Enhanced 2-deoxy-D-glucose uptake and metabolism in splenocytes from diabetic and diabetes-prone BB rats. Further evidence to support prior in vivo activation

Glucose metabolism in splenocytes from the BB rat was studied for the presence of abnormalities in [14C] 2-deoxy-D-glucose (2-dGlc) uptake, [U-14C]glucose conversion to 14CO2, and the production of lactate and pyruvate. Cells were studied freshly isolated ("resting"), and following culture both unstimulated (control) and stimulated with concanavalin A (ConA) or phorbol myristate acetate (PMA) + ionomycin. Both resting and control cells from diabetic (BBd) and diabetes-prone (BBdp) rats transported more (p less than 0.05) 2-dGlc than did cells from nondiabetes-prone (BBn) rats. Consistent with prior in vivo activation, sustained in vitro, lactate production was higher (p less than 0.05) under control conditions in BBd and BBdp than in BBn cells. Lactate production increased less with ConA and PMA + ionomycin in both BBd and BBdp than in BBn cells. PMA + ionomycin increased 2-dGlc uptake as much in BBd and BBdp cells as in BBn cells. Elevated rates of pyruvate production were observed in BBd cells under resting, control, and (especially) ConA conditions, suggesting an abnormality in pyruvate conversion to lactate. Few changes were observed in 14CO2 production. The presence of similar abnormalities in BBdp cells to those of the BBd cells suggests that the diabetic state is not causal, and the absence of an in vitro effect of 15 mmol/liter glucose in BBn cells further tends to exclude hyperglycemia as a cause of these alterations.     

Lactate production is the major metabolic fate of glucose in splenocytes and is altered in spontaneously diabetic BB rats.

Enhanced glucose metabolism is necessary to support the activation and proliferation of lymphocytes. To define further quantitatively the metabolic fates of glucose and assess glucose utilization both in normal cells and in an autoimmune disease with abnormal lymphocytes, [U-14C]glucose conversion into 14CO2 and the production of lactate and pyruvate were measured in splenocytes. Cells from non-diabetes-prone (BBn) and spontaneously diabetic (BBd) rats were studied both freshly isolated 'resting' and cultured for 96 h with and without concanavalin A (Con A) stimulation. (1) Lactate was confirmed to be the major end product in both freshly isolated (53% of utilized glucose) and unstimulated cultured (62% of utilized glucose) cells from BBn animals studied at (2-8) x 10(6) cells/ml concentration. The use of concentrations from 10 x 10(6) to 300 x 10(6) cells/ml resulted in progressively less lactate production per 10(6) splenocytes. (2) Cells from BBd animals after stimulation with Con A incorporated less [3H]thymidine and produced significantly less lactate (155 +/- 14 versus 305 +/- 24 nmol/2 h per 10(6) cells) than did BBn cells (P less than 0.05). (3) However, more lactate (101 +/- 8 versus 78 +/- 6 nmol/5 h per 10(6) cells) was produced by 'resting' cells from BBd animals compared with BBn (P less than 0.03), and this difference was sustained after 4 days in culture. (4) Significantly greater amounts of pyruvate were produced by BBd than by BBn cells, particularly when stimulated with Con A, suggesting an alteration in the availability of reducing equivalents in BBd cells. (5) These results are consistent with prior metabolic as well as immunological 'activation' of cells in vivo in the BB diabetic animals.     

Abnormal thymocyte maturation in spontaneously diabetic BB rats involves the deletion of CD4-8+ cells.

