EC:6.4.1.1 - FACTA Search

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Query: EC:6.4.1.1 (pyruvate carboxylase)
1,516 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A mitochondrial model of gluconeogenesis and the tricarboxylic acid cycle, where pyruvate is metabolized via pyruvate carboxylase and pyruvate dehydrogenase, and pyruvate kinase is examined. The effect of the rate of tricarboxylic acid flux and the rates of the three reactions of pyruvate metabolism on the labeling patterns from [14C]pyruvate and [24C]acetate are analyzed. Expressions describing the specific radioactivities and 14C distribution in glucose as a function of these rates are derived. Specific radioactivities and isotopic patterns depend markedly on the ratio of the rates of pyruvate carboxylation and decarboxylation to the rate of citrate synthesis, but the effect of phosphoenolpyruvate hydrolysis is minor. The effects of these rates on 1) specific radioactivity of phosphoenolpyruvate, 2) labeling pattern in glucose, and 3) contribution of pyruvate, acetyl-coenzyme A, and CO2 to glucose carbon are illustrated. To determine the contribution of lactate or alanine to gluconeogenesis, experiments with two compounds labeled in different carbons are required. Methods in current use to correct for the dilution of 14C in gluconeogenesis from [14C]pyruvate are shown to be erroneous. The experimental design and techniques to determine gluconeogenesis from 14C-labeled precursors are presented and illustrated with numerical examples.
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PMID:Determination of gluconeogenesis in vivo with 14C-labeled substrates. 398 80

1. In freshly prepared isolated rat liver cells there is a lag in gluconeogenesis from lactate. The magnitude of the lag increases with increasing lactate concentration. 2. The lag is virtually abolished by lysine. 3. A few other amino acids (tyrosine, arginine, asparagine, ornithine) and NH(4)Cl had effects similar to, but less pronounced than, lysine during the early stage of incubation. Lysine was unique in accelerating gluconeogenesis beyond the lag period. 4. The effects of the accelerators are not additive. 5. Glycine, serine, threonine, cysteine, tryptophan and histidine at 2mm markedly inhibit (>20%) gluconeogenesis from lactate. 6. Oleate, which promotes gluconeogenesis from lactate by supplying acetyl-CoA required for the pyruvate carboxylase reaction, had no effect on the lag, yet oleate oxidation showed no lag. 7. Preincubation of cells decreased the lag and decreased the magnitude of the lysine effect. 8. Pyruvate (added at 1mm to give an initial [lactate]/[pyruvate] ratio of 10) also abolished the lag and decreased the lysine effect by about 50%. 9. Lysine reversed the inhibition by ethanol of gluconeogenesis from lactate. 10. All accelerators increased the rate of re-oxidation of cytosolic NADH as shown by a rapid re-adjustment of the [lactate]/[pyruvate] ratio on addition of 10mm-lactate. 11. The accelerated rates of gluconeogenesis are associated with an increased formation of aspartate and glutamate and especially alanine. 12. The existence of the lag period can be explained on the basis of the fact that the accumulation of pyruvate during the lag diverts oxaloacetate from gluconeogenesis to malate formation, i.e. that the re-oxidation of cytosolic NADH takes precedence over gluconeogenesis. This means that much oxaloacetate formed by the pyruvate carboxylase reaction has to be transferred twice from the mitochondria to the cytosol by the aspartate shuttle. Under these conditions the operation of the shuttle limits the rate of gluconeogenesis from lactate. Lysine and other accelerators may increase the effectiveness of the shuttle by providing components of the aspartate aminotransferases involved. The question of why lysine specifically accelerates gluconeogenesis beyond the lag period is discussed.
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PMID:The effect of lysine on gluconeogenesis from lactate in rat hepatocytes. 415 92

1. 3-Mercaptopicolinic acid (SK&F 34288) inhibited gluconeogenesis in vitro, with lactate as substrate, in rat kidney-cortex and liver slices. 2. In perfused rat livers, gluconeogenesis was inhibited when lactate, pyruvate or alanine served as substrate, but not with fructose, suggesting pyruvate carboxylase or phosphoenolpyruvate carboxylase as the site of inhibition. No significant effects were evident in O(2) consumption, hepatic glycogen, urea production, or [lactate]/[pyruvate] ratios. 3. A hypoglycaemic effect was evident in vivo in starved and alloxan-diabetic rats, starved guinea pigs and starved mice, but not in 4h-post-absorptive rats. 4. In the starved rat the hypoglycaemia was accompanied by an increase in blood lactate. 5. A trace dose of [(14)C]lactate in vivo was initially oxidized to a lesser extent in inhibitor-treated rats, but during 90min the total CO(2) evolved was slightly greater. The total amount of the tracer oxidized was not significantly different from that in the controls.
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PMID:3-mercaptopicolinic acid, an inhibitor of gluconeogenesis. 442 41

