Showing papers on "Glycolysis published in 1995"

Metabolic coupling factors in pancreatic beta-cell signal transduction.

Abstract: This chapter focuses on the biochemical mechanisms that mediate glucose-stimulated insulin secretion (GSIS) from beta-cells of the islets of Langerhans and the potentiating role played by fatty acids. We summarize evidence supporting the idea that glucose metabolism is required for GSIS and that the GLUT-2 facilitated glucose transporter and the glucose phosphorylating enzyme glucokinase play important roles in measuring changes in extracellular glucose concentration. The idea that glucose metabolism is linked to insulin secretion through a sequence of events involving changes in ATP:ADP ratio, inhibition of ATP-sensitive K+ channels, and activation of voltage-gated Ca2+ channels is critically reviewed, and the relative importance of ATP generated from glycolytic versus mitochondrial metabolism is evaluated. We also present the growing concept that an important signal for insulin secretion may reside at the linkage between glucose and lipid metabolism, specifically the generation of the regulatory molecule malonyl CoA that promotes fatty acid esterification and inhibits oxidation. Finally, we show that in contrast to its short term potentiating effect on GSIS, long-term exposure of islets to high levels of fatty acids results in beta-cell dysfunction, suggesting that hyperlipidemia associated with obesity may play a causal role in the diminished GSIS characteristic of non insulin-dependent diabetes mellitus (NIDDM).

Functional Coupling Between Glycolysis and Sarcoplasmic Reticulum Ca2+ Transport

Abstract: To investigate whether the energy derived from glycolysis is functionally coupled to Ca2+ active transport in sarcoplasmic reticulum (SR), we determined whether glycolytic enzymes were associated with SR membranes and whether metabolism through these enzymes was capable of supporting 45Ca transport. Sealed right-side-out SR vesicles were isolated by step sucrose gradient from rabbit skeletal and cardiac muscle. Intravesicular 45Ca transport was measured after the addition of glycolytic substrates and cofactors specific for each of the glycolytic reactions being studied or after the addition of exogenous ATP and was expressed as transport sensitive to the specific Ca(2+)-ATPase inhibitor thapsigargin. We found that the entire chain of glycolytic enzymes from aldolase onward, including aldolase, GAPDH, phosphoglycerate kinase (PGK), phosphoglyceromutase, enolase, and pyruvate kinase (PK), was associated with SR vesicles from both cardiac and skeletal muscle. Iodoacetic acid, an inhibitor of GAPDH, eliminated 45Ca transport supported by fructose-1,6-diphosphate, the substrate for aldolase, but transport was completely restored by phosphoenolpyruvate (the substrate for PK), indicating that both of the ATP-producing glycolytic enzymes, GAPDH/PGK and PK, were associated with the SR and functionally capable of providing ATP for the Ca2+ pump. Addition of a soluble hexokinase ATP trap eliminated 45Ca transport fueled by exogenous ATP but had markedly less effect on 45Ca transport supported by endogenously produced ATP (via glycolysis). Similarly, at very low concentrations of ATP and ADP (10 to 50 nmol/L), ATP that was produced endogenously from ADP and phosphoenolpyruvate supported 15-fold more 45Ca transport than ATP that was supplied exogenously at the same concentration. These results are consistent with functional coupling of glycolytic ATP to Ca2+ transport and support the hypothesis that ATP generated by SR-associated glycolytic enzymes may play an important role in cellular Ca2+ homeostasis by driving the SR Ca2+ pump.

Plant Mitochondrial Electron Transfer and Molecular Biology.

Abstract: Severa1 types of reduced carbon com- pounds, including fatty acids, organic acids, and amino acids, can serve as the primary reducing substrates for plant respi- ration. However, the most common substrate used by plant tissues for respiration is carbohydrate (CHpO). The complete oxidation of a carbohydrate releases a large amount of free energy, much of which is coupled to the conversion of ADP and Pi to ATI? When sucrose (Cl2H=0,1) is the substrate, aer- obic respiration can be divided into three distinct phases: glycolysis, the tricarboxylic acid (TCA) cycle, and the coupled processes of mitochondrial electron transfer and ATP synthe- sis. Except for glycolysis, all of the metabolic steps of aerobic respiration take place in the mitochondrion. Like mitochon- dria found in other eukaryotes, plant mitochondria are roughly spherical subcellular organelles that usually range from

Elevated glucose levels increase retinal glycolysis and sorbitol pathway metabolism. Implications for diabetic retinopathy.

