EC:2.6.1.2 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.6.1.2 (alanine aminotransferase)
26,722 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Epimastigotes of Trypanosoma cruzi, the causative agent of Chagas disease, catabolize proteins and amino acids with production of MH3, and glucose with production of reduced catabolites, chiefly succinate and L-alanine, even under aerobic conditions. This "aerobic fermentation of glucose" is probably due to both the presence of low levels of some cytochromes, causing a relative inefficiency of the respiratory chain for NADH, reoxidation during active glucose catabolism, and the lack of NADH dehydrogenase and phosphorylation site I, resulting in the entry of reduction equivalents into the chain mostly as succinate. Phosphoenol pyruvate carboxykinase and pyruvate kinase may play an essential role in diverting glucose carbon to succinate or L-alanine, and L-malate seems to be the major metabolite for the transport of glucose carbon and reduction equivalents between glycosome and mitochondrion. The parasite contains proteinase and peptidase activities. The major lysosomal cysteine proteinase, cruzipain, has been characterized in considerable detail, and might be involved in the host/parasite relationship, in addition to its obvious role in parasite nutrition. Among the enzymes of amino acid catabolism, two glutamate dehydrogenases (one NADP- and the other NAD-linked), alanine aminotransferase, and the major enzymes of aromatic amino acid catabolism (tyrosine aminotransferase and aromatic alpha-hydroxy acid dehydrogenase), have been characterized and proposed to be involved in the reoxidation of glycolytic NADH.
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PMID:Intermediate metabolism in Trypanosoma cruzi. 805 82

We found that NADPH-dependent ubiquinone reductase (NADPH-UQ reductase) in rat liver cytosol reduces ubiquinone (UQ) to ubiquinol (UQH2) in lipid membranes and consequently inhibits lipid peroxidation [Takahashi T., et al., Biochem. J., 309, 883-890 (1995)]. Here we examined whether or not this UQH2-regenerating system functions as a cellular antioxidant defense in animals. Rats were given UQ-10 for 2 weeks, and were then exposed to carbon tetrachloride (CCl4). The UQ-10 supplement increased only in the NADPH-UQ reductase and the UQH2-10 pool of rat liver without any appreciable change in the levels of other antioxidant factors. On the other hand, CCl4 markedly increased plasma aspartate aminotransferase and alanine aminotransferase, liver weight and thiobarbituric acid reacting substances formation, which are indicators of CCl4-hepatitis, and it decreased the liver levels of L-ascorbic acid, reduced form of glutathione (GSH), alpha-tocopherol, NADPH-UQ reductase and glutathione S-transferase. However, all the above indicators of CCl4-induced hepatitis were significantly improved in rats given UQ-10. Furthermore, alpha-tocopherol, but neither L-ascorbic acid nor GSH, was significantly saved. UQ-10 supplement also was recovered glutathione S-transferase and NADPH-UQ reductase activities slightly. These results indicated that UQ-10 given to rats increased the cellular UQH2-10 pool and cytosolic NADPH-UQ reductase activity in their livers, resulting in the inhibition of lipid peroxidation in the biomembranes, and consequently protected the rats from the CCl4-hepatotoxicity.
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PMID:Cellular antioxidant defense by a ubiquinol-regenerating system coupled with cytosolic NADPH-dependent ubiquinone reductase: protective effect against carbon tetrachloride-induced hepatotoxicity in the rat. 887 5

