Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:4.6.1.1 (adenylate cyclase)
 19,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The present study was designed to examine the interrelationship between the intrarenal vascular receptor and the sympathetic nerve, beta-adrenergic system, for renin secretion in the anesthetized dog. 1) A reduction in renal arterial pressure from a control pressure to 100 mmHg changed neither ther flow rates of all cortex zones nor renin secretion. Further reduction of renal arterial pressure to 75 mmHg resulted in a significant increase of renin secretion and a decrease of blood flow in the outer cortex. Intrarenal arterial infusion of norepinephrine at a control pressure increased a renin secretion. However, norepinephrine infusion at a reduced pressure suppressed the renin release with a recovery of the vascular resistance to the control level. These results suggest that the changes in the degree of blood flow and pressure in the renal afferent arterioles are not essential for the renin secretion,but renin secretion by the pressure reduction might be related to the autoregulatory capacity of afferent arterioles in the outer cortex. 2) At 5 min of hemorrhagic period (75 mmHg) arterial PRA elevated in control, and phenoxybenzamine and propranolol treated groups and any significant difference in responses was not observed among groups. However, at 60 min of hemorrhagic hypotensive period PRA in control and phenoxybenzamine treated groups further increased, but PRA in propranolol treated group was not alter from its 15 min value. These results indicated that the roles of vascular receptor and renal sympathetic nervous sytem in receptor and renal sympathetic nervous system in renin secretion might be separated, and that the renal sympathetic nervous system did not relate to the early response of renin release, but related to the late response. 3) Intrarenal arterial infusion of cAMP and DbcAMP resulted in a significant increase of renin release. In addition, CaC12 solution was infuesed into the renal artery and a significant rise in renal venous PRA was observed within 5 min of infusion. These data suggested that a beta-adrenergic receptor-adenyl cyclase-cAMP system was involved in the control of renin secretion, and that since the intracellular effect of cAMP was partly related to the change of intracellular Ca distribution, its change resulted in an increase in renin secretion.
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PMID:Control of renin secretion. 19 22

The effect of intravenous infusion of low-dose dopamine on electrolyte excretion, lithium clearance, nephrogenous cAMP formation and renal haemodynamics was investigated in healthy volunteers. Dopamine significantly increased the urine flow rate by 70.6% and urinary sodium excretion by 72%, but did not change creatinine clearance, PRA or plasma levels of AVP, ANP and cAMP. Renal plasma flow significantly increased by 48.6%; the glomerular filtration rate was not changed. Lithium per se increased basal PRA, but had no effect on the increments of urine flow rate, sodium excretion and renal blood flow induced by dopamine. Dopamine significantly increased the fractional excretion of lithium (representing fractional excretion of sodium at the proximal level). The increase in urinary sodium excretion during dopamine infusion, significantly correlated with the increase in fractional excretion of lithium (r = 0.94; P less than 0.01) and the increase in nephrogenous cAMP formation (r = 0.96; P less than 0.01). No correlation was found between the increase in urinary sodium excretion and the increase in renal blood flow. In conclusion, this study confirms that low-dose dopamine increases renal blood flow and urinary sodium excretion in healthy volunteers. This natriuretic response appears to be due to interaction with proximal tubular dopamine receptors, which are positively coupled to adenylate cyclase.
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PMID:Further studies on the mechanism of the natriuretic response to low-dose dopamine in man: effect on lithium clearance and nephrogenic cAMP formation. 217 43

Dopamine receptors are classified to DA-1 and DA-2 and are characterized in renal tissue by radioligand binding and by the response of renal adenylate cyclase to dopaminergic agonists and antagonists. DA-1 receptors are localized in the renal tubules, the medial layer of renal microvessels, and the juxtaglomerular apparatus. DA-1 receptor stimulation causes dilation of renal, mesenteric, coronary, and cerebral vessels. In the present study, we tested the hypothesis that dopamine is a paracrine substance in the control of renal function. We employed a potent specific DA-1 receptor antagonist, SCH, to evaluate the role of intrarenal DA-1 receptor in the maintenance of renal function. Intrarenal DA-1 receptor blockade with SCH caused a highly significant dose-dependent antidiuresis and antinatriuresis, and decreased FENa. A rebound diuresis and natriuresis above control values were observed after cessation of DA-1 receptor blockade. There were no changes in renal hemodynamic function during DA-1 receptor blockade. These results strongly suggest that the antinatriuresis and antidiuresis induced by DA-1 receptor blockade are mediated by an action at the renal tubule. The infusion rate of SCH administered intrarenally was sufficiently low to produce no measurable systemic effects including PRA, PAC, and MAP. Thus, these results can be interpreted as due to intrarenal DA-1 blockade. In summary, we have demonstrated that renal excretory function is highly sensitive to DA-1 receptor blockade within the kidney and appears to be mediated by renal tubular events. This study provides strong evidence that DA-1 receptors play a physiological role in the control of renal function.
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PMID:Intrarenal dopamine-1 receptors control renal function. 297 36