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)

This study was designed to test the hypothesis that endogenous adenosine participates in the global coronary functional hyperemia accompanying intracoronary infusions of norepinephrine (NE) and isoproterenol (ISO). Intracoronary adenosine deaminase (ADA) was employed to test the hypothesis in isolated, perfused guinea pig hearts. We measured coronary perfusate flow (CPF) at a constant coronary perfusion pressure. Heart rate (HR), left ventricular pressure, and its rate of development were also measured. Global myocardial oxygen consumption (MVO2) and oxygen extraction were calculated, and blood gases and pH were measured routinely in inflow and outflow perfusate samples. In the absence of ADA, NE and ISO increased HR 67 +/- 6 and 106 +/- 11 beats.min-1, left ventricular pressure development 519 +/- 46 and 375 +/- 35 mm Hg.s-1, MVO2 22 +/- 2 and 28 +/- 3 microliters.min-1.g-1, and CPF 1.6 +/- 0.2 and 2.2 +/- 0.2 ml.min-1.g-1, respectively. With constant infusion of ADA (4.5 U.min-1.g-1, a dose which produces no direct effects on cardiac function) for 4 min, similar increments in HR and left ventricular pressure development were achieved with both catecholamines. Corresponding changes in MVO2 (9 +/- 2 and 6 +/- 3 microliters.min-1.g-1) were significantly less than those seen in the absence of ADA. Moreover, CPF did not increase in response to NE and ISO in the presence of ADA. These findings support an important role for adenosine in catecholamine-induced global coronary functional hyperemia in isolated, perfused guinea pig hearts.
J Cardiovasc Pharmacol 1990 Jun
PMID:Role of adenosine in catecholamine-induced global coronary functional hyperemia in isolated guinea pig hearts. 169 17

Inosine applied as a continuous i.v. infusion of 400 mg/kg/h for 20 min had a negative chronotropic and inotropic effect in closed-chest, anesthetized rats. In the presence of adenosine deaminase (ADA, 133 U/kg/h), the reduction in heart rate was abolished indicating that adenosine is responsible for that effect. However, the negative inotropic effect persisted. It was characterized by a 38 and 56% decrease in left ventricular systolic pressure (LVSP) and diastolic aortic pressure, respectively, a 24% decline in LV dp/dtmax and a 16% fall in cardiac output. Total peripheral resistance was diminished by 38%. Inosine in combination with ADA antagonized the noradrenaline-induced positive inotropic effect and the increase in cardiac output. On the other hand, i.v. bolus injection of noradrenaline in rats pretreated with inosine and ADA did not increase blood pressure and total peripheral resistance. Inosine administered in animals pretreated with the beta-receptor blocker metoprolol or with the calcium antagonist verapamil aggravated the negative inotropic effect. Inosine in combination with ADA caused a decline in cardiac output in metoprolol-pretreated rats that was more pronounced than that induced by inosine alone. However, in rats pretreated with verapamil, inosine did not cause a reduction in cardiac output.
J Cardiovasc Pharmacol 1990 Aug
PMID:Hemodynamic effects of inosine in combination with positive and negative inotropic drugs: studies on rats in vivo. 169 81

In spontaneously beating atria from reserpine-treated guinea pigs, milrinone (1-100 micrograms/ml) induced a positive inotropic and chronotropic effect but was ineffective in preparations preincubated with adenosine deaminase (1 U/ml). Both in spontaneously beating and in electrically driven atria, ATP and adenosine evoked a dual effect: a first negative phase characterized by a reduction in contractile force, followed by a positive phase of increased inotropism. In these preparations milrinone inhibited the early negative influence exerted by purine compounds and amplified the following positive phase. These data suggest that the positive inotropic and chronotropic effect of milrinone may originate from its interference with endogenous purines.
Cardiovasc Drugs Ther 1990 Apr
PMID:Involvement of purine compounds in the inotropic action of milrinone. 228 34