The oxidative metabolism of glutamine in HeLa cells was investigated using intact cells and isolated mitochondria. The concentrations of the cytoplasmic amino acids were found to be aspartate, 8.0 mM; glutamate, 22.2 mM; glutamine, 11.3 mM; glycine, 9.8 mM; taurine, 2.3 mM; and alanine, < 1 mM. Incubation of the cells with [14C]glutamine gave steady-state recoveries of 14C-label (estimated as exogenous glutamine) in the glutamine, glutamate, and aspartate pools, of 103%, 80%, and 25%, respectively, indicating that glutamine synthetase activity was absent and that a significant proportion of glutamate oxidation proceeded through aspartate aminotransferase. No label was detected in the alanine pool, suggesting that alanine aminotransferase activity was low in these cells. The clearance rate of [14C]glutamine through the cellular compartment was 65 nmol/min per mg protein. There was a 28 s delay after [14C]glutamine was added to the cell before 14C-label was incorporated into the cytoplasm, while the formation of glutamate commenced 10 s later. Aspartate was the major metabolite formed when the mitochondria were incubated in a medium containing either glutamine, glutamate, or glutamate plus malate. The transaminase inhibitor AOA inhibited both aspartate efflux from the mitochondria and respiration. The addition of 2-oxoglutarate failed to relieve glutamate plus malate respiration, indicating that 2-oxoglutarate is part of a well-coupled truncated cycle, of which aspartate aminotransferase has been shown to be a component [Parlo and Coleman (1984): J Biol Chem 259:9997-10003]. This was confirmed by the observation that, although it inhibited respiration, AOA did not affect the efflux of citrate from the mitochondria. Thus citrate does not appear to be a cycle component and is directly transported to the medium. Therefore, it was concluded that the truncated TCA cycle in HeLa cells is the result of both a low rate of citrate synthesis and an active citrate transporter. DNP (10 microM) induced a state III-like respiration only in the presence of succinate, which supports the evidence that NAD-linked dehydrogenases were not coupled to respiration, and suggests that these mitochondria may have a defect in complex I of the electron transport chain. Arising from the present results with HeLa cells and results extant in the literature, it has been proposed that a major regulating mechanism for the flux of glutamate carbon in tumour cells is the competitive inhibition exerted by 2-oxoglutarate on aspartate and alanine aminotransferases. This has been discussed and applied to the data.
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PMID:Oxidation of glutamine in HeLa cells: role and control of truncated TCA cycles in tumour mitochondria. 944 77

Bromobenzene (BB) and furosemide (FS) are two hepatotoxicants whose bioactivation to reactive intermediates is crucial to the development of liver injury. However, the events which lead to hepatocellular toxicity following metabolite formation and covalent binding to cellular macromolecules remain unknown. The present study was undertaken to investigate the effect of administered BB and FS on mitochondrial total glutathione (GSH+GSSG, henceforth referred to as glutathione) content and respiratory function as potential initiating mechanisms of the hepatotoxicity of these compounds in the mouse. Bromobenzene (2 g/kg i.p.) significantly decreased mitochondrial glutathione to 48% of control at 3 h post administration, and to 41% at 4 h. This decrease in mitochondrial glutathione was subsequent to a significant decrease in cytosolic glutathione to 64 and 28% of control at 1 and 2 h, respectively. Oxygen consumption supported by complex I (glutamate-supported) of the respiratory chain was not inhibited by BB until 4 h, where state 3 (active) respiration was reduced to 16% of control. This resulted in a decreased respiratory control ratio (RCR) for complex I-supported respiration. Complex II (succinate)-supported state 3 and state 4 respiration were unaffected by BB until 4 h, at which time they were reduced to 57 and 48% of control, respectively. However, the similar reductions in state 3 and state 4 respiratory rates did not alter the corresponding RCR for complex II. Overt hepatic injury was detected at 4 h, with plasma alanine aminotransferase (ALT) activity increasing significantly at this time point. In contrast to the effects of BB, FS administration (400 mg/kg i.p.) did not alter mitochondrial or cytosolic glutathione, and had no effect on respiration supported by complex I or II for up to 5 h following dosing. However, ALT activity was significantly increased 5 h following FS administration. These results suggest that inhibition of mitochondrial respiratory function coinciding with a decrease in mitochondrial glutathione content may be crucial to the initiation of BB-induced hepatotoxicity, while such events are not required for the initiation of FS-induced hepatotoxicity.
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PMID:The role of mitochondrial injury in bromobenzene and furosemide induced hepatotoxicity. 1099 78

