the net reabsorption of Na+ by the renal tubules, with the percentage of filtered Na+ reabsorbed and with the glomerular filtration rate. The major fraction of the net renal reabsorption of Na+ was probably supported by the metabolism of substrates either bound to albumin or derived from renal tissue since the percentage of filtered Na+ reabsorbed increased from ca. 78%, when no lactate was added, to 97% when initial lactate concentration was 10 mM. Therefore, addition of lactate increased both the basal mebabolism and tubular function. However, these observations do not permit us to conclude whether it was the presence of lactate, or its utilization by oxidative or by other pathways which enhanced net renal reabsorption of Na+ and the glomerular filtration rate.     

Metabolic response to carbon monoxide by isolated rat lungs.

Glucose metabolism was studied in isolated rat lungs ventilated with 95% O2.5% CO2 (control), 95% N2: 5% CO2 (hypoxia), and 95% CO:5% CO2 (carbon monoxide) and perfused for 100-120 min with Krebs-Ringer-bicarbonate buffer, pH 7.4, containing [U-14C] and [3-3H]glucose. The production of 14C-labeled lactate plus pyruvate (L + P) and of 14CO2 represented 48% and 22% respectively, of the total [14C]glucose utilization. The lactate-to-pyruvate ratio (L/P) was 8.7. Tritium was recovered predominantly as 3H2O in the perfusate. Wth carbon monoxide ventilation, L + P production was increased by 357% with an L/P of 52.9, and 14CO2 production was markedly decreased. A 56% decrease in lung ATP content was associated with decreased incorporation of 14C into fatty acids. Compared with CO, changes with N2 ventilation were less marked, indicating that ventilation with CO is a more effective method with which to study inhibtion of oxidative metabolism. The lung exhibits a Pasteur effectbintain ATP content or its supply for synthetic activity.     

Functional role of aerobic glycolysis in rat portal vein

The functional role of aerobic lactate production in the rat portal vein was investigated. Changing substrate from glucose (11.5 mM) to pyruvate (11.5 mM) or beta-hydroxybutyrate (3 mM) had virtually no effect on spontaneous mechanical activity. Lactate production (FLA) was smaller with pyruvate than with glucose (0.05 +/- 0.01 vs. 0.14 +/- 0.03 mumol g-1 min-1, n = 4). Addition of 0.5 mM iodoacetate to inhibit glycolysis abolished mechanical activity in 15-20 min with glucose as substrate, whereas with pyruvate the mechanical activity was only moderately reduced over this time period. With beta-hydroxybutyrate (3 mM) as substrate no aerobic lactate production was detected during normal spontaneous activity. Inhibition of cellular respiration with increasing concentrations of cyanide in beta-hydroxybutyrate medium led to a graded decrease in mechanical activity and FO2, but only a marginal increase in lactate production. With glucose as substrate, repeated stimulation with a combination of isoproterenol (10(-5) M) and papaverine (10(-4) M) gave similar increases in lactate production at each exposure. With beta-hydroxybutyrate some lactate production was found at the first stimulation, but decreased to be abolished at the third stimulation. The mechanical inhibition caused by the stimulation was however similar at the three exposures for both substrates. Lactate production induced by cAMP-raising stimulation in beta-hydroxybutyrate could be accounted for by glycogenolysis. These results show that aerobic glycolysis leading to net lactate production is not necessary for normal spontaneous mechanical activity or the relaxing effect of hypoxia or cAMP raising stimuli in rat portal vein.     

Reutilization of fatty acid carbons for lung lipid synthesis

The utilization of glucose, palmitate, and oleate for the synthesis of lung lipids was studied in isolated rat lungs. Lungs were ventilated with 5% CO2 in air and perfused for 100 min with a Krebs-Ringer bicarbonate buffer (pH 7.4), containing 3% fatty acid-free albumin and either 5.6 mM [U-14C]glucose or 0.25 mM [1-14C]palmitate, or 0.25 mM [1-14C]-oleate. At the end of 100 min of perfusion with these precursors, between 73 and 85% of total lipid 14C was recovered as phospholipid. Glucose carbon was mainly incorporated into triglyceride fatty acids (TG-FA) and phosphatidylcholine fatty acids (PC-FA) of 16- and 18-carbon chain length. After perfusion with [14C]palmitate and [14C]oleate, only 65 and 20% of 14C was recovered as PC 16-carbon and 18-carbon FA, respectively. The remaining 14C was mainly recovered as FA shorter than the 14C precursors. Schmidt degradation analysis of lipid FA demonstrated considerable labeling of alkyl carbons on perfusion with the carboxyl-labeled precursors, indicating that FA degradation products were used for synthesis of lipid FA. This process was enhanced on addition of glucose to the perfusate.     

