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)

Dichloro- and trichloroacetic acids (DCA and TCA) and chloroform are formed during chlorination disinfection of drinking water. The effects of DCA and TCA treatment on CHCl3 toxicity were assessed in these studies. Male and female rats were gavaged with DCA or TCA (0.92 and 2.45 mmol/kg administered 3 times over 24 h). Three hours after the last dose CHCl3 was injected ip (0.75 mg/kg). Male rats experienced some weight loss (15%) and slight increases of ALT and BUN, but there were no effects of either DCA or TCA on any of these responses. In females, CHCl3 increased plasma ALT and this response was greater (up to threefold) in the DCA group, compared to saline controls. Similarly, BUN was increased by CHCl3 and this was more severe (up to threefold) in both the DCA and TCA pretreated groups. These results show that CHCl3 toxicity is increased by DCA and TCA, and this effect is gender-specific, occurring only in females. DCA increases both liver and kidney toxicity, whereas TCA affects only kidney toxicity.
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PMID:Dichloroacetic acid and trichloroacetic acid increase chloroform toxicity. 152 7

Several key enzymes related to carbohydrate metabolism were assayed in Setaria digitata. In the cytosolic fraction pyruvate kinase, phosphoenolpyruvate carboxykinase, malate dehydrogenase, malic enzyme, aspartate transaminase and alanine transaminase were found. Among the TCA cycle enzymes succinate dehydrogenase, fumarate reductase, fumarase (malate dehydration), malate dehydrogenase (malate oxidation and oxaloacetate reduction) and malic enzyme (malate decarboxylation) were detected in the mitochondrial fraction. Only reduced nicotinamide adenine dinucleotide (NADH) dehydrogenase, NADH oxidase and NADH-cytochrome c reductase were found in the mitochondrial fraction. The significance of these results with respect to the metabolic capabilities of the worm are discussed.
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PMID:Intermediary carbohydrate metabolism in the adult filarial worm Setaria digitata. 177 15

Male Wistar rats pretreated with ethanol (2.0 g in 80 ml liquid diet/day for 3 weeks) or phenobarbital (PB, 80 mg/kg/day ip for 4 days) were exposed by inhalation to 500, 1000, 2000, 4000, or 8000 ppm trichloroethylene (TRI) for 2 or 8 hr, and the blood concentration of TRI and the urinary concentration of TRI metabolites (trichloroethanol (TCE) and trichloroacetic acid (TCA] were determined at various times. Plasma glutamic-pyruvic transaminase (GPT) activity was measured 22 hr after the end of exposure as an indicator of hepatic damage. Both ethanol and PB enhanced TRI metabolism as evidenced by accelerated disappearance of TRI from the blood and increased excretion of total trichloro compounds (TCE + TCA) in the urine. However, the effects of ethanol and PB were different from each other: ethanol markedly enhanced the metabolism particularly at TRI concentration of 2000 ppm or lower, whereas PB enhanced it only at 4000 ppm or higher. This difference was also reflected in the effect of TRI on liver: ethanol potentiated TRI hepatotoxicity more markedly than did PB when TRI concentration remained 2000 ppm or lower, whereas PB potentiated the toxicity more markedly than ethanol when the concentration was 4000 ppm or higher. It is noteworthy that ethanol potentiated TRI hepatotoxicity at a TRI concentration as low as 500 ppm. The severity of hepatic damage expressed by plasma GPT activity essentially paralleled the urinary excretion rate of total trichloro compounds during and 4 hr after exposure (r = 0.87 to 0.93). Compared between the contribution of concentration and duration of exposure to the toxicity, a higher concentration of TRI tended to cause more severe liver damage to PB-treated rats than did a prolonged period of exposure, whereas the toxicity in ethanol-treated rats was generally more marked in rats exposed to TRI for a longer period than in rats exposed to a higher concentration.
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PMID:Ethanol-induced enhancement of trichloroethylene metabolism and hepatotoxicity: difference from the effect of phenobarbital. 338 20

The activity levels of aspartate aminotransferase (AAT), alanine aminotransferase (AlAT) and total adenosine triphosphatase (ATPase) were studied in muscle, gill, liver and brain tissues of control and methyl parathion exposed (MPE) fish. Both aminotransferases were elevated in all the tissues inferring the diversion of alpha-amino acids into the TCA cycle as keto acids to augment energy production during methyl parathion (MP) stress. In gill, liver and brain tissues, there seemed to be a shift in the aminotransferase reactions under MP impact. The total ATPase activity was decreased in all tissues, suggesting inhibition of active transport and oxidative phosphorylation.
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PMID:Tissue specific alteration of aminotransferases and total ATPases in the fish (Tilapia mossambica) under methyl parathion impact. 622 5