1. Gluconeogenesis from 10mm-lactate in the perfused liver of starved rats is inhibited by ethanol. The degree of inhibition reached a maximum of 66% at 10mm-ethanol under the test conditions and decreased at higher ethanol concentrations. The concentration-dependence of the inhibition is paralleled by the concentration-dependence of the activity of alcohol dehydrogenase. The enzyme is also inhibited by ethanol concentrations above 10mm. 2. Gluconeogenesis from pyruvate is not inhibited by ethanol. 3. The degree of the inhibition of gluconeogenesis from lactate by ethanol depends on the concentration of lactate and other oxidizable substances, e.g. oleate, in the perfusion medium. 4. Ethanol also inhibits, to different degrees, gluconeogenesis from glycerol, dihydroxyacetone, proline, serine, alanine, fructose and galactose. 5. The inhibition of gluconeogenesis from lactate by ethanol is reversed by acetaldehyde. 6. Pyrazole, a specific inhibitor of alcohol dehydrogenase, also reverses the inhibition of gluconeogenesis by ethanol. 7. Gluconeogenesis in kidney cortex, where the activity of alcohol dehydrogenase is very low, is not inhibited by ethanol. 8. Kidney cortex, testis, ovary, uterus and certain tissues of the alimentary tract were the only rat tissues, apart from the liver, that showed measurable alcohol dehydrogenase activity. 9. The concentrations of pyruvate in the liver were decreased to about one-fifth by ethanol. 10. The concentration of lactate in the perfused liver was about 3mm below that of the perfusion medium 30min. after the addition of 10mm-lactate. 11. The great majority of the findings support the view that the inhibition of gluconeogensis by ethanol is caused by the alcohol dehydrogenase reaction, which decreases the [free NAD(+)]/[free NADH] ratio. The decrease lowers the concentration of pyruvate and this is the immediate cause of the inhibition of gluconeogenesis from lactate, alanine and serine: the fall in the concentration of pyruvate lowers the rate of the pyruvate carboxylase reaction, one of the rate-limiting reactions of gluconeogenesis. The cause of the inhibition of gluconeogenesis from other substrates is discussed.
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PMID:Inhibition of hepatic gluconeogenesis by ethanol. 577 87

A male infant had severe muscular hypotonia from birth. Recurrent vomiting with dehydration and severe metabolic acidosis complicated the course. Elevated lactate (up to 12.3 mmol/l; n less than 2), pyruvate (0.4 mmol/l; n less than 0.05) and alanine levels were found in serum with an abnormal lactate/pyruvate ratio (greater than 30; n less than 15). In urine the concentrations of lactate, pyruvate, alanine and of several intermediates of the citric acid cycle were increased. In muscle, numerous disseminated "ragged red fibres" were found by light microscopy; muscle fibres were found to contain subsarcolemmal aggregates of mitochondria, lipid droplets and glycogen by electromicroscopical methods. Moreover, mitochondria with a typical circular arrangement of cristae were noticed. In liver homogenates normal activities of pyruvate carboxylase and pyruvate dehydrogenase complex were found; in liver mitochondria also succinate-cytochrome-c-oxidoreductase activity was normal. However, in muscle no succinate-cytochrome-c-oxidoreductase activity was detectable. The patient became increasingly lethargic and died because of sepsis at 5 months of age.
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PMID:Mitochondrial myopathy with lactic acidosis and deficient activity of muscle succinate cytochrome-c-oxidoreductase. 609 51

The role of thyroid hormones in the metabolic adaptation to starvation was investigated in vivo. Glucose production, measured by tracer technique, was enhanced in hyperthyroid (185%) and reduced in hypothyroid (39%) 48-hour starved rats (euthyroid control = 100%). Urinary nitrogen excretion was increased in hyperthyroidism (132%) and decreased in hypothyroidism (70%). Compared with euthyroid controls (=100%) significant alterations for the following regulatory parameters of hepatic gluconeogenesis were observed: 1) tissue cAMP (124%/91%) and protein kinase activation (132%/90%), with a corresponding crossover between pyruvate and P-enolpyruvate (-/+/+/-); 2) pyruvate carboxylase (165%/60%), P-enolpyruvate carboxykinase (140%/82%) and fructose-1.6-bis-P-phosphatase activity (99%/61%), and 3) tissue content of the glucogenic amino acids: alanine (187%/66%) and glutamate (187%/88%), aspartate (179%/68%) and glutamate (137%/75%), as well as of oxaloacetate (254%/66%) and malate (164%/104%). The observed alterations in hepatic oligomycine-sensitive oxygen consumption in hyper- (161%) and hypothyroidism (51%) were related to the measured concentration of the intermediates of the citric acid cycle, the energy state and the mitochondrial redox state. In summary, the different rates of hepatic glucose production in hyper- and hypothyroid starved rats observed in vivo can be ascribed to 1) cAMP content, 2) gluconeogenic key enzyme activities, 3) glucogenic precursor supply and 4) cofactor (ATP) availability.
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PMID:Starvation-induced changes of hepatic glucose metabolism in hypo- and hyperthyroid rats in vivo. 626 36