The object of this study was to further characterize the pathophysiology of the peripheral T lymphopenia in the BB rat. Towards this end, surface markers on unseparated thymocytes and purified thymocyte subsets from age- and sex-matched diabetes-resistant (BBn) and diabetes-prone (BBd) rats were analyzed by two-color flow cytometry. The proportions of thymocytes falling into each of the four main phenotypic subsets were comparable in BBn (n = 9) and BBd (n = 8) rats: respectively, 4.6 +/- 0.6% and 4.4 +/- 0.8%, CD4-8-; 68.1 +/- 1.9% and 71.1 +/- 3.2%, CD4+8+; 18.3 +/- 1.5% and 15.4 +/- 2.3%, CD4+8-; 9.1 +/- 0.9% and 9.1 +/- 1.0%, CD4-8+. In addition, absolute numbers of thymocytes were not significantly different. The levels of expression of CD4, TCR-alpha beta within each thymocyte subset were comparable in BBn and BBd animals as were the anti-TCR-induced proliferative responses of their CD4+8- and CD4-8+ thymocytes. However, phenotypic abnormalities within the CD4-8+ thymocyte subset of the BBd rat were found. A very significant (p less than 0.005) deletion of mature CD4-8+, TCR-alpha beta + thymocytes and a proportional increase (p less than 0.005) of immature CD4-8+, TCR-alpha beta low thymocytes. Moreover, a twofold decrease of CD8 expression by mature CD4-8+ thymocytes was observed in BBd animals. These results suggest that an impaired thymic maturation contributes to the peripheral T lymphopenia of the BBd rat.     

Effect of alpha-phenyl-N-tert-butylnitrone on diabetes and lipid peroxidation in BB rats.

Oxygen free radicals have been shown to interfere with pancreatic islet beta cell function and integrity, and have been implicated in autoimmune type 1 diabetes. We hypothesized that the spontaneous autoimmune type 1 diabetes of the BB rat would be prevented by in vivo administration of a free-radical spin trap, alpha-phenyl-N-tert-butylnitrone (PBN). Twenty-eight diabetes-prone (BBdp) and 13 non-diabetes-prone (BBn) rats received PBN (10 mg/kg) subcutaneously twice daily, and 27 BBdp and 12 BBn rats received saline as controls. Rats were treated from age 47 +/- 6 days until diabetes onset or age 118 +/- 7 days. PBN caused no growth, biochemical, or hematological side effects. Sixteen control BBdp rats became diabetic (BBd, mean age 77 +/- 6 days) and six demonstrated impaired glucose tolerance (IGT rats). The incidence of diabetes and IGT was not different in PBN-treated BBdp rats. Saline-treated rats showed no differences in pancreatic malondialdehyde (MDA) contents of BBd, IGT rats, and the BBdp that did not develop diabetes, versus BBn rats (2.38 +/- 0.35 nmoL/g). Among rats receiving PBN, BBn had lower pancreatic MDA than BBd and IGT rats (1.38 +/- 0.15 vs. 1.88 +/- 0.15 and 2.02 +/- 0.24 nmoL/g, p < 0.05), but not than BBdp rats (1.78 +/- 0.12 nmoL/g, ns). BBn rats receiving PBN also had lower pancreatic MDA than the saline controls (p < 0.05). Thus, PBN is remarkably nontoxic and is able to decrease MDA in the absence of the autoimmune process, but does not prevent diabetes. A combination of PBN with other complementary antioxidant agents may hold better promise for disease prevention.     

Effects of deflazacort and the L-6485 metabolite on epiphyseal cartilage carbohydrate metabolism: comparison with prednisone

Male Sprague-Dawley rats were injected with 1 mg/100 g bw/day of prednisone, 1.25 mg/1--g bw/day of deflazacort, or its metabolite, for a period of 20 days. Epiphyseal cartilage slices were incubated in a modified Krebs Ringer bicarbonate buffer, at 37 degrees C for 60 min, with either 14C-1- or 14C-6-glucose to quantitate both the absolute and relative rates of pentose shunt versus aerobic and anaerobic glycolytic activity, respectively. Measurements of both total and radioactive glucose uptake, lactate production and 14CO2 generation were expressed as either mumoles or DPM/mg cellular DNA/hr, respectively. This study demonstrated: (1) chronic prednisone administration decreased anaerobic glycolysis (glucose uptake and lactate production) 3-fold (P less than 0.01); (2) prednisone on a chronic basis produced no measured alteration in either the pentose shunt or Kreb's cycle activity; (3) both deflazacort and the deflazacort metabolite significantly stimulated (P less than 0.02) anaerobic glycolytic activity in epiphyseal cartilage tissue. In contrast to prednisone, the administration of either deflazacort or its L-6485 metabolite did not inhibit the glycolytic pathway of metabolism so necessary for epiphyseal cartilage growth and mineralization.     

