Showing papers on "Glycolysis published in 1987"

Effect of severe burn injury on substrate cycling by glucose and fatty acids.

Abstract: Increases in metabolic rate and core temperature are common responses to severe injury. We have investigated the hypothesis that these responses are due to increases in substrate cycling. A substrate cycle exists when opposing, nonequilibrium reactions catalyzed by different enzymes are operating simultaneously. At least one of the reactions must involve the hydrolysis of ATP. Thus, a substrate cycle both liberates heat and increases energy expenditure, yet there is no net conversion of substrate to product. In studies in volunteers (n = 18) and in patients with severe burns who were in a hypermetabolic state (n = 18), we used stable-isotope tracers to quantify substrate cycling in the pathways of glycolysis and gluconeogenesis and a cycle involving the simultaneous breakdown and synthesis of stored triglyceride (triglyceride–fatty acid cycle). The total rates of triglyceride–fatty acid and glycolytic–gluconeogenic cycling were elevated in the patients by 450 and 250 percent, respectively (P<0.01...

Role of fructose 2,6-bisphosphate in the control of glycolysis in mammalian tissues.

Abstract: Glycolysis is an ubiquitous metabolic pathway. In addition to its catabolic role, glycolysis also serves an anabolic function by providing C3 precursors for the synthesis of fatty acids, cholesterol and amino acids. It is therefore an amphibolic pathway. The difference in metabolic orientation is tissue-specific and depends on the hormonal and nutritional state. Therefore, it is not surprising that different and specific regulatory mechanisms exist to control glycolysis under these various conditions. Cancer cells are a special case in which glycolysis is abnormally high. Qualitative and quantitative approaches have been developed to elucidate the control mechanisms of glycolysis. On the one hand, so-called 'rate-limiting' steps in the pathway have been identified by qualitative analysis. Reactions displaced far from equilibrium, particularly when catalysed by an allosterically regulated enzyme, have been assumed to qualify for control [1]. One such reaction is catalysed by phosphofructokinase (PFK-1). The experimental evidence supporting the key role of PFK-1 stems from the changes in the concentration of PFK-1 effectors observed when glycolysis is stimulated, e.g. following anoxia [2,3]. However, this information remains qualitative and may lead to an oversimplified view. On the other hand, the quantitative analysis of control, developed by Kacser & Burns [4] and Heinrich & Rapoport [5], allows the distribution of control among all steps in a pathway to be calculated. Such an approach has been applied to glycolysis in erythrocytes [6] and yeast [7], and it indicates that control is mainly distributed between hexokinase and PFK1. The study of the mechanism of action of glucagon on liver gluconeogenesis led to the discovery of fructose 2,6-bisphosphate (Fru-2,6-P2) [8,9]. This sugar phosphate is a potent stimulator of PFK-1 [10-12] and is also an inhibitor of fructose 1,6-bisphosphatase (FBPase-l) [13,14]. Fru-2,6-P2 has been detected in all mammalian tissues studied so far, as well as in fungi and plants, but not in prokaryotes [15]. Earlier reviews have dealt with the effect of Fru-2,6-P2 on its two main targets, PFK-1 and FBPase-1, together with the regulation of its synthesis and breakdown in relation to the control of glycolysis/gluconeogenesis in liver [15-22]. Since Fru-2,6-P2 is present in all mammalian tissues, it is tempting to suppose that it plays the major role in the control of glycolysis. The purpose of this article is to specify the conditions under which Fru-2,6-P2 plays a role in the control of glycolysis, and to review recent studies dealing with Fru-2,6-P2 metabolism in mammalian tissues other than liver.

Glycolysis preferentially inhibits ATP-sensitive K+ channels in isolated guinea pig cardiac myocytes

Abstract: In heart, glycolysis may be a preferential source of adenosine triphosphate (ATP) for membrane functions. In this study the patch-clamp technique was used to study potassium channels sensitive to intracellular ATP levels in permeabilized ventricular myocytes. Activation of these K+ channels has been implicated in marked cellular K+ loss leading to electrophysiological abnormalities and arrhythmias during myocardial ischemia. The results showed that glycolysis was more effective than oxidative phosphorylation in preventing ATP-sensitive K+ channels from opening. Experiments in excised inside-out patches suggested that key glycolytic enzymes located in the membrane or adjacent cytoskeleton near the channels may account for their preference for glycolytic ATP.

