Glycolytic and oxidative metabolism in relation to retinal function

Measurements of lactate production and ATP concentration in superfused rat retinas were compared with extracellular photoreceptor potentials (Fast PIII). The effect of glucose concentration, oxygen tension, metabolic inhibition, and light were studied. Optimal conditions were achieved with 5-20 mM glucose and oxygen. The isolated retina had a high rate of lactate production and maintained the ATP content of a freshly excised retina, and Fast PIII potentials were similar to in vivo recordings. Small (less than 10%) decreases in aerobic and anaerobic lactate production were observed after illumination of dark-adapted retinas. There were no significant differences in ATP content in dark- and light-adapted retinas. In glucose-free medium, lactate production ceased, and the amplitude of Fast PIII and the level of ATP declined, but the rates of decline were slower in oxygen than in nitrogen. ATP levels were reduced and the amplitude of Fast PIII decreased when respiration was inhibited, and these changes were dependent on glucose concentration. Neither glycolysis alone nor Krebs cycle activity alone maintained the superfused rat retina at an optimal level. Retinal lactate production and utilization of ATP were inhibited by ouabain. Mannose but not galactose or fructose produced lactate and maintained ATP content and Fast PIII. Iodoacetate blocked lactate production and Fast PIII and depleted the retina of ATP. Pyruvate, lactate, and glutamine maintained ATP content and Fast PIII reasonably well (greater than 50%) in the absence of glucose, even in the presence of iodoacetate. addition of glucose, mannose, or 2-deoxyglucose to medium containing pyruvate and iodoacetate abolished Fast PIII and depleted the retina of its ATP. It is suggested that the deleterious effects of these three sugars depend upon their cellular uptake and phosphorylation during the blockade of glycolysis by iodoacetate.     

Glucose Metabolism in Rat Retinal Pigment Epithelium

The retinal pigment epithelium (RPE) is the major transport pathway for exchange of metabolites and ions between choroidal blood supply and the neural retina. To gain insight into the mechanisms controlling glucose metabolism in RPE and its possible relationship to retinopathy, we studied the influence of different glucose concentrations on glycogen and lactate levels and CO₂ production in RPE from normal and streptozotocin-treated diabetic rats. Incubation of normal RPE in the absence of glucose caused a decrease in lactate production and glycogen content. In normal RPE, increasing glucose concentrations from 5.6 mM to 30 mM caused a four-fold increase in glucose accumulation and CO₂ yield, as well as reduction in lactate and glycogen production. In RPE from diabetic rats glucose accumulation did not increase in the presence of high glucose substrate, but it showed a four- and a seven-fold increase in CO₂ production through the mitochondrial and pentose phosphate pathways, respectively. We found high glycogen levels in RPE which can be used as an energy reserve for RPE itself and/or neural retina. Findings further show that the RPE possesses a high oxidative capacity. The large increase in glucose shunting to the pentose phosphate pathway in diabetic retina exposed to high glucose suggests a need for reducing capacity, consistent with increased oxidative stress.     

Lactate prevents the alterations in tissue amino acids, decline in ATP, and cell damage due to aglycemia in retina

Under conditions of energy impairment, CNS tissue can utilize substrates other than glucose to maintain energy metabolism. Retinas produce large amounts of lactate, although it has not been shown that lactate can be utilized by retina to prevent the cell damage associated with hypoglycemia. To investigate this, intact, isolated retinas were subjected to aglycemic conditions in the presence or absence of 20 mM lactate. Retinas incubated in the absence of glucose for 60 min showed a threefold elevation in tissue aspartate and 60% decreases in tissue glutamate and glutamine, demonstrating a mobilization of carbon from glutamine and glutamate to the tricarboxylic acid cycle. Lactate prevented these changes in tissue amino acids, indicating metabolism of lactate with sparing of tissue glutamate and glutamine. Tissue ATP was 20 and 66% of control values with zero glucose or zero glucose plus lactate, respectively. Consistent with previous findings, incubation of retinas in the absence of glucose caused acute swelling of retinal neurons and release of GABA into the medium at 60 min. These acute toxic affects caused by the absence of glucose were completely prevented by the presence of lactate. At 24 h of recovery following 60 min of zero glucose, many pyknotic profiles were observed and lactate dehydrogenase (LDH) release into the medium was elevated sevenfold, indicating the extent of cell death. In contrast, no elevation in LDH was found and histology appeared normal in retinas exposed to zero glucose in the presence of lactate. alpha-Cyano-4-hydroxy cinnamate (4-CIN; 0.5 mM), an inhibitor of the monocarboxylic acid transporter and mitochondrial pyruvate carrier, blocked the ability of lactate to maintain ATP and protect retinas from aglycemia but had no effect on ATP or toxicity per se. Derangements in tissue aspartate, glutamate, and glutamine, which were prevented by lactate during zero glucose incubation, were again observed with lactate plus zero glucose in the presence of 4-CIN. However, 0.5 mM 4-CIN alone in the presence of glucose produced similar increases in aspartate and decreases in glutamate and glutamine as observed with zero glucose while having only modest inhibitory effects on [U-(14)C]lactate uptake, suggesting the mitochondrial pyruvate carrier as the main site of action. The above findings show that lactate is readily utilized by the chick retina during glucose deprivation to prevent derangements in tissue amino acids and ATP and retinal neuronal cell death.     

