EC:3.5.4.4 - FACTA Search

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Query: EC:3.5.4.4 (adenosine deaminase)
5,136 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1) The rate of 2,3-bisphosphoglycerate breakdown is independent of pH value. 2) The adenine nucleotide pattern at alkaline pH values with its characteristic lowering of ATP and the accompanying accumulation of fructose-1,6-bisphosphate is caused by a relative excess of the activity of the hexokinase-phosphofructokinase system as compared wity pyruvate kinase. 3) The breakdown of adenine nucleotides proceeds via AMP mainly through phosphatase and not via AMP deaminase. 4) The constancy of the sum of nucleotides as long as glucose is present is postulated to be due to resynthesis via adenosine kinase which competes successfully with adenosine deaminase. 5) A procedure is given to calculate ATPase activity of glucose-depleted red cells. The results indicate that the ATPase activity is less at lower pH values and declines with time. An ATPase with a high Km for ATP is postulated. 6) During glucose depletion ATP production is mostly derived from the breakdown of 2,3-bisphosphoglycerate and the supply from the pentose phosphate pool both of which proceed at a constant rate. The contribution of pentose phosphate from the breakdown of adenine nucleotides amounts to 40% of the lactate formed at pH 6.8 and is about twice the lactate at pH 8.1.
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PMID:The breakdown of adenine nucleotides in glucose-depleted human red cells. 4 52

In fat cells isolated from the parametrial adipose tissue of rats, the addition of purified adenosine deaminase increased lipolysis and cyclic adenosine 3':5'-monophosphate (cyclic AMP) accumulation. Adenosine deaminase markedly potentiated cyclic AMP accumulation due to norepinephrine. The increase in cyclic AMP due to adenosine deaminase was as rapid as that of theophylline with near maximal effects seen after only a 20-sec incubation. The increases in cyclic AMP due to crystalline adenosine deaminase from intestinal mucosa were seen at concentrations as low as 0.05 mug per ml. Further purification of the crystalline enzyme preparation by Sephadex G-100 chromatography increased both adenosine deaminase activity and cyclic AMP accumulation by fat cells. The effects of adenosine deaminase on fat cell metabolism were reversed by the addition of low concentrations of N6-(phenylisopropyl)adenosine, an analog of adenosine which is not deaminated. The effects of adenosine deaminase on cyclic AMP accumulation were blocked by coformycin which is a potent inhibitor of the enzyme. These findings suggest that deamination of adenosine is responsible for the observed effects of adenosine deaminase preparations. Protein kinase activity of fat cell homogenates was unaffected by adenosine or N6-(phenylisopropyl)adenosine. Norepinephrine-activated adenylate cyclase activity of fat cell ghosts was not inhibited by N6-(phenylisopropyl)adenosine. Adenosine deaminase did not alter basal or norepinephrine-activated adenylate cyclase activity. Cyclic AMP phosphodiesterase activity of fat cell ghosts was also unaffected by adenosine deaminase. Basal and insulin-stimulated glucose oxidation were little affected by adenosine deaminase. However, the addition of adenosine deaminase to fat cells incubated with 1.5 muM norepinephrine abolished the antilipolytic action of insulin and markedly reduced the increase in glucose oxidation due to insulin. These effects were reversed by N6-(phenylisopropyl)adenosine. Phenylisopropyl adenosine did not affect insulin action during a 1-hour incubation. If fat cells were incubated for 2 hours with phenylisopropyl adenosine prior to the addition of insulin for 1 hour there was a marked potentiation of insulin action. The potentiation of insulin action by prior incubation with phenylisopropyl adenosine was not unique as prostaglandin E1, and nicotinic acid had similar effects.
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PMID:Effects of adenosine deaminase on cyclic adenosine monophosphate accumulation, lipolysis, and glucose metabolism of fat cells. 16 37

