Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.3.5 (5'-nucleotidase)
 3,167 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have utilized S-farnesyl-Leu-Ala-Arg-Tyr-Lys-Cys as a methyl-accepting substrate to characterize a membrane-bound C-terminal protein methyltransferase from rat liver. We have localized the activity to the microsomal fraction and show that the bulk of the enzyme fractionates by density gradient centrifugation with glucose-6-phosphatase, a marker of the endoplasmic reticulum, and not with 5'-nucleotidase, a marker of the plasma membrane, or galactosyl:N-acetylglucosamine transferase, a marker of the Golgi apparatus. This methyltransferase appears to form an integral part of the membrane structure. Its activity is markedly affected by a variety of detergents used to solubilize membrane proteins in their native form. All activity is lost when membranes are treated with seven different detergents at a concentration of 1% (w/v). The activity is inhibited by N-ethylmaleimide, although it can be protected against inactivation with its substrate S-adenosyl-L-methionine, or its product S-adenosyl-L-homocysteine. Finally, we find that 5'-methylthioadenosine, a substrate analogue reported to be an inhibitor of this activity in other studies, is not an effective inhibitor in vitro.
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PMID:Characterization of a rat liver protein carboxyl methyltransferase involved in the maturation of proteins with the -CXXX C-terminal sequence motif. 132 16

Regulation of blood flow and mitochondrial respiration in the heart would be clarified by improved knowledge of interstitial concentrations and cellular production rates of adenosine; however, these variables cannot be measured directly. To interpret indexes that are available, a comprehensive mathematical model was developed, based on a large body of experimental data. The model describes most of the important pathways of capillary-tissue transport and cellular metabolism of adenosine in the guinea pig heart. It includes capillary flow, solute transport between tissue regions, nonlinear enzyme kinetics for adenosine kinase and adenosine deaminase, and reversible biunireactant kinetics for S-adenosylhomocysteine hydrolase in cardiomyocytes and endothelial cells, intracellular production of adenosine via AMP hydrolysis and transmethylation, and extracellular production of adenosine. A single set of parameter values for the model was obtained in the first stage of the analysis by taking certain values directly from published sources, other values were subject to specific constraints, and other values were determined by parameter optimization. The effects of flow and endothelial metabolism on the relation between interstitial and venous adenosine concentrations were determined. The relation between myocardial adenosine production rate and S-adenosylhomocysteine accumulation in the presence of excess homocysteine was estimated. In the second stage of the analysis, the model was used to investigate the mechanism of myocardial adenosine production, without changing the parameter values. Cellular adenosine production rates were estimated by fitting measurements of venous adenosine release obtained during altered energetic conditions in experiments by different investigators. The original results showed a dissociation between measurements of cytosolic AMP concentrations and venous adenosine release. It is concluded that 1) it is essential to account for the effect of flow on interstitial and venous adenosine concentrations, since decreased flow may produce effects outwardly resembling inhibition of the enzyme 5'-nucleotidase, 2) adenosine concentrations in epicardial transudate are not in equilibrium with interstitial fluid, and 3) the rate of cellular adenosine production increases monotonically with free cytosolic concentrations of AMP during a variety of alterations in energy balance of the guinea pig heart.
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PMID:Comprehensive model of transport and metabolism of adenosine and S-adenosylhomocysteine in the guinea pig heart. 149 7

1. The metabolic control of adenosine concentration in the rat liver through the 24-hr cycle is related to the activity of adenosine-metabolizing enzymes [5'-nucleotidase (5'N), adenosine deaminase (A.D.), adenosine kinase (A.K.) and S-adenosylhomocysteine hydrolase (SAH-H)]. 2. Two peaks of adenosine were observed, one at 12:00 hr caused by high activity of 5'N and SAH-H, and the other at 02:00 hr, caused by a decrease in purine catabolism and purine utilization, low activity of SAH-H and de novo purine formation. 3. The similarity of the adenosine and S-adenosylmethionine (SAM) profiles through the 24-hr cycle suggests a role of adenosine in transmethylation reactions, because, during the night (02:00 hr), the metabolic conditions favor the formation and accumulation of S-adenosylhomocysteine (SAH), with consequent inhibition of transmethylation reactions. 4. In the 24-hr variation of phosphatidylcholine (PC) and phosphatidylethanolamine (PE), the lowest ratio of PC/PE was observed at 24:00-02:00 hr when SAH concentration is high, whereas the highest PC/PE ratio occurs at the same time as one of the SAM/SAH ratio maxima.
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PMID:Twenty-four-hour changes of S-adenosylmethionine, S-adenosylhomocysteine adenosine and their metabolizing enzymes in rat liver; possible physiological significance in phospholipid methylation. 176 Nov 53