Recent studies of isotope exchange across lactate dehydrogenase (LDH) and alanine aminotransferase (AAT) in hearts call into question whether both reactions are in equilibrium. To compare the oxidative and non-oxidative fates of glycolytic end products, isolated rabbit hearts were perfused with 5 mM [2-13C] glucose and 2.5 mM [3-13C] pyruvate: with (n = 6) and without (n = 7) stimulation of pyruvate oxidation using dichloroacetate (DCA), and during normal perfusion or hypoxia (n = 7/n = 6, +/- DCA). 13C NMR spectroscopy of intact hearts confirmed a steady-state enrichment level in both alanine and lactate. 1H- and 13C-NMR spectroscopy of tissue extracts identified the fractions of lactate, alanine and glutamate pools formed from each exogenous substrate. Glycolysis from glucose accounted for 22 +/- 7% of lactate formed and 10 +/- 2% of alanine formed in control hearts, and 16 +/- 2% lactate and 15 +/- 2% alanine in hypoxic hearts (mean +/- S.E.M.). In contrast, exogenous pyruvate formed 36 +/- 5% of the lactate pool, and 86 +/- 3% of the alanine pool in controls and 47 +/- 3% of lactate and of 67 +/- 3% alanine during hypoxia. [2(-13)C] glucose did not contribute to oxidative energy production via the TCA cycle as determined from low 13C enrichment of glutamate C5 from glucose (< 2%), while [3-13C] pyruvate accounted for 84 +/- 7% of labeled glutamate C4. Thus, exogenous pyruvate out-competed the metabolism of glucose, indicating low glycolytic activity. At 40 min, 96 +/- 2% of the total alanine was labeled from either glucose or pyruvate, confirming equilibrium at AAT. However, only 55 +/- 10% of total lactate was labeled, suggesting that the LDH reaction is not in rapid equilibrium within the myocardium.
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PMID:Chemical versus isotopic equilibrium and the metabolic fate of glycolytic end products in the heart. 876 37

Skeletal muscle biopsies were performed on 12 healthy sedentary subjects and on 22 non-dyalized chronic renal failure patients (CRF) on a free diet and after overnight fasting. Parathormone, glucagon and insulin were determined at the same time of biopsies. CRF patients showed significantly low ATP and creatine phosphate levels. Regarding enzyme activities, a high hexokinase Vmax was found, while the pyruvate kinase activity was lower than in the control group. For the tricarboxylic acid cycle, citrate synthase, succinate dehydrogenase and malate dehydrogenase activities were higher; total NADH cytochrome c reductase activity was also high, while cytochrome oxidase activity was slightly lower. Both alanine aminotransferase and aspartate aminotransferase activities were considerably high in comparison with the control group. In conclusion, our study revealed a hypermetabolic TCA cycle, but impaired oxidative phosphorylation, which partly explained the reduced ATP concentration. Excessive protein intake and hormonal derangements may play a role in these metabolic changes.
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PMID:Altered muscle energy metabolism in post-absorptive patients with chronic renal failure. 924 94

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

Six amino acids are metabolized in resting muscle. They are leucine, isoleucine, valine, asparagine, aspartate, and glutamate. These amino acids provide the amino groups and probably the ammonia required for synthesis of glutamine and alanine, which are released in excessive amounts in the postabsorptive state and during ingestion of a protein-containing meal. Only leucine and part of the isolecine molecule can be oxidized in muscle as they are converted to acetyl-CoA. The other carbon skeletons are used solely for de novo synthesis of TCA-cycle intermediates and glutamine. The carbon atoms of the released alanine originate primarily from glycolysis of blood glucose and from muscle glycogen (about half each in resting conditions). After consumption of a protein-containing meal, BCAA and glutamate are taken up by muscle and their carbon skeletons are used for de novo synthesis of glutamine. About half of the glutamine released from muscle originates from glutamate taken up from the blood, both after overnight starvation, after prolonged starvation, and after consumption of a mixed meal. Glutamine produced by muscle is an important fuel and regulator of DNA and RNA synthesis in mucosal cells and immune system cells, and fulfils several other important functions in human metabolism. The alanine aminotransferase reaction functions to establish and maintain high concentrations of TCA-cycle intermediates in muscle during the first 10 min of exercise. The increase in concentration of TCA-cycle intermediates probably is needed to increase the flux of the TCA-cycle and meet the increased energy demand of exercise. A gradual increase in leucine oxidation subsequently leads to a carbon drain on the TCA-cycle in glycogen-depleted muscles, and may thus reduce the maximal flux in the TCA-cycle and lead to fatigue. Deamination of amino acids and glutamine synthesis present alternative anaplerotic mechanisms in glycogen-depleted muscles, but only allow exercise at 40-50% of Wmax. One-leg exercise leads to the net breakdown of muscle protein. The liberated amino acids are used for synthesis of TCA-cycle intermediates and glutamine. Today, the importance of this process in endurance exercise in the field (running or cycling) in athletes who ingest carbohydrates is not clear. It is proposed that the maximal flux in the TCA-cycle is reduced in glycogen-depleted muscles due to insufficient TCA-cycle anaplerosis, and that this presents a limitation for the maximal rate of fatty acid oxidation. Interactions between the amino acid pool and the TCA-cycle are suggested to play a central role in the energy metabolism of the exercising muscle.
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PMID:Muscle amino acid metabolism at rest and during exercise: role in human physiology and metabolism. 969 93