Lactate as substrate for glycogen resynthesis after exercise

Muscle glycogen levels in the perfused rat hemicorpus preparation were reduced two-thirds by electrical stimulation plus exposure to epinephrine (10(-7) M) for 30 min. During the contraction period muscle lactate concentrations increased from a control level of 3.6 +/- 0.6 to a final value of 24.1 +/- 1.6 mumol/g muscle. To determine whether the lactate that had accumulated in muscle during contraction could be used to resynthesize glycogen, glycogen levels were determined after 1-3 h of recovery from the contraction period during which time the perfusion medium (flow-through system) contained low (1.3 mmol/l) or high (10.5 or 18 mmol/l) lactate concentrations but no glucose. With the low perfusate lactate concentration, muscle lactate levels declined to 7.2 +/- 0.8 mumol/g muscle by 3 h after the contraction period and muscle glycogen levels did not increase (1.28 +/- 0.07 at 3 h vs. 1.35 +/- 0.09 mg glucosyl U/g at end of exercise). Lactate disappearance from muscle was accounted for entirely by output into the venous effluent. With the high perfusate lactate concentrations, muscle lactate levels remained high (13.7 +/- 1.7 and 19.3 +/- 2.0 mumol/g) and glycogen levels increased by 1.11 and 0.86 mg glucosyl U/g, respectively, after 1 h of recovery from exercise. No more glycogen was synthesized when the recovery period was extended. Therefore, it appears that limited resynthesis of glycogen from lactate can occur after the contraction period but only when arterial lactate concentrations are high; otherwise the lactate that builds up in muscle during contraction will diffuse into the bloodstream.     

Lactate production in the perfused rat liver

1. In aerobic conditions the isolated perfused liver from well-fed rats rapidly formed lactate from endogenous glycogen until the lactate concentration in the perfusion medium reached about 2mm (i.e. the concentration of lactate in blood in vivo) and then production ceased. Pyruvate was formed in proportion to the lactate, the [lactate]/[pyruvate] ratio remaining between 8 and 15. 2. The addition of 5mm- or 10mm-glucose did not affect lactate production, but 20mm- and 40mm-glucose greatly increased lactate production. This effect of high glucose concentration can be accounted for by the activity of glucokinase. 3. The perfused liver released glucose into the medium until the concentration was about 6mm. When 5mm- or 10mm-glucose was added to the medium much less glucose was released. 4. At high glucose concentrations (40mm) more glucose was taken up than lactate and pyruvate were produced; the excess of glucose was probably converted into glycogen. 5. In anaerobic conditions, livers of well-fed rats produced lactate at relatively high rates (2.5mumol/min per g wet wt.). Glucose was also rapidly released, at an initial rate of 3.2mumol/min per g wet wt. Both lactate and glucose production ceased when the liver glycogen was depleted. 6. Addition of 20mm-glucose increased the rate of anaerobic production of lactate. 7. d-Fructose also increased anaerobic production of lactate. In the presence of 20mm-fructose some glucose was formed anaerobically from fructose. 8. In the perfused liver from starved rats the rate of lactate formation was very low and the increase after addition of glucose and fructose was slight. 9. The glycolytic capacity of the liver from well-fed rats is equivalent to its capacity for fatty acid synthesis and it is pointed out that hepatic glycolysis (producing acetyl-CoA in aerobic conditions) is not primarily an energy-providing process but part of the mechanism converting carbohydrate into fat.     

