Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.23.15 (renin)
 35,795 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Experiments were performed on three groups of rats. The first group consisted of sodium loaded (SL) rats (high sodium diet, 10 meq Na/day, the second group consisted of sodium restricted (SR) rats (low sodium diet, 0.7 meq Na/day) and the third group consisted of hemorrhagic rats (HR), which were bled with 1-1,5% of the body weight. Blood pressure, glomerular filtration rate (GFR) and sodium excretion were measured. In some animals renal blood flow (RBF) was recorded with an electromagnetic flow meter. Adenosine was injected or infused into the thoracic aorta. Bolus injection of 10 nmoles adenosine resulted in a rapid and marked decrease of RBF (40%) in SR rats whereas in SL rats only a very small decrease of RBF (2%) was observed. Continuous infusion of adenosine (10(-7) moles/min) decreased GFR by 54% in SR rats and by 33% in HR rats, whereas GFR in SL rats did not change significantly. 5'-AMP decreased GFR in SR rats by 18% and in HR rats by 32%. Adenosine and 5'-AMP caused a slight fall in the systemic blood pressure, but this decrease could not account for the decrease of GFR. The sensitivity of kidney vasculature to adenosine parallelled high plasma renin activity (162 ng ang/ml-h in SR and 76 ng ang/ml-h in HR), elevated renal vascular resistance and low GFR. Simultaneous infusion of angiotensin (Hypertensin), 250 ng/min, in SL rats resulted in an increase of sensivity to adenosine infusion: GFR decreased by 21%. Our experiments demonstrated that a marked renal vasoconstriction caused by adenosine only occurs in rats in which renin-angiotensin system was stimulated.
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PMID:Adenosine response of the rat kidney after saline loading, sodium restriction and hemorrhagia. 123 94

Administration of adenosine results in profound hypotension without the expected activation of reflex sympathetic and renin mechanisms in most animal models. This action can be explained by the vasodilatory and neuroinhibitory effects of adenosine. It is generally considered an inhibitory neuromodulator because it inhibits the release of virtually all neurotransmitters studied and produces hyperpolarization of neurons. In contrast, adenosine produces vasoconstriction of some vascular beds, including the renal and pulmonary circulations. Renal vasoconstriction is caused by activation of A1 receptors and involves an interaction with angiotensin II. In other vascular beds adenosine releases eicosanoids, including thromboxane, also resulting in vasoconstriction. Adenosine-induced vasoconstriction is transient and species dependent. Neither the receptor type, the molecular mechanisms of these actions, nor their significance to pathophysiological processes have been defined. Adenosine also has an apparent excitatory effect in the nucleus tractus solitarii. Microinjections of adenosine into this brain stem nucleus lead to decreased sympathetic tone and hypotension similar to those produced by the excitatory amino acid glutamate. The mechanism that explains this action has recently been explored and involves the release of glutamate by adenosine. Adenosine also stimulates afferent fibers mediating sympathetic activity, including renal and myocardial afferent nerves, and carotid and aortic chemoreceptors. Afferent nerve activation seems to be more pronounced in humans and may explain most of the cardiovascular and respiratory actions of adenosine in this species. Finally, animal studies suggest that endogenous adenosine plays a role in the regulation of the baroreceptor reflex and restrains the full expression of renin-dependent hypertension.
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PMID:Contrasting excitatory and inhibitory effects of adenosine in blood pressure regulation. 139 81