Metabolism of D-[3-3H]glucose, D-[5-3H]glucose, D-[U-14C]glucose, D-[1-14C]glucose and D-[6-14C]glucose in pancreatic islets in an animal model of type-2 diabetes

This study aims at exploring specific aspects of D-glucose metabolism, so far not yet investigated, in pancreatic islets from adult control rats and animals (STZ rats) injected with streptozotocin during the neonatal period. The latter animals, which represent a current model of type-2 diabetes, displayed a lower body weight, higher plasma D-glucose concentration and lower insulinogenic index than control rats. The protein, DNA and insulin content were all also lower in islets prepared from STZ, rather than control rats. In the presence of 10.0 mM D-glucose, the paired ratio between D-[U-14C]glucose oxidation and D-[5-3H]glucose utilization was also decreased in the islets from STZ rats. No significant difference between control and STZ rats was observed, however, in terms of the ratios between D-[3-3H]glucose and D-[5-3H]glucose utilization, between the generation of radioactive lactate from 14C-labelled D-glucose and tritiated D-glucose utilization and between D-[1-14C]glucose and D-[6-14C]glucose oxidation. These findings reinforce the view that the previously documented preferential impairment of the oxidative modality of glycolysis in islets from STZ rats contrasts with the absence of any major anomaly in other variables of D-glucose catabolism.     

Assessment of mitochondrial function in cells grown in tissue culture.

To assess mitochondrial function (pyruvate dehydrogenase [PDH] activity), cells were grown in the appropriate media to confluence, rinsed and incubated in glucose free media containing 25 microM L-lactate and [1-14C]-D,L-lactate. Lactate oxidation was measured as the amount of lactate oxidized in nmol of 14CO2 generated per mg of protein per minute. Basal activity varied with cell number and the cell type studied: fibroblast 2.26 +/- 0.01; Chinese hamster ovary (CHO) 42 +/- 0.4; BC3H-1 52 +/- 2.1 nmol per mg per minute. The CHO cells screened for PDH activity decreased their dependence on lactate as a substrate in the presence of 5mM glucose by 60 percent. Increasing the cold lactate concentration diluted the labelled lactate available for pyruvate oxidation in a dose dependent manner. The mitochondrial inhibitor rotenone (25 microM) decreased assay activity by > 75 percent in CHO and BC3H-1 cells. The lactate oxidation assay was shown to be sensitive enough to measure insulin stimulation of PDH in a dose dependent manner with maximum activity occurring at concentrations between 1 microU per ml and 100 microU per ml.     

Altered metabolic priming by D-glucose in pancreatic islets from Goto-Kakizaki rats

The possible priming by D-glucose of metabolic events in islets from control rats and Goto-Kakizaki rats (GK rats) was investigated by first incubating the islets for 120 min either in the absence of any exogenous nutrient or presence of 16.7 mM D-glucose. The islets were then incubated for a second period of 120 min either at 2.8 mM or 16. 7 mM D-glucose, the hexose being now mixed with tracer amounts of D-[U-14C]glucose and D-[5-3H]glucose. In islets from control rats first incubated in the absence of exogenous nutrient the hierarchy in the 16.7 mM/2.8 mM ratio for metabolic variables was as follows: D-[U-14C]glucose oxidation > D-[5-3H]glucose utilization and D-[U-14C]glucose conversion to amino acids > D-[U-14C]glucose conversion to acidic metabolites. When the islets from control rats were first incubated in the presence of 16.7 mM D-glucose, the preferential stimulation of mitochondrial oxidative events at high hexose concentration, as documented by the increase in the paired ratio between D-[U-14C]glucose oxidation and D-[5-3H]glucose utilization, was further enhanced. The 16.7 mM/2.8 mM ratio for the conversion of D-[U-14C]glucose to amino acids, relative to that for D-[U-14C]glucose conversion to acidic metabolites, was much lower, however, after a first incubation in the presence of D-glucose, rather than in its absence, probably as a result of the progressive exhaustion of endogenous amino acids considered as transamination partners. The major differences between these results and those obtained in islets from GK rats consisted, in the latter animals, in i) higher absolute values for all metabolic fluxes, ii) lower 16.7 mM/ 2.8 mM ratios, iii) lower paired ratio between D-[U-14C]glucose oxidation and D-[5-3H]glucose utilization, and iv) absence of a priming effect of D-glucose (16.7 mM) upon such a paired ratio in the islets incubated at 16.7 mM D-glucose during the second incubation. Taken as a whole, these observations confirm that the preferential stimulation of mitochondrial oxidative events, in response to a rise in D-glucose concentration, is impaired in islets from GK rats and extend this knowledge to the priming action of D-glucose, in high concentration, on the catabolism of the hexose during a subsequent incubation.     