Effect of Diabetes on Glycogen Metabolism in Rat Retina

Glucose is the main fuel for energy metabolism in retina. The regulatory mechanisms that maintain glucose homeostasis in retina could include hormonal action. Retinopathy is one of the chemical manifestations of long-standing diabetes mellitus. In order to better understand the effect of hyperglycemia in retina, we studied glycogen content as well as glycogen synthase and phosphorylase activities in both normal and streptozotocin-induced diabetic rat retina and compared them with other tissues. Glycogen levels in normal rat retina are low (46 +/- 4.0 nmol glucosyl residues/mg protein). However, high specific activity of glycogen synthase was found in retina, indicating a substantial capacity for glycogen synthesis. In diabetic rats, glycogen synthase activity increased between 50% and 100% in retina, brain cortex and liver of diabetic rats, but only retina exhibited an increase in glycogen content. Although, total and phosphorylated glycogen synthase levels were similar in normal and diabetic retina, activation of glycogen synthase by glucose-6-P was remarkable increased. Glycogen phosphorylase activity decreased 50% in the liver of diabetic animals; it was not modified in the other tissues examined. We conclude that the increase in glycogen levels in diabetic retina was due to alterations in glycogen synthase regulation.     

Changes in glucose and energy metabolism in Vivo in developing retinae from visually-competent (DBA-1J) and mutant (C3H-HeJ) mice

Abstract— The distribution in vivo of glucose and lactate between the complete or sub- divided retina and the blood has been evaluated in DBA and C3H mice during postnatal development. Levels in vivo of several intermediates of glucose and energy metabolism were measured by enzyme-linked fluorometric assays of freeze-dried retinae; glucose and lactate were determined in freshly-drawn plasma. DBA retinae. During the first 20 days of postnatal life, the level of glucose in the plasma rose slightly while that in the retina declined: during this period the level of lactate in the plasma rose and became nearly equal to that in the retina. Changes during development in levels of glucose and glycogen were consistent with the interpretation that the rate of utilization of glucose in vivo is enhanced during early postnatal life. C3H retinae. The levels of glucose and glycogen in vivo were abnormally high throughout the developmental period, whereas levels of lactate were normal. The rise in levels of glucose after the 15th postnatal day was not related to an increase in blood levels of glucose but rather to a decreased utilization of glucose during this period. For the first 10 postnatal days the content of glucose, lactate, ATP and P-creatine within the photoreceptor layer of C3H retinae were within normal limits. Then, biochemical changes occurred which were secondary to ultrastructural pathology in the photoreceptors. This observation suggested that glucose metabolism and energy production are not involved in the primary aetiology of the inherited disease.     

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.     

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.     

Acute inhibition of hepatic glucose-6-phosphatase does not affect gluconeogenesis but directs gluconeogenic flux toward glycogen in fasted rats. A pharmacological study with the chlorogenic acid derivative S4048