The objective of this study was to determine if augmentation of myocardial adenosine levels during global ischemia improves functional recovery after reperfusion. Isolated adult rabbit hearts were subjected to 120 minutes of mildly hypothermic ischemia (34 degrees C) with modified St. Thomas' Hospital cardioplegic solution used to provide myocardial protection. Myocardial adenosine levels were augmented during ischemia by providing exogenous adenosine in the cardioplegic solution or by inhibiting adenosine degradation with 2-deoxycoformycin, a noncompetitive inhibitor of adenosine deaminase. Four groups of hearts were studied: (1) control (n = 23)--cardioplegia alone; (2) adenosine group (n = 10)--adenosine 200 mumol/L added to the cardioplegic solution; (3) 2-deoxycoformycin group (n = 8)--2-deoxycoformycin 1 mumol/L added to the cardioplegic solution; and (4) a combined adenosine/deoxycoformycin group (n = 10). Recovery of developed pressure 45 minutes after reperfusion in the control group averaged only 38% +/- 4% of baseline values. Significantly better recovery was evident in the adenosine (66% +/- 7%), deoxycoformycin (59% +/- 2%), and adenosine/deoxycoformycin (75% +/- 2%) groups. The slope of the relationship between end-diastolic pressure and volume was used as an index of diastolic stiffness. The slope averaged 85 +/- 2 mm Hg/ml in the control group 45 minutes after reperfusion, significantly higher than that in the adenosine (31 +/- 6), deoxycoformycin (75 +/- 5), and adenosine/deoxycoformycin (58 +/- 5) groups; this suggests better diastolic function in the adenosine-augmented groups. During ischemia, adenosine levels were significantly elevated in the adenosine-augmented groups, whereas adenosine triphosphate decreased equally in all four groups, which indicates that augmenting myocardial adenosine had no effect on depletion of adenosine triphosphate during ischemia. After reperfusion, adenosine triphosphate levels were depressed in the control group but increased in the other groups above baseline values, which suggests that improvement in functional recovery was due to accelerated repletion of adenine nucleotide stores in the adenosine-augmented groups.
J Thorac Cardiovasc Surg 1990 Mar
PMID:Augmenting intracellular adenosine improves myocardial recovery. 230 64

Adenosine is known to induce rapid cardioplegic arrest and to improve postischemic recovery in the isolated rat heart. Long exposures to high doses of adenosine impair postischemic recovery, however. In this paper we tested the combination of low-dose adenosine (1 mmol/L) with potassium (26 mmol/L), with the aim of achieving rapid arrest (as with high-dose adenosine) but eliminating the need for postarrest washout of adenosine. Cardioplegic solutions studied were (1) Krebs-Henseleit potassium (26 mmol/L) (K); (2) K plus adenosine (1 mmol/L) (KA); (3) K plus an adenosine deaminase inhibitor [erythro-9-(2-hydroxy-3-nonyl)adenine] (0.1 mmol/L) (KE); and as control (4) Krebs-Henseleit potassium (6 mmol/L) (C). We induced cardiac arrest in Langendorff-perfused rat hearts by infusing the cardioplegic solution for 3 minutes at 3 ml/min. Total ischemia lasted 20 minutes at 37 degrees C, followed by reperfusion for 30 minutes. High potassium decreased the arrest time from 260 +/- 16 seconds (group C, mean values +/- standard error of the mean) to 22 +/- 4 seconds (group K). A further decrease to 10 +/- 2 seconds was observed with KA (p = 0.016 versus K). KE, which increased endogenous adenosine, gave intermediate effects. All hearts recovered during reperfusion; the product of developed tension and heart rate (grams per minute) was superior in KA hearts (6250 +/- 740 versus K hearts 4380 +/- 390; p = 0.050). KE gave an intermediate result (5290 +/- 900), while C showed the worst recovery (3180 +/- 830). Our electrophysiologic studies with sinus node and atrial tissue suggest that adenosine induced hyperpolarization and an increase in potassium permeability, thereby arresting the sinus node before depolarization of the membrane by potassium (26 mmol/L). We conclude that low-dose adenosine as an adjunct to potassium shortens the arrest time in this model and improves postischemic recovery.
J Thorac Cardiovasc Surg 1990 Sep
PMID:Adenosine as adjunct to potassium cardioplegia: effect on function, energy metabolism, and electrophysiology. 239 80

