EC:2.7.1.1 - FACTA Search

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Query: EC:2.7.1.1 (hexokinase)
5,274 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The steady-state oxidation of 2 mM pyruvate in pigeon and rat heart mitochondria in the presence of ADP-glucose-hexokinase load can be strongly inhibited by excess (10-40 mM) of pyruvate or beta-hydroxybutyrate. This inhibition is accompanied by the accumulation of alpha-ketoglutarate and a decrease of malate. The mechanism of such substrate inhibition may be associated with the limitation of the tricarboxylic acid cycle flux by low levels of oxaloacetate and free CoA due to their being trapped as alpha-ketoglutarate and acetyl-CoA. Contrary to pyruvate, the ketone bodies in the absence of other substrates produce self-inhibition of their oxidation at as low concentrations as 0.5-1 mM. At 10-15 mM of acetoacetate, a complete suppression of respiration may develop. At a high load (preset by ADP or the uncoupler CCCP), the suppression is characterised by the accumulation of malate and a decrease of alpha-ketoglutarate. At low loads, the reverse distribution of the intermediates takes place. It is concluded that the system of ketone body oxidation in heart mitochondria is an example of biochemical triggers (systems with two alternative stable states).
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PMID:Stoichiometric traps in the tricarboxylic acid cycle. I. Self-inhibition and triggering phenomena. 357 62

Maximum activities of some key enzymes of metabolism were studied in elicited (inflammatory) macrophages of the mouse and lymph-node lymphocytes of the rat. The activity of hexokinase in the macrophage is very high, as high as that in any other major tissue of the body, and higher than that of phosphorylase or 6-phosphofructokinase, suggesting that glucose is a more important fuel than glycogen and that the pentose phosphate pathway is also important in these cells. The latter suggestion is supported by the high activities of both glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase. However, the rate of glucose utilization by 'resting' macrophages incubated in vitro is less than the 10% of the activity of 6-phosphofructokinase: this suggests that the rate of glycolysis is increased dramatically during phagocytosis or increased secretory activity. The macrophages possess higher activities of citrate synthase and oxoglutarate dehydrogenase than do lymphocytes, suggesting that the tricarboxylic acid cycle may be important in energy generation in these cells. The activity of 3-oxoacid CoA-transferase is higher in the macrophage, but that of 3-hydroxybutyrate dehydrogenase is very much lower than those in the lymphocytes. The activity of carnitine palmitoyltransferase is higher in macrophages, suggesting that fatty acids as well as acetoacetate could provide acetyl-CoA as substrate for the tricarboxylic acid cycle. No detectable rate of acetoacetate or 3-hydroxybutyrate utilization was observed during incubation of resting macrophages, but that of oleate was 1.0 nmol/h per mg of protein or about 2.2% of the activity of palmitoyltransferase. The activity of glutaminase is about 4-fold higher in macrophages than in lymphocytes, which suggests that the rate of glutamine utilization could be very high. The rate of utilization of glutamine by resting incubated macrophages was similar to that reported for rat lymphocytes, but was considerably lower than the activity of glutaminase.
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PMID:Metabolism of glucose, glutamine, long-chain fatty acids and ketone bodies by murine macrophages. 380 Sep 71

1. The activities of gluconeogenic and glycolytic enzymes and the concentrations of citrate, ammonia, amino acids, glycogen, glucose 6-phosphate, acetyl-CoA, lactate and pyruvate were measured in kidney cortex of normal, diabetic, cortisone-treated and growth hormone-treated rats. 2. In kidney cortex of diabetic, cortisone-treated and growth hormone-treated rats the activities of glucose 6-phosphatase (EC 3.1.3.9), fructose 1,6-diphosphatase (EC 3.1.3.11) and phosphopyruvate carboxylase (EC 4.1.1.32) were increased. 3. The activities of glutamate dehydrogenase (EC 1.4.1.3), alanine aminotransferase (EC 2.6.1.2), aspartate aminotransferase (EC 2.6.1.10) and pyruvate carboxylase (EC 6.4.1.1) were increased in diabetic and cortisone-treated rats. In growth hormone-treated rats the activity of aspartate aminotransferase was depressed but those of the other three enzymes were unchanged. 4. The activity of hexokinase (EC 2.7.1.1) was not altered in any of these conditions. Phosphofructokinase (EC 2.7.1.11) activity was depressed only in growth hormone-treated rats. Pyruvate kinase (EC 2.7.1.40) activity was depressed in cortisone-treated and growth hormone-treated rats but unchanged in diabetic rats. 5. Amino acids, acetyl-CoA and glucose 6-phosphate contents were increased in rat kidneys in all these three conditions. Ammonia content was increased in diabetic and cortisone-treated rats but was markedly diminished in growth hormone-treated rats. 6. The [lactate]/[pyruvate] ratio was elevated in diabetic and cortisone-treated rats but unchanged in growth hormone-treated rats. Citrate content was increased in the kidney cortex of diabetic and growth hormone-treated rats but was unchanged in cortisone-treated rats. The activity of ATP citrate lyase (EC 4.1.3.8) was depressed in diabetic and growth hormone-treated rats but was increased in cortisone-treated rats. 7. Glycogen content was moderately elevated in growth hormone-treated rats and markedly elevated in diabetic rats, whereas no change in glycogen content was observed in cortisone-treated rats. Glycogen synthetase (EC 2.4.1.11) activity was unchanged in all these three conditions. Phosphorylase (EC 2.4.1.1) activity was not affected in cortisone-treated rats but was depressed in diabetic and growth hormone-treated rats.
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PMID:Evaluation of the rate-limiting steps in the pathway of glucose metabolism in kidney cortex of normal, diabetic, cortisone-treated and growth hormone-treated rats. 434 56