Adenosine is an important modulator of renal function. Adenosine produced and released within the kidney is thought to participate in the metabolic regulation of glomerular filtration (tubuloglomerular feedback), as well as in regulating renal excretory function and renin secretion. The recent cloning of cDNAs encoding the A1 and A2a adenosine receptors from rat brain allows direct examination of potential sites of adenosine action within the rat kidney. Northern blot analysis of rat kidney poly(A)+ RNA revealed that A1 adenosine receptor mRNA was more abundant in kidney than the A2a adenosine receptor transcript. In situ hybridization with 35S-labeled cRNA probes was used to localize A1 and A2a adenosine receptor mRNAs within the kidney. A1 adenosine receptor mRNA was most abundant in the collecting ducts of the papilla and inner medulla. Collecting ducts in the outermost portion of the inner stripe of the outer medulla and cells of the juxtaglomerular apparatus also expressed A1 adenosine receptor mRNA. A2a adenosine receptor mRNA was localized to the renal papilla. The distribution of A1 and A2a adenosine receptor mRNAs within the rat kidney supports previously postulated roles for adenosine in the regulation of renal hemodynamics, excretory function, and renin secretion.
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PMID:Adenosine receptor gene expression in rat kidney. 148 90

In vitro data indicate that the activation of A2 adenosine receptors increases renin release by the accumulation of cyclic AMP. Because in human forearm vessels beta-adrenergic receptor stimulation causes the local release of renin and angiotensin II through the increase of cyclic AMP, we evaluated in six essential hypertensive subjects whether adenosine can release vascular angiotensin II. Adenosine was infused into the brachial artery at cumulatively increasing doses (0.5, 1.5, and 5 micrograms/100 ml forearm tissue per minute for 5 minutes each) during saline infusion and in the presence of the adenosine antagonist theophylline (100 micrograms/100 ml forearm tissue per minute for 15 minutes), while venous (ipsilateral deep forearm vein) and arterial (brachial artery) angiotensin II (picograms per milliliter) were measured at the end of each infusion period, and forearm angiotensin II net balance (picograms per minute) was calculated by venous-arterial differences corrected for forearm blood flow (strain-gauge venous plethysmography) and hematocrit. In control conditions, adenosine, at higher doses, caused a dose-dependent vasodilation and increased venous angiotensin II without affecting arterial values; therefore, the calculated angiotensin II net balance showed an adenosine-mediated dose-dependent release. Theophylline pretreatment blunted adenosine-mediated forearm blood flow increments and angiotensin II release. The local origin of angiotensin II was further confirmed in another group of six hypertensive subjects in whom the angiotensin converting enzyme inhibitor captopril, locally infused at the rate of 2.5 micrograms/100 ml forearm tissue per minute for 15 minutes, abolished the adenosine-mediated venous angiotensin II increments. Our data indicate that exogenous adenosine can stimulate the production of angiotensin II in the forearm vessels of hypertensive patients.
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PMID:Adenosine activates a vascular renin-angiotensin system in hypertensive subjects. 159 66

Adenosine exerts numerous effects in the central and autonomic nervous systems, most of which seem to be receptor mediated. Several studies have revealed two distinct receptors, based upon effects of adenosine on adenylate cyclase activity, designed A1 or A2 according to whether the cyclase is inhibited or activated. However, since not all adenosine receptors are linked to adenylate cyclase some authors base their classification on the rank orders of potencies of adenosine analogues in eliciting responses. The purine seems to function as a modulatory substance in the heart, blood, ileum, vas deferens, and adipose tissue. In addition, important responses to exogenously added adenosine are also induced in the bronchi, urinary bladder, taenia coli, parietal cells of the stomach and renin secretion. Adenosine and its analogues elicit anticonvulsant responses, sedation and hypothermia through their actions in the central nervous system. The mechanisms by which adenosine elicits its responses have not been clearly established. The activation of A1 receptors depresses the release of neurotransmitters and inhibit the influx of Ca into nerve terminals. Whether this effect is induced by interaction with Ca channels or by impairment of Ca dependent processes associated with neurotransmitter release is unknown. In the rat heart adenosine inhibits adenylate cyclase and subsequently the phosphorylation of L-type Ca channels, resulting in a decrease of calcium influx in the muscle cell. The responses to activation of A2 receptors in smooth muscle consist in relaxation presumptively by an increase of K current which would hyperpolarize the cell.
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PMID:[Adenosine: physiological and pharmacological actions]. 215 91