Effects of acute inhibition of glucose-6-phosphatase activity by the chlorogenic acid derivative S4048 on hepatic carbohydrate fluxes were examined in isolated rat hepatocytes and in vivo in rats. Fluxes were calculated using tracer dilution techniques and mass isotopomer distribution analysis in plasma glucose and urinary paracetamol-glucuronide after infusion of [U-(13)C]glucose, [2-(13)C]glycerol, [1-(2)H]galactose, and paracetamol. In hepatocytes, glucose-6-phosphate (Glc-6-P) content, net glycogen synthesis, and lactate production from glucose and dihydroxyacetone increased strongly in the presence of S4048 (10 microm). In livers of S4048-treated rats (0.5 mg kg(-1)min(-)); 8 h) Glc-6-P content increased strongly (+440%), and massive glycogen accumulation (+1260%) was observed in periportal areas. Total glucose production was diminished by 50%. The gluconeogenic flux to Glc-6-P was unaffected (i.e. 33.3 +/- 2.0 versus 33.2 +/- 2.9 micromol kg(-1)min(-1)in control and S4048-treated rats, respectively). Newly synthesized Glc-6-P was redistributed from glucose production (62 +/- 1 versus 38 +/- 1%; p < 0.001) to glycogen synthesis (35 +/- 5% versus 65 +/- 5%; p < 0.005) by S4048. This was associated with a strong inhibition (-82%) of the flux through glucokinase and an increase (+83%) of the flux through glycogen synthase, while the flux through glycogen phosphorylase remained unaffected. In livers from S4048-treated rats, mRNA levels of genes encoding Glc-6-P hydrolase (approximately 9-fold), Glc-6-P translocase (approximately 4-fold), glycogen synthase (approximately 7-fold) and L-type pyruvate kinase (approximately 4-fold) were increased, whereas glucokinase expression was almost abolished. In accordance with unaltered gluconeogenic flux, expression of the gene encoding phosphoenolpyruvate carboxykinase was unaffected in the S4048-treated rats. Thus, acute inhibition of glucose-6-phosphatase activity by S4048 elicited 1) a repartitioning of newly synthesized Glc-6-P from glucose production into glycogen synthesis without affecting the gluconeogenic flux to Glc-6-P and 2) a cellular response aimed at maintaining cellular Glc-6-P homeostasis.     

Stimulation of glycogen synthesis by proglycosyn (LY177507) by isolated hepatocytes of normal and streptozotocin diabetic rats

The phenacylimidazolium compound LY177507 was shown by Harris et al. (Harris, R. A., Yamanuchi, K., Roach, P. J., Yen, T. T., Dominiani, S. J., and Stephens, T. W. (1989) J. Biol. Chem. 264, 14674-14680) to stimulate glycogen synthesis greatly in isolated rat hepatocytes. We extended studies with this compound, designated proglycosyn (Yamaguchi, K., Stephens, T. W., Chikadar, K., Depaoli-Roach, A., And Harris, R. A. (1991) Diabetes 40, (Suppl. 1) 102 (abstr.] employing hepatocytes from normal and streptozotocin diabetic rats. Proglycosyn is more effective than amino acids in stimulating glycogen synthesis. In cells incubated with glucose, lactate, or dihydroxyacetone the effect of glutamine and proglycosyn was synergistic. In cells incubated with glucose plus lactate, or glucose plus dihydroxyacetone, the stimulation by the two agonists was additive. Proglycosyn diverted the gluconeogenic flux from glucose to glycogen. The maximal rates of glycogen deposition attained in the presence of glutamine and proglycosyn from cells incubated with glucose plus lactate, or glucose plus dihydroxyacetone, where about 80 and 110 mumols/h/g of liver, respectively. Proglycosyn depressed glycogenolysis in hepatocytes of fed rats and stimulated glycogen synthesis from lactate and dihydroxyacetone. The incorporation of [U-14C]glucose and [U-14C]lactate in these cells occurred in the presence of glycogen breakdown or exceeded net production, indicating the occurrence of recycling of glycogen in hepatocytes of fed rats. Hepatocytes from fasted streptozotocin diabetic rats contained high levels of glycogen. Glycogenolysis was markedly depressed by proglycosyn. Glycogen synthesis from lactate and dihydroxyacetone in these cells was stimulated by glutamine and proglycosyn in a fashion similar to that in cells from fasted control rats, and the rates of glycogen synthesis were similar in cells of control and diabetic rats. With glucose as sole substrate, glutamine did not stimulate glycogen synthesis. When both agonists were present, there was a marked synergism and substantial glycogen formation. Streptozotocin diabetic rats prior to the onset of cachexia have a normal capacity for glycogen synthesis.     

Gluconeogenesis in the amphibian retina. Lactate is preferred to glutamate as the gluconeogenic precursor.