Activities of several adenosine metabolizing enzymes were examined in capillary preparations isolated from rabbit ventricle. Vmax and Km values for 5'-nucleotidase were 2.3 nmol/min/mg and 10 microM, respectively. For adenosine deaminase the corresponding values were 7.8 nmol/min/mg and 32 microM. S-adenosyl-homocysteine hydrolase, which forms adenosine by the hydrolysis of S-adenosylhomo-cysteine, was also present (Vmax, 0.07 nmol/min/mg; Km, 0.81 microM), as were adenosine kinase (Vmax, 0.2 nmol/min/mg; Km, 0.52 microM) and purine nucleoside phosphorylase (Vmax, 13.8 nmol/min/mg; Km, 96 microM). These enzymes were also present in microvessels (capillaries and arterioles) purified from rabbit brain. Activities of several enzymes, especially 5'-nucleotidase and adenosine deaminase, were much lower in myocytes isolated from rabbit ventricle. The study provides evidence that endothelial cells of the microvasculature from heart and brain are capable of activity forming and degrading adenosine. It is possible that adenosine formed by these cells may contribute to the local regulation of blood flow.
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PMID:Adenosine metabolism in microvessels from heart and brain. 300 95

The effect of adenosine on the metabolism of prelabeled adenine nucleotides was investigated in isolated hepatocytes. Adenosine caused an approximately equal to 2-fold increase in the ATP content of the cells. This effect was in part counteracted by an increased rate of adenine nucleotide catabolism that could be explained by a stimulation of both AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) and the cytoplasmic 5'-nucleotidase (5'-ribonucleotide phosphohydrolase, EC 3.1.3.5) because of the increased concentration of ATP. The unexpected finding that labeled adenosine was formed immediately after the addition of the unlabeled nucleoside could be explained by the trapping effect of adenosine. An accumulation of labeled adenosine was observed also in the presence of 5-iodotubercidin, a potent inhibitor of adenosine kinase (ATP:adenosine 5'-phosphotransferase, EC 2.7.1.20). Under these conditions, there was a decrease in the concentration of ATP in the cell and a 2- to 3-fold increase in the rate of formation of allantoin. This formation of adenosine was only slightly decreased by inhibition of the membranous 5'-nucleotidase; it led to the accumulation of S-adenosylhomocysteine in the presence of coformycin and an excess of L-homocysteine. It was concluded that, under basal conditions, the cytoplasmic 5'-nucleotidase present in the liver cell continuously produces adenosine, which is immediately reconverted into AMP by adenosine kinase, without giving rise to allantoin. This futile cycle between AMP and adenosine amounts to at least 20 nmol/min per g of liver and, thus, exceeds the basic rate of allantoin formation.
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PMID:Evidence for a substrate cycle between AMP and adenosine in isolated hepatocytes. 630 84

This study was conducted to elucidate the role of S-adenosyl-L-homocysteine (SAH) hydrolase, 5'-nucleotidase and adenosine kinase in the production and removal of adenosine in the isolated guinea pig heart during normoxic (95% O2) and hypoxic (30% O2) perfusion. Using an adenosine kinase inhibitor (5'-amino-5'-deoxy-adenosine; 50 microM) and an adenosine deaminase inhibitor (EHNA; 5 microM) the total steady-state production rate of adenosine in the heart was estimated to be greater than 1.2 nmol.min-1 per g wet wt., during normoxia. Most (95%) of the SAH-derived adenosine is salvaged by adenosine kinase action. The rate of adenosine phosphorylation increased 3-fold when isolated hearts were perfused with hypoxic medium, suggesting that adenosine kinase is not substrate-saturated under normoxic conditions. The steady-state production of adenosine was also estimated during hypoxia (5.9 nmol-min-1 per g wet wt.) and compared with previously determined transmethylation rate during hypoxia (1.12 nmol.min-1 x g wet wt.). In an attempt to assess the in-vivo activity of cytosolic 5'-nucleotidase, the 5'-AMP pool was labelled by perfusing the isolated hearts with tricyclic nucleoside (TCN) which became phosphorylated (TCN-P). The release rate of both adenosine and TCN in the post-labelling phase was increased by hypoxic perfusion, suggesting that the increased rate of 5'-AMP hydrolysis may be due to increased availability of substrate, as well as activation of 5'-nucleotidase. Our findings suggest that during normoxic perfusion a significant amount of adenosine is derived from an apparently oxygen-independent mechanism (cellular transmethylation) whereas during hypoxic perfusion hydrolysis of adenine nucleotides to adenosine prevails.
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PMID:Adenosine metabolism in the guinea pig heart: the role of cytosolic S-adenosyl-L-homocysteine hydrolase, 5'-nucleotidase and adenosine kinase. 829 79