Metabolic-flux analysis of continuously cultured hybridoma cells using (13)CO(2) mass spectrometry in combination with (13)C-lactate nuclear magnetic resonance spectroscopy and metabolite balancing

Protein production of mammalian-cell culture is limited due to accumulation of waste products such as lactate, CO(2), and ammonia. In this study, the intracellular fluxes of hybridoma cells are measured to determine the amount by which various metabolic pathways contribute to the secretion of waste products derived from glucose. Continuously cultured hybridoma cells are grown in medium containing either 1-(13)C-, 2-(13)C-, or 6-(13)C-glucose. The uptake and production rates of amino acids, glucose, ammonia, O(2), and CO(2) as well as the cellular composition are measured. In addition, the (13)C distribution of the lactate produced and alanine produced by the hybridomas is determined by (1)H-NMR spectroscopy, and the (13)CO(2)/(12)CO(2) ratio is measured by on-line mass spectrometry. These data are used to calculate the intracellular fluxes of the glycolysis, the pentose phosphate pathway, the TCA cycle, and fluxes involved in amino acid metabolism. It is shown that: (i) approximately 20% of the glucose consumed is channeled through the pentose shunt; (ii) the glycolysis pathway contributes the most to lactate production, and most of the CO(2) is produced by the TCA cycle; (iii) the pyruvate-carboxylase flux is negligibly small; and (iv) the malic-enzyme flux is estimated to be 10% of the glucose uptake rate. Based on these flux data suggestions are made to engineer a more efficient glucose metabolism in mammalian cells.     

Interrelationship and control of glucose metabolism and lipogenesis in isolated fat-cells. Effect of the amount of glucose uptake on the rates of the pentose phosphate cycle and of fatty acid synthesis

In order to study the quantitative relationship between fatty acid synthesis and pentose phosphate-cycle activity under different hormonal and dietary conditions affecting the extent of glucose uptake, cells isolated from rat epididymal adipose tissue were incubated in bicarbonate buffer containing [U-(14)C]-, [1-(14)C]- or [6-(14)C]-glucose. From the amount of glucose taken up, the production of lactate and pyruvate, and the incorporation of (14)C from differently labelled [(14)C]glucose into CO(2), fatty acids and glyceride glycerol, the rates of glucose metabolism via different pathways and the extent of lipogenesis under various experimental conditions were determined. The contribution of the pentose phosphate-cycle to glucose metabolism under normal conditions was calculated to be 8%. Starvation and re-feeding, and the presence of insulin, caused an enhancement of glucose uptake, pentose phosphate-cycle activity and fatty acid synthesis. Plots of both pentose phosphate-cycle activity and fatty acid synthesis versus glucose uptake revealed that the extent of glucose uptake, over a wide range, determines the rates of fatty acid synthesis and glucose metabolism via the pentose phosphate cycle. A balance of formation and production of nicotinamide nucleotides in the cytoplasm was established. The total amount of cytoplasmic NADH and NADPH formed was only in slight excess over the hydrogen equivalents required for the synthesis of fatty acids, glyceride glycerol and lactate. Except in cells from starved animals, the pentose phosphate cycle was found to provide only about 60% of the NADPH required for fatty acid synthesis. The results are discussed with respect to an overall control of the different metabolic and biosynthetic reactions in the fat-cells by the amount of glucose transported into the cell.     

Insulin stimulates glucose metabolism via the pentose phosphate pathway in Drosophila Kc cells

