EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Exposure of rats to an ambient temperature of 5 degrees C for 4 to 6 weeks led to a 30 to 80 percent increase in the rate of oxygen consumption and a 50 percent increase in the rate of ethanol oxidation by liver slices, a 50 percent increase in mitochondrial alpha-glycerophosphate oxidase activity of liver, and a 100 percent increase in Na++K+-activated adenosine-triphosphatase, activity. Ouabain, an inhibitor of the Na++K+-activated adenosine-triphosphatase, completely blocked the extra respiration and ethanol oxidation. Dinitrophenol, which increases oxygen consumption and ethanol oxidation by liver slices from normal rats, was ineffective with slices from cold-exposed animals. Ethanol disappearance rate in vivo was also increased by cold acclimation, even though liver alcohol dehydrogenase activity was reduced. It is suggested that increased hydrolysis of ATP by the sodium pump system is responsible for the increased oxygen consumption and ethanol metabolism in the livers of cold-acclimated animals.
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PMID:Ethanol metabolism and liver oxidative capacity in cold acclimation. 12 85

Changes in cardiac metabolism in myocardial failure and after alcohol ingestion are discussed. The main effect of alcohol ingestion is loss of cardiac contractility. Since heart muscle does not contain alcohol dehydrogenase, its toxicity is probably the result of a direct toxic effect of ethanol and acetaldehyde on the myocardial cell, possibly involving various membrane systems. Alcohol inhibits mitochondrial respiration and the activity of enzymes in the tricarboxylic acid cycle, and its interferes with both mitochondrial calcium uptake and binding. Ethanol profoundly affects myocardial lipid metabolism. Acetaldehyde diminishes myocardial protein synthesis and inhibits Ca++-activated myofibrillar ATPase. In myocardial failure, a series of possibilities may be responsible for the loss of contractility. Excitation-contraction coupling could be disturbed at the level of the sarcolemma, at the sarcoplasmic reticulum, at the mitochondria, and between calcium and the regulatory proteins. Deficiencies in Ca++ delivery systems of excitation-contraction coupling on the myosin ATPase activity could be responsible for the dimunition in cardiac contractility. Mitochondrial function may also be involved, since mitochondria from failing human hearts are defective with respect to respiratory control and calcium accumulation. Under certain conditions, the relationship of mitochondria to calcium sequestration is very important in influencing contractility. The involvement of contractile and regulatory proteins in myocardial failure cannot be excluded.
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PMID:Cardiac metabolsim: its contributions to alcoholic heart disease and myocardial failure. 15 68

Perfused livers from ethanol pretreated rats utilized ethanol and acetaldehyde at higher rates than appropriate controls. This adaptive increase in hepatic ethanol and acetaldehyde uptake was associated with a marked (greater than 60%) increase in hepatic oxygen uptake. Ethanol uptake in both ethanol-treated and control livers was similarly sensitive to inhibition by 4-methylpyrazole, rotenone, and antimycin A. The adaptive increase in ethanol uptake was apparently specifically abolished by ouabain, an inhibitor of the sodium-plus potassium-activated ATPase. The data are consistent with the hypothesis that chronic treatment with ethanol increases ATPase activity. The ADP produced from these initiating events enters the mitochondrial space and stimulates electron transport and oxygen uptake. As a consequence of these events, a greater rate of NADH reoxidation occurs, resulting in a greater rate of production of NAD+ which stimulates ethanol oxidation via alcohol dehydrogenase and acetaldehyde oxidation via aldehyde dehydrogenase(s).
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PMID:Common mechanism for the adaptive increase in hepatic ethanol and acetaldehyde metabolism due to chronic pretreatment with ethanol. 56 3

N alpha-Acetylation is a major co-translational modification occurring at the alpha-NH2 group of eukaryotic cytosolic proteins. In order to understand better the specificity of N alpha-acetyltransferase, we used the purified enzyme from yeast (Lee, F.-J. S., Lin, L.-W., and Smith J. A. (1988) J. Biol. Chem. 263, 14948-14955) and synthetic peptides mimicking the NH2 terminus of yeast and human proteins. Alcohol dehydrogenase I-(1-24) and 8 of the 19 synthetic analogues with substitutions at the NH2-terminal residue were N alpha-acetylated with varying efficiency. Penultimate amino acid substitutions, except for proline, had little influence on N alpha-acetylation. Substitution of sequences from N alpha-acetylated proteins into the yeast sequences which cannot be N alpha-acetylated demonstrated that not only the first 3 NH2-terminal residues but also more carboxyl-terminal residues were important for determining the specificity of N alpha-acetyltransferase. Two other peptides mimicking yeast mitochondrial cytochrome c oxidase (subunit VI) and ATPase inhibitor, which are naturally non-acetylated, were efficiently acetylated. In addition, recombinant human alcohol dehydrogenase I and basic fibroblast growth factor, which are naturally N alpha-acetylated, were not acetylated post-translationally.
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PMID:Model peptides reveal specificity of N alpha-acetyltransferase from Saccharomyces cerevisiae. 219 22