Rates of utilization and fates of glucose, glutamine, pyruvate, fatty acids and ketone bodies by mouse macrophages

Abstract: The concentrations of ATP and the ATP/AMP concentration ratios were maintained in thioglycollate-elicited mouse peritoneal macrophages incubated in vitro for 90 min in the presence or absence of added substrate: rates of glycolysis, lactate formation and glutamine utilization were approximately linear with time for at least 60 min of incubation. The rate of oxygen consumption by macrophages was only increased above the basal rate (i.e. that in the absence of added substrate) by addition of succinate or pyruvate, or by addition of the uncoupling agent carboxyl cyanide m-chlorophenylhydrazone ('CCCP'); it was decreased by 75% by the addition of KCN. These findings suggest that metabolism of endogenous substrate can provide most, if not all, of the energy requirement of these cells, at least for a short period. The rates of glucose and glutamine utilization by incubated macrophages were approx. 300 and 100 nmol/min per mg of protein respectively. A large proportion of the glutamine that is utilized is converted into glutamate and aspartate, and very little (perhaps less than 10%) is oxidized. Similarly almost all of the glucose that is utilized is converted into lactate and very little is oxidized. This characteristic is similar to that of resting lymphocytes and rapidly dividing cells; in non-proliferating macrophages it may be a mechanism to provide precision in control of the rate of biosynthetic processes that utilize intermediates of these pathways, e.g. purines and pyrimidines for mRNA for the synthesis of secretory proteins and glycerol 3-phosphate for phospholipid synthesis for membrane recycling. No utilization of acetoacetate or 3-hydroxybutyrate by macrophages was detected. In contrast, both butyrate and oleate were oxidized. The rate of [14C]oleate conversion into 14CO2 (1.3 nmol/h per mg of protein) could account for most of the oxygen consumption by incubated macrophages, suggesting that long-chain fatty acids might provide an important fuel in situ. This may be one explanation for the secretion of lipoprotein lipase by these cells, to provide fatty acids for oxidation from the degradation of local triacylglycerol.

Anaerobic energy release in skeletal muscle during electrical stimulation in men

Abstract: The quadriceps femoris muscles of seven men were electrically stimulated under extended anaerobic conditions to quantitate anaerobic energy release and the contribution of the glycolytic system to total ATP production. Muscles were intermittently stimulated 64 times at 20 Hz while leg blood flow was occluded. Each contraction lasted 1.6 s and was followed by 1.6 s of rest. The total contraction time was 102.4 s. Muscle biopsies were taken at rest and following 16, 32, 48, and 64 contractions. The ATP turnover rates during the four 16-contraction periods were 6.12, 2.56, 2.17, and 0.64 mmol X kg dry muscle-1 X s-1 contraction time. Glycolysis provided 58%, phosphocreatine 40% and a decreased ATP store 2% of the consumed energy during the initial 16 contractions. Glycolysis was responsible for 90% of the total ATP production beyond contraction 16. Absolute glycolytic ATP production decreased to 60, 55, and 17% of the amount in the initial 16 contractions during the final three periods, respectively. In conclusion glycolysis produced approximately 195 mmol ATP/kg dry muscle during the initial 48 contractions (76.8 s) and only approximately 15 mmol ATP/kg dry muscle during the final 16 contractions. Equivalent values for total ATP turnover were 278 and 16.5 mmol/kg dry muscle.

Mechanisms of hormonal regulation of hepatic glucose metabolism

Abstract: Acute hormonal regulation of liver carbohydrate metabolism mainly involves changes in the cytosolic levels of cAMP and Ca2+. Epinephrine, acting through beta 2-adrenergic receptors, and glucagon activate adenylate cyclase in the liver plasma membrane through a mechanism involving a guanine nucleotide-binding protein that is stimulatory to the enzyme. The resulting accumulation of cAMP leads to activation of cAMP-dependent protein kinase, which, in turn, phosphorylates many intracellular enzymes involved in the regulation of glycogen metabolism, gluconeogenesis, and glycolysis. These are (1) phosphorylase b kinase, which is activated and, in turn, phosphorylates and activates phosphorylase, the rate-limiting enzyme for glycogen breakdown; (2) glycogen synthase, which is inactivated and is rate-controlling for glycogen synthesis; (3) pyruvate kinase, which is inactivated and is an important regulatory enzyme for glycolysis; and (4) the 6-phosphofructo-2-kinase/fructose 2,6-bisphosphatase bifunctional enzyme, phosphorylation of which leads to decreased formation of fructose 2,6-P2, which is an activator of 6-phosphofructo-1-kinase and an inhibitor of fructose 1,6-bisphosphatase, both of which are important regulatory enzymes for glycolysis and gluconeogenesis. In addition to rapid effects of glucagon and beta-adrenergic agonists to increase hepatic glucose output by stimulating glycogenolysis and gluconeogenesis and inhibiting glycogen synthesis and glycolysis, these agents produce longer-term stimulatory effects on gluconeogenesis through altered synthesis of certain enzymes of gluconeogenesis/glycolysis and amino acid metabolism. For example, P-enolpyruvate carboxykinase is induced through an effect at the level of transcription mediated by cAMP-dependent protein kinase. Tyrosine amino-transferase, serine dehydratase, tryptophan oxygenase, and glucokinase are also regulated by cAMP, in part at the level of specific messenger RNA synthesis. The sympathetic nervous system and its neurohumoral agonists epinephrine and norepinephrine also rapidly alter hepatic glycogen metabolism and gluconeogenesis acting through alpha 1-adrenergic receptors. The primary response to these agonists is the phosphodiesterase-mediated breakdown of the plasma membrane polyphosphoinositide phosphatidylinositol 4,5-P2 to inositol 1,4,5-P3 and 1,2-diacylglycerol. This involves a guanine nucleotide-binding protein that is different from those involved in the regulation of adenylate cyclase. Inositol 1,4,5-P3 acts as an intracellular messenger for Ca2+ mobilization by releasing Ca2+ from the endoplasmic reticulum.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of glycolysis in adenylate depletion and repletion during work and recovery in teleost white muscle