The capacity for gluconeogenesis in the isolated amphibian retina was found to be approx. 70-fold greater with lactate than with glutamate as the gluconeogenic precursor, 1426 versus 21 pmol of glucose incorporated into glycogen/h per mg of protein. It was also found that 11-15% of the glucosyl units in glycogen are derived from C3 metabolites of the glycolytic pathway, suggesting that lactate is recycled within the retina. In concert with these metabolic observations, a full complement of the gluconeogenic enzymes was detected in retinal homogenates. These included: glucose-6-phosphatase, fructose-1,6-bisphosphatase, acetyl-CoA-dependent pyruvate carboxylase and phosphoenolpyruvate carboxykinase. Agents that regulate the rate of gluconeogenesis in hepatic tissue were tested on the retina. At concentrations of glutamate and lactate that are presumed to be relevant physiologically, it was found that vasoactive intestinal peptide, ionophore A23187 and elevated [K+] each enhanced the rate of gluconeogenesis in Ringer containing 50 microM-glutamate, whereas in Ringer containing 8.5 mM-lactate these agents inhibited the rate of gluconeogenesis. Further, it was found that the classic gluconeogenic hormone glucagon inhibited gluconeogenesis in both glutamate- and lactate-containing Ringer. Retinal energy metabolism was found to be altered in lactate-containing Ringer, in that lactate production was suppressed completely. In addition, glycogen metabolism appeared to be dependent on increased cytosolic Ca2+ and was insensitive to increased retinal cyclic AMP.     

Decreased responsiveness of gluconeogenesis to the modulation by sulfonylureas in hepatocytes isolated from obese (fa/fa) Zucker rats

The influence of the hypoglycemic agent glipizide (0-100 microM) on the rate of gluconeogenesis from lactate, as well as on the levels of fructose 2,6-bisphosphate, has been investigated in hepatocytes isolated from genetically obese (fa/fa) Zucker rats and from their corresponding lean (Fa/-) littermates. As compared to lean rat hepatocytes, liver cells isolated from obese animals showed a lower rate of basal gluconeogenesis (0.9 +/- 0.2 vs 5.4 +/- 0.5 micromol of lactate converted to glucose/g cell x 30 min, n=4) and higher levels of fructose 2,6-bisphosphate (11.5 +/- 1.0 vs 5.9 +/- 0.4 nmol/g cell, n=8-9). In lean rat hepatocytes, the presence of glipizide in the incubation medium caused a dose-dependent inhibition of the rate of lactate conversion to glucose (maximal inhibition=46%; EC50 value=26 microM), and simultaneously raised the cellular content of fructose-2,6-bisphosphate (maximal increment=40%; EC50 value=10 microM). In contrast, in hepatocytes isolated from obese rats, the inhibition of gluconeogenesis and the increment in fructose-2,6-bisphosphate levels elicited by glipizide were significantly reduced (maximal effects of 22 and 13%, respectively). Similarly, the activation of glycogen phosphorylase and the increase in hexose 6-phosphate levels in response to glipizide were less marked in obese rat hepatocytes than in liver cells isolated from lean animals. These results demonstrate that the efficacy of sulfonylureas as inhibitors of hepatic gluconeogenesis is reduced in the genetically obese (fa/fa) Zucker rat.     

The supply of metabolic substrate from glia to photoreceptors in the retina of the honeybee drone

1. The drone retina is composed essentially of only two types of cells: a population of identical photoreceptor cells occupying 38% of the volume is embedded in a syncytium of glia (called outer pigment cells). Nearly all the mitochondria are in the photoreceptors. 2. A retinal slice consumes 18 microliter O2 (ml tissue)-1 min-1 in the dark for up to 6 h, even without exogenous substrate; in 6 h this would require the equivalent of 127 mM glucose in the photoreceptors or 8.7 mg glycogen (ml tissue)-1. 3. Freshly dissected retinas contain about 45 mg glycogen (ml tissue)-1, but this appears, from electron micrographs and from the PAS reaction, to be exclusively in the glia. After superfusion with substrate-free Ringer solution for 30 min, slices of retina contained less than 20 microM glucose. It therefore appears that to sustain respiration, carbohydrate substrate must be transferred from the glia to the photoreceptors. 4. Even after 6 h superfusion with substrate-free Ringer solution O2 consumption (QO2) was not increased by exogenous glucose, pyruvate, trehalose or lactate, nor decreased by 2-deoxy-D-glucose. QO2 was increased 2-3 fold by either light stimulation or (for at least 20 min) by 50 microM dinitrophenol. 5. QO2 was only slightly reduced when Na-dependent glucose transport was inhibited either by reduction of extracellular [Na+], or the presence of phlorizin. 6. It is suggested that drone retinal function does not require the uptake of glucose by the photoreceptors, but that the glia do take up glucose.     

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.     