Ketone bodies effectively compete with glucose for neuronal acetyl‐CoA generation in rat hippocampal slices

Ketone bodies can be used for cerebral energy generation in situ, when their availability is increased as during fasting or ingestion of a ketogenic diet. However, it is not known how effectively ketone bodies compete with glucose, lactate, and pyruvate for energy generation in the brain parenchyma. Hence, the contributions of exogenous 5.0 mM [1‐¹³C]glucose and 1.0 mM [2‐¹³C]lactate + 0.1 mM pyruvate (combined [2‐¹³C]lactate + [2‐¹³C]pyruvate) to acetyl‐CoA production were measured both without and with 5.0 mM [U‐¹³C]3‐hydroxybutyrate in superfused rat hippocampal slices by ¹³C NMR non‐steady‐state isotopomer analysis of tissue glutamate and GABA. Without [U‐¹³C]3‐hydroxybutyrate, glucose, combined lactate + pyruvate, and unlabeled endogenous sources contributed (mean ± SEM) 70 ± 7%, 10 ± 2%, and 20 ± 8% of acetyl‐CoA, respectively. With [U‐¹³C]3‐hydroxybutyrate, glucose contributions significantly fell from 70 ± 7% to 21 ± 3% (p < 0.0001), combined lactate + pyruvate and endogenous contributions were unchanged, and [U‐¹³C]3‐hydroxybutyrate became the major acetyl‐CoA contributor (68 ± 3%) – about three‐times higher than glucose. A direct analysis of the GABA carbon 2 multiplet revealed that [U‐¹³C]3‐hydroxybutyrate contributed approximately the same acetyl‐CoA fraction as glucose, indicating that it was less avidly oxidized by GABAergic than glutamatergic neurons. The appearance of superfusate lactate derived from glycolysis of [1‐¹³C]glucose did not decrease significantly in the presence of 3‐hydroxybutyrate, hence total glycolytic flux (Krebs cycle inflow + exogenous lactate formation) was attenuated by 3‐hydroxybutyrate. This indicates that, under these conditions, 3‐hydroxybutyrate inhibited glycolytic flux upstream of pyruvate kinase. Copyright © 2015 John Wiley & Sons, Ltd.     

Influence of altered O2 tension on substrate metabolism in perfused rat lung.

Effects of hypoxia (1.5 h) on glucose and palmitate metabolism were investigated in perfused lungs from normal rats and rats exposed for 24 h to hypobaric conditions (simulated altitude of 24,000 ft). Hypoxic lungs were ventilated with 5% O2-5% CO2 and control lungs with 21% O2-5% CO2. Blood gases and pH remained stable during the 1.5-h perfusion period. Exposure of normal rat lungs to 1.5 h of in vitro hypoxia (blood Po2=34 mmHg) significantly increased lactate production and mean arterial pulmonary pressure, but did not alter glucose uptake, pyruvate levels, and oxidation of either [U-14C]glucose or [1-14C]palmitate to CO2. Incorporation of labeled glucose and palmitate into lung lipids was also unaltered. In contrast to normal lungs, prior exposure to hypoxia for 24 h and subsequent perfusion under hypoxic conditions significantly stimulated glucose uptake (74% increase), markedly increased glucose incorporation into lung lipids, and increased oxidation of glucose to CO2. Lactate/pyruvate ratios also showed a significant 38% increase. Lung glycogen was unchanged following 24 h hypoxia. These data indicate that adaptive changes occur in metabolic processes within the lung during acute changes in O2 tension.     

31P NMR and enzymatic analysis of cytosolic phosphocreatine, ATP, Pi and intracellular pH in the isolated working perfused rat heart.