Abstract: Measurements of metabolite concentrations before and immediately after swimming of trout to exhaustion indicate that all three potential endogenous fuels of anaerobic metabolism [glycogen, phosphocreatine (PCr) and adenosine triphosphate (ATP)] are utilized during anaerobic white muscle work. Lactate, H+, creatine Pi, NH4+ and inosine monophosphate (IMP) are formed in the process. Glycolysis is considered to be functionally (if loosely) coupled to adenylate depletion by setting up conditions favouring AMP-deaminase-catalysed formation of IMP and NH3. During recovery under these experimental conditions, glycolysis appears to outcompete oxidative metabolism as an ADP acceptor; therefore, in this kind of white muscle, glycolysis is also linked to IMP reconversion to AMP and thus to adenylate replenishment. The net process generates H+, which is why ATP replenishment must be completed before PCr concentrations can be returned to pre-exercise values.

31P NMR studies of ATP synthesis and hydrolysis kinetics in the intact myocardium

Abstract: The origin of the nuclear magnetic resonance (NMR)-measurable ATP in equilibrium P/sub i/ exchange and whether it can be used to determine net oxidative ATP synthesis rates in the intact myocardium were examined by detailed measurements of ATP in equilibrium P/sub i/ exchange rates in both directions as a function of the myocardial oxygen consumption rate (MVO/sub 2/) in (1) glucose-perfused, isovolumic rat hearts with normal glycolytic activity and (2) pyruvate-perfused hearts where glycolytic activity was reduced or eliminated either by depletion of their endogenous glycogen or by use of the inhibitor iodoacetate. In glucose-perfused hearts, the P/sub i/ ..-->.. ATP rate measured by the conventional two-site saturation transfer (CST) technique remained constant while MVO2 was increased approximately 2-fold. When the glycolytic activity was reduced, the P/sub i/ ..-->.. ATP rate decreased significantly, demonstrating the existence of a significant glycolytic contribution. The ATP ..-->.. P/sub i/ rates and rate:MVO ratios measured by the multiple-site saturation transfer method at two MVO/sub 2/ levels were equal to the corresponding P/sub i/..-->.. ATP rates and rate:MVO ratios obtained in the absence of a glycolytic contribution. The following conclusions are drawn from these studies: (1) unless the glycolytic contribution to the ATP in equilibriummore » P/sub i/ exchange is inhibited or is specifically shown not to exist, the myocardial P/sub i/ in equilibrium ATP exchange due to oxidative phosphorylation cannot be studied by NMR; (2) at moderate MVO/sub 2/ levels, the reaction catalyzed by the two glycolytic enzymes glyceraldehyde-3-phosphate dehydrogenase and 3-phosphoglycerate kinase is near equilibrium; (3) the ATP synthesis by the mitochondrial H/sup +/-ATPase occurs unidirectionally (i.e., the reaction is far out of equilibrium); (4) the operative P:O ratio in the intact myocardium under our conditions is significantly less than the canonically accepted value of 3.« less

Regulation and roles for alternative pathways of hexose metabolism in plants

Abstract: Plant cells have two cytoplasmic pathways of glycolysis and gluconeogenesis for the reversible interconversion of fructose 6-phosphate (F-6-P) and fructose 1,6-bisphosphate (F-1,6-P2). One pathway is described as a maintenance pathway that is catalyzed by a nucleotide triphosphate-dependent phosphofructokinase (EC 2.7.1.11; ATP-PFK) glycolytically and a F-1,6 bisphosphatase (EC 3.1.3.11) gluconeogenically. These are non-equilibrium reactions that are energy consuming. The second pathway, described as an adaptive pathway, is catalyzed by a readily reversible pyrophosphate-dependent phosphofructokinase (EC 2.7.1.90; PP-PFK) in an equilibrium reaction that conserves energy through the utilization and the synthesis of pyrophosphate. A constitutive regulator cycle is also present for the synthesis and hydrolysis of fructose 2,6-bisphosphate (F-2,6-P2) via a 2-kinase and a 2-phosphatase, respectively. The pathway catalyzed by the ATP-PFK and F-1,6-bisphosphatase, the maintenance pathway, is fairly constant in maximum activity in various plant tissues and shows less regulation by F-2,6-P2. Plants use F-2,6-P2 initially to regulate the adaptive pathway at the reversible PPi-PFK step. The adaptive pathway, catalyzed by PPi-PFK, varies in maximum activity with a variety of phenomena such as plant development or changing biological and physical environments. Plants can change F-2,6-P2 levels rapidly, in less than 1 min when subjected to rapid environmental change, or change levels slowly over periods of hours and days as tissues develop. Both types of change enable plants to cope with the environmental and developmental changes that occur during their lifetimes. The two pathways of sugar metabolism can be efficiently linked by the cycling of uridylates and pyrophosphate required for sucrose breakdown via a proposed sucrose synthase pathway. The breakdown of sucrose via the sucrose synthase pathway requires half the net energy of breakdown via the invertase pathway. Pyrophosphate occurs in plant tissues as a substrate pool for biosynthetic reactions such as the PPi-PFK or uridine diphosphate glucose pyrophosphorylase (EC 2.7.7.9; UDPG pyrophosphorylase) that function in the breakdown of imported sucrose. Also, pyrophosphate links the two glycolytic/gluco-neogenic pathways; and in a reciprocal manner pyrophosphate is produced as an energy source during gluconeogenic carbon flow from F-1,6-P2 toward sucrose synthesis.