Drosophila melanogaster has become a prominent and convenient model for analysis of insulin action. However, to date very little is known regarding the effect of insulin on glucose uptake and metabolism in Drosophila. Here we show that, in contrast to effects seen in mammals, insulin did not alter [(3)H]2-deoxyglucose uptake and in fact decreased glycogen synthesis ( approximately 30%) in embryonic Drosophila Kc cells. Insulin significantly increased ( approximately 1.5-fold) the production of (14)CO(2) from D-[1-(14)C]glucose while the production of (14)CO(2) from D-[6-(14)C]glucose was not altered. Thus, insulin-stimulated glucose oxidation did not occur via increasing Krebs cycle activity but rather by stimulating the pentose phosphate pathway. Indeed, inhibition of the oxidative pentose phosphate pathway by 6-aminonicotinamide abolished the effect of insulin on (14)CO(2) from D-[U-(14)C]glucose. A corresponding increase in lactate production but no change in incorporation of D-[U-(14)C]glucose into total lipids was observed in response to insulin. Glucose metabolism via the pentose phosphate pathway may provide an important source of 5'-phosphate for DNA synthesis and cell replication. This novel observation correlates well with the fact that control of growth and development is the major role of insulin-like peptides in Drosophila. Thus, although intracellular signaling is well conserved, the metabolic effects of insulin are dramatically different between Drosophila and mammals.     

Effects of prostaglandin E2, indomethacin and adenosine deaminase on basal and insulin-stimulated glucose metabolism in human adipocytes

The effects of prostaglandin E2 were studied on glucose metabolism (3-O-methylglucose transport, CO2 production and lipogenesis) in human adipocytes. Initially, the effects of endogenously produced adenosine and prostaglandins were indirectly demonstrated by using adenosine deaminase and indomethacin in the incubations. From these studies it was found that adenosine deaminase (5 micrograms/ml) had a pronounced effect on adipocyte glucose metabolism in vitro. In the basal (nonhormonal-stimulated) state, glucose transport, CO2 production and lipogenesis were inhibited by about 30% (P less than 0.05). Furthermore, adenosine deaminase significantly inhibited the isoproterenol- and insulin-stimulated CO2 production and lipogenesis (P less than 0.01). Indomethacin (50 microM) had a consistently inhibitory effect on the insulin-stimulated CO2 production (P less than 0.05), whereas indomethacin had no significant effects on basal or isoproterenol-stimulated glucose metabolism. In contrast to the relatively minor effect of endogenous prostaglandins, the addition of exogenous prostaglandin E2 significantly stimulated the glucose transport, glucose oxidation and lipogenesis in human adipocytes, especially in the presence of adenosine deaminase. Half-maximal stimulation was obtained at prostaglandin E2 concentrations of 2.2, 0.8 and 0.8 nM, respectively. The effect of prostaglandin E2 was specific, since the structurally related prostaglandin, prostaglandin F2 alpha, had practically no effect on glucose metabolism. The maximal effect of prostaglandin E2 (1 microM) on glucose metabolism was 30-35% of the maximal insulin (1 nM) effect. When insulin and prostaglandin E2 were added together, the effect of prostaglandin E2 on glucose metabolism was additive at all insulin concentrations tested.     

Eicosapentaenoic fatty acid increases leptin secretion from primary cultured rat adipocytes: role of glucose metabolism

Eicosapentaenoic acid (EPA), one of the n-3 polyunsaturated fatty acids, has been shown to stimulate leptin mRNA expression and secretion in 3T3-L1 cells. However, other studies have reported inhibitory effects of EPA on leptin expression and secretion in vivo and in vitro. To determine the direct effects of EPA on basal and insulin-stimulated leptin secretion, isolated rat adipocytes were incubated with EPA in the absence and presence of insulin. EPA (10, 100, and 200 microM) increased basal leptin gene expression and secretion (+43.8%, P < 0.05; +71.1%, P < 0.01; and +73.7%, P < 0.01, respectively). EPA also increased leptin secretion in the presence of 1.6 nM insulin; however, the effect was less pronounced than in the absence of it. Because adipocyte glucose and lipid metabolism are involved in the regulation of leptin production, the metabolic effects of this fatty acid were also examined. EPA (200 microM) increased basal glucose uptake in isolated adipocytes (+50%, P < 0.05). Anaerobic metabolism of glucose, as assessed by lactate production and proportion of glucose metabolized to lactate, has been shown to be inversely correlated to leptin secretion and was decreased by EPA in both the absence and presence of insulin. EPA increased basal glucose oxidation as determined by the proportion of (14)C-labeled glucose metabolized to CO(2). Lipogenesis ((14)C-labeled glucose incorporation into triglyceride) was decreased by EPA in the absence of insulin, whereas lipolysis (glycerol release) was unaffected. The EPA-induced increase of basal leptin secretion was highly correlated with increased glucose utilization (r = +0.89, P < 0.01) and inversely related to the anaerobic glucose metabolism to lactate. EPA's effect on insulin-stimulated leptin secretion was not related to increased glucose utilization but was inversely correlated with anaerobic glucose metabolism to lactate (r = -0.84, P < 0.01). Together, the results suggest that EPA, like insulin, stimulates leptin production by increasing the nonanaerobic/oxidative metabolism of glucose.     