Abstract: Purpose. To assess effects of elevated glucose levels on retinal glycolysis and sorbitol pathway metabolism. Methods. Freshly isolated retinas from normal male Sprague-Dawley rats were incubated for 2 hours at 37°C, pH 7.45, in Krebs bicarbonate-Hepes buffer containing 5, 10, 20, or 30 mM glucose. Glycolytic metabolites, sorbitol, and fructose were measured in extracts of retina and medium. Results. Elevated glucose levels increased retinal levels of sorbitol and triose phosphates, decreased sn-glycerol-3-phosphate levels, increased lactate and fructose production, and increased the retinal lactate-pyruvate ratio (indicative of an increased cytosolic ratio of free NADH-NAD + like that induced by hypoxia). An inhibitor of aldose reductase (AL 4114) normalized sorbitol, fructose, triose phosphates, and the lactate-pyruvate ratio without affecting lactate production or sn-glycerol 3-phosphate levels. Conclusions. Elevation of retinal glucose levels causes a hypoxia-like redox imbalance pseudo-hypoxia that results from increased oxidation of sorbitol to fructose in the second step of the sorbitol pathway. This redox imbalance provides a plausible explanation for impaired regulation of retinal blood flow (in the absence of vascular structural changes) in humans with diabetes and in nondiabetic acutely hyperglycemic animals. These findings, together with other observations, suggest that this redox imbalance precedes, and may contribute to, hypoxic and ischemic retinopathy associated with diabetes. Invest Ophthalmol Vis Sci. 1995 ;36 :1675-1685.

Pyruvate dehydrogenase influences postischemic heart function

Abstract: Background The pyruvate dehydrogenase (PDH) enzyme complex determines the extent of carbohydrate oxidation in the myocardium. PDH is in a largely inactive state during early reperfusion of postischemic myocardium. The resultant decrease in pyruvate oxidation in postischemic hearts has been documented with 13C nuclear magnetic resonance (NMR) spectroscopy. This study demonstrates that counteracting depressed pyruvate oxidation can enhance contractile recovery in the absence of increases in either glycolytic activity or glucose oxidation. The findings indicate that increased incorporation of carbon units from pyruvate into the intermediates of the oxidative pathways by PDH influences the metabolic efficiency and mechanical work of postischemic hearts. Methods and Results Isolated rabbit hearts were situated in an NMR magnet and perfused or reperfused (10 minutes of ischemia) with 2.5 mmol/L [3-13C]pyruvate as sole substrate to target PDH directly and bypass the glycolytic pathway. Hearts were observed with or without activation of PDH with dichloroacetate. Mechanical function and oxygen consumption (MVo2) were monitored. 13C and 31P NMR spectroscopy allowed observations of pyruvate oxidation and bioenergetic state in intact, functioning hearts. Metabolite content and 13C enrichment levels were then determined with in vitro NMR spectroscopy and biochemical assay. PDH activation did not affect performance of normal hearts. Postischemic hearts with augmented pyruvate oxidation (dichloroacetate-treated) sustained improved mechanical function throughout 40 minutes of reperfusion. Rate-pressure-product (RPP) increased from 8300±1800 (mean±SEM) in untreated postischemic hearts to 21 300±2400 in hearts treated with dichloroacetate ( P <.05). Oxygen use per unit work [MVo2 multiplied by 104 divided by RPP] was improved from 1.50±0.13 to 1.14±0.11 ( P <.05) without differences in high-energy phosphate content between treated and untreated hearts. Values of dP/dt were also consistently higher, by as much as 185%, during reperfusion with dichloroacetate. Postischemic hearts displayed reduced pyruvate oxidation from the incorporation of 13C into the tissue glutamate pool. With the tissue alanine level as a marker of 13C-enriched pyruvate availability in the cell, the ratio of labeled glutamate to alanine was only 58% of the control value during early reperfusion. With dichloroacetate, that ratio was 167% greater than that of untreated hearts ( P <.05). By the end of the reperfusion period, the 13C enrichment of the tissue glutamate pool by pyruvate oxidation was elevated from dichloroacetate treatment (untreated, 62±7%; DCA-treated, 81±6%; P <.05), but glycogen content was similar in both groups and 13C enrichment of tissue alanine remained unchanged, near 60%, indicating no increases in glycolytic end-product formation. Conclusions Metabolic reversal of contractile dysfunction was achieved in isolated hearts by counteracting depressed PDH activity in the postischemic myocardium. Improved cardiac performance did not result from, nor require, increased glycolysis secondary to the activation of PDH. Rather, restoring carbon flux through PDH alone was sufficient to improve mechanical work by postischemic hearts.