In comparison to cardiac tissue, relatively few data are available regarding the concentrations of tricarboxylic acid cycle intermediates (TCAI) and the potential influence of TCAI pool size on the regulation of cycle flux in mammalian skeletal muscle. However, recent human exercise studies have confirmed the fundamental observation made in electrically-stimulated rodent muscle that moderate to intense contraction results in a net accumulation of TCAI. The increase in TCAI pool size, termed "anaplerosis," appears exponentially related to work intensity, although the relative changes in the individual cycle intermediates differ markedly. While a number of mechanisms could potentially contribute to the increase in TCAI, the reaction catalyzed by alanine aminotransferase appears primarily responsible for anaplerosis at the onset of exercise in humans. The expansion of the TCAI pool has been suggested to be important for aerobic energy provision, and various theories have been proposed which link the total concentration of TCAI with the capacity for TCA cycle flux during exercise. However, despite the recent advances which have been made with regard to the magnitude and potential source of TCAI expansion in humans, our understanding of the physiological significance of anaplerosis is limited. Indeed, it remains speculative whether the increase in TCAI pool size represents an important regulatory signal or is simply a consequence of the huge increase in metabolic flux which occurs during exercise.
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PMID:Anaplerosis of the tricarboxylic acid cycle in human skeletal muscle during exercise. Magnitude, sources, and potential physiological significance. 978 33

Muscle proteins turn over slowly and there are minimal diurnal changes in the size of the muscle protein pool in response to feeding and fasting. Nitrogen balance and tracer studies indicate that protein oxidation and net protein breakdown (degradation--synthesis) is not increased during dynamic exercise at intensities of < or = 70% VO2max. An imbalance between muscle protein synthesis and degradation does exist during one leg knee extensor exercise and during two legged cycling in patients with glycogen phosphorylase deficiency. In these latter cases amino acids liberated from the protein pool are used for synthesis of TCA-cycle intermediates and glutamine. Six amino acids are metabolized in resting muscle: leucine, isoleucine, valine, asparagine, aspartate and glutamate. Only leucine and part of the isoleucine molecule can be converted to acetylCoA and oxidized. The carbon skeleton of the other amino acids is used for synthesis of TCA-cycle intermediates and glutamine. The six amino acids provide the amino groups and the ammonia for synthesis of glutamine and alanine, which are released by muscle in excessive amounts. About half of the glutamine release from muscle originates from glutamate taken up from the blood. Glutamine produced by muscle is an important fuel and regulator of DNA and RNA synthesis in mucosal cells and immune system cells and fulfils several other important functions in human metabolism. The alanine aminotransferase reaction functions to establish and maintain high concentrations of TCA-cycle intermediates and a high TCA cycle flux in the first minutes of exercise. A gradual increase in leucine oxidation subsequently leads to a carbon drain on the TCA-cycle in glycogen depleted muscles and may thus reduce the maximal flux in the TCA-cycle and lead to fatigue. Deamination of amino acids and glutamine synthesis present alternative anaplerotic mechanisms in glycogen depleted muscles but only allow exercise at 40-50% of Wmax. It is proposed that the maximal flux in the TCA-cycle is reduced in glycogen depleted muscles due to insufficient TCA-cycle anaplerosis and that this presents a limitation for the maximal rate of fatty acid oxidation. Interactions between the amino acid pool and the TCA-cycle thus seem to play a central role in the energy metabolism of the exercising muscle.
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PMID:Protein and amino acid metabolism in human muscle. 978 36

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