Purification of rat papillary collecting duct cells: functional and metabolic assessment.

Abstract: Rat renal papillary collecting duct (PCD) cells were isolated using collagenase and hyaluronidase digestion and a three-step low-speed centrifugation. As assessed by binding of the lectin Dolichos biflorus and determination of vasopressin-sensitive adenylate cyclase and Na+-K+-ATPase, the enrichment of PCD cells over a crude papillary cell preparation was 1.8, 2.4, and 1.4, respectively. Microscopic evaluation indicated that the preparation was greater than 90% pure PCD cells. The isolated cells were viable as evident from the high K/Na ratio of intracellular electrolytes measured by electron probe analysis (5.3), from the high ATP/ADP ratio (2.15), and the metabolic response to alterations in Na transport. Exposure to 2 mM ouabain or removal of Na reduced O2 consumption by 25-35%; the uncoupler carboxylcyanide-m-chlorophenylhydrazone more than doubled O2 consumption. In the presence of 14 mM glucose and at a PO2 of 100 Torr the cells produced substantial quantities of lactate. This aerobic glycolysis may account for greater than 20% of the ATP production. In the presence of rotenone, glycolysis increased by 56% and was able to maintain the cellular ATP level at 65% of control. In the absence of any exogenous substrate PCD cells respired normally and had a close to normal ATP content, but lactate production was markedly decreased. These results demonstrate that viable PCD cells can be isolated from rat kidney. At normal PO2 and in the presence of D-glucose the cells show a substantial amount of aerobic glycolysis, although their mitochondrial respiration is not rate limiting. In the absence of glucose the cells derive the majority of their energy from an as yet unidentified endogenous substrate.

Fructose 6‐phosphate metabolism in plants

Abstract: The kinetic and regulatory properties of the ATP-dependent phosphofructokinase from various plant tissues are reviewed. Particular attention is given to the differences in properties between the plastid and cytosolic isozymes of this enzyme. A model for fructose 6-phosphate utilization in plants is presented which incorporates a role for the pyrophosphate-dependent phosphofructokinase.

Regulation of sugar transport and metabolism in lactic acid bacteria

Abstract: The phosphoenolpyruvate (PEP)-dependent lactose: phosphotransferase system (PTS), P-β-galactosidase, and enzymes of the d -tagatose-6P pathway, are prerequisite for rapid homolactic fermentation of lactose by Group N (‘starter’) streptococci. Moreover, the reactions of transport and catabolism constitute an open cycle in which ATP and lactic acid are metabolic products. The efficient and controlled operation of this cycle requires ‘fine-control’ mechanisms to ensure: (i) tight coupling between transport and energy-yielding reactions, (ii) co-metabolism of both glucose and galactose moieties of the disaccharide, and (iii) coordination of the rate of sugar transport to the rate of sugar catabolism. The elucidation of these fine-control mechanisms in intact cells of Streptococcus lactis has required the isolation of glucokinase (GK) and mannose-PTS defective mutants, the synthesis of novel lactose analogs, and the use of high resolution [ 31 P]NMR spectroscopy. It has been established that PEP provides the crucial link between transport and energy-yielding reactions of the PTS: glycolysis cycle, and that both ATP-dependent glucokinase and PEP-dependent mannose-PTS can participate in the phosphorylation of intracellular glucose. Finally, evidence has been obtained in vivo, for modulation of pyruvate kinase activity in response to fluctuation in, concentrations of positive (FDP), and negative (P i ) effectors of the allosteric enzyme. Fine-control of pyruvate kinase activity may in turn regulate: (i) the distribution of PEP to either the PTS or ATP synthesis, (ii) overall activity of the PTS: glycolysis cycle, and (iii) the formation of the endogenous PEP-potential in starved organisms. The accumulation of non-metabolizable PTS sugars (e.g., 2-deoxy- d -glucose) by growing cells can perturb these fine-control mechanisms and, by establishment of a PEP-dissipating futile cycle, may result in bacteriostasis.

Fructose prevents hypoxic cell death in liver.