Skeletal muscle pyruvate dehydrogenase activity during maximal exercise in humans

Abstract: The regulation of the active form of pyruvate dehydrogenase (PDHa) and related metabolic events were examined in human skeletal muscle during repeated bouts of maximum exercise. Seven subjects completed three consecutive 30-s bouts of maximum isokinetic cycling, separated by 4 min of recovery. Biopsies of the vastus lateralis were taken before and immediately after each bout. PDHa increased from 0.45 +/- 0.15 to 2.96 +/- 0.38, 1.10 +/- 0.11 to 2.91 +/- 0.11, and 1.28 +/- 0.18 to 2.82 +/- 0.32 mmol.min-1.kg wet wt-1 during bouts 1, 2, and 3, respectively. Glycolytic flux was 13-fold greater than PDHa in bouts 1 and 2 and 4-fold greater during bout 3. This discrepancy between the rate of pyruvate production and oxidation resulted in substantial lactate accumulation to 89.5 +/- 11.6 in bout 1, 130.8 +/- 13.8 in bout 2, and 106.6 +/- 10.1 mmol/kg dry wt in bout 3. These events coincided with an increase in the mitochondrial oxidation state, as reflected by a fall in mitochondrial NADH/NAD, indicating that muscle lactate production during exercise was not an O2-dependent process in our subjects. During exercise the primary factor regulating PDHa transformation was probably intracellular Ca2+. In contrast, the primary regulatory factors causing greater PDHa during recovery were lower ATP/ADP and NADH/NAD and increased concentrations of pyruvate and H+. Greater PDHa during recovery facilitated continued oxidation of the lactate load between exercise bouts.

Impaired activation of glucose oxidation and NADPH supply in human endothelial cells exposed to H2O2 in high-glucose medium

Abstract: The effects of glucose concentration on D-glucose oxidation and reduced nicotinamide adenine dinucleotide phosphate (NADPH) supply were studied during exposure of cultured human umbilical vein endothelial cells to hydrogen peroxide (H 2 O 2 ). The activation of glucose oxidation via the pentose phosphate pathway (PPP), induced by exposure of cells to 200 μmol/l H 2 O 2 for 1 h, was reduced by 50% ( P P 2 O 2 . The decrease in NADPH was dependent on D-glucose concentration in the medium and was prevented in glutathione (GSH)-depleted cells. The latter observation suggests that the decrease in NADPH is associated with activation of the GSH redox cycle. In the presence of 200 μmol/l H 2 O 2 , lactate release into the medium, NADH/NAD ratio, and phosphofructokinase activity in HG cells were 56, 53, and 68% greater, respectively, than in the NG group, which indicates that inhibition of glycolysis by H 2 O 2 is less marked in the HG group compared with NG group. These results indicate that activation of the PPP was impaired in endothelial cells cultured under conditions of high-glucose and oxidative stress, resulting in a decreased supply of NADPH to various NADPH-dependent pathways, including the GSH redox cycle.