Chronic ethanol ingestion alters mitochondrial function in the liver including inhibition of complex I of the electron transport chain. This leads to a shift in the NAD/NADH ratio to the reduced state when blood ethanol levels are high. Rotenone also inhibits complex I and induces a reduced state. The combination of ethanol feeding and rotenone toxicity should amplify the reduced state and block the cyclic increase and decrease in the rate of metabolism in the liver. The change in the redox state occurs during the urinary ethanol cycle in the intragastric tube feeding rat model of alcoholic liver disease. To test this hypothesis, rats were fed ethanol with rotenone and the 24-h urinary ethanol levels were measured daily. When ethanol was fed alone, the urinary ethanol cycle occurred. However, when ethanol was fed with rotenone the cycle was prevented and the urinary ethanol levels remained at the 200-mg% range. The rats fed ethanol or fed ethanol plus rotenone had the same increase in the pathology score and ALT elevations in the blood. Rotenone fed alone had the same normal values as the dextrose pair fed control rats. The results indicate that the UAL cycle is driven by fluctuation in the NAD/NADH ratio. When this fluctuation is blocked by rotenone, the cycle does not occur. It is concluded that the urinary ethanol cycle is dependent on cyclic fluctuation of the NAD/NADH ratio, which regulates the rate of ethanol elimination.
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PMID:The effect of rotenone on the urinary ethanol cycle in rats fed ethanol intragastrically. 1550 38

The blood alcohol level cycle (BALC) of the intragastric tube feeding model first described by Tsukamoto et al., has three separate essential mechanistic components. The first is the requirement for an intact functioning thyroid. The evidence for this is that propylthiouracil or severance of the pituitary stalk completely prevents the cycle. What happens instead of the cycle is that the blood alcohol level rises to a lethal level when ethanol is given continuously at a dose of 11 g/kg/day by stomach tube. When excess thyroid hormone is given orally it markedly attenuates the cycle because it interferes with the changes in the level of thyroid hormone during the cycle. The second component is norepinephrine. Catecholamines are markedly elevated at the peaks of the cycle. Both propranolol and phenoxybenzamine, which are beta- and alpha-blockers, prevent the cycle. Also, when catecholamines are fed in excess in the form of ephedrine, the cycle is eliminated. The third element essential to the cycle is the generation of NAD to support the oxidation of alcohol by alcohol dehydrogenase. When complex I (NADH dehydrogenase) of the mitochondrial electron transport chain is inhibited by feeding rotenone, the cycle is totally eliminated and blood alcohol levels remain constant at 200 mg/%. Thus NADH increases and NAD decreases at the peak of the cycle. Without the fluxuation of NAD, ADH activity cannot fluctuate during the cycle and the cycle is prevented. The significance of the BALC in the understanding of alcohol liver disease pathogenesis is that there's a marked difference in the gene expression and liver toxicity when the peaks and troughs of the cycle are compared. The expression of 1000+ genes is either two-fold up or down regulated as determined by microarray analysis. At the peaks there is increased liver pathology, especially inflammatory changes in the liver associated with an increase of iNOS expression. The genes responsive to hypoxia inducible factor 1alpha (HIF1alpha) regulation are increased including the expression of erythropoietin, adrenomedullin and adrenergic receptor alpha 1a and d. The expression of prolyl hydroxylase, which destabilizes HIF1alpha, increases when the BAL drops to low levels during the cycle. The level of oxygen, as measured on the surface of the liver, is decreased at the peaks, compared to control livers. The NADH/NAD ratio is markedly increased and ATP levels are markedly decreased at the BAL peaks. Also, endotoxin in the blood is very high at the peaks and very low at the troughs. When the blood alcohol levels fall during the cycle, there is an increase in ALT, suggesting that reoxygenation from the hypoxic state at the peaks causes an ischemic reperfusion injury-like lesion in the liver. At this time there is also an increase in expression of many important enzymes such as manganese SOD. Genes such as c-fos and CTGF are increased in expression. These contrasting findings at the peaks and troughs indicate that the blood alcohol levels, which fluctuate up and down, change the gene expression and the pathology of the liver.
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PMID:The pathogenesis and significance of the urinary alcohol cycle in rats fed ethanol intragastrically. 1634 1