Glutamine and glucose metabolism in thymocytes from normal and spontaneously diabetic BB rats.

Metabolism of glutamine and glucose was studied in thymocytes from normal rats and BB rats with the spontaneous autoimmune diabetic syndrome to assess their potential roles as fuels. The major measured products from glucose were lactate and, to a lesser extent, CO2, and pyruvate. Glutamine had no effect on the rates of their production from glucose. Glutamine was metabolized to ammonia, aspartate, glutamate, and CO2, with aspartate being the major product of carbons from glutamine in the absence of glucose. Glucose markedly decreased the formation of ammonia, aspartate, and CO2 from glutamine, but increased that of glutamate, with an overall decrease in glutamine utilization by 55%. More glutamate than aspartate was produced from glutamine in the presence of glucose. The potential production of ATP from glucose was similar to that when glutamine was present alone. However, glucose markedly decreased production of ATP from glutamine, but not vice versa. This resulted in ATP production from glucose being 2.5 times that from glutamine when both substrates were present. The oxidation of glucose to CO2 via the Krebs cycle accounts for 75-80% of glucose-derived ATP production. Cellular ATP levels markedly decreased in the absence of exogenous substrates, but were constant throughout a 2-h incubation in the presence of glutamine, glucose, or both. There were no differences in thymocyte glucose or glutamine metabolism between normal and diabetic BB rats, in contrast to previous findings in peripheral lymphoid organs. Our results suggest that glucose is a more important fuel than glutamine for "resting" thymocytes, again in contrast to the cells of peripheral lymphoid organs in which glutamine is as important as glucose as a fuel.(ABSTRACT TRUNCATED AT 250 WORDS)     

5-3H]glucose overestimates glycolytic flux in isolated working rat heart: role of the pentose phosphate pathway

We set out to study the pentose phosphate pathway (PPP) in isolated rat hearts perfused with [5-3H]glucose and [1-14C]glucose or [6-14C]glucose (crossover study with 1- then 6- or 6- then 1-14C-labeled glucose). To model a physiological state, hearts were perfused under working conditions with Krebs-Henseleit buffer containing 5 mM glucose, 40 microU/ml insulin, 0.5 mM lactate, 0.05 mM pyruvate, and 0.4 mM oleate/3% albumin. The steady-state C1/C6 ratio (i.e., the ratio from [1-14C]glucose to [6-14C]glucose) of metabolites released by the heart, an index of oxidative PPP, was not different from 1 (1.06 +/- 0.19 for 14CO2, and 1.00 +/- 0.01 for [14C]lactate + [14C]pyruvate, mean +/- SE, n = 8). Hearts exhibited contractile, metabolic, and 14C-isotopic steady state for glucose oxidation (14CO2 production). Net glycolytic flux (net release of lactate + pyruvate) and efflux of [14C]lactate + [14C]pyruvate were the same and also exhibited steady state. In contrast, flux based on 3H2O production from [5-3H]glucose increased progressively, reaching 260% of the other measures of glycolysis after 30 min. The 3H/14C ratio of glycogen (relative to extracellular glucose) and sugar phosphates (representing the glycogen precursor pool of hexose phosphates) was not different from each other and was <1 (0.36 +/- 0.01 and 0.43 +/- 0.05 respectively, n = 8, P < 0.05 vs. 1). We conclude that both transaldolase and the L-type PPP permit hexose detritiation in the absence of net glycolytic flux by allowing interconversion of glycolytic hexose and triose phosphates. Thus apparent glycolytic flux obtained by 3H2O production from [5-3H]glucose overestimates the true glycolytic flux in rat heart.     