Improved culture conditions stimulate gluconeogenesis in primary cultures of renal proximal tubule cells

Abstract: Unlike renal proximal tubule cells (RPTC) in vivo, RPTC cultured in standard conditions are hypoxic, glycolytic, and not gluconeogenic. This study investigated the effects of glucose and lactate on glycolysis and gluconeogenesis in rabbit RPTC cultured in conditions of increased oxygen supply (Shake). Confluent Shake cultures grown in the presence of glucose exhibited increased oxygen consumption and decreased glycolysis compared with stationary (Still) cultures. Addition of 5 mM lactate to a 5 mM glucose medium decreased net glucose consumption and glucose oxidation in Shake cultures by 34 and 50%, respectively, and resulted in net lactate consumption. Addition of 5 mM lactate to a glucose-free medium resulted in a threefold increase in net glucose production (0.024 +/- 0.003 vs. 0.074 +/- 0.013 mumol.mg protein-1.day-1) in Shake cultures. Net glucose production further increased to 0.430 +/- 0.020 and 1.640 +/- 0.040 mumol.mg protein-1.day-1 when glucose reuptake was inhibited by 1 mM phloridzin or 1 mM phloridzin + 1 mM phloretin, respectively. These results show that, under conditions of improved oxygenation and in the presence of lactate and physiological levels of glucose and insulin, RPTC aerobic metabolism increases and glucose metabolism changes from glycolysis and net lactate production to gluconeogenesis and net lactate consumption.

High Km Glucose-phosphorylating (Glucokinase) Activities in a Range of Tumor Cell Lines and Inhibition of Rates of Tumor Growth by the Specific Enzyme Inhibitor Mannoheptulose

Abstract: Differences in modes of control of glycolysis in tumor cells, compared with normal cells, have suggested that phosphofructokinase may not catalyse the rate-controlling step. Instead, hexokinase activity may assume a more important regulatory role. Hexokinase activities are consistently lower than those of phosphofructokinase in tumor cells, and the former enzyme may be saturated with its substrate (M. Board et al., Biochem. J. 265: 503-509, 1990). The present work has focused on the glucose-phosphorylation step in tumor cell glycolysis. A range of eight human tumor cell-lines, one human tumor tissue, and four rat tumor cell lines were found to have an additional glucose-phosphorylating activity, with properties similar to hepatic glucokinase. Maximal activities range from 1.1-20 nmol/min/mg cell protein, and the activity is consistently absent from any untransformed cell line or tissue tested, except rat liver tissue (18 nmol/min/mg cell protein). Tumor cell glucokinase activity has been characterized by its high Km for glucose (8-11.8 mM); inhibition by the specific glucokinase inhibitor, mannoheptulose (I50, 12.5 mM); and lack of inhibition by 10 mM glucose-6-phosphate. Mannoheptulose also causes inhibition of glucose uptake by tumor cells (25-75% at 30 mM mannoheptulose) and inhibition of rates of growth of cultured tumor cell lines (I50, 21.4 mM). Rates of growth of human tumors in experimental animals are dramatically reduced (by 65-79%) by a dose of 1.7 mg/g mannoheptulose daily for 5 days. The potential of the naturally occurring sugar, mannoheptulose (which is purified from avocados and is assumed to be of low toxicity), as a cancer treatment is discussed.

Effects of glycogen depletion on ischemic injury in isolated rat hearts: insights into preconditioning.

Abstract: Limitation of myocardial injury and infarction has been demonstrated by interventions such as ischemic preconditioning or the use of pyruvate as a substrate, which reduces glycogen content before, and acidosis during, ischemia. An isolated perfused rat heart model of global ischemia was employed to test the hypothesis that glycogen depletion reduces ischemic injury as measured by creatine kinase release. 31P-nuclear magnetic resonance spectroscopy was used to measure high-energy phosphates (ATP and phosphocreatine), phosphomonoesters (PME), and intracellular pH. Compared with control glucose-perfused hearts with normal glycogen content (1.49 +/- 0.13 mg Glc/g wet wt), glycogen-depleted pyruvate, ischemic preconditioned, and glycogen-depleted glucose hearts all had reduced glycogen content before ischemia (0.62 +/- 0.16, 0.81 +/- 0.10, and 0.67 +/- 0.12 mg Glc/g wet wt, respectively; P = 0.003) and significantly higher pH at the end of ischemia (5.85 +/- 0.02, 6.33 +/- 0.06, 6.24 +/- 0.04, and 6.12 +/- 0.02 in control, glycogen-depleted pyruvate, preconditioned, and glycogen-depleted glucose-perfused hearts, respectively; P < 0.01), although acidification during the initial phase of ischemia was differentially affected by the three interventions. Glycogen-depleted pyruvate and preconditioned hearts had reduced PME accumulation, greater recovery of function and phosphocreatine, and lower creatine kinase release on reperfusion, whereas glycogen-depleted glucose-perfused hearts were similar to control hearts. In summary, glycogen depletion by these three methods limits the fall in pH during global ischemia, although glycogen depletion in the absence of preconditioning does not limit ischemic injury.(ABSTRACT TRUNCATED AT 250 WORDS)