Abstract: Perfusion of livers from fasted rats with nitrogen-saturated buffer caused hepatocellular damage within 30 min. Lactate dehydrogenase (LDH) was released at maximal rates of approximately 300 U . g-1 . h-1 under these conditions, and virtually all cells in periportal and pericentral regions of the liver lobule were stained with trypan blue. Infusion of glucose, xylitol, sorbitol, or mannitol (20 mM) did not appreciably change the time course or extent of damage due to perfusion with nitrogen-saturated perfusate. However, fructose (20 mM) completely prevented damage assessed by LDH release, trypan blue uptake, and ultrastructural changes for at least 2 h of perfusion. Neither glucose, xylitol, sorbitol, nor mannitol (20 mM) increased lactate formation above basal levels during hypoxia. On the other hand, fructose (0.4-20 mM) caused a concentration-dependent increase in lactate formation that reached maximal rates of approximately 180 mumol . g-1 . h-1. The dose-dependent increase in glycolytic lactate production from fructose correlated well with cellular protection reflected by decreases in LDH release. ATP:ADP ratios were also increased from 0.4 to 1.8 in a dose-dependent manner by fructose. The results indicate that fructose protects the liver against hypoxic cell death by the glycolytic production of ATP in the absence of oxygen.

Phosphorus NMR spectroscopy study of muscular enzyme deficiencies involving glycogenolysis and glycolysis

Abstract: We used phosphorus NMR spectroscopy to study 16 patients with muscular enzyme deficiencies affecting glycogenolysis and glycolysis. Study of phosphomonoester (Pm) kinetics and intracellular pH during exercise and recovery provided criteria for the distinction of these metabolic myopathies by NMR spectroscopy. The Pm peak was undetectable in patients lacking debrancher enzyme or phosphorylase. By contrast, in phosphofructokinase (PFK) or phosphoglycerate kinase (PGK) deficiency, the Pm peak was larger than that of inorganic phosphate in exercise, whereas it was always smaller in normal subjects. During recovery, the disappearance of Pm was slower in PGK than in PFK deficiency.

Enzymes of intermediary metabolism in tissue of the little skate, Raja erinacea

Abstract: Enzymes of intermediary metabolism were assayed in seven tissues (liver, kidney rectal gland, white muscle, red muscle, heart and brain) of the little skate, Raja erinacea, to assess the general metabolic desing of these tissues. Judged by the activities of enzymes linked to oxidative processes, the kidney, red and heart muscles, and rectal gland are the most metabolically active tissues, with ketone bodies potentially supplying the bulk of the required energy. The brain is only tissue with substantial potential to utilize exogenous glucose as an oxidative substrate; it also has the capacity to synthesize and degrade glycogen. The rectal gland may also use exogenous glucose, although its glycolytic potential is minor compared to that of other tissues. Amino acids, in addition to ketone bodies, may play significant metabolic role in these oxidative tissues based on the tissue activities of the amino transferases and the plasma content of amono acids. Enzyme activities in white skeletal muscle reflect the benthic, sluggish lifestyle of this species with low oxidative potential and rather limited anaerobic capacity. Hepatic tissue appears to be designed for the export of ketone bodies and to display a high potential for amino acid metbolism. The potential for gluconeogenesis, albeit at a low level, is realized only in the liver. Other pathways, especially fatty acid oxidation and pentose shunt, appear to play only monor roles in the intermediary metabolism of this elasmobranch.

Relationships among ATP synthesis, K+ gradients, and neurotransmitter amino acid levels in isolated rat brain synaptosomes.

Abstract: Correlations were made among ATP synthesis, transmembrane K+ gradients, and leakage of three amino acid neurotransmitters, gamma-aminobutyric acid (GABA), aspartate, and glutamate, in rat brain synaptosomes incubated under normoxic and respiration-limited conditions. Even under normoxic conditions, a substantial proportion of total ATP synthesis (8%) was provided by glycolysis. Limitation of respiration by approximately 30% through addition of amobarbital (Amytal) caused a twofold decrease in the creatine phosphate/creatine ([CrP]/[Cr]) ratio, and consequently the [ATP]/[ADP] ratio, and a threefold increase in lactate production. There was a detectable decrease in intracellular [K+] and small rises in external GABA, aspartate, and glutamate concentrations. More severe limitations in ATP synthesis caused larger declines in the [CrP]/[Cr] ratio and progressive leakage of K+ and neurotransmitter amino acids. A comparison of delta GATP and delta GNa, K showed the former to be larger by 6 kcal, which indicates that the plasma membrane Na+/K+ pump operates at far from equilibrium. Under respiration-limited conditions, even when total ATP synthesis decreased by approximately 80% and [ATP] declined to less than 0.4 mM, delta GATP was still larger than delta GNa,K. It is suggested that during hypoxia and ischemia, the activity of the plasma membrane Na+/K+ pump in brain becomes limited by [ATP], which falls below the Km value for the low-affinity regulatory site on the enzyme. This failure of the pump and consequent collapse of the ion gradients may contribute to the leakage of neurotransmitter amino acids that occurs in these pathological states.