Hearts from fed male Wistar rats (200-350 g) were perfused at low and high workloads with Pi-free Krebs-Henseleit medium containing either 10 mM glucose or 10 mM glucose plus 15 mU/mL insulin. The intracellular pH by 31P NMR ranged between 6.99 and 7.02 and agreed to within 0.1 pH unit of estimates calculated using enzymatically determined total tissue HCO3-/CO2 contents. At high work, where the tissue contents of phosphocreatine (PCr) and ATP were determined on the same heart as NMR areas (n = 16), the proportionality factors, defined as the 31P NMR area units divided by the total enzymatically determined tissue content (area units/mumol/g dry wt), were 112 +/- 8 for PCr, 99 +/- 4 for gamma-ATP, 138 +/- 9 for alpha-ATP and 100 +/- 4 for beta-ATP. These values were normalized by taking beta-ATP as 100 area units/mumol/g dry wt. Since the proportionality factor for PCr and gamma- and beta-ATP were not statistically different (p less than 0.05), it was concluded that each was equally visible by 31P NMR and that no significant breakdown of PCr occurred during freezing or tissue acid extraction procedures. The cytosolic Pi estimated from NMR in glucose plus insulin perfused hearts at low and high work was 4.92 +/- 0.67 and 6.33 +/- 0.42 mumol/g dry wt. Using the near-equilibrium expression of KCK/KG + G and the metabolite levels in heart extracts, the calculated cytosolic Pi was 13.08 +/- 1.83 and 16.17 +/- 3.08 mumol/g dry wt, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Carbohydrate metabolism of the rat C6 glioma. An in vivo 13C and in vitro 1H magnetic resonance spectroscopy study

Surface coil 13C nuclear magnetic resonance (NMR) spectroscopy was used to investigate the in vivo carbohydrate metabolism of rat C6 gliomas during and after infusion with [1-13C] glucose. In vivo 1H-decoupled 13C NMR spectra of the glioma following infusion with [1-13C]glucose revealed the direct production of [3-13C]lactic acid, [1-13C]glycogen, and [4-13C], [3-13C], and [2-13C]glutamate/glutamine. Lactate levels of in vivo gliomas increased and reached steady state levels during [1-13C]glucose infusion, and decreased following termination of infusion. Complementary in vitro studies using supernatant media collected from C6 glioma cells incubated with media containing [1-13C] or [6-13C]glucose and glutamine were examined by 1H NMR spectroscopy. The [3-(13C/12C)]lactate ratios obtained from 1H spectra of supernatant media containing [1-13C]glucose revealed the percentage of glucose metabolized through the hexose monophosphate shunt to be 10.01 +/- 0.85% (n = 3), while similar measurements of media containing [6-13C]glucose and glutamine showed that glutaminolysis contributed 9.0 +/- 1.0% of total lactate production under these conditions. Enzymatic analysis of media determined lactate production to be 139 +/- 9 nmol per 10(6) cells per h (n = 4). These measurements demonstrate the ability of NMR to monitor brain tumor carbohydrate metabolism both in vitro and in vivo.     

Substrate utilization and oxygen consumption by canine jejunal mucosa in vitro.

Oxygen consumption, carbon dioxide production, and substrate utilization by small pieces of canine jejunal mucosa have been measured in vitro. In the absence of added substrate, the Qo2 was 0.21 mumol/h per mg dry wt and the respiratory quotient (RQ) was 0.73 indicating the endogenous substrate to be lipid in nature. When glucose or galactose was added, Qo2 and RQ increased. Metabolism of the endogenous substrate was depressed by fructose but not by glucose or galactose. Less than 15% of the metabolized glucose and fructose was degraded to Co2; 80% of the metabolized glucose was recovered as lactate. Galactose disappeared at one-seventh the rate of glucose, but 40% of that metabolized was degrated to CO2. In all experiments Qo2 showed marked cyclic fluctuations with an amplitude of 30-40% of the mean value and a period of 30-40 min. For tissues from a single animal, the cycles were in phase on a clock time basis, indicating that the cycles were synchronized by some in vivo mechanism.     