The effects of tetracycline on the metabolism of isolated rat white fat cells were examined. Tetracycline at a concentration of 0.05 mg/ml inhibited lipolysis due to 0.075 or 0.15 muM norepinephrine, but not that due to adenosine deaminase, theophylline, dibutyryl cyclic AMP or 1.5 muM norepinephrine. Higher concentrations of tetracycline (1 mg/ml) inhibited lipolysis due to all added agents except dibutyryl cyclic AMP. The accumulation of cyclic AMP after 5 minutes incubation with 0.15 muM norepinephrine plus adenosine deaminase was inhibited by 0.05 mg/ml of tetracycline. The large rise in cyclic AMP accumulation at 5 minutes due to 1.5 muM norepinephrine in the presence of 100 muM theophylline was only slightly inhibited by 0.05 or 0.1 mg/ml of tetracycline. Tetracycline at 1 mg/ml did markedly inhibit cyclic AMP accumulation due to all added agents. The stimulation of adenylate cyclase activity of fat cell ghosts by norepinephrine or fluoride was inhibited by 0.05 mg/ml or greater concentration of tetracycline. Insulin-stimulated glucose oxidation by fat cells was inhibited by 1 mg/ml of tetracycline. These results suggest that the anti-lipolytic action of tetracycline on rat fat cells is secondary to inhibition of cyclic AMP accumulation.
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PMID:Inhibition of lipolysis and cyclic AMP accumulation in white fat cells by tetracycline. 16 21

1. Adenosine was determined in rapidly frozen rat and guinea-pig brain and in guinea-pig cerebral tissues after incubation in vitro. Adenosine concentrations were approx. 2nmol/g wet wt. in frozen tissue, diminished at room temperature, and returned to 2nmol/g on incubation in oxygenated glucose/salines. 2. Superfusion with noradrenaline then increased the tissue's adenosine concentration 2.5-fold, and hypoxia caused an 8-fold increase. 3. Electrical stimulation alone or in the presence of noradrenaline or histamine increased the tissue's adenosine and cyclic AMP, but adenosine concentrations reached their peak later and were maintained for longer than those of cyclic AMP. 4. Superfusion with l-glutamate with and without electrical excitation raised adenosine concentrations to 15-34nmol/g. The increases in cyclic AMP on electrical stimulation, superfusion with glutamate or a combination of these treatments were diminished by addition of adenosine deaminase or theophylline. 5. It is concluded that adenosine can be produced endogenously in cerebral systems, in sufficient concentrations to accelerate an adenosine-activated adenylate cyclase, and by this route can contribute to the cerebral actions of electrical stimulation and of the neurohumoral agents. In certain instances cyclic AMP as substrate contributes to an increase in adenosine.
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PMID:Adenosine as a constituent of the brain and of isolated cerebral tissues, and its relationship to the generation of adenosine 3':5'-cyclic monophosphate. 19 79

Glucose transport into adipocytes of the rat was measured by monitoring the conversion of [1-(14)C]glucose into (14)CO(2). Glucose transport was made rate-limiting by increasing the flux through the pentose phosphate pathway with phenazine methosulphate, an agent that rapidly reoxidizes NADPH. Under these conditions, the observed rate of glucose disappearance from the incubation medium was about 20% higher than the rate of conversion of the C-1 of glucose into (14)CO(2). Apparent rates of glucose transport were significantly increased by insulin, H(2)O(2), adenosine and nicotinic acid. Stimulation of the apparent rate of glucose transport by insulin was dependent on adipocyte concentration, the hormone being most effective at relatively high cell concentrations. Adenosine and nicotinic acid further enhanced the maximum stimulation of glucose transport by insulin. Potentiation of insulin action by adenosine was more pronounced at lower cell concentrations. At relatively high cell concentrations the stimulatory action of insulin was markedly decreased by adenosine deaminase. Stimulation of apparent rates of glucose transport by the compounds noted above were antagonized by agents that increased intracellular cyclic AMP concentrations (theophylline and isoprenaline) and by dibutyryl cyclic AMP. Intracellular concentrations of cyclic AMP were significantly lowered when adipocytes were incubated with insulin, H(2)O(2), adenosine or nicotinic acid. These effects were observed under basal conditions or when intracellular cyclic AMP concentrations were elevated by theophylline or isoprenaline. On the basis of the above data, we suggest that insulin, H(2)O(2), adenosine and nicotinic acid may all stimulate glucose transport in rat adipocytes by lowering the intracellular cyclic AMP concentration. These data therefore support the hypothesis that cyclic AMP inhibits glucose transport in rat adipocytes.
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PMID:Stimulation of glucose transport in rat adipocytes by insulin, adenosine, nicotinic acid and hydrogen peroxide. Role of adenosine 3':5'-cyclic monophosphate. 22 Sep 63