Alteration of amino acid metabolism in neuronal aggregate cultures exposed to hypoglycaemic conditions

The neuronal effects of glucose deficiency on amino acid metabolism was studied on three-dimensional cultures of rat telencephalon neurones. Transient (6 h) exposure of differentiated cultures to low glucose (0.25 mm instead of 25 mm) caused irreversible damage, as judged by the marked decrease in the activities of two neurone-specific enzymes and lactate dehydrogenase, 1 week after the hypoglycemic insult. Quantification of amino acids and ammonia in the culture media supernatants indicated increased amino acid utilization and ammonia production during glucose-deficiency. Measurement of intracellular amino acids showed decreased levels of alanine, glutamine, glutamate and GABA, while aspartate was increased. Added lactate (11 mm) during glucose deficiency largely prevented the changes in amino acid metabolism and ammonia production, and attenuated irreversible damage. Higher media levels of glutamine (4 mm instead of 0.25 mm) during glucose deprivation prevented the decrease of intracellular glutamate and GABA, while it further increased intracellular aspartate, ammonia production and neuronal damage. Both lactate and glutamine were readily oxidized in these neuronal cultures. The present results suggest that in neurones, glucose deficiency enhances amino acid deamination at the expense of transamination reactions. This results in increased ammonia production and neuronal damage.     

Glycogen consumption in hypoxic rat cardiomyocytes.

Glycogen consumption was investigated in isolated adult rat myocytes incubated for 2 h (37 degrees C) in substrate-free, hypoxic Krebs-Henseleit bicarbonate buffer. No consumption of glycogen occurred after 1 h of incubation, and the residual glycogen after 2 h was 23% despite an 89% reduction of the initial ATP content (from 27.1 +/- 1.8 to 3.1 +/- 0.5 nmol/mg dry weight, n = 12). The residual glycogen was not due to lactate inhibition of glycolytic enzymes, since myocytes incubated in the presence of 5 mM glucose maintained high energy phosphates throughout the incubation period despite a considerable lactate accumulation (1740 +/- 43 nmol/mg dry weight in glucose-supplemented vs. 138 +/- 14 nmol/mg dry weight in substrate-free incubations, n = 12). We have previously shown that the content of cyclic AMP in myocytes is not altered in response to hypoxia, thereby excluding activation of glycogen phosphorylase a. In the present study, the fall in myocyte ATP content was not followed by a rise in AMP, possibly preventing allosteric activation of glycogen phosphorylase b. However, addition of cyanide to the hypoxic incubations increased cellular AMP (initial level 2.1 +/- 0.4 nmol/mg dry weight vs. 9.8 +/- 0.7 after 30 min, n = 12) without increasing the amount of glycogen consumed, also ruling out the lack of glycogen phosphorylase b activation in the myocytes. Therefore, the glycogen rest was probably confined to the 17% of myocytes hypercontracted at the start of incubations.     

Acclimation temperature affects the metabolic response of amphibian skeletal muscle to insulin

Frog skeletal muscle mainly utilizes the substrates glucose and lactate for energy metabolism. The goal of this study was to determine the effect of insulin on the uptake and metabolic fate of lactate and glucose at rest in skeletal muscle of the American bullfrog, Lithobates catesbeiana, under varying temperature regimens. We hypothesize that lactate and glucose metabolic pathways will respond differently to the presence of insulin in cold versus warm acclimated frog tissues, suggesting an interaction between temperature and metabolism under varying environmental conditions. We employed radiolabeled tracer techniques to measure in vitro uptake, oxidation, and incorporation of glucose and lactate into glycogen by isolated muscles from bullfrogs acclimated to 5 °C (cold) or 25 °C (warm). Isolated bundles from Sartorius muscles were incubated at 5 °C, 15 °C, or 25 °C, and in the presence and absence of 0.05 IU/mL bovine insulin. Insulin treatment in the warm acclimated and incubated frogs resulted in an increase in glucose incorporation into glycogen, and an increase in intracellular [glucose] of 0.5 μmol/g (P<0.05). Under the same conditions lactate incorporation into glycogen was reduced (P<0.05) in insulin-treated muscle. When compared to the warm treatment group, cold acclimation and incubation resulted in increased rates of glucose oxidation and glycogen synthesis, and a reduction in free intracellular glucose levels (P<0.05). When muscles from either acclimation group were incubated at an intermediate temperature of 15 °C, insulin's effect on substrate metabolism was attenuated or even reversed. Therefore, a significant interaction between insulin and acclimation condition in controlling skeletal muscle metabolism appears to exist. Our findings further suggest that one of insulin's actions in frog muscle is to increase glucose incorporation into glycogen, and to reduce reliance on lactate as the primary metabolic fuel.     