Adenosine is recognised as an important regulator of myocardial function and coronary vascular tone in the ischaemic myocardium. It is produced by the enzymatic dephosphorylation of 5'-AMP by 5'-nucleotidase and the hydrolysis of SAH by SAH-hydrolase. 5'-Nucleotidase is thought to contribute to adenosine production aside from the accumulation of 5'-AMP in the ischaemic myocardium, while the hydrolysis of SAH plays a major role in adenosine production in the normoxic myocardium. 5'-Nucleotidase activity is reported to increase adenosine production through accumulation of ATP, ADP, H+, Mg2+ and inorganic phosphate during ischaemia. In addition, we have found that alpha 1 adrenergic receptors, activated in ischaemic hearts, increase both 5'-nucleotidase activity and adenosine production. Inactivation of adenosine deaminase and adenosine kinase may also contribute to adenosine production. On the other hand, the major role of endogenous adenosine is to increase coronary blood flow. This adenosine induced coronary vasodilatation is amplified by alpha 2 adrenoceptor stimulation. Adenosine induced vasodilatation is also enhanced by increasing H+ and opening ATP sensitive K+ channels, which occurs in the ischaemic myocardium. However, coronary vasodilatation is not the only effect of adenosine in the ischaemic myocardium. Stimulation of adenosine A2 receptors coupled to Gs proteins attenuates both free radical generation by activated leucocytes and aggregation of platelets. Adenosine A1 receptor activation coupled to G(i) proteins attenuates beta adrenoceptor mediated increases in myocardial contractility, Ca2+ influx into myocytes, and noradrenaline release from the presynaptic nerves. Any or all of these effects may attenuate ischaemic and reperfusion injury.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Role of adenosine and its interaction with alpha adrenoceptor activity in ischaemic and reperfusion injury of the myocardium. 838 27

Eight diurnally active (06:00-23:00 h) subjects were adapted for 2 days to the room conditions where the experiments were performed. Blood sampling for adenosine metabolites and metabolizing enzymes was done hourly during the activity span and every 30 min during sleep. The results showed that adenosine and its catabolites (inosine, hypoxanthine, and uric acid), adenosine synthesizing (S-adenosylhomocysteine hydrolase and 5'-nucleotidase), degrading (adenosine deaminase) and nucleotide-forming (adenosine kinase) enzymes as well as adenine nucleotides (AMP, ADP, and ATP) undergo statistically significant fluctuations (ANOVA) during the 24 h. However, energy charge was invariable. Glucose and lactate chronograms were determined as metabolic indicators. The same data analyzed by the chi-square periodogram and Fourier series indicated ultradian oscillatory periods for all the metabolites and enzymatic activities determined, and 24-h oscillatory components for inosine, hypoxanthine, adenine nucleotides, glucose, and the activities of SAH-hydrolase, 5'-nucleotidase, and adenosine kinase. The single cosinor method showed significant oscillatory components exclusively for lactate. As a whole, these results suggest that adenosine metabolism may play a role as a biological oscillator coordinating and/or modulating the energy homeostasis and physiological status of erythrocytes in vivo and could be an important factor in the distribution of purine rings for the rest of the organism.
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PMID:Temporal variations of adenosine metabolism in human blood. 887 80

The quantitatively most important source of adenosine under well-oxygenated conditions is 5'-AMP hydrolyzed by cytosolic 5'-nucleotidase N-I. Hydrolysis of S-adenosylhomocysteine and extracellular dephosphorylation of 5'-AMP further contribute to total production. More than 90% of the total production occur intracellularly under well-oxygenated conditions. Besides cardiomyocytes, endothelial cells and smooth muscle contribute significantly to total cardiac adenosine production. Rapid enzymatic conversion of adenosine is provided by adenosine kinase and adenosine deaminase, keeping the cytosolic adenosine concentration in the nanomolar range. Due to the high intracellular rates of adenosine rephosphorylation and deamination the cytosolic is normally below the extracellular adenosine concentration, making the cytosol to a sink rather than a source of adenosine. It is for this reason that blockers of membrane transport enhance the plasma adenosine concentration. With increasing catabolism of adenine nucleotides the rate of intracellular adenosine production exceeds the rate of adenosine deamination and rephosphorylation. Thus, this condition will result in a concentration gradient from intra- to extracellular. Thence, membrane transport blockers would be expected to increase the intracellular adenosine concentration. A considerable insecurity on the importance of experimental data results from species differences of purine metabolism. Cardiac adenosine metabolism has recently been described in quantitative terms using mathematical model analysis. This analysis tool may prove useful in future when (1) clarifying the importance of various regulatory actions described for the different pathways of adenosine metabolism, (2) making quantitative comparisons of different experimental models possible and (3) deepening the insight from experimental data.
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PMID:Metabolic flux rates of adenosine in the heart. 1111 29