The effect of adenosine was tested on the energetic metabolism of fed rat liver cells after isolation. The cells were incubated in a buffered saline medium with glucose (5 mM) and adenosine (1 mM) for 30 minutes at 37 degrees C. This increased the concentration of the adenylic nucleotides ATP (+57 per cent, ADP (+39 per cent). Cyclic AMP was increased (+50 per cent) and the intracellular inorganic phosphate decreased (-22 per cent). These changes were accompaned by a decrease of glycogenolysis, glucose consumption and lactate production. Measurement of glycolytic intermediates showed decreased concentrations of fructose 1,6-bis-phosphate and 3-phosphoglycerate proportional to the increase in ATP concentration. The near-equilibrium of the glyceraldehyde 3-phosphate dehydrogenase-phosphoglycerate kinase system was not modified by adenosine. The decrease of the NAD+/NADH ratio along with the increase of the ATP/ADP X PO4 ratio explains the decrease of 3-phosphoglycerate. The decrease in glucose consumption can be explained by the cross over at the phosphofructokinase stage with the decrease of fructose 1,6-bisphosphate. The major part of adenosine was deaminated as indicated by an increase in the production of ammonia and urea. The effects of inosine, or adenosine along with an inhibitor of adenosine deaminase (pentostatin) suggest that adenosine acts on the glucose consumption through adenylic nucleotides. However the increase of the adenylic nucleotide level cannot totally explain the other metabolic changes: decrease of the NAD+/NADH cytoplasmic ratio, constancy of this ratio in mitochondria, decrease of gluconeogenesis from lactate. A direct action of adenosine can therefore be expected.
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PMID:The influence of adenosine on intermediary metabolism of isolated hepatocytes. 23 80

Adenine nucleotide breakdown to nucleosides and purine bases was measured in cultures of human lymphoblastoid cells following: 1) the inhibition of oxidative phosphorylation in the absence of glucose or 2) the addition of 2-deoxyglucose. A mutant cell line, deficient in adenosine kinase, in the presence of an adenosine deaminase inhibitor was used to measure utilization of the two pathways of AMP catabolism involving initial action of either purine 5'-nucleotidase or AMP deaminase. In such a system the appearance of adenosine induced by the oxidative phosphorylation inhibitor, rotenone, implies that approximately 70% of AMP breakdown occurs via dephosphorylation. By the same method, deamination accounts for 82% of AMP breakdown when 2-deoxyglucose is added. The occurrence of AMP dephosphorylation is not correlated with elevated concentrations of substrate or with decreased concentrations of the inhibitors of 5'-nucleotidase, ATP and ADP. Dephosphorylation occurs if, and only if, the adenylate energy charge decreases to about 0.6 in these experiments. In cultures deprived of glucose and oxygen, adenine nucleotide degradation via dephosphorylation results in recovery of normal energy charge values.
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PMID:Adenine nucleotide degradation during energy depletion in human lymphoblasts. Adenosine accumulation and adenylate energy charge correlation. 47 72

