Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Administration of a large dose of atrial natriuretic peptide is associated with an increase in glomerular filtration rate, diuresis and natriuresis in normal-sodium rats. However, glomerular hyperfiltration induced by atrial natriuretic peptide is markedly decreased in low-sodium rats. Glomerular insensitivity to atrial natriuretic peptide may be due to increased activity of the renin-angiotensin system in low-sodium rats and to an accompanying hypersensitivity to adenosine. The results indicate that attenuated glomerular responses to atrial natriuretic peptide are restored by the administration of adenosine deaminase in low-sodium rats. Moreover atrial natriuretic peptide markedly increases the urinary excretion of adenosine deaminase, which may be due to increased permeability of glomeruli to the enzyme.
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PMID:Adenosine deaminase restores the ability of atrial natriuretic peptide to induce glomerular hyperfiltration in low-sodium rats. 149 57

Analysis of cyclic nucleotide phosphodiesterase (PDE) activity in cellular fractions from cultured rat pheochromocytoma (PC12) cells has shown that the predominant hydrolytic activity in both cytosolic and particulate compartments is characteristic of a PDE II, the cGMP-activatable family of PDE isozymes. Cytosolic PDE activity was purified to a high degree utilizing DE-52 anion exchange and cGMP-Sepharose affinity chromatographies. The physicochemical properties of PC12 PDE II were similar to those of PDE II isolated from particulate or soluble fractions of other tissues, including subunit molecular weight of approximately 102,000, activation of cAMP hydrolysis by cGMP, and positive cooperative kinetic behavior for cAMP and cGMP hydrolysis. The potential role of PDE II in regulating cAMP metabolism in intact PC12 cells was studied using an [3H]adenine prelabeling technique. Stimulation of PC12 cell adenosine receptors resulted in a 5-8-fold increase in cAMP accumulation. Removal of the adenosine stimulus by the addition of exogenous adenosine deaminase resulted in a rapid decay of cAMP to prestimulated basal levels within 2 min. Treatment of PC12 cells with atrial natriuretic factor or sodium nitroprusside caused 1) increased intracellular cGMP levels, 2) attenuation of adenosine-stimulated cAMP accumulation, and 3) increased rates of cAMP decay after removal of the adenosine stimulus. Treatment of PC12 cells with HL-725 (a potent inhibitor of isolated PDE II activity in vitro) caused 1) increased basal cAMP accumulation, 2) potentiation of adenosine-stimulated cAMP accumulation, and 3) retardation of the rate of cAMP decay after removal of the adenosine stimulus. HL-725 blocked both the attenuation of cAMP accumulation and the accelerated rate of cAMP decay observed with the cGMP-elevating agents. These results suggest that, in PC12 cells, drugs or hormones that inhibit PDE II or increase intracellular cGMP levels to activate PDE II can modulate cAMP metabolism by altering the catalytic status of the enzyme.
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PMID:Phosphodiesterase II, the cGMP-activatable cyclic nucleotide phosphodiesterase, regulates cyclic AMP metabolism in PC12 cells. 164 46

The mechanism by which hyperglycaemia causes decreased (Na+,K+)-ATPase activity preventable by aldose reductase inhibitors and by raising plasma myo-inositol in specific tissues can be activated in vitro in normal rabbit aortic wall; it selectively inhibits a component of resting (Na+,K+)-ATPase activity maintained by a novel regulatory system through rapid basal phosphatidylinositol turnover (hydrolysis) in a discrete pool, which is replenished by a fraction of phosphatidylinositol synthesis that selectively requires myo-inositol transport. A role for endogenously released adenosine in this regulatory system was examined. Adding adenosine deaminase or 8-phenyltheophylline, an adenosine receptor antagonist, selectively inhibited the component of (Na+,K+)-ATPase activity maintained by the regulatory system; when inhibited with adenosine deaminase this component was restored by 2-chloroadenosine, 5'-N-ethylcarbox-amidoadenosine, and 1-oleoyl-2-acetylglycerol, but not by forskolin (which also did not inhibit this component). Adenosine deaminase inhibited the rapid basal turnover of the discrete phosphatidylinositol pool, and 2-chloroadenosine then stimulated its turnover. Raising medium glucose from 5 to 10-30 mmol/l inhibits the regulatory system by making myo-inositol transport at a normal plasma level inadequate to maintain the replenishment of the discrete phosphatidylinositol pool. 2-Chloroadenosine stimulation of the "adenosine-sensitive" component of (Na+,K+)-ATPase activity was inhibited in tissue incubated with 30 mmol/l glucose and myo-inositol in a normal plasma level, but this effect was demonstrable when the medium myo-inositol was raised seven-fold. Hyperglycaemia-induced decreased (Na+,K+)-ATPase activity that is preventable by aldose reductase inhibitors and by raising plasma myo-inositol results from the inhibition of a novel adenosine-(Na+,K+)-ATPase regulatory system.
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PMID:Elevated extracellular glucose inhibits an adenosine-(Na+,K+)-ATPase regulatory system in rabbit aortic wall. 165 55