The effectiveness of trental administration was investigated in 94 patients aged 18-65 suffering from hepatitis A or B running a moderate course. The data were analyzed for clinical features, blood red cell diene conjugates and ATPase activity, malonic dialdehyde production, plasma alcohol dehydrogenase. Administration of trental produced a positive action on lipid peroxidation, liver size, jaundice duration. Hospital stay of the patients reduced. Basing on the above observations, the authors advocate wider introduction of trental in management of virus hepatitides.
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PMID:[Use of trental in combined treatment of viral hepatitis]. 237 Jul 59

Brain (Na+ + K+)-ATPase was protected by low concentrations of GSH from the inhibitory effect of pyrithiamin. The possible involvement of sulfhydryl groups in the inhibition was then studied by comparing the effect of pyrithiamin with that of N-ethylmaleimide on the enzyme. The treatment of rat brain (Na+ + K+)-ATPase with thesee inhibitors caused a significant decrease in reactivity of the enzyme to N-ethyl[3H]maleimide. N-Ethylmaleimide, like pyrithiamin, inhibited the partial reactions of (Na+ + K+)-ATPase system in parallel with the inhibition of the overall reaction. An SDS-polyacrylamide gel electrophoresis procedure indicated that pyrithiamin and N-ethylmaleimide inhibited Na+-dependent phosphorylation of the alpha(+) form of rat brain (Na+ + K+)-ATPase more than that of alpha, though the selectivity for the alpha(+) seemed to be higher with the former inhibitor than in the latter. The treatment also decreased sensitivity of the enzyme to ouabain inhibition. However, pyrithiamin- and N-ethylmaleimide-induced inactivations of the enzyme differed in the efficacy of GSH for protection and in the effect of the kind of ligands present during the reaction. Furthermore, pyrithiamin did not appear to interact directly with sulfhydryl groups, but caused the formation of disulfide in bovine brain (Na+ + K+)-ATPase. In contrast to N-ethylmaleimide, pyrithiamin did not affect the sulfhydryl-enzymes such as alcohol dehydrogenase and L-alanine dehydrogenase. It is concluded that pyrithiamin modifies the functional sulfhydryl groups of brain (Na+ + K+)-ATPase in a way different from N-ethylmaleimide and causes a structural change and inactivation of the enzyme.
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PMID:Involvement of sulfhydryl groups in the inhibition of brain (Na+ + K+)-ATPase by pyrithiamin. 298 20

In this report the disturbances in biochemistry of the heart muscle exposed to alcohol are delineated. All elements of cellular substructures are affected. In plasma membranes, (Na+ + K+)-activated ATPase (EC 3.6.1.3) is inhibited. Mitochondrial damage consists in diminished respiratory function and calcium uptake and binding. High-energy phosphates remain intact. Alcohol also affects the malate-aspartate shuttle. Acetaldehyde, a metabolite of ethanol, has a direct effect on myocardial protein synthesis through microsomal inhibition; however, the development of cardiac hypertrophy is not affected. Malfunction of sarcoplasmic reticulum is evidenced by disturbances in calcium binding and uptake. Effects of ethanol on the contractile machinery are deficiencies in the turnover rate of chemical into mechanical energy (diminished Vmax), and in the number of cross-bridges formed (P0). It increases stiffness of series elastic elements. There is diminished fatty acid oxidation with increased esterification. The involvement of CoA synthetase (EC 6.2.1.1), palmityl-carnitine transferase (EC 2.3.1.7), and pyruvate dehydrogenase complex in disturbed fatty acid oxidation is not certain. The role of catalase in myocardial ethanol oxidation was examined. Ethanol activates myocardial catalase-H2O2 complex (EC 1.11.1.6). The biochemical basis of fetal alcohol syndrome is low hepatic alcohol dehydrogenase (EC 1.1.1.1) activity during fetal life.
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PMID:Effect of alcohol on the heart and cardiac metabolism. 628 54