Disease caused by viruses, especially white spot syndrome virus (WSSV), present the greatest challenge to shrimp aquaculture worldwide. Massive tissue disintegration occurs in WSSV-infected ectodermal and mesodermal tissues of penaeid shrimp. The activities of membrane bound phosphatases (Na(+)K(+)ATPase, Ca(2+)ATPase, Mg(2+)ATPase and Total ATPase), transaminases (alanine transaminase (ALT) and aspartate transaminase (AST)) and mitochondrial enzymes (isocitrate dehydrogenase (ICDH), succinate dehydrogenase (SDH), malate dehydrogenase (MDH), alpha-ketoglutarate dehydrogenase (KGDH), NADH dehydrogenase, cytochrome C oxidase) in WSSV-infected tissues (hemolymph, hepatopancreas, gills and muscle) of Fenneropenaeus indicus were determined at intervals after WSSV infection (0, 24, 48, 72 and after 72 h (moribund)). The activities of phosphatases, transaminases and mitochondrial enzymes in healthy as compared with WSSV-infected hemolymph, hepatopancreas, gills and muscle showed marked divergence throughout the course of infection. WSSV infected hemolymph, hepatopancreas, gills and muscle exhibited significantly reduced activity of membrane bound phosphatases compared with the uninfected animals. Inactivation of these enzymes may occur due to increased production of free radicals, that cause conformational change by oxidation of 'SH' groups present at the active site. Significantly marked elevation in the activities of transaminases (ALT and AST) was observed in WSSV-infected hemolymph, hepatopancreas, gills and muscle compared to the uninfected tissues. This may be due to leakage of these enzymes from the damaged tissues. The activities of mitochondrial enzymes in WSSV-infected tissues were significantly decreased compared to the activities in uninfected animals. WSSV-infected animals showed reduced feeding that may have led to decreased oxidation of glucose via the TCA cycle. Excessive production of free radicals in WSSV-infected animals may have affected aerobic oxidation leading to lower production of ATP. It is concluded that membrane dynamics play a major role in the pathogenesis of WSSV infection.
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PMID:Activities of membrane bound phosphatases, transaminases and mitochondrial enzymes in white spot syndrome virus infected tissues of Fenneropenaeus indicus. 1641 26

Troglitazone, a first-generation thiazolidinedione antidiabetic drug, was withdrawn from the market due to an unacceptable risk of idiosyncratic hepatotoxicity. Troglitazone does not cause hepatotoxicity in normal healthy rodents, but it produces mitochondrial injury in vitro at high concentrations. The aim of this study was to explore whether genetic mitochondrial abnormalities might sensitize mice to hepatic adverse effects of troglitazone. We used heterozygous superoxide dismutase 2 (Sod2(+/-)) mice as a model of clinically silent mitochondrial stress. Troglitazone was daily administered for 4 weeks (0, 10 or 30 mg/kg/day, ip). We found that troglitazone caused overt liver injury in the high-dose group, manifested by increased serum alanine aminotransferase activity (> twofold) and midzonal areas of hepatic necrosis, in Sod2(+/-) but not in wild-type mice. No signs of hepatotoxicity were apparent at 2 weeks of treatment. Hepatic mitochondria isolated from troglitazone-treated mice exhibited decreased activities of aconitase (by 45%) and complex I (by 46%) and increased (by 58%) protein carbonyls, indicative of enhanced mitochondrial oxidant stress. This was paralleled by compensatory increases in mitochondrial glutathione levels. Finally, in hepatocytes isolated from untreated Sod2(+/-), but not wild-type mice, troglitazone caused a concentration-dependent increase in superoxide anion levels as demonstrated with a selective mitochondria-targeting fluorescent probe. In conclusion, prolonged administration of troglitazone can superimpose oxidant stress, potentiate mitochondrial damage, and induce delayed hepatic necrosis in mice with genetically compromised mitochondrial function. These data are consistent with our hypothesis that inherited or acquired mitochondrial abnormalities may be one of the contributing determinants of susceptibility to troglitazone-induced idiosyncratic liver injury.
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PMID:Troglitazone-induced hepatic necrosis in an animal model of silent genetic mitochondrial abnormalities. 1757 88