Adenosine has been proposed to act within the juxtaglomerular apparatus (JGA) as a mediator of the inhibition of renin secretion produced by a high NaCl concentration at the macula densa. To test this hypothesis, we studied the effects of the adenosine1 (A1)-receptor blocker 8-cyclopentyl-1,3-dipropylxanthine (CPX) on renin release from single isolated rabbit JGAs with macula densa perfused. The A1-receptor agonist, N6-cyclohexyladenosine (CHA), applied in the bathing solution at 10(-7) M, was found to inhibit renin secretion, an effect that was completely blocked by adding CPX (10(-5) M) to the bath. Applied to the lumen, 10(-5) M CPX produced a modest stimulation of renin secretion rates suppressed by a high NaCl concentration at the macula densa (P less than 0.05). The effect of changing luminal NaCl concentration on renin secretion rate was examined in the presence of CPX (10(-7) and 10(-5) M) in the bathing solution and in vehicle control experiments. The control response to increasing luminal NaCl concentration was a marked suppression of renin secretion, that was maintained as long as luminal NaCl concentration was high and was promptly reversible when concentration was lowered. CPX did not alter renin release when luminal NaCl was low, but diminished the reduction caused by high NaCl (P less than 0.01). It is concluded that A1-receptors are located within the JGA, and that A1-receptor activation inhibits renin release. A high NaCl concentration at the macula densa appears to influence A1-receptor activation, but a low NaCl concentration does not. The findings support participation of adenosine in macula densa control of renin secretion.
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PMID:Effect of adenosine1-receptor blockade on renin release from rabbit isolated perfused juxtaglomerular apparatus. 218 76

Adenosine, a potent vasodilator both in animals and in humans, has been used to produce controlled hypotension in patients, especially during cerebral aneurysm surgery. However, in animals adenosine by intrarenal infusion decreases renal blood flow (RBF), glomerular filtration rate (GFR), urine flow, and causes an inhibition of renin secretion. In this study we evaluated the effect of adenosine on RBF in patients (n = 15) scheduled for cerebral aneurysm surgery who had been anesthetized with a modified neurolept-anesthesia during controlled hyperventilation. Perioperative hypotension was achieved with infusion of adenosine (252.8 +/- 55.8 micrograms.kg-1.min-1) (n = 8) or sodium nitroprusside (2.5 +/- 0.8 micrograms.kg-1.min-1) (n = 7). Mean arterial pressure was lowered by 25%-30%, to approximately 60-70 mm Hg, in both groups. Glomerular filtration rate and RBF were measured using standard renal clearance methods for 51Cr-ethylenediaminetetraacetic acid and paraaminohippuric acid. Urine and blood samples were collected during normotension before and after a bolus dose of hypertonic mannitol, during hypotension, and during normotension after clipping of the aneurysm. Adenosine induced a marked decrease in GFR (-91%) and RBF (-92%), and a pronounced increase in renal vascular resistance. Sodium nitroprusside caused a significantly (P less than 0.01) less pronounced decrease in GFR (-24%) and RBF (-36%), but did not affect renal vascular resistance. After discontinuation of the hypotensive agents, GFR returned to baseline levels in both groups. Renal blood flow, however, increased above baseline after discontinuation of adenosine (+93%) but not after sodium nitroprusside. Sodium nitroprusside increased renin secretion, which was not seen with adenosine. Four patients in the adenosine group developed reversible atrioventricular conduction disturbances.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Controlled hypotension with adenosine or sodium nitroprusside during cerebral aneurysm surgery: effects on renal hemodynamics, excretory function, and renin release. 224 Jun 36