Glycolytic flux in Zymomonas mobilis: enzyme and metabolite levels during batch fermentation.

Abstract: The rate at which Z. mobilis (Entner-Doudoroff pathway) converts high concentrations of glucose (20%) into ethanol plus CO2 changes as ethanol accumulates in the surrounding broth. This decline in glycolytic activity (per milligram of cell protein) does not result from inhibitory effects of ethanol, which can be reversed immediately by ethanol removal. The peak of fermentative activity (58 mumol of CO2 evolved per mg of cell protein per h) occurred after the accumulation of 1.1% ethanol (18 h) and declined to one-half this rate after 30 h (6.2% accumulated ethanol), although the cell number continued to increase. These times corresponded to the end of exponential growth and to the onset of the stationary phase (on the basis of measurement of cell protein), respectively. An examination of many of the requirements for fermentation (nucleotides, magnesium, enzyme levels, intracellular pH, delta pH) revealed three possible reasons for this early decline in activity: decreased abundance of nucleotides, a decrease in internal pH from 6.3 to 5.3, and a decrease in the specific activities of two glycolytic enzymes (pyruvate kinase and glyceraldehyde-3-phosphate dehydrogenase). 31P nuclear magnetic resonance spectra of perchlorate extracts from cells fermenting in broth revealed very low levels of glycolytic intermediates (Entner-Doudoroff pathway) in cells examined at the peak of fermentative activity (18-h cells) in comparison with cells examined at a later stage (30-h cells), consistent with limitation of the fermentation rate by glycolytic enzymes near the end of the pathway. It is likely that cell death (loss of colony-forming ability) and the collapse of delta pH also contribute to the further decline in fermentative activity after 30 h.

Coupling of aerobic glycolysis and Na+-K+-ATPase in renal cell line MDCK.

Abstract: The relation between the activity of the Na+-K+-ATPase and the metabolic source of ATP was investigated in suspensions of MDCK cells. The pump activity of Na+-K+-ATPase was estimated from the initial rate of ouabain-sensitive K+ uptake into K+-depleted cells. Uptake was initiated by the reintroduction of K+ to the medium in which the cells were suspended. The metabolic source of ATP was varied by changing the substrates supplied to the suspension. Cells respiring on glutamine produced ATP from oxidative metabolism alone, whereas cells incubated with glucose and glutamine produced ATP via glycolysis and oxidative phosphorylation. Over a wide range of extracellular K+ concentrations, the initial rate of K+ uptake was faster in cells incubated with glucose and glutamine when compared with cells incubated with glutamine alone. Kinetic analysis together with ouabain-binding data demonstrated that this increase in K+ uptake was due to an increase in maximal velocity (Vmax) at a constant number of Na+-K+-ATPase transport sites. In addition, steady-state studies revealed that the addition of glucose to K+-depleted cells respiring on glutamine alone resulted in a net ouabain-sensitive influx of K+. These data demonstrate that in MDCK cells the maximal capacity for transport via the Na+-K+-ATPase is greater when ATP is produced from both glycolysis and oxidative phosphorylation than when ATP is produced from oxidative phosphorylation alone.(ABSTRACT TRUNCATED AT 250 WORDS)

Compartmentation of carbohydrate metabolism in vascular smooth muscle

Abstract: In vascular smooth muscle, oxidative phosphorylation and glycolysis are independently regulated. Previous studies indicated that the independent regulation of these pathways was related to a compartmentation of carbohydrate metabolism. To further study carbohydrate metabolism, glucose transport and the incorporation of radiolabel from glucose into glycogen and lactate were measured after the oxidative and glycolytic pathways were independently altered. Ouabain stimulated mechanical activity, oxygen consumption, and glycogenolysis, whereas lactate production was decreased. Although glycogenolysis was substantial, glucose was the only substrate for lactate, indicating that intermediates derived from glycogen do not mix with those from glucose uptake. Thus glycogenolysis and glycolysis are carried out by independent enzymatic pathways. Insulin-stimulated lactate production and glucose transport without affecting the other parameters. Again, lactate was produced only from glucose. Phenytoin decreased isometric tension and oxygen consumption, whereas stimulating lactate production and glycogenolysis. Glycogen was the primary substrate for the lactate produced. Our findings indicate that the compartmentation of substrate utilization is ascribable to the coordination of glycogenolysis with increases in oxygen consumption and the coupling of glycolysis to the Na-K-adenosine triphosphatase. The coupling of independent energy providing pathways to specific endergonic processes indicates a mechanism by which cellular energetic efficiency may be optimized.

Effects of various metabolic conditions and of the trivalent arsenical melarsen oxide on the intracellular levels of fructose 2,6-bisphosphate and of glycolytic intermediates in Trypanosoma brucei.