Lactate metabolism in the perfused rat hindlimb.

A preparation of isolated rat hindleg was perfused with a medium consisting of bicarbonate buffer containing Ficoll and fluorocarbon, containing glucose and/or lactate. The leg was electrically prestimulated to deplete partially muscle glycogen. The glucose was labelled uniformly with 14C and with 3H in positions 2, 5 or 6, and lactate uniformly with 14C and with 3H in positions 2 or 3. Glucose carbon was predominantly recovered in glycogen, and to a lesser extent in lactate. The 3H/14C ration in glycogen from [5-3H,U-14C]- and [6-3H,U-14C]-glucose was the same as in glucose. Nearly all the utilized 3H from [2-3H]glucose was recovered as water. Insulin increased glucose uptake and glycogen synthesis 3-fold. When the muscle was perfused with a medium containing 10 mM-glucose and 2 mM-lactate, there was little change in lactate concentration. 14C from lactate was incorporated into glycogen. There was a marked exponential decrease in lactate specific radioactivity, much greater with [3H]- than with [14C]-lactate. The 'apparent turnover' of [U-14C]lactate was 0.28 mumol/min per g of muscle, and those of [2-3H]- and [3-3H]-lactate were both about 0.7 mumol/min per g. With 10 mM-lactate as sole substrate, there was a net uptake of lactate, at a rate of about 0.15 mumol/min per g, and the apparent turnover of [U-14C]lactate was 0.3 mumol/min per g. The apparent turnover of [3H]lactate was 3-5 times greater. When glycogen synthesis was low (no prestimulation, no insulin), the incorporation of lactate carbon into glycogen exceeded that from glucose, but at high rates of glycogen deposition the incorporation of lactate carbon was much less than that of glucose. Lactate incorporation into glycogen was similar in fast-twitch white and fast-twitch red muscle, but was very low in slow-twitch red fibres. We find that (a) pyruvate in muscle is incorporated into glycogen without randomization of carbon, and synthesis is not inhibited by mercaptopicolinate or cycloserine; (b) there is extensive lactate turnover in the absence of net lactate uptake, and there is a large dilution of 14C-labelled lactate from endogenous supply; (c) there is extensive detritiation of [2-3H]- and [3-3H]-lactate in excess of 14C utilization.     

Effects of altering carbohydrate metabolism on energy status and contractile function of vascular smooth muscle

Substrate-dependent changes in vascular smooth muscle energy metabolism and contractile function were investigated in isolated porcine carotid arteries. In media containing glucose glycogen catabolism accounted for all the estimated high-energy phosphate turnover that occurred in conjunction with contraction induced by 80 mM KCl. However, in glucose-free media glycogen catabolism accounted for only a portion of the estimated ATP utilization in resting and contracting arteries, even though glycogen stores were not depleted. The glycogenolysis and lactate production that ordinarily accompanies contraction was completely inhibited by 5 mM 2-deoxyglucose (2-DG). However, there was no decrease in the high-energy phosphate levels when compared to control resting arteries similarly treated with 2-DG. The results suggest that an endogenous non-carbohydrate source may be an important substrate for energy metabolism. Treatment of arteries with 50 microM iodoacetate (IA) in media containing glucose resulted in a marked reduction of high energy phosphate levels and an accumulation of phosphorylated glycolytic intermediates, as demonstrated by 31P-NMR spectroscopy. In glucose-free media, 50 microM IA had only a slight effect on high-energy phosphate levels, while glycogenolysis proceeded unhindered. With 1 mM IA in glucose-free media, the oxidative metabolism of glycogen was inhibited as evidenced by the depletion of high-energy phosphates and the appearance of sugar phosphates in the 31P-NMR spectra. Thus, the titration of enzyme systems with IA reveals a structural partitioning of carbohydrate metabolism, as suggested by previous studies.