(1) A ;cycling' method involving citrate synthase (EC 4.1.3.7) and malate dehydrogenase (EC 1.1.1.37) was modified by the inclusion of succinyl-CoA synthetase (EC 6.2.1.5) and hexokinase (EC 2.7.1.1) to permit the determination of very small amounts of succinyl-CoA in addition to CoA and acetyl-CoA. (2) Application of this technique to blowfly (Phormia regina) flight-muscle extracts reveals no change in acetyl-CoA concentration, a slight fall in CoA concentration and a rise in succinyl-CoA concentration during flight. (3) Extraction of isolated mitochondria during controlled (state 4) pyruvate oxidation reveals essentially only acetyl-CoA. Activation of respiration by ADP (state 3) or uncoupling agents leads to a fall in acetyl-CoA and a rise in CoA and succinyl-CoA content. (4) The presence of glycerol phosphate in addition to pyruvate results in a lower acetyl-CoA content in state 4. (5) It is contended that these results are consistent with a primary control of one of the reactions of the tricarboxylate cycle, rather than of pyruvate dehydrogenase, during the state 4 oxidation of pyruvate by isolated mitochondria, and that the modulation of citrate synthase activity by the ratio of acetyl-CoA/succinyl-CoA is unimportant under these conditions.
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PMID:The control of tricarboxylate-cycle of oxidations in blowfly flight muscle. The steady-state concentrations of coenzyme A, acetyl-coenzyme A and succinyl-coenzyme A in flight muscle and isolated mitochondria. 446 39

1. The work of the perfused rat heart was acutely increased by raising the aortic pressure in the Langendorff preparation from 50 to 120mmHg; within 1 min in perfusions with media containing glucose or glucose+acetate, rates of oxygen consumption and tricarboxylate-cycle turnover increased 2.5-fold, glycolysis rate doubled and oxidation of triglyceride fatty acid was strikingly enhanced. 2. Increased cardiac work had no significant effects on the heart concentrations of creatine phosphate, ATP, ADP or 5'-AMP. The only significant changes in tricarboxylate-cycle intermediates were a decrease in malate in perfusions with glucose and decreases in acetyl-CoA and citrate and an increase in aspartate in perfusions with glucose+acetate. 3. Measurements of intracellular concentrations of hexose phosphates, glucose and glycogen indicated that work accelerated glycolysis by activation of phosphofructokinase and subsequently hexokinase; the activation could not be accounted for by changes in the known effectors of phosphofructokinase. 4. Acetate at either perfusion pressure increased heart concentrations of acetyl-CoA, citrate, glutamate and malate and decreased that of aspartate; acetate increased tricarboxylate-cycle turnover by 50-60% and inhibited glycolysis and pyruvate oxidation. 5. In view of the markedly different effects of acetate and of cardiac work on the concentrations of cycle intermediates the changes that accompany acetate utilization may be specifically concerned with the regulatory functions of the cycle in control of glycolysis and pyruvate oxidation and not with the associated increase in cycle turnover. It is suggested that the concentrations of key metabolites controlling the rate of cycle turnover may fluctuate with each heart beat and that this may explain why no significant changes (for example, in adenine nucleotide concentrations) have been detected with increased work in the present study.
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PMID:The effects of increased heart work on the tricarboxylate cycle and its interactions with glycolysis in the perfused rat heart. 508 51