Addition of adenosine deaminase to cultured cerebellar neurones, led to large increases in the influx of 45Ca2+ and hydrolysis of polyphosphoinositide. These effects were inhibited or attenuated by glutamate receptor antagonists (AP5 or MK-801) and were not observed in cells stimulated by maximum concentrations of glutamate or quisqualate. Stimulation of the influx of 45Ca2+ and hydrolysis of phosphoinositide by adenosine deaminase may be secondary to an enhanced release of endogenous glutamate that in turn activates specific excitatory amino acid receptors. Accordingly, adenosine deaminase potently increased release of D-[3H]aspartate, an effect that requires the presence of extracellular Na+ and is insensitive to inhibition by MK-801. None of the effects of adenosine deaminase may be simply related to a fall in endogenous adenosine. In fact, the action of adenosine deaminase was neither reversed by agonists (L-PIA or NECA), nor mimicked by antagonists (IBMX or theophylline) of adenosine receptors. It is speculated that adenosine deaminase stimulates release of neurotransmitter through a mechanism independent of depletion of adenosine. A possible direct action of adenosine deaminase should be taken into account when the enzyme is used to unmask the effects of endogenous adenosine.
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PMID:Adenosine deaminase increases release of excitatory amino acids through a mechanism independent of adenosine depletion. 170 78

The present studies define the physiologic role of endogenous adenosine in the perfused shark rectal gland, a model epithelia for hormone-stimulated chloride transport. Chloride ion secretion, and venous adenosine and inosine concentrations increased in parallel in response to hormone stimulation. From a basal rate of 157 +/- 26 mu eq/h per g, chloride secretion increased to 836 +/- 96 and 2170 +/- 358 with 1 and 10 microM forskolin, venous adenosine increased from 5.0 +/- 1 to 126 +/- 29 and 896 +/- 181 nM, and inosine increased from 30 +/- 9 to 349 +/- 77 and 1719 +/- 454 nM (all P less than 0.01). Nitrobenzylthioinosine (NBTI), a nucleoside transport inhibitor, completely blocked the release of adenosine and inosine. Inhibition of chloride transport with bumetanide, an inhibitor of the Na+/K+/2Cl- cotransporter, or ouabain, an inhibitor of Na+/K+ ATPase activity, reduced venous adenosine and inosine to basal values. When the interaction of endogenous adenosine with extracellular receptors was prevented by adenosine deaminase, NBTI, or 8-phenyltheophylline, the chloride transport response to secretagogues increased by 1.7-2.3-fold. These studies demonstrate that endogenous adenosine is released in response to hormone-stimulated cellular work and acts at A1 adenosine receptors as a feedback inhibitor of chloride transport.
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PMID:Endogenous adenosine is an autacoid feedback inhibitor of chloride transport in the shark rectal gland. 175 53