Transgenic GLUT-4 overexpression in fat enhances glucose metabolism: preferential effect on fatty acid synthesis

Abstract: GLUT-4 expression varies widely among normal humans and those with obesity and diabetes. Using the alpha P2 promoter/enhancer ligated to the human GLUT-4 gene, we created transgenic mice to study the impact of alterations in GLUT-4 expression selectively in adipocytes on glucose homeostasis and body composition. Here we investigated molecular mechanisms for enhanced glucose tolerance and obesity in these mice. [U-14C]glucose incorporation into triglycerides, glyceride-glycerol, glyceride-fatty acids, CO2, and lactate was measured in adipocytes incubated at 3, 0.5, and 3 microM glucose with or without maximally stimulating insulin. In nontransgenic and transgenic mice, the major pathway for glucose metabolism shifts from lipogenesis at tracer glucose concentration to glycolysis at physiological glucose concentration. In transgenic adipocytes incubated at 3 microM glucose, metabolism via all major pathways is enhanced by 8.6- to 38-fold in the absence of insulin and 3- to 13-fold in the presence of insulin. At physiological glucose concentration, constitutive metabolism to triglycerides, CO2, and lactate is two- to threefold greater in transgenic than in nontransgenic adipocytes. De novo fatty acid synthesis is preferentially increased: 31-fold for basal and 21-fold for insulin-stimulated compared with nontransgenic adipocytes. Thus overexpression of GLUT-4 in adipocytes of transgenic mice results in increased glucose metabolism in all major pathways, with differential regulation of the pathways involved in lipogenesis.

Evidence from transgenic mice that myc regulates hepatic glycolysis.

Abstract: The product of the c-myc proto-oncogene (c-Myc) is involved in the control of cell proliferation, differentiation, and apoptosis. It acts as a transcription factor that recognizes the CACGTG motif. This sequence has also been found in the glucose-responsive elements of genes involved in the control of liver glycolysis and lipogenesis. To determine whether c-Myc can regulate hepatic carbohydrate metabolism in vivo, transgenic mice that overexpress c-myc under control of the P-enolpyruvate carboxykinase (PEPCK) gene promoter have been generated. These mice showed a threefold increase in c-Myc protein in liver nuclei. Hepatocytes from transgenic mice were normal and did not acquire the fetal phenotype. However, transgenic mice showed higher levels (threefold) of L-type pyruvate kinase mRNA and enzyme activity than control mice. The increase in pyruvate kinase activity led to a three- to fivefold increase in liver lactate content and a fivefold induction of lactate production by hepatocytes in primary culture. The expression of the 6-phosphofructo-2-kinase gene was also increased in the liver of these transgenic mice. The induction of hepatic glycolysis was related with an increase in the expression (about fourfold) and activity (about threefold) of liver glucokinase, whereas no change was noted in hexokinase-I. This change in glucokinase activity led to an increase in both glucose 6-phosphate and glycogen contents in the liver of transgenic mice. The expression of the liver-specific glucose transporter GLUT2 was also increased in transgenic mice, whereas no change was noted in the mRNA concentration of GLUT1. Furthermore, the changes of liver glucose metabolism led to a marked reduction of blood glucose (25%) and insulin (40%) concentrations in starvation, whereas the fall in both was only 10% in fed mice. Thus, liver glucose metabolism could determine the blood glucose and insulin set points in the transgenic mice. All these results indicated that the increase in c-Myc protein was able to induce liver glucose utilization and accumulation, and suggested that c-Myc transcription factor is involved in the control in vivo of liver carbohydrate metabolism.