Just before birth, changes occur in the metabolic capacities of rat liver so that the animal can adapt to changes in the substrate supply. In utero, glucose is the main energy-generating fuel and the liver metabolism is directed towards glucose degradation. The activities of the rate-limiting enzymes of glycolysis, hexokinase and phosphofructokinase, are high. In preparation for post-natal life, when the continuous glucose supply from the mother is interrupted, very large amounts of glycogen are stored in the late fetal liver. With the intake of the fat-rich and carbohydrate-poor milk diet, the animal develops the ability to synthesize glucose de novo from non-carbohydrate precursors. During suckling, metabolic energy is derived mainly from the beta-oxidation of fatty acids, which in turn is an essential prerequisite for the high rate of gluconeogenesis, by yielding acetyl-CoA for the activation of pyruvate carboxylase and by generating a high NADH/NAD ratio for the shift of the glyceraldehyde 3-phosphate dehydrogenase reaction in the direction of glucose formation.--The developmental adaptation of metabolism and the process of enzymatic differentiation are closely connected with the maturation of the endocrine system and the changes in the concentration of circulating hormones. The neonatal regulation of phosphoenolpyruvate carboxykinase and of tyrosine aminotransferase by variations in the hormonal milieu around birth, and also the interaction of hormonal and nutritional factors in the induction of serine dehydratase and glucokinase at the end of the suckling period, will be discussed in detail.
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PMID:Biochemistry of liver development in the perinatal period. 613 74

When 1-, 2- and 9-month-old rats adapted to a stock diet were fed a fat-free/high-sucrose diet, the changes in the substrate and effector levels of glycolytic and lipogenic enzymes in liver, and the effects of aging on the changes were investigated. By the sucrose diet feeding, the activities of phosphofructokinase, pyruvate kinase and fructokinase were increased, whereas hexokinase activity was markedly decreased. The fructose 1-phosphate levels were significantly increased in the liver, while conversely, the glucose 6-phosphate and fructose 6-phosphate levels were decreased. As a result of sucrose diet feeding, the changed enzyme activities would appear to be consistent with the metabolic pathway for fructose being predominant over that for glucose. Consequently, the concentrations of acetyl-CoA, citrate and malate were increased and would in turn appear to favour an increase in lipogenesis. The changes in the substrate and effector levels of lipogenic enzymes were reduced with aging, as were those in the enzyme activities. However, the changes in enzyme activities and metabolite levels of glycolysis were not much affected with aging.
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PMID:Effect of aging on changes in substrate and effector levels of rat-liver glycolytic and lipogenic enzymes during induction. 614 60

A sensitive and specific GTP-activated Ca2+ translocation process induces rapid Ca2+ movements within cells and appears to reflect G protein-induced membrane fusion or junctional communication between discrete subpopulations of Ca(2+)-pumping organelles (Ghosh, T. K., Mullaney, J. M., Tarazi, F. I., and Gill, D. L. (1989) Nature 340, 236-239). Since fatty acylation can modify G protein action, modification of GTP-induced Ca2+ translocation by fatty acyl-CoA was investigated to throw light on the mechanism underlying Ca2+ transfer. Using permeabilized DDT1MF-2 smooth muscle cells, 2 microM palmitoyl-CoA completely blocked Ca2+ release activated by 20 microM GTP, while having no effect on inositol 1,4,5-trisphosphate-induced Ca2+ release. The IC50 (50% inhibitory concentration) for palmitoyl-CoA was 0.5 microM. Above 3 microM, palmitoyl-CoA inhibited Ca2+ accumulation. Fatty acyl chain length was important, C-13 to C-16 fatty acyl-CoA esters all fully blocking the action of GTP; the IC50 for myristoyl-CoA was also 0.5 microM. C-18 or larger acyl groups had diminished effectiveness as did C-8 or smaller acyl groups. Acetyl-CoA had no blocking effect. In contrast, 10 microM CoA itself blocked GTP-induced Ca2+ release. CoA required a free sulfhydryl group to block, desulfo-CoA having no effect. Removal of ATP by hexokinase and glucose prevented the action of CoA but not palmitoyl-CoA. The free sulfhydryl and ATP requirements indicated CoA was being acylated by endogenous fatty-acyl-CoA synthetase to be effective. The nonhydrolyzable myristoyl-CoA analog, S-(2-oxopentadecyl)-CoA, blocked the GTP effect identically to myristoyl- and palmitoyl-CoA (IC50 = 0.5 microM); thus, fatty acyl transfer is not required, indicating that blockade is due to a direct allosteric modification of a component of the GTP-activated process by acyl-CoA esters. Palmitoyl-CoA not only inhibited but completely reversed GTP-activated Ca2+ release, resulting in the released Ca2+ being taken back up into pools. In the presence of oxalate, GTP-activated Ca2+ transfer results in a substantial increase in Ca2+ accumulation; palmitoyl-CoA also completely reversed this effect resulting in rapid termination of Ca2+ uptake. This reversal provides strong evidence that GTP-activated Ca2+ translocation does not reflect a membrane fusion event. Instead, it likely represents formation of a reversible junction or pore between organelles which may be a required prefusion event.
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PMID:Modification of GTP-activated calcium translocation by fatty acyl-CoA esters. Evidence for a GTP-induced prefusion event. 798 31