Metabolism of Lactate in the Rat Brain During the Early Neonatal Period

The metabolism of lactate in isolated cells from early neonatal rat brain has been studied. In these circumstances, lactate was mainly oxidized to CO2, although a significant portion was incorporated into lipids (78% sterols, 4% phosphatidylcholine, 2% phosphatidylethanolamine, and 1% phosphatidylserine). The rate of lactate incorporation into CO2 and lipids was higher than those found for glucose and 3-hydroxybutyrate. Lactate strongly inhibited glucose oxidation through the pyruvate dehydrogenase-catalyzed reaction and the tricarboxylic acid cycle while scarcely affecting glucose utilization by the pentose phosphate pathway. Lipogenesis from glucose was strongly inhibited by lactate without relevant changes in the rate of glycerol phosphate synthesis. These results suggest that lactate inhibits glucose utilization at the level of the pyruvate dehydrogenase-catalyzed reaction, which may be a mechanism to spare glucose for glycerol and NADPH synthesis. The effect of 3-hydroxybutyrate inhibiting lactate utilization only at high concentrations of 3-hydroxybutyrate suggests that before ketogenesis becomes active, lactate may be the major fuel for the neonatal brain. (-)-Hydroxycitrate and aminooxyacetate markedly inhibited lipogenesis from lactate, suggesting that the transfer of lactate carbons through the mitochondrial membrane is accomplished by the translocation of both citrate and N-acetylaspartate.     

Lactate production in adipose tissue: a regulated function with extra-adipose implications.

Estimates of the quantitative contribution of adipose tissue to whole-body glucose metabolism, previously reported as 1-3%, have been revised to be on the order of 10-30%. These revised estimates come, in part, from a recognition that adipose tissue uses glucose to produce lactate and pyruvate, in addition to CO2 and triglycerides. Lactate production by adipose tissue is modulated in vitro by changes in glucose, insulin, and epinephrine concentrations. In vivo, lactate production is regulated acutely by the animal's nutritional state (fed or fasted) and chronically by the degree of obesity. A strong positive correlation exists between rat fat cell size and relative conversion of glucose to lactate (r = 0.89, P less than 0.001). Diabetes is also associated with markedly increased lactate production in adipocytes. Fat cells from obese or diabetic rats (or humans) can metabolize to lactate as much as 50-70% of the glucose taken up. From these recent studies, a picture is emerging in which the adipose organ may provide lactate for hepatic gluconeogenesis during fasting, and also lactate for hepatic glycogen synthesis after food ingestion. Modulation of adipocyte lactate production and contribution of adipose tissue lactate to the body's fuel economy in physiological and pathological states are the focus of this review.     

Glucose metabolism in proliferating epithelial cells from the rat colon.

1. The effects of fasting and fasting followed by refeeding on the activities of the oxidative pentose pathway (OPP) and the tricarboxylic acid cycle (TCA) in isolated rat colonocytes were estimated by the rate of production of 14CO2 from [1-14C]glucose and [6-14C]glucose, respectively. 2. Refeeding after a fast induced a 2-3-fold increase in glucose flux through the OPP and TCA cycle and the degree of change was similar in colonocytes from the proximal and distal colon. 3. Butyrate at a concentration of 40 mM inhibited the OPP by 20-30% (P less than 0.05) but had no effect on the activity of the TCA cycle. Glutamine at a concentration of 2 mM decreased the glucose flux through both the OPP and the TCA cycle by 30-50% (P less than 0.05). 4. Production of 14CO2 from the oxidation of butyrate or glucose indicated that the former was 5-7 times more active in colonocytes from fasted rats. After refeeding, however, butyrate utilization was similar to fasting values in the proximal colon but significantly lower (P less than 0.05) in the distal colon.     