Phosphofructokinase Isozymes in Pancreatic Islets and Clonal β-Cells (INS-1)

Abstract: Normal insulin secretion is oscillatory in vivo, and the oscillations are impaired in type II diabetes. We and others have shown oscillations in insulin secretion from isolated perifused islets stimulated with glucose, and in this study we show oscillations in insulin secretion from the glucose-sensitive clonal beta-cell line INS-1. We have proposed that the oscillatory insulin secretion may be caused by spontaneous oscillations of glycolysis and the ATP:ADP ratio in the beta-cell, analogous to those seen in glycolyzing muscle extracts. The mechanism of the latter involves autocatalytic activation of the key regulatory enzyme, phosphofructokinase (PFK), by its product fructose 1,6-bisphosphate (F16BP). However, of the three PFK subunit isoforms (M-[muscle], L-[liver], and C-type, predominant in fibroblasts), only M-type is activated by micromolar F16BP at near-physiological conditions. We therefore studied PFK isoforms in the beta-cell. Western analysis of PFK subunits in isolated rat islets and INS-1 cells showed the presence of M-type, as well as C-type and perhaps lesser amounts of L-type. Kinetic studies of PFK activity in INS-1 cell extracts showed strong activation by micromolar concentrations of F16BP at near-physiological concentrations of ATP (several millimolar) and AMP and fructose 6-phosphate (micromolar), indicative of the M-type isoform. Activation by submicromolar concentrations of fructose 2,6-bisphosphate (F26BP) and potent inhibition by citrate were also observed. The F16BP-stimulatable activity was about one-half of the F26BP-stimulatable activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Biochemistry Primer for Exercise Science

Abstract: Part 1 The major players: amino acids, peptides and proteins enzymes DNA and RNA. Part 2 Basic molecular biology: transcription and its control protein synthesis. Part 3 Metabolism: biochemical energetics glycolysis oxidative phosphorylation the citric acid cycle lipid metabolism gluconeogenesis glycogen metabolism amino acid metabolism.

Effects of chronic renal failure on enzymes of energy metabolism in individual human muscle fibers.

Abstract: In order to improve knowledge about the mechanisms underlying the alterations of energy metabolism recently observed in the skeletal muscle of patients suffering from chronic renal failure, this study was designed to test (1) whether changes in the activity of key enzymes of energy metabolism occur in the muscle of these patients, and if so (2) whether the different muscle fiber types are equally altered in their metabolic machinery. For this, the maximum activities of 14 enzymes were measured in individual muscle fibers microdissected from biopsies of rectus abdominis muscle obtained from seven normal subjects and seven patients with end-stage renal failure before renal replacement therapy. A large decrease in the activities of beta-hydroxyacyl-coenzyme A dehydrogenase, a key enzyme of the beta-oxidation pathway, of citrate synthase, which initiates the tricarboxylic acid cycle, and of fructose-1,6-bisphosphatase, which contributes to the synthesis of glycogen from lactate, was observed in the three fiber types (slow-twitch oxidative, fast-twitch oxidative-glycolytic, and fast-twitch glycolytic). A smaller reduction of the activities of phosphofructokinase and/or pyruvate kinase, two key enzymes of glycolysis, was also observed in slow-twitch oxidative and/or fast-twitch oxidative-glycolytic fibers. These results demonstrate that the abnormalities of muscle energy metabolism observed in patients with chronic renal failure are due, at least in part, to intrinsic changes in the key enzymes of major energy-providing pathways; they also offer a satisfactory explanation for the defect of oxidative metabolism recently demonstrated in the muscle of these patients.

Glucose-transporter (GLUT4) protein content in oxidative and glycolytic skeletal muscles from calf and goat.