Regulation of carbohydrate and fat utilization by skeletal muscle at rest and during exercise has been the subject of investigation since the early 1960s when Randle et al. proposed the so-called glucose-fatty acid cycle to explain the reciprocal relationship between carbohydrate and fat metabolism. The suggested mechanisms were based on the premise that an increase in fatty acid (FA) availability would result in increased fat metabolism and inhibition of carbohydrate metabolism. Briefly, accumulation of acetyl-CoA would result in inhibition of pyruvate dehydrogenase (PDH), accumulation of citrate would inhibit phosphofructokinase (PFK), and accumulation of glucose-6-phosphate (G6P) would reduce hexokinase (HK) activity. Ultimately, this would inhibit carbohydrate metabolism with increasing availability and oxidation of FA. Although there is some evidence for the existence of the glucose-FA cycle at rest and during low-intensity exercise, it cannot explain substrate use at moderate to high exercise intensities. More recently, evidence has accumulated that increases in glycolytic flux may decrease fat metabolism. Potential sites of regulation are the transport of FA into the sarcoplasma, lipolysis of intramuscular triacylglycerol (IMTG) by hormone-sensitive lipase (HSL), and transport of FA across the mitochondrial membrane. There are several potential regulators of fat oxidation: first, malonyl-CoA concentration, which is formed from acetyl-CoA, catalyzed by the enzyme acetyl-CoA carboxylase (ACC), which in turn will inhibit carnitine palmitoyl transferase I (CPT I). Another possible mechanism is accumulation of acetyl-CoA that will result in acetylation of the carnitine pool, reducing the free carnitine concentration. This could theoretically reduce FA transport into the mitochondria. There is also some recent evidence that CPT I is inhibited by small reductions in pH that might be observed during exercise at high intensities. It is also possible that FA entry into the sarcolemma is regulated by translocation of FAT/CD36 in a similar manner to glucose transport by GLUT-4. Studies suggest that the regulatory mechanisms may be different at rest and during exercise and may change as the exercise intensity increases. Regulation of skeletal muscle fat metabolism is clearly multifactorial, and different mechanisms may dominate in different conditions.
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PMID:Regulation of fat metabolism in skeletal muscle. 1207 50

1. The effects of adenine nucleotides on pyruvate metabolism by isolated liver cells and isolated mitochondria have been investigated. The amount of pyruvate carboxylated has been estimated by determining the tricarboxylic acid-cycle intermediates, glutamate and aspartate accumulating in the incubation medium. The extent of pyruvate oxidation has been assessed by measuring oxygen uptake and the yield of (14)CO(2) from [1-(14)C]pyruvate and [2-(14)C]pyruvate. 2. When catalytic amounts of adenine nucleotides (1-2mm) were added to suspensions of isolated liver cells incubated with pyruvate an ATP:ADP ratio greater than 6:1 was maintained. Both pyruvate oxidation to acetyl-CoA and the oxidation of acetyl-CoA through the tricarboxylic acid cycle were stimulated but pyruvate carboxylation was not affected. The production of acetyl-CoA exceeded the capacity of the cells for the oxidation of acetyl-CoA and the excess was converted into ketone bodies. 3. If a low ATP:ADP ratio was maintained in isolated cells or mitochondria by incubating them with dinitrophenol or hexokinase, pyruvate carboxylation was grossly inhibited, oxygen uptake depressed and ketone-body formation stimulated. Measurement of oxaloacetate concentrations confirmed that under these conditions oxaloacetate was rate-limiting for the oxidation of acetyl-CoA via the tricarboxylic acid cycle. The inclusion in the incubation medium of fumarate (1.25mm) completely prevented the ketogenic action of dinitrophenol or hexokinase. 4. When ADP (5mm) was added to a suspension of isolated liver cells incubated with pyruvate an actual ADP concentration of about 1mm was attained. This brought about effects on pyruvate metabolism similar to those obtained with dinitrophenol or hexokinase. 5. These results support the concept that the relative concentrations of adenine nucleotides within the liver cell may play a role in governing the rates of pyruvate oxidation and carboxylation. In addition, they provide further evidence that the availability of oxaloacetate in the liver cell can play a key role in determining whether acetyl-CoA arising from pyruvate is oxidized through the tricarboxylic acid cycle or converted into ketone bodies.
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PMID:THE EFFECTS OF ADENINE NUCLEOTIDES ON PYRUVATE METABOLISM IN RAT LIVER. 1434 91

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