A randomized, double-blind and placebo-controlled study was performed in 10 normotensive male subjects to analyze a possible antagonism between caffeine and adenosine with respect to their effects on the cardiovascular system in humans. Caffeine alone, 250 mg intravenously (i.v.), increased blood pressure by 9/12 mm Hg, and resulted in a fall of heart rate (HR) of 3 beats/min. Plasma epinephrine (E) rose by 114% after caffeine. Adenosine alone, in an increasing dose of 0.04-0.16 mg/kg/min, induced an increase in systolic blood pressure (SBP) (17 mm Hg), and HR (33 beats/min), a moderate fall in diastolic blood pressure (DBP) (-4 mm Hg), and no change of mean arterial pressure (MAP). At the highest adenosine infusion rate, forearm blood flow, skin temperature (ST), and transcutaneous oxygen tension were lowered, whereas plasma (nor)epinephrine was increased 227.2 and 215.9%, respectively. Adenosine infusion after caffeine induced comparable effects, but the fractional adenosine-induced changes of SBP, HR, plasma catecholamines, plasma renin activity (PRA), and aldosterone all were significantly reduced by previous administration of caffeine. Our results indicate an antagonism between caffeine and adenosine in humans, which may support the suggestion that some circulatory effects of caffeine are caused by an interaction with endogenous adenosine.
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PMID:Evidence for an antagonism between caffeine and adenosine in the human cardiovascular system. 244 Nov 63

The possibility of a coexistence of coronary arteriolar constriction mediated by the renin-angiotensin system and myocardial ischemia was evaluated. Left anterior descending coronary artery was cannulated and perfused at normal (mean aortic), intermediate (50 mm Hg), and low (30-40 mm Hg) pressure in analogy to a progressive coronary stenosis. Lactate production was present at low coronary pressure indicating myocardial ischemia. In control animals (n = 18), mean coronary conductance was higher (p less than 0.005) at intermediate than at high coronary pressure consistent with autoregulation at coronary flow. Coronary conductance was lower (p less than 0.05) at low than at intermediate coronary pressure, indicating coronary constriction during myocardial ischemia. Adenosine (20 micrograms/kg per min i.c., n = 6) resulted in higher coronary conductance, suggesting coronary vasodilator reserve even at low coronary pressure. Indomethacin (5 mg/kg i.v., n = 12) resulted in low coronary conductance; however, the increase at intermediate (autoregulation) and the decrease (constriction) at low pressure was maintained. Plasma renin activity increased, and saralasin (0.1 microgram/kg per min i.c.) and captopril (0.25 mg/kg i.v.) acted as coronary vasodilators in various models of myocardial ischemia. Captopril limited myocardial infarct size at 6 hours of coronary occlusion, diminished flow repayment and prevented lactate production after 30 s of coronary occlusion, and abolished the deterioration of myocardial function during myocardial ischemia induced by coronary hypoperfusion and atrial pacing. Thus, myocardial ischemia does not generally represent a state of maximal coronary dilatation. The renin-angiotensin system is activated by myocardial ischemia and may exert a coronary constrictive tone. Captopril was beneficial in experimental myocardial ischemia.
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PMID:Coronary vasoconstriction in experimental myocardial ischemia. 244 Dec 6

The hydrolysis of 5'-AMP by 5'-nucleotidase is the main source of adenosine. In various tissues adenosine is a local mediator adjusting the organ work to the available energy. In the kidney it regulates renal hemodynamics, glomerular filtration rate and renin release via specific receptors of the arteriolar walls. By immunocytochemistry we identified interstitial and tubular sites of 5'-nucleotidase in the rat kidney. In the interstitium the enzyme was detected only in the cortical labyrinth, the compartment that comprises all arteriolar vessels besides other putative targets of adenosine. The 5'-nucleotidase-positive cells of the interstitium were identified as fibroblasts. The fibroblasts are in close contact with the tubules as well as with the vessels. Thus, any 5'-AMP released by the tubules into the interstitial space would be converted to adenosine in the direct vicinity of its assumed targets. Adenosine produced by tubular cells would hardly have access to its known targets, since 5'-nucleotidase is restricted to the luminal cell surface. Pathological events affecting the fibroblasts might influence renal function by modifying the interstitial adenosine production.
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PMID:Distribution of 5'-nucleotidase in the renal interstitium of the rat. 255 62


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