The concept of a hypermetabolic state to explain metabolic tolerance to ethanol grew from the recognition that the rate of alcohol metabolism is, in general, limited by the rate at which mitochondria can reoxidize reducing equivalents and thus by the rate at which oxygen can be consumed by the liver. This relationship appears to be most important in conditions in which the alcohol dehydrogenase (ADH)/QO2 ratio is high and is not in conflict with observations suggesting that ADH can, under certain conditions, constitute a rate-determining step for ethanol metabolism in rodents. Liver preparations from animals fed alcohol chronically, in which an increase in ethanol metabolism is shown, consume oxygen at higher rates. This effect, concerning which there is discrepancy among investigators, depends on the type of preparation. Thyroid hormones play a permissive role in the development of the hypermetabolic state, while increased circulating levels of these hormones are not required. Antithyroid drugs inhibit both metabolic tolerance in vivo and the hypermetabolic state. While the hypermetabolic state requires an increased ATP utilization in the form of an adenosine triphosphatase, or an inhibition of ATP synthesis, the different mechanisms proposed for such an effect do not quantitatively account for the increases in oxygen consumption. In humans and animals chronically exposed to ethanol, but withdrawn, oxygen tensions in blood leaving the liver are significantly reduced. In some situations, low oxygen tensions in zone 3 of the hepatic acinus can reach critical hypoxic levels and may lead to cell necrosis. Studies in which the effectiveness of propylthiouracil is tested in human alcoholic hepatitis are discussed.
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PMID:Hypermetabolic state and hypoxic liver damage. 632 88

The activities of 13 liver and 6 brain enzymes were studied in 7-12 week old CD2F1 male mice that had been fed ad libitum and standardized either to 12 hours of light (0600-1800) alternating with 12 hours of darkness (1800-0600) (LD12:12); or to a reversed light-dark cycle (darkness 0600-1800; light 1800-0600) (DL12:12). Three separate studies were performed on two different days; in each experiment, subgroups of 14 animals were sacrificed at 3-hour intervals. Livers were assayed for: isocitrate dehydrogenase, glutamate dehydrogenase, lactate dehydrogenase, alcohol dehydrogenase, glutathione reductase, glyoxylate reductase, L-alanine aminotransferase, glutamate oxalacetate transaminase, pyruvate decarboxylase, fructose-1-phosphate aldolase, fructose diphosphate aldolase, fructose 1,6-diphosphatase, and fatty acid synthetase. Brains were assayed for phosphoglucose isomerase, adenosine triphosphatase, creatine phosphokinase, pyruvate kinase, adenylate kinase, and malate dehydrogenase. All 19 enzymes demonstrated a prominent circadian rhythm in at least one experiment. Moreover, each rhythmic variable showed a statistically significant fit to a 24-hour cosine (sine) curve by the method of least squares. In general, peak activities of the liver enzymes analyzed were associated with the beginning of the dark cycle and initiation of the animal's activity, while the group of brain enzymes had peak activities which occurred at the beginning of the animals' rest span and were near the beginning of the light cycle. The phasing of each of the rhythms could be reversed within a two-week span after reversing the environmental light-dark cycle 180 degrees.
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PMID:Circadian organization of thirteen liver and six brain enzymes of the mouse. 731 49

Gastric intubation of female Sprague-Dawley rats (80-150 g) with one large dose (5 g/kg) of ethanol nearly doubled oxygen uptake of the isolated, perfused rat liver in only 2.5 hours. This increased hepatic respiration can account for the Swift Increase in Alcohol Metabolism (SIAM). Inhibition of enhanced oxygen and ethanol uptake by KCN (2 mM) and 4-methylpyrazole (0.8 mM) indicated the involvement of the mitochondrial respiratory chain and alcohol dehydrogenase in this phenomenon, respectively. Epinephrine (2 mg/kg, i.p.) mimicked the increase in respiration observed with ethanol; however, the effects of epinephrine and ethanol were not additive. Pretreatment with alpha- and beta-adrenergic blocking agents, hypophysectomy and adrenalectomy prevented the increase in oxygen and ethanol uptake due to ethanol treatment. These data suggest that hormones including epinephrine are involved in the mechanism of SIAM. Hormone action in all likelihood activates a number of metabolic ATPase activities which lead to elevated oxygen uptake. One such process involved in the activation of oxygen uptake is diminished glycolysis, a ATP producing reaction sequence. The ADP not phosphorylated in the cytosol then enters the mitochondria where it stimulates oxygen uptake and NADH reoxidation. This ultimately leads to an acceleration of ADH-dependent ethanol metabolism.
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PMID:Mechanism of the swift increase in alcohol metabolism ("SIAM") in the rat. 742 36

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