Abstract: Upon differential centrifugation of cell-free extracts of Trypanosoma brucei, 6-phosphofructo-2-kinase and fructose-2,6-bisphosphatase behaved as cytosolic enzymes. The two activities could be separated from each other by chromatography on both blue Sepharose and anion exchangers. 6-phosphofructo-2-kinase had a Km for both its substrates in the millimolar range. Its activity was dependent on the presence of inorganic phosphate and was inhibited by phosphoenolpyruvate but not by citrate or glycerol 3-phosphate. The Km of fructose-2,6-bisphosphatase was 7 microM; this enzyme was inhibited by fructose 1,6-bisphosphate (Ki = 10 microM) and, less potently, by fructose 6-phosphate, phosphoenolpyruvate and glycerol 3-phosphate. Melarsen oxide inhibited 6-phosphofructo-2-kinase (Ki less than 1 microM) and fructose-2,6-bisphosphatase (Ki = 2 microM) much more potently than pyruvate kinase (Ki greater than 100 microM). The intracellular concentrations of fructose 2,6-bisphosphate and hexose 6-phosphate were highest with glucose, intermediate with fructose and lowest with glycerol and dihydroxyacetone as glycolytic substrates. When added with glucose, salicylhydroxamic acid caused a decrease in the concentration of fructose 2,6-bisphosphate, ATP, hexose 6-phosphate and fructose 1,6-bisphosphate. These studies indicate that the concentration of fructose 2,6-bisphosphate is mainly controlled by the concentration of the substrates of 6-phosphofructo-2-kinase. The changes in the concentration of phosphoenolpyruvate were in agreement with the stimulatory effect of fructose 2,6-bisphosphate on pyruvate kinase. At micromolar concentrations, melarsen oxide blocked almost completely the formation of fructose 2,6-bisphosphate induced by glucose, without changing the intracellular concentrations of ATP and of hexose 6-phosphates. At higher concentrations (3-10 microM), this drug caused cell lysis, a proportional decrease in the glycolytic flux, as well as an increase in the phosphoenolypyruvate concentrations which was restricted to the extracellular compartment. Similar changes were induced by digitonin. It is concluded that the lytic effect of melarsen oxide on the bloodstream form of T. brucei is not the result of an inhibition of pyruvate kinase.

Muscle energy metabolism in human phosphofructokinase deficiency as recorded by 31P nuclear magnetic resonance spectroscopy.

Abstract: 31P nuclear magnetic resonance studies of a patient with phosphofructokinase deficiency in muscle provided the following new findings: First, ATP metabolism is disturbed at rest and during exercise. At rest, ATP levels are lower than normal and continue to decline during exercise. Second, exercise kinetics are normal, suggesting a normal mitochondrial fuel supply although glycolysis is blocked. Third, no "phosphate trapping" is observed during prolonged low-level exercise. Fourth, postexercise recovery is abnormally prolonged by the slow dephosphorylation of sugar phosphates, which has an in vivo half-life of about nine minutes. These findings demonstrate how muscle tissue adapts to a block in a major bioenergetic pathway.

Regulation of anaerobic ATP-generating pathways in trout fast-twitch skeletal muscle

Abstract: In the process of defining the recruitment of fuel and pathway selection in rainbow trout fast-twitch white skeletal muscle, it was clear that the near-maximal myosin adenosinetriphosphatase activity during a 10-s sprint was supported solely by phosphocreatine hydrolysis. A conservative estimate of the ATP turnover was 188 mumol X g wet wt-1 X min-1. It was not until the rate and force of contraction decreased that the relative contribution of anaerobic glycogenolysis became increasingly important. Over a 10-min period of burst swimming at approximately 120% of maximum aerobic steady-state swimming velocity of trout determined in a Brett-type swim tunnel, fatigue was associated with the near-depletion of glycogen in white muscle. The ATP turnover supported by anaerobic glycogenolysis was 78 mumol X g wet wt-1 X min-1. The glycolytic pathway appeared functional at this time with control sites being identified at hexokinase and phosphofructokinase (PFK-1). PFK-1 did not appear to be inhibited by low muscle pH (pH 6.66). In another exercise protocol lasting 30 min, complete exhaustion was related to glycogen depletion. The sum of all glycolytic intermediates from glucose 6-phosphate to pyruvate at exhaustion decreased by a dramatic 80% compared with the 25% decrease for the 10-min fatigue swimming protocol. This large depletion of glycolytic intermediates was accompanied by an 80% fall in ATP, a 70-80% reduction in the ATP/ADP and phosphorylation potential, and a 2.5-fold increase in the NAD/NADH. Associated with these changes was a marked displacement of the phosphoglycerate kinase (PGK), and the combined glyceraldehyde-3-phosphate dehydrogenase-PGK reactions from thermodynamic equilibrium. As a general conclusion, fatigue and exhaustion should be viewed as a multicomponent biochemical process in response to low glycogen and not leveled at one particular step of the glycolytic pathway.

Glucokinase in pancreatic B-cells and its inhibition by alloxan.