Glucose metabolism by lymphocytes, macrophages, and tumor cells from Walker 256 tumor-bearing rats supplemented with fish oil for one generation

Here we investigated the effect of lifelong supplementation of the diet with coconut fat (CO, rich in saturated fatty acids) or fish oil (FO, rich in n-3 polyunsaturated fatty acids) on tumor growth and lactate production from glucose in Walker 256 tumor cells, peritoneal macrophages, spleen, and gut-associated lymphocytes. Female Wistar rats were supplemented with CO or FO prior to mating and then throughout pregnancy and gestation and then the male offspring were supplemented from weaning until 90 days of age. Then they were inoculated subcutaneously with Walker 256 tumor cells. Tumor weight at 14 days in control rats (those fed standard chow) and CO supplemented was approximately 30 g. Supplementation of the diet with FO significantly reduced tumor growth by 76%. Lactate production (nmol h(-1) mg(-1) protein) from glucose by Walker 256 cells in the group fed regular chow (W) was 381.8 +/- 14.9. Supplementation with coconut fat (WCO) caused a significant reduction in lactate production by 1.6-fold and with fish oil (WFO) by 3.8-fold. Spleen lymphocytes obtained from W and WCO groups had markedly increased lactate production (553 +/- 70 and 635 +/- 150) when compared to non-tumor-bearing rats ( approximately 260 +/- 30). FO supplementation reduced significantly the lactate production (297 +/- 50). Gut-associated lymphocytes obtained from W and WCO groups increased lactate production markedly (280 +/- 31 and 276 +/- 25) when compared to non-tumor-bearing rats ( approximately 90 +/- 18). FO supplementation reduced significantly the lactate production (168 +/- 14). Lactate production by peritoneal macrophages was increased by tumor burden but there was no difference between the groups fed the various diets. Lifelong consumption of FO protects against tumor growth and modifies glucose metabolism in Walker tumor cells and lymphocytes but not in macrophages.     

Glucose metabolism by preimplantation pig embryos

Pig embryos were collected, 2-7 days after oestrus, in modified BMOC-2 containing glucose as the only energy source. Embryos were incubated individually in medium containing [5-(3)H]-, [1-(14)C]- or [6-(14)C]glucose. Total glucose metabolism, as measured by [5-(3)H]glucose use, increased steadily from the 1-cell to the 8-cell stage. Total glucose use increased (P less than 0.05) at the compacted morula stage and was highest (P less than 0.05) at the blastocyst stage. Production of 14CO2 from embryos metabolizing [1-(14)C]glucose increased steadily from the unfertilized ovum to the 8-cell stage. Metabolism of [1-(14)C]glucose increased at the compacted morula stage (P less than 0.05) and continued to increase (P less than 0.05) to the blastocyst stage. Metabolism of [6-(14)C]glucose increased steadily from the unfertilized ovum to the compacted morula stage. Metabolism of [6-(14)C]glucose was highest (P less than 0.05) for the blastocyst stage. Percentage pentose phosphate pathway activity of total glucose metabolism before the 4-cell stage was higher (greater than 5%) than that of 8-cell to blastocyst stage embryos (approximately 1%). When embryo metabolism was determined on a per cell basis for each isotope, the compacted morulae stage (16 cells) had a higher total glucose metabolism than all other embryo stages (P less than 0.05), while early blastocyst (32 cells) and blastocyst (64 cells) stage embryos metabolized more [5-(3)H]glucose than all stages except compacted morulae (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Carbon Balance Studies of Glucose Metabolism in Rat Cerebral Cortical Synaptosomes

Synaptosomes were isolated from rat cerebral cortex and incubated with [U-14C]-, [1-14C]- or [6-14C]glucose. Glucose utilization and the metabolic partitioning of glucose carbon in products were determined by isotopic methods. From the data obtained a carbon balance was constructed, showing lactate to be the main product of glucose metabolism, followed by CO2, amino acids and pyruvate. Measuring the release of 14CO2 from glucose labelled in three different positions allowed the construction of a flow diagram of glucose carbon atoms in synaptosomes, which provides information about the contribution of the various pathways of glucose metabolism. Some 2% of glucose utilized was calculated to be degraded via the pentose phosphate pathway. Addition of chlorpromazine, imipramine or haloperidol at concentrations of 10(-5) M reduced glucose utilisation by 30% without changing the distribution pattern of radioactivity in the various products.     