The distribution of pyruvate between cell compartments measured in isolated hepatocytes in the presence of lactate was in agreement with delta pH across plasma and mitochondrial membranes. In isolated liver mitochondria NH4Cl decreased the transmembrane potential (delta psi) by about 14 mV, whereas no change of delta pH was observed. In the presence of lactate or alanine NH4Cl increased the mitochondrial pyruvate concentration presumably due to the inhibition of the flux through pyruvate carboxylase. In the presence of lactate or alanine changes in the amount of the active form of pyruvate dehydrogenase (PDHa) were correlated with the mitochondrial pyruvate concentration, NH4Cl increased the amount of PDHa by lowering the mitochondrial ATP/ADP and NADH/NAD+ ratios.
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PMID:The elucidation of the effect of ammonium chloride on pyruvate distribution and pyruvate dehydrogenase interconversion in isolated rat hepatocytes. 646 32

An oligonucleotide probe specific for the amino acid sequence at the biotin site in pyruvate carboxylase was used to screen a human liver cDNA library. Nine cDNA clones were isolated and three proved to be pyruvate carboxylase clones based on nucleotide sequencing and Northern blotting. The biotin site amino acid sequence of human pyruvate carboxylase agreed perfectly with that of the sheep enzyme in 14 consecutive positions. The highly conserved amino acid sequence, Ala-Met-Lys-Met, found at the biotin site in most biotin-containing carboxylases was also present in human pyruvate carboxylase. The termination codon was located 35 residues 3' to the lysine residue at which the biotin is attached. Therefore, the biotin cofactor is covalently linked near the carboxyl-terminal end of the carboxylase protein. These data are consistent with that observed for other biotin-containing carboxylases and strongly suggests that the genes encoding the biotin-containing carboxylases may have evolved from a common ancestral gene. Northern blotting of mRNA isolated from human, baboon, and rat liver demonstrated that the pyruvate carboxylase mRNA was 4.2 kilobase pairs in length in all species examined. Southern blot analysis of genomic DNA isolated from human-Chinese hamster somatic cell hybrids localized the pyruvate carboxylase gene on the long arm of human chromosome 11. The human cDNA was also used to quantitate pyruvate carboxylase mRNA levels in a differentiating mouse preadipocyte cell line. These data demonstrated that pyruvate carboxylase mRNA content increased 23-fold in 7 days after the onset of differentiation.
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PMID:Molecular cloning of a cDNA for human pyruvate carboxylase. Structural relationship to other biotin-containing carboxylases and regulation of mRNA content in differentiating preadipocytes. 654 74

Oxalate was shown to enter isolated rat hepatocytes and to inhibit gluconeogenesis from lactate, pyruvate, and alanine, but not from glutamine, proline, propionate or dihydroxyacetone. Oxalate apparently acts by inhibiting pyruvate carboxylase (EC 6.4.1.1.). It is known to inhibit the isolated enzyme, and inhibition of gluconeogenesis was much greater in a bicarbonate-deficient medium where pyruvate carboxylase activity limits the overall rate of the pathway. A slight inhibition of gluconeogenesis from asparagine was observed, suggesting that oxalate may also inhibit gluconeogenesis at another site. Chelation of extracellular Ca2+ does not contribute to the inhibition of gluconeogenesis. Compared to oxalate, other Ca2+ chelators have little effect upon gluconeogenesis. Also, oxalate inhibits gluconeogenesis effectively both in low Ca2+ medium and in medium containing 2.6 mM Ca2+. Chelation of intracellular Ca2+ also appears to be of little importance, since oxalate does not block the glycogenolytic effects of epinephrine, vasopressin, and angiotensin which are thought to act via Ca2+ as the second messenger. The inhibition of gluconeogenesis could conceivably contribute to the toxic actions of oxalate and to the hypoglycemic action of dichloroacetate, a compound that is metabolized to oxalate. However, oxalate did not cause hypoglycemia in the suckling rat, a model in vivo system very dependent upon gluconeogenesis for maintenance of normal blood glucose levels. Thus, inhibition of gluconeogenesis is probably of little importance in oxalate toxicity and the hypoglycemic effects of dichloroacetate.
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PMID:Studies on the inhibition of gluconeogenesis by oxalate. 677 9

Two unrelated Canadian Indian infants presented with metabolic acidosis. Lactate, pyruvate, glutamic acid, proline and alanine were greatly elevated in plasma. Urinary excretion of alpha-ketoglutarate and pyruvate was increased. Pyruvate carboxylase activity was very low in skin fibroblasts and liver. Phosphoenolpyruvate carboxykinase was low in liver. Both infants were unresponsive to several enzyme cofactors, including biotin. Both survive at age 2 years with severe mental retardation..
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PMID:Lactic acidosis due to pyruvate carboxylase deficiency. 679 Aug 46

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