1. In dogs anaesthetized with sodium pentobarbitone and artificially ventilated, the gracilis muscles were vascularly isolated and perfused at a constant flow of 28.4 +/- 4.6 ml min-1 (100 g muscle tissue)-1 (99.8 +/- 4.5% of maximum free flow, means +/- standard error of the mean (S.E.M.), n = 9). 2. Three to five minutes of electrical stimulation of the cut peripheral end of the obturator nerve (4 Hz, 6 V, 0.2 ms) resulted in muscle contraction (0.61 +/- 0.14 kg (100 g)-1 during solvent infusion and 0.56 +/- 0.10 kg (100 g)-1 during intra-arterial adenosine deaminase infusion (50 U min-1) and an immediate decrease in arterial perfusion pressure from 184.5 +/- 8.1 mmHg to 148.2 +/- 5.7 mmHg (18.7 +/- 3.4% decrease) during solvent infusion, and from 193.5 +/- 7.16 to 142.0 +/- 10.2 mmHg (25.4 +/- 6.1% decrease) during adenosine deaminase infusion 10 s after the commencement of muscle stimulation. After about 5 min of muscle contractions, the arterial perfusion pressure decreased to 120.8 +/- 7.8 mmHg (32.9 +/- 5.8% decrease) during solvent infusion, and to 152.8 +/- 11.2 mmHg (20.9 +/- 5.3% decrease) during adenosine deaminase infusion (i.e. 37.9 +/- 6.2% attenuation of the fall in arterial perfusion pressure). The time taken for 90% recovery of the arterial perfusion pressure was 72.1 +/- 10.9 s during solvent infusion, and 51.5 +/- 9.3 s during adenosine deaminase infusion (P less than 0.05). 3. Adenosine (2 x 10(-3) mol l-1) infusion in the resting muscle during solvent infusion (final concentration in arterial blood 1.3 x 10(-4) +/- 6.0 x 10(-5) mol l-1) resulted in a 34.8 +/- 7.2% fall in arterial perfusion pressure but a fall of only 7.2 +/- 1.8% during adenosine deaminase infusion (50 U min-1; P less than 0.05; n = 5) indicating that adenosine deaminase infused at 50 U min-1 was more than adequate to metabolize endogenous adenosine produced during muscle contractions. 4. These data suggest that adenosine contributes about 40% to the sustained-exercise vasodilatation under constant high-flow conditions and also in post-exercise vasodilatation, but does not contribute to the initiation of exercise vasodilatation.
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PMID:Attenuation of exercise vasodilatation by adenosine deaminase in anaesthetized dogs. 179 47

We have measured cyclic GMP accumulation in co-cultures of bovine aortic endothelial cells and rat smooth muscle cells as an index of endothelium-derived relaxing factor (EDRF) production. Adenosine deaminase (EC 3.5.4.4, Sigma type VI) produced a 5- to 10-fold increase in the basal and bradykinin-stimulated cyclic GMP content of co-cultures but had no effect on smooth muscle cells alone. Cyclic GMP accumulation in response to adenosine deaminase was not blocked by adenosine deaminase inhibitors or affected by adenosine, the products of adenosine deamination (inosine and ammonia), or adenosine receptor antagonists. Since superoxide anion is known to destroy EDRF and nitric oxide (NO) (which is similar or identical to EDRF in composition), we tested for superoxide dismutase (SOD, EC 1.15.1.1) in single lots of eight commercial sources of adenosine deaminase by measuring inhibition of the superoxide-mediated reduction of cytochrome c. SOD activity was found in all sources of adenosine deaminase, but varied widely. One lot of Sigma type VI enzyme contained 0.08 units SOD/unit adenosine deaminase. The EC50 values of purified SOD (0.23 units/mL) and Sigma type VI adenosine deaminase (2.1 units/mL) needed to increase the cyclic GMP content of co-cultures differed by a similar factor, 0.11. Thus, the SOD activity in adenosine deaminase is sufficient to account for its effect on cyclic GMP accumulation. One lot of Boehringer Mannheim adenosine deaminase contained much less SOD contamination (0.006 units SOD/unit adenosine deaminase) and produced much less accumulation of cyclic GMP in co-cultures. Cyclic GMP accumulations in response to adenosine deaminase and SOD were both abolished by the NO synthetase inhibitor NG-monomethyl-L-arginine (0.1 mM), consistent with the idea that these enzymes act by stabilizing EDRF. Adenosine deaminase and the SOD activity contaminating it were found to have similar molecular masses of 33-34 kD as assessed by gel permeation chromatography. When run under reducing conditions to dissociate homodimeric SOD into monomers, a 16.6 kD peptide which co-migrates with purified cupro-zinc SOD was visible in silver-stained sodium dodecyl sulfate-polyacrylamide gels of the Sigma type VI but not the Boehringer Mannheim adenosine deaminase. We conclude that commercial sources of adenosine deaminase are variably contaminated by SOD. Since EDRF is synthesized by many tissues, the use of adenosine deaminase contaminated with SOD may produce numerous effects not attributable to the deamination of adenosine.
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PMID:Contamination of adenosine deaminase by superoxide dismutase. Stabilization of endothelium-derived relaxing factor. 184 47