Intravenous injection of mioflazine, a nucleoside transport antagonist, caused maximal coronary vasodilation in canine hearts. This was completely reversed by intravenous injection of the enzyme adenosine deaminase. Coronary vasodilation was induced again by the adenosine deaminase inhibitor EHNA [Erythro-9(2-hydroxy-3-nonyl)adenine]; however, without previous injection of mioflazine, EHNA did not produce coronary vasodilation. Mioflazine-induced coronary vasodilation was antagonized by theophylline, but it was not associated with increased plasma levels of adenosine. Under the influence of mioflazine, ischemic myocardium contained adenosine and inosine at a ratio of 65:30, which is the reverse of the control ratio. Total nucleoside content following mioflazine showed reduced nucleoside losses as compared with control. A significant amount of the accumulated adenosine is extracellular since it was accessible to exogenous adenosine deaminase. Reperfusion of ischemic myocardium did not result in increased rates of adenosine phosphorylation, another indicator of its extracellular accumulation. The data are best explained by assuming release of adenosine by mioflazine in addition to its known effect of inhibiting nucleoside transport. The adenosine release occurs most probably into the interstitial space where it occupies smooth muscle adenosine receptors. The existence of nonsymmetric transport (uptake is more inhibited than release) is postulated for the myocyte, as well as for the endothelial cell plasma membrane.
J Cardiovasc Pharmacol 1987 Aug
PMID:Influence of mioflazine on canine coronary blood flow and on adenine nucleotide and nucleoside content under normal and ischemic conditions. 244 Nov 73

To test the hypothesis that adenosine contributes to the coronary hyperaemia produced by regional non-ischaemic myocardial hypoxia coronary blood flow and myocardial oxygen extraction and consumption were continuously monitored in 21 anaesthetised open chest dogs under the following conditions: control 1--postinstrumentation, steady state control; hypoxia 1--3-5 min of regional (LAD) hypoxaemia (partial pressure of oxygen, PO2, 21.4(2.0) mmHg (3.1(0.2) kPa), coronary arterial oxygen content, CaO2, 3.9(0.4) ml.100 ml-1 (39(4) ml.litre-1): control 2--repeat steady state control; and hypoxia 2--3-5 min repeat regional hypoxaemia (PO2 18.9(2.4) mmHg (2.5(0.3) kPa); CaO2 3.6(0.6) ml.100 ml-1 (36(6) ml.litre-1) blood). Left anterior descending artery perfusion pressure was held constant for all conditions. Control 2 and hypoxia 2 were performed in the presence of locally infused adenosine deaminase (n = 16) or saline vehicle (n = 5). The 16 dogs given adenosine deaminase were further subdivided into those perfused with blood deoxygenated by a donor canine lung (group 1, n = 11) and those perfused with blood from a paediatric oxygenator (group 2, n = 5). Systemic haemodynamics, heart rate, and coronary arterial PO2 and O2 contents were similar during the two control periods and during the two exposures to hypoxia in all three groups. Left anterior descending artery blood flow increased by approximately 400% (p less than 0.05) in all three groups during the first exposure to hypoxia. Myocardial oxygen consumption was unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)
Cardiovasc Res 1988 May
PMID:Adenosine deaminase attenuates canine coronary vasodilatation during regional non-ischaemic myocardial hypoxia. 319 18