Abstract: It is well accepted that skeletal muscle is a major glucose-utilizing tissue and that insulin is able to stimulate in vivo glucose utilization in ruminants as in monogastrics. In order to determine precisely how glucose uptake is controlled in various ruminant muscles, particularly by insulin, this study was designed to investigate in vitro glucose transport and insulin-regulatable glucose-transporter protein (GLUT4) in muscle from calf and goat. Our data demonstrate that glucose transport is the rate-limiting step for glucose uptake in bovine fibre strips, as in rat muscle. Insulin increases the rate of in vitro glucose transport in bovine muscle, but to a lower extent than in rat muscle. A GLUT4-like protein was detected by immunoblot assay in all insulin-responsive tissues from calf and goat (heart, skeletal muscle, adipose tissue) but not in liver, brain, erythrocytes and intestine. Unlike the rat, bovine and goat GLUT4 content is higher in glycolytic and oxido-glycolytic muscles than in oxidative muscles. In conclusion, using both a functional test (insulin stimulation of glucose transport) and an immunological approach, this study demonstrates that ruminant muscles express GLUT4 protein. Our data also suggest that, in ruminants, glucose is the main energy-yielding substrate for glycolytic but not for oxidative muscles, and that insulin responsiveness may be lower in oxidative than in other skeletal muscles.

Inhibitors of glycolytic metabolism affect neurulation-staged mouse conceptuses in vitro

Abstract: In order to evaluate the apparent discordance between altered glucose metabolism and embryonic energy production, the effects of inhibitors of glucose utilization on morphological development and biochemical changes in mouse embryos in culture were evaluated. Day 9 ICR mouse conceptuses having 3-6 pairs of somites were prepared for culture as previously described. 2-Deoxyglucose (2DG) produced a concentration-dependent effect on development. A 25 microM 2DG concentration did not induce neural tube closure defects (NTDs) but 100 microM, 100% of embryos exhibited this defect. A 17% reduction in the rate of lactate production by the conceptus was produced by a 24-hr exposure period to 100 microM 2DG. Iodoacetate, which inhibits glyceraldehyde-3-phosphate dehydrogenase in adult tissues, produced high rates of NTDs at concentrations > or = 2.5 microM. Following a 24 hour exposure to iodoacetate, lactate production was inhibited at 10 and 25 microM. The effects of 2DG on embryonic ATP content were assessed to test the hypothesis that effects on glucose utilization would effect embryonic ATP content. Despite using 2DG concentrations that alter development and inhibit glycolysis, there were no effects on whole embryo or visceral yolk sac (VYS) ATP content. However, when the embryo was divided into regions, there was a specific reduction in ATP content in the head following a 24-hr exposure period. No effect of 2DG on head ATP content was produced after 12 hr of exposure. To determine if there were region specific differences in 2DG uptake and distribution that could account for the differential effects of 2DG on ATP content, 14C-2DG accumulation in different regions of the embryo and VYS was determined over the 24-hr culture period. The uptake of 2DG was dependent on the medium 2DG concentration and suggested a higher accumulation in regions with decreased ATP. However, when the uptake was monitored for a 1-hr period after a 24-hr exposure, there was no region specific differences in 2DG uptake. These studies further document the adverse developmental effects of inhibitors of glucose utilization during the early stage of neurulation. The biochemical mechanism for induction of these defects is unclear, but an effect on ATP content does not appear to be solely responsible for the dysmorphogenesis.

Effects of glycolytic metabolites on preservation of high energy phosphate level and synaptic transmission in the granule cells of guinea pig hippocampal slices

Abstract: The present study was undertaken to investigate whether neural activity of hippocampal slices can be preserved after replacingd-glucose with glycolytic intermediate metabolites such as lactate, pyruvate and citrate or with other sugars such as fructose, mannose, maltose, glucosamine, sucrose and galactose. As an index of neural activity, population spikes (PS) were recorded in the granule cell layers after electrical stimulation to the perforant path of guinea pig hippocampal slices. In addition, we determined the levels of ATP and creatine phosphate (CrP) in each slice after the replacement ofd-glucose with these substrates, and correlated it with the neural activity. Substrates other thand-glucose could not maintain the PS for even 20 min although the slices perfused with medium containing lactate, pyruvate, galactose, fructose and maltose maintained similar levels of ATP and CrP as in slices incubated in thed-glucose-containing medium. These results indicate thatd-glucose is essential for the preservation of synaptic activity in addition to its main role as the substrate for energy production to maintain the levels of high energy phosphates.