Abstract: Characterization of glucokinase in pancreatic B-cells from ob/ob mice and from rat liver revealed identical characteristics. A narrow substrate specificity; high Km values for the two substrates, D-glucose and D-mannose, in the range of 10 and 20 mmol/l, respectively; higher Vmax values for D-glucose than for D-mannose; inhibition of glucokinase activities by D-mannoheptulose and by a specific glucokinase antibody. These characteristics distinguish glucokinase in soluble cytoplasmic fractions of pancreatic B-cells and liver from low Km hexokinases. Alloxan is a pancreatic B-cell cytotoxic agent, which has been widely used as a tool for the elucidation of the mechanisms of insulin secretion, because its inhibitory action on insulin secretion has been presumed to be intimately related to the mechanism of glucose-induced insulin secretion. Alloxan inhibited glucokinase but not hexokinase activity in cytoplasmic fractions of pancreatic B-cells and liver. The half maximal inhibitory concentration of alloxan was 5 mumol/l. Glucokinase activity was protected from alloxan toxicity only by D-glucose and D-mannose; the alpha anomer of D-glucose provided significantly greater protection than the beta anomer. The non-metabolizable sugar 3-O-methyl-D-glucose did not provide protection of glucokinase activity against inhibition by alloxan. Thus, inhibition of pancreatic B-cell glucokinase may contribute to the inhibition of glucose-induced insulin secretion by alloxan. These results support the contention that glucokinase regulates the metabolic flux rate through the glycolytic chain in the pancreatic B-cell and thereby generates the signal for glucose-induced insulin secretion.

Acetate oxidation to CO 2 via a citric acid cycle involving an ATP-citrate lyase: a mechanism for the synthesis of ATP via substrate level phosphorylation in Desulfobacter postgatei growing on acetate and sulfate

Abstract: Desulfobacter postgatei is an acetate-oxidizing, sulfate-reducing bacterium that metabolizes acetate via the citric acid cycle. The organism has been reported to contain a si-citrate synthase (EC 4.1.3.7) which is activated by AMP and inorganic phosphate. It is show now, that the enzyme mediating citrate formation is an ATP-citrate lyase (EC 4.1.3.8) rather than a citrate synthase. Cell extracts (160,000xg supernatant) catalyzed the conversion of oxaloacetate (apparent K m=0.2 mM), acetyl-CoA (app. K m=0.1 mM), ADP (app. K m=0.06 mM) and phosphate (app. K m=0.7 mM) to citrate, CoA and ATP with a specific activity of 0.3 μmol·min-1·mg-1 protein. Per mol citrate formed 1 mol of ATP was generated. Cleavage of citrate (app. K m=0.05 mM; V max=1.2 μmol · min-1 · mg-1 protein) was dependent on ATP (app. K m=0.4 mM) and CoA (app. K m=0.05 mM) and yielded oxaloacetate, acetyl-CoA, ADP, and phosphate as products in a stoichiometry of citrate:CoA:oxaloacetate:ADP=1:1:1:1. The use of an ATP-citrate lyase in the citric acid cycle enables D. postgatei to couple the oxidation of acetate to 2 CO2 with the net synthesis of ATP via substrate level phosphorylation.

Glycolysis and the regulation of cryoprotectant synthesis in liver of the freeze tolerant wood frog

Abstract: Wood frogs,Rana sylvatica, were sampled after freezing at −4°C (a short time course from 2 to 70 min after the appearance of the freezing exotherm) and thawing (20 h at 3°C after 70 min of freezing) and the regulation of liver glycolysis with respect to cryoprotectant glucose synthesis was examined. Within 5 min of the initiation of freezing, cryoprotectant concentrations in blood and liver had begun to increase. This was correlated with a rapid rise in the levels of hexose monophosphates in liver, including a 2.5 fold increase in glucose-6-P and 10 fold rise in fructose-6-P contents within the first 5 min post-exotherm. Contents of fructose-1,6-P2, fructose-2,6-P2, triose phosphates, P-enolpyruvate, and pyruvate did not significantly change over the course of freezing. Thawing sharply reduced the levels of hexose monophosphates in liver but raised P-enolpyruvate content by 2.3 fold. Changes in the contents of glycolytic intermediates over the freeze/thaw course are consistent with an inhibitory block of glycolysis at phosphofructokinase during freezing in order to facilitate a rapid glycogenolysis and production of cryoprotectant; during thawing, however, glycolysis appears to be inhibited at the level of pyruvate kinase. Possible regulatory control of cryoprotectant synthesis by covalent modification of liver glycolytic enzymes was examined. Glycogenolysis during freezing was facilitated by an increase in the percentage of glycogen phosphorylase in the activea (phosphorylated) form and also by an increase in the total amount (a+b) of enzyme expressed. For phosphofructokinase, kinetic changes as a result of freezing included a 40% reduction inK m for fructose-6-P, a 60% decrease inK a for fructose-2,6-P2, and a 2 fold increase in I50 for ATP. These changes imply a freezing-induced covalent modification of the enzyme but are not, apparently, the factors responsible for inhibition of glycolytic flux at the phosphofructokinase locus during glucose synthesis. Kinetic parameters of pyruvate kinase were not altered over the freeze/thaw course.