Epidermal growth factor and 12-O-tetradecanoylphorbol 13-acetate stimulate lactate production and the pentose phosphate pathway in freshly isolated rat hepatocytes

Epidermal growth factor (EGF) and tetradecanoylphorbol acetate (TPA) rapidly stimulated the production of lactate by hepatocytes isolated from fed rats. Our results indicate that enzymes of both glycolysis and the pentose phosphate pathway are involved in these actions. EGF stimulated CO2 release from the 1-position of glucose, and caused a small but significant increase in pyruvate kinase activity. In addition, EGF caused a rise in fructose 1,6-bisphosphate and fructose 2,6-bisphosphate concentrations, indicating activation of phosphofructokinase. TPA did not alter the concentrations of these sugar phosphates, but did cause an increased lactate production and CO2 production from the 1-position of glucose similar to EGF. Furthermore, the EGF stimulation of lactate formation was independent of the presence of medium Ca2+. Phenylephrine stimulation of this process, in parallel incubations, was entirely dependent upon the presence of Ca2+ in the medium. We conclude that EGF stimulates glycolysis and the pentose phosphate pathway in isolated hepatocytes from fed rats. The duplication of these actions by TPA suggests that protein kinase C is a mediator of EGF action in hepatocytes.     

Effects of insulin on the pattern of glucose metabolism in the perfused working and Lagendorff heart of normal and insulin-deficient rats

1. The metabolic pattern of [U-(14)C]glucose in the isolated rat heart has been studied, with both retrograde aortic (Langendorff) and atrially (working) perfused preparations in the presence and absence of insulin, in normal animals, animals rendered insulin-deficient (by injection of anti-insulin serum 1hr. before excision of the heart) and animals rendered diabetic by streptozotocin injection 7 days before use. 2. Radioautochromatograms of heart extracts show that the pattern of glucose metabolism in heart muscle is more complex than in diaphragm muscle. In addition to (14)CO(2), glycogen, oligosaccharides, phosphorylated sugars and lactate (the main metabolites formed from [(14)C]glucose in diaphragm muscle), (14)C label from [(14)C]glucose appears in heart muscle in glutamate, glutamine, aspartate and alanine, and in tricarboxylic acid-cycle intermediates. 3. By a quantitative scanning technique of two-dimensional chromatograms it was found that a mechanical work load stimulates glucose metabolism, increasing by a factor of 2-3 incorporation of (14)C into all the metabolites mentioned above except lactate and phosphorylated sugars, into which (14)C incorporation is in fact diminished; (14)CO(2) production is equally stimulated. 4. Addition of insulin to the perfusion fluid of the working heart causes increases in (14)C incorporation, by a factor of about 1.5 into (14)CO(2), by a factor of about 3-5 into glycogen, lactate and phosphorylated sugars, by a factor of about 2-3 into glutamate and tricarboxylic acid-cycle intermediates and by a factor of about 0.5 into aspartate, whereas incorporation into alanine and glutamine is not affected. The effect of a work load on the pattern of glucose metabolism is thus different from that of insulin. 5. Increasing the concentration of glucose in the perfusion fluid from 1 to 20mm leads to changes of the pattern of glucose metabolism different from that brought about by insulin. (14)CO(2) production steadily increases whereas [(14)C]lactate and glycogen production levels off at 10mm-glucose, at values well below those reached in the presence of insulin. 6. In Langendorff hearts of animals rendered insulin-deficient by anti-insulin serum or streptozotocin, glucose uptake, formation of (14)CO(2) and [(14)C]lactate, and (14)C incorporation into glycogen and oligosaccharides are decreased. In insulin-deficient working hearts, however, glucose uptake and (14)CO(2) production are normal, whereas incorporation of (14)C into glycogen and [(14)C]lactate production are greatly decreased. 7. Insulin added to the perfusion fluid restores (14)C incorporation from glucose into (14)CO(2), glycogen and lactate in the Langendorff heart from animals rendered insulin-deficient by anti-insulin serum; in hearts from streptozotocin-diabetic animals addition of insulin restores (14)C incorporation into glycogen and lactate, but (14)CO(2) production remains about 50% below normal. 8. The bearing of these results on the problem of the mode of action of insulin is discussed.