Metabolism of D-[1,2-13C]glucose and alpha-D-[1,2-13C]glucose pentaacetate in tumoral pancreatic islet cells

Tumoral pancreatic islet cells of the RINm5F line were incubated, in groups of 25x106 cells each, for 120 min at 37 degrees C in media (5. 0 ml) containing either alpha-D-[1,2-13C]glucose pentaacetate (1.7 mM) or both D-[1,2-13C]glucose (1.7 mM) and acetate (8.5 mM). In both cases, the amounts of 13C-enriched metabolites (D-glucose, L-lactate and acetate) and non-enriched metabolites (acetate) recovered in the incubation medium after incubation were close to the initial amount of esterified or non-esterified D-[1, 2-13C]glucose and acetate, respectively. The 13C-enriched metabolites corresponded mainly to double-labelled D-[1, 2-13C]glucose, L-[2,3-13C]lactate and [1,2-13C]acetate. The output of L-[2,3-13C]lactate and [1,2-13C]acetate was about 3-4 times lower in the cells exposed to alpha-D-[1,2-13C]glucose pentaacetate than in those incubated with unesterified D-[1,2-13C]glucose. These findings indicate that, despite extensive hydrolysis of alpha-D-[1, 2-13C]glucose pentaacetate in the RINm5F cells, the hexose moiety of the ester is less efficiently metabolized than unesterified D-[1, 2-13C]glucose tested at the same molar concentration (1.7 mM) in the presence of 8.5 mM acetate. Thus, a higher utilization of the hexose moiety of alpha-D-glucose pentaacetate than that of unesterified D-glucose, as previously documented in isolated pancreatic islets, represents a far-from-universal situation.     

Effect of in vivo exposure to insulin on glucose metabolism in rat aorta

The effect of administration of insulin in vivo on accumulation of [14C]glucose carbon in rat aorta in vitro was studied. Insulin was injected intravenously in a tail vein 5-60 min before the rats were killed and the accumulation of [14C]glucose was determined after incubation for 30-120 min in 5.6 mM [14C]glucose. When determined 30 min after injection of insulin (4 U kg-1) the aortic [14C]glucose incorporation was significantly increased when an incubation period of 120 min was used, while no significant effect was found after incubation for 30 or 60 min. In subsequent experiments an incubation time of 120 min was used. The aortic [14C]glucose accumulation was not increased when determined 5 or 60 min after injection of insulin (4 U kg-1). Injection of insulin (2 U kg-1) 5 or 30 min before the rats were killed had no effect on the aortic [14C]glucose accumulation but it had a pronounced effect on [14C]glucose accumulation in rat diaphragm. Serum insulin determined 30 min after injection of insulin (2 U kg-1) was 731 +/- 58 mU-1 and in saline-treated control rats 37 +/- 3 mU l-1. These results suggest that the glucose metabolism of vascular smooth muscle has a low sensitivity to the immediate effects of insulin.     

Effect of fasting and refeeding on glucose metabolism in rat aorta

The effect of refeeding on accumulation of [14C]glucose carbon, oxidation of [14C]glucose and glycogen concentration in rat aortic intima-media was studied in rats fasted for 3 days. Accumulation of glucose carbon and glucose oxidation were determined by incubating rat aorta in vitro for 2 h with 5.6 mM 14C-labelled glucose in the medium. Refeeding with standard pellets for 2-4 h augmented [14C]glucose accumulation in rat aorta but had no significant effect on glucose oxidation. The glycogen concentration in rat aorta tended to increase. After refeeding for 16 h both [14C]glucose incorporation and [14C]glucose oxidation were increased in rat aorta. Refeeding with carbohydrate-rich pellets (92% carbohydrate) for 3 h increased blood glucose more than did protein-rich (92% protein) pellets, whereas the rise in plasma insulin was about the same. The accumulation of [14C]glucose carbon measured during the subsequent in vitro incubation for 2 h was augmented after refeeding with protein-rich pellets and slightly reduced after carbohydrate-rich pellets. Refeeding of diabetic rats for 2 h with standard pellets increased plasma insulin and markedly increased blood glucose but had no effect on aortic [14C]glucose incorporation. Intravenous infusion of glucose in normal rats for 2 h markedly raised blood glucose but did not increase the aortic glucose incorporation. Raising the ambient glucose concentration from 5 to 10 mM during incubation of normal rat aorta in vitro for 2 h slightly decreased the [14C]glucose incorporation determined during a subsequent incubation for 2 h. These results suggest that refeeding with standard pellets augments glucose incorporation and glucose oxidation in rat aorta.(ABSTRACT TRUNCATED AT 250 WORDS)     

De novo synthesis of alanine by the perfused rat hindlimb.