Attempts to identify mechanisms by which calcium antagonists might influence intracellular metabolism have not yet yielded conclusive findings. In this study bepridil, verapamil, nifedipine, and nisoldipine were found to have no influence on the rate of rat heart myosin adenosine triphosphatase or the calcium dependence of myofibrillar adenosine triphosphatase. None of these calcium antagonists alters the rate of reaction of any of the adenine nucleotide catabolic or adenosine salvage enzymes, adenylate kinase, creatine kinase, adenosine kinase, adenosine deaminase, or 5' nucleotidase, in extracts of rat heart. All four compounds, however, reduced, apparently in a non-specific manner, the rate of uptake of adenosine by myocytes isolated from rat heart. It is concluded that calcium antagonists may, through intercalation with the sarcolemmal membrane, inhibit efflux of adenosine formed by catabolism of adenine nucleotides in ischaemic myocytes. This might offer therapeutic advantage since the intracellular concentration of adenosine would thereby be increased, allowing an increased rate of incorporation of adenosine into the adenosine triphosphate pool in reoxygenated myocardium.
Cardiovasc Res 1986 Aug
PMID:Calcium antagonists and adenine nucleotide metabolism in rat heart. 349 85

A study was designed to test the hypothesis that endogenous adenosine concentration may increase during episodes of rapid ventricular pacing and, by virtue of its negative chronotropic effects, contribute to the transient suppression of automaticity that follows the period of overdrive. Isolated, perfused, rat ventricular preparations were subjected to periods of 6.0 Hz overdrive stimulation while adenosine release, oxygen consumption, and subsequent suppression of automaticity were measured. At the end of a 1 min episode of overdrive oxygen consumption and adenosine release were significantly increased, and the initial beating rate after 1 min overdrive was suppressed. At the end of 10 min overdrive oxygen consumption was still increased but adenosine release had returned to control values. Suppression of automaticity after 10 min overdrive was similar to that after 1 min overdrive. The relative magnitude of suppression after 1 min overdrive was decreased by theophylline (10(-4) mol.litre-1), and increased by the adenosine deaminase inhibitor, EHNA (10(-5) mol.litre-1). Neither theophylline nor EHNA had any discernible influence on suppression after 10 min overdrive. It its therefore concluded that endogenous adenosine may contribute to the suppression of ventricular automaticity that follows a 1 min episode of overdrive, but because of the transient nature of the increase in adenosine during overdrive endogenous adenosine does not contribute to the suppression that follows prolonged overdrive.
Cardiovasc Res 1987 Jun
PMID:Transient increase in release of adenosine during rapid cardiac pacing; transient effects on overdrive suppression of ventricular automaticity. 365 5

To test the hypothesis that adenosine is required to mediate the coronary vasodilative response to acute hypoxia haemodynamic indices, regional myocardial blood flow, and oxygen and lactate metabolism were measured in nine closed chest anaesthetised domestic swine at control, after 3-5 min of 100% nitrogen inhalation, at second control, and after 3-5 min of 100% nitrogen inhalation plus adenosine deaminase infusion in the left anterior descending coronary artery. Cardiac lymph adenosine deaminase concentration was also measured in a separate group of four animals previously reported on. Heart rate was held constant by atrial pacing during the study. Aortic mean pressure did not change. Changes in arterial and anterior interventricular vein pH, PO2, PCO2, and oxygen content were similar for each intervention. Transmural left anterior descending artery zone flow increased significantly (p less than 0.01) compared with control (1.22(0.23) ml.min-1.g-1; mean(SD)) in response to hypoxia (2.73(0.92)). Intracoronary adenosine deaminase infusion (167 nmol.s-1), however, failed to blunt the flow response to hypoxia (1.33(0.30) to 2.79(1.32); second control to hypoxia plus adenosine deaminase respectively, p less than 0.01). Mean adenosine deaminase activity (nmol.s-1) in cardiac lymph was 105(85) at the end of 10 min of intracoronary infusion (167 nmol.s-1) and 203 (148) nmol.s-1 at the end of 15 min.(ABSTRACT TRUNCATED AT 250 WORDS)
Cardiovasc Res 1987 Feb
PMID:Role of adenosine in mediating the coronary vasodilative response to acute hypoxia. 366 45


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