In the present study, the role of vitamin E and curcumin on hyperthyroidism induced mitochondrial oxygen consumption and oxidative damage to lipids and proteins of rat liver are reported. Adult male rats were rendered hyperthyroid by administration of 0.0012% l-thyroxine in their drinking water, while vitamin E (200 mg/kg body weight) and curcumin (30 mg/kg body weight) were supplemented orally for 30 days. Hyperthyroidism induced elevation in serum aspartate aminotransferase and alanine aminotransferase activities were reduced significantly in response to vitamin E and curcumin treatment. On the other hand, effects of vitamin E and curcumin on hyperthyroidism induced hepatic complexes I and II mediated respiration were found to be different. While curcumin administration ameliorates hyperthyroidism induced state 3 and state 4 respiration in complex I, vitamin E treatment was effective only in reducing state 4 respiration of complex I. On the contrary, curcumin administration was ineffective in modulating hyperthyroidism induced complex II respiration, but vitamin E treatment to hyperthyroid rats resulted in augmentation of complex II respiration both at state 3 and state 4 level. Moreover, vitamin E and curcumin treatment resulted in alleviation of hyperthyroidism induced lipid peroxidation. Enhanced protein carbonylation in hyperthyroid rats is decreased only in response to simultaneous supplementation of vitamin E and curcumin. Above findings suggest that both vitamin E and curcumin have differential regulation on complexes I and II mediated mitochondrial respiration and have a protective role against L-thyroxine induced hepatic dysfunction and oxidative stress.
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PMID:Alleviation of enhanced oxidative stress and oxygen consumption of L-thyroxine induced hyperthyroid rat liver mitochondria by vitamin E and curcumin. 1837 85

Monocrotaline (MCT) is a pyrrolizidine alkaloid present in plants of the Crotalaria species that causes cytotoxicity and genotoxicity, including hepatotoxicity in animals and humans. It is metabolized by cytochrome P-450 in the liver to the alkylating agent dehydromonocrotaline (DHM). In previous studies using isolated rat liver mitochondria, we observed that DHM, but not MCT, inhibited the activity of respiratory chain complex I and stimulated the mitochondrial permeability transition with the consequent release of cytochrome c. In this study, we evaluated the effects of MCT and DHM on isolated rat hepatocytes. DHM, but not MCT, caused inhibition of the NADH-linked mitochondrial respiration. When hepatocytes of rats pre-treated with dexamethasone were incubated with MCT (5 mM), they showed ALT leakage, impaired ATP production and decreased levels of intracellular reduced glutathione and protein thiols. In addition, MCT caused cellular death by apoptosis. The addition of fructose or dithiotreitol to the isolated rat hepatocyte suspension containing MCT prevented the ATP depletion and/or glutathione or thiol oxidation and decreased the ALT leakage and apoptosis. These results suggest that the toxic effect of MCT on hepatocytes may be caused by metabolite-induced mitochondrial energetic impairment, together with a decrease of cellular glutathione and protein thiols.
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PMID:Cytotoxicity of monocrotaline in isolated rat hepatocytes: effects of dithiothreitol and fructose. 2153 May 70

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