Liver plasma membrane ecto-ATPase activity is largely restricted to the bile canalicular membrane. To determine whether a transport process is also selectively present on this membrane surface to reclaim adenosine derived from the intracanalicular degradation of ATP, the characteristics of hepatic nucleoside transport were examined in canalicular (cLPM) and basolateral (blLPM) rat liver plasma membrane vesicles. In the presence of the adenosine deaminase inhibitor, deoxycoformycin, an inwardly directed Na+ gradient markedly stimulated [3H]adenosine uptake in cLPM vesicles. Canalicular Na(+)-dependent [3H]adenosine uptake was enhanced by an intravesicular-negative membrane potential and inhibited by dissipation of the Na+ gradient with gramicidin D. Both purine and pyrimidine nucleosides inhibited canalicular adenosine transport. 6-[(4-Nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine, an inhibitor of nucleoside transport in erythrocytes and nonepithelial cells, had no effect on canalicular adenosine transport. Canalicular Na(+)-dependent [3H]adenosine uptake exhibited saturability with a Michaelis-Menten constant of 8.3 microM and a maximum transport rate of 7.6 pmol.5 s-1.mg protein-1. In contrast, [3H]adenosine uptake in blLPM vesicles was not stimulated by an inwardly directed Na+ gradient. These findings demonstrate asymmetric distribution of hepatic Na(+)-dependent nucleoside transport. Reclamation of intracanalicular adenosine resulting from ecto-ATPase activity may explain the presence of this transport process selectively on the bile canalicular membrane.
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PMID:Adenosine transport in rat liver plasma membrane vesicles. 195 95

Intake of completely purine-free foods of low sodium content increased the plasma concentrations of both hypoxanthine and inosine and the urinary excretion of hypoxanthine, while it decreased the urinary excretion of uric acid and the fractional clearance of uric acid. However, this diet affects neither nucleotides (inosine monophosphate, adenosine monophosphate, adenosine diphosphate and adenosine triphosphate) in red blood cells, enzymes (purine nucleoside phosphorylase, adenosine deaminase and hypoxanthine guanine phosphoribosyl transferase) in red blood cells nor the fractional clearance of oxypurines. These results suggest that the salvage of purines becomes more effective by limiting the conversion of hypoxanthine to xanthine and limiting the loss of uric acid during intake of completely purine-free foods of low sodium content; also that a decrease in the fractional clearance of uric acid due to completely purine-free foods of low sodium content may be an additional mechanism associated with the conservation of purines but is more likely to be a response to the low sodium diet on the renal handling of uric acid.
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PMID:The effect of completely purine-free diet of low sodium content on purine intermediates and end-product. 226 97

Adenosine transport has been further characterized in rat renal brush-border membranes (BBM). The uptake shows two components, one sodium-independent and one sodium-dependent. Both components reflect, at least partly, translocation via a carrier mechanism, since the presence of adenosine inside the vesicles stimulates adenosine uptake in the presence as well as in the absence of sodium outside the vesicles. The sodium-dependent component is saturable (Km adenosine = 2.9 microM, Vmax = 142 pmol/min per mg protein) and is abolished at low temperatures. The sodium-independent uptake has apparently two components: one saturable (Km = 4-10 microM, Vmax = 174 pmol/min per mg protein) and one non-saturable (Vmax = 3.4 pmol/min per mg protein, Km greater than 2000 microM). Inosine, guanosine, 2-chloroadenosine and 2'-deoxyadenosine inhibit the sodium-dependent and -independent transport, as shown by trans-stimulation experiments, probably because of translocation via the respective transporter. Uridine and dipyridamole inhibited only the sodium-dependent uptake. Other analogs of adenosine showed no inhibition. The kinetic parameters of the inhibitors of the sodium-dependent component were further investigated. Inosine was the most potent inhibitor with a Ki (1.9 microM) less than the Km of adenosine. This suggests a physiological role for the BBM ecto-adenosine deaminase (enzyme which extracellularly converts adenosine to inosine), balancing the amount of nucleoside taken up as adenosine or inosine by the renal proximal tubule cell.
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PMID:Further characterization of adenosine transport in renal brush-border membranes. 235 78


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