A series of hexofuranosyladenine nucleosides have been tested as substrates and inhibitors of adenosine deaminase from calf intestinal mucosa. The nucleosides differed from each other in configuration at the various carbon atoms of the hexose and had either a methyl group or hydroxymethyl group at the terminal position. It has been confirmed that the best substrates have the beta-D or alpha-L configuration at the anomeric position and an hydroxyl group on the same side of the furanose ring as adenine. However, these properties are not minimal and other nucleosides will act as substrates even if they do not have the preferred configurations or groups available. The effect of having two hydroxyl groups in the same region of the molecule and in the preferred configurations was to greatly reduce Vmax. Most structural changes resulted in changes in Vmax, whereas KM values remained fairly close. Only a change in configuration of the hydroxyl group at C-5' caused a dramatic change in affinity, as reflected in the KM. All nucleosides exhibited competitive inhibitory kinetics. In the latter studies also, a change of configuration at C-5' greatly affected binding.
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PMID:Hexofuranosyladenine nucleosides as substrates and inhibitors of calf intestinal adenosine deaminase. 49 May 34

The metabolic and growth inhibitory effects of adenosine toward the human lymphoblast line WI-L2 were potentiated by the adenosine deaminase inhibitors erythro-9-(2-hydroxy-3-nonyl) adenine (EHNA) and coformycin. EHNA, 5 micron, or coformycin, 3.5 micron, at concentrations that inhibited adenosine deaminase activity more than 90% had little effect on cell growth or the metabolic parameters studied. Adenosine, 50 micron, plus EHNA, 5 micron, arrested cell growth in both parent and adenosine kinase-deficient lymphoblasts, implicating the nucleoside as the mediator of the cytostatic effect. Adenosine, 50 micron, in combination with the adenosine deaminase inhibitors reduced 14CO2 generation from [1-14C]glucose by 38%, depleted 5-phosphoribosyl-1-pyrophosphate by more than 90%, and reduced pyrimidine ribonucleotide concentrations. Uridine, 10 or 100 micron, reversed adenosine plus EHNA growth inhibition in WI-L2 but not in adenosine kinase mutants. Adenine, 500 micron, which may be converted to the same intracellular nucleotides as adenosine, reduced the growth rate by 50% in both parent and adenine phosphoribosyltransferase-deficient lymphoblasts. Although adenine also depleted cells of 5-phosphoribosyl-1-pyrophosphate and reduced pyrimidine ribonucleotide by 50%, the mechanisms of adenine and adenosine toxicity differ. In contrast to the ability of uridine to reverse adenosine cytostasis, growth inhibition by adenine was not reversed by uridine, indicating that pyrimidine ribonucleotide depletion is not the primary mechanisms of adenine toxicity.
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PMID:Cytotoxic and metabolic effects of adenosine and adenine on human lymphoblasts. 66 33

To elucidate the mode of action of hexobendine, its effects on some enzyme activities, the uptake of adenosine by rat erythrocytes and changes in the concentration of various myocardial substrates following induced hypoxia in rat were studied. Hexobendine had no effect on the in vitro activities of the adenosine degrading enzyme, adenosine deaminase and of the A-PRTase, HG-PRTase which are associated with the salvage pathways of purine biosyntheses. The uptake of adenosine by rat erythrocytes in vitro was inhibited considerably by hexobendine. Hypoxic states results in a significant decrease in creatine phosphate, ATP, glycogen and glucose contents, and increase in ADP, AMP, adenosine and lactate contents in rat myocardials. These alterations in cardiac metabolism induced by hypoxia were significantly improved by hexobendine given orally in doses of 10 approximately 100 mg/kg. Thus, hexobendine was shown to maintain the normal aerobic energy metabolism of the heart under states of hypoxia. In such states adenosine may be released from tissues and this increase in the available concentration of adenosine in plasma through inhibition of uptake by erythrocytes may be involved in the coronary vasodilating action of hexobendine.
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PMID:[Effects of hexobendine on adenosine metabolism and myocardial energy metabolism (author's transl)]. 74 50

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