Due to the disproportionately large production of alanine by muscle, it has been suggested that part of the alanine released by muscle is synthesized de novo by the transamination of glucose-derived pyruvate. This glucose-alanine conversion was quantitated in the isolated rat hindlimb perfused with a solution of bicarbonate buffer containing 2% albumin, 2.4% dextran, 2.5-15.9 mM glucose, 32-34% dog erythrocytes, and 0.05 muCi/ml [14C]glucose. Measurement of labeled alanine production allowed quantitation of de novo alanine synthesis. De novo derived alanine accounted for an average of 33% of the total alanine released by the perfused tissue (perfusate glucose concentration 8.3 mM), concurrently 2.7% of the glucose taken up by the limb was converted to alanine. By increasing the glucose concentration perfusing the muscle, both the rate of glucose uptake and de novo alanine release were increased. Addition of insulin to the perfusate (700 muU/ml) resulted in a significant increase in the rate of glucose uptake and de novo alanine production, but the rate of total alanine release was significantly decreased by the hormone. It was concluded that de novo alanine production accounts for a sizeable portion of the total alanine released by muscle, nevertheless a comparatively small fraction of the glucose carbons are actually transformed to alanine.     

Gluconeogenesis from alanine in vivo by the ovine fetus and lamb

Gluconeogenesis from alanine was determined with an intravenous infusion of [U-14C]alanine and [6-3H]glucose or [U-14C]glucose in five fetal lambs (3.6 +/- 0.1 kg; 127 days of gestation) and four growing ewe lambs (37 +/- 2 kg). Conversion of alanine to glucose (mmol/h) was 0.40 +/- 0.12 and 0.51 +/- 0.10 and accounted for 7.3 and 25.6% of the alanine turnover in fetal and growing lambs, respectively. Alanine contributed 2.3 and 1.1% of the glucose turnover and 22.3 and 1.1% of the lactate turnover in fetal and growing lambs, respectively. Lactate contributed 19.5% of the glucose turnover in growing lambs, and glucose synthesis from lactate accounted for 24.7% of the lactate turnover. Glucose turnover (mmol/h) was 10.2 and 25.1 in fetal and growing lambs, respectively. Results from these studies have shown that the fetal lamb at 127 days of gestation has a high rate of alanine turnover and conversion to glucose when compared with that of the growing lamb on a high plane of nutrition.     

Isomeric and anomeric specificity of the metabolic and secretory response of rat pancreatic islets to glucose pentaacetate.

In the presence of 2.8 mM D-glucose, beta-D-glucose pentaacetate (1. 7 mM) augmented insulin release from isolated rat pancreatic islets more than alpha-D-glucose pentaacetate. Likewise, the further increment in insulin output evoked by nateglinide (0.01 mM) was higher in islets exposed to beta- rather than alpha-D-glucose pentaacetate. Inversely, in the presence of 2.8 mM unesterified D-glucose, alpha-L-glucose pentaacetate, but not beta-L-glucose pentaacetate, significantly augmented insulin output. The higher insulinotropic potency of the beta-anomer of D-glucose pentaacetate coincided with the fact that it significantly increased the paired ratio between D-[U-14C]glucose oxidation and D-[5-3H]glucose utilization, whereas alpha-D-glucose pentaacetate failed to do so. These findings are interpreted to support the concept that the stimulation of insulin release by these esters is largely attributable to their direct interaction with a stereospecific receptor, with preference for the configuration of the C1 common to beta-D-glucose pentaacetate and alpha-L-glucose pentaacetate.     

Effects of gliquidone on D-glucose metabolism in rat pancreatic islets depend on hexose concentration

The hypoglycemic sulfonylurea gliquidone, used at a 10 microM concentration, failed to affect the metabolism of D-glucose in rat pancreatic islets incubated in the presence of 5.6 mM, 8.3 mM or 16.7 mM D-glucose. However, at 2.8 mM D-glucose, gliquidone increased D-[U-14C]glucose oxidation while decreasing the utilization of D-[5-3H]glucose and generation of radioactive acidic metabolites and amino acids from D-[U-14C]glucose. These dissociated effects could conceivably be attributable, respectively, to activation of FAD-linked glycerophosphate dehydrogenase as a result of an increase in cytosolic Ca2+ concentration and to a subsequent inhibition of phosphofructokinase as a result of an increase in cytosolic ATP concentration. The effect of gliquidone on the paired ratio between D-[U-14C]glucose oxidation and D-[5-3H]glucose utilization was indeed duplicated by repaglinide and suppressed in the absence of extracellular Ca2+ or at low temperature. The present findings thus provide a further illustration of the often contrasting effects of pharmacological and physiological insulinotropic agents on selected metabolic, cationic and functional variables in pancreatic islet cells.