BIOMAT Database Logo BIOMAT Database Logo

Involvement of renal alpha- and beta-adrenoceptors in release of renin by carotid baroreflex. 1979

D A Powis, and D E Donald

In anesthetized vagotomized dogs with renal arterial pressure constant, carotid sinus hypotension (BCO) caused a reflex rise in systemic arterial pressure, a fall in renal blood flow, and a similar increase in renin release from both kidneys. Unilateral alpha-adrenoceptor blockade with phenoxybenzamine resulted in an increase in basal renal blood flow, a depression of basal renin release, and an abolition of the responses to BCO in the treated kidney. The untreated kidney responsed to BCO as before. Nonblocked and alpha-blocked kidneys released similar amounts of renin when renal blood flow was mechanically reduced by aortic constriction. Administration of propranolol to the nonblocked kidney prevented the release of renin but not the hemodynamic changes resulting from BCO. The experiments demonstrated that under certain conditions carotid sinus hypotension produced alpha-adrenoceptor-mediated changes in the kidney sufficient to cause increased renin release. A step in the renin release mechanism subsequent to the alpha-adrenoceptor-mediated changes in sensitive to propranolol.

UI MeSH Term Description Entries
D007668 Kidney Body organ that filters blood for the secretion of URINE and that regulates ion concentrations. Kidneys
D010643 Phenoxybenzamine An alpha-adrenergic antagonist with long duration of action. It has been used to treat hypertension and as a peripheral vasodilator. Dibenylene,Dibenyline,Dibenziran,Dibenzylin,Dibenzyline,Dibenzyran,Phenoxybenzamine Hydrochloride,Hydrochloride, Phenoxybenzamine
D011311 Pressoreceptors Receptors in the vascular system, particularly the aorta and carotid sinus, which are sensitive to stretch of the vessel walls. Baroreceptors,Receptors, Stretch, Arterial,Receptors, Stretch, Vascular,Stretch Receptors, Arterial,Stretch Receptors, Vascular,Arterial Stretch Receptor,Arterial Stretch Receptors,Baroreceptor,Pressoreceptor,Receptor, Arterial Stretch,Receptor, Vascular Stretch,Receptors, Arterial Stretch,Receptors, Vascular Stretch,Stretch Receptor, Arterial,Stretch Receptor, Vascular,Vascular Stretch Receptor,Vascular Stretch Receptors
D011433 Propranolol A widely used non-cardioselective beta-adrenergic antagonist. Propranolol has been used for MYOCARDIAL INFARCTION; ARRHYTHMIA; ANGINA PECTORIS; HYPERTENSION; HYPERTHYROIDISM; MIGRAINE; PHEOCHROMOCYTOMA; and ANXIETY but adverse effects instigate replacement by newer drugs. Dexpropranolol,AY-20694,Anaprilin,Anapriline,Avlocardyl,Betadren,Dociton,Inderal,Obsidan,Obzidan,Propanolol,Propranolol Hydrochloride,Rexigen,AY 20694,AY20694,Hydrochloride, Propranolol
D011941 Receptors, Adrenergic Cell-surface proteins that bind epinephrine and/or norepinephrine with high affinity and trigger intracellular changes. The two major classes of adrenergic receptors, alpha and beta, were originally discriminated based on their cellular actions but now are distinguished by their relative affinity for characteristic synthetic ligands. Adrenergic receptors may also be classified according to the subtypes of G-proteins with which they bind; this scheme does not respect the alpha-beta distinction. Adrenergic Receptors,Adrenoceptor,Adrenoceptors,Norepinephrine Receptor,Receptors, Epinephrine,Receptors, Norepinephrine,Adrenergic Receptor,Epinephrine Receptors,Norepinephrine Receptors,Receptor, Adrenergic,Receptor, Norepinephrine
D011942 Receptors, Adrenergic, alpha One of the two major pharmacological subdivisions of adrenergic receptors that were originally defined by the relative potencies of various adrenergic compounds. The alpha receptors were initially described as excitatory receptors that post-junctionally stimulate SMOOTH MUSCLE contraction. However, further analysis has revealed a more complex picture involving several alpha receptor subtypes and their involvement in feedback regulation. Adrenergic alpha-Receptor,Adrenergic alpha-Receptors,Receptors, alpha-Adrenergic,alpha-Adrenergic Receptor,alpha-Adrenergic Receptors,Receptor, Adrenergic, alpha,Adrenergic alpha Receptor,Adrenergic alpha Receptors,Receptor, alpha-Adrenergic,Receptors, alpha Adrenergic,alpha Adrenergic Receptor,alpha Adrenergic Receptors,alpha-Receptor, Adrenergic,alpha-Receptors, Adrenergic
D011943 Receptors, Adrenergic, beta One of two major pharmacologically defined classes of adrenergic receptors. The beta adrenergic receptors play an important role in regulating CARDIAC MUSCLE contraction, SMOOTH MUSCLE relaxation, and GLYCOGENOLYSIS. Adrenergic beta-Receptor,Adrenergic beta-Receptors,Receptors, beta-Adrenergic,beta Adrenergic Receptor,beta-Adrenergic Receptor,beta-Adrenergic Receptors,Receptor, Adrenergic, beta,Adrenergic Receptor, beta,Adrenergic beta Receptor,Adrenergic beta Receptors,Receptor, beta Adrenergic,Receptor, beta-Adrenergic,Receptors, beta Adrenergic,beta Adrenergic Receptors,beta-Receptor, Adrenergic,beta-Receptors, Adrenergic
D012018 Reflex An involuntary movement or exercise of function in a part, excited in response to a stimulus applied to the periphery and transmitted to the brain or spinal cord.
D012039 Regional Blood Flow The flow of BLOOD through or around an organ or region of the body. Blood Flow, Regional,Blood Flows, Regional,Flow, Regional Blood,Flows, Regional Blood,Regional Blood Flows
D012083 Renin A highly specific (Leu-Leu) endopeptidase that generates ANGIOTENSIN I from its precursor ANGIOTENSINOGEN, leading to a cascade of reactions which elevate BLOOD PRESSURE and increase sodium retention by the kidney in the RENIN-ANGIOTENSIN SYSTEM. The enzyme was formerly listed as EC 3.4.99.19. Angiotensin-Forming Enzyme,Angiotensinogenase,Big Renin,Cryorenin,Inactive Renin,Pre-Prorenin,Preprorenin,Prorenin,Angiotensin Forming Enzyme,Pre Prorenin,Renin, Big,Renin, Inactive

Related Publications

D A Powis, and D E Donald
Interaction of renal beta 1-adrenoceptors and prostaglandins in reflex renin release.
April 1983, The American journal of physiology,
D A Powis, and D E Donald
[Is renal renin release mediated through beta 1- or beta 2-adrenoceptors?].
October 1988, Nihon Jinzo Gakkai shi,
D A Powis, and D E Donald
Release of renin by the carotid baroreflex in anesthetized dogs. Role of cardiopulmonary vagal afferents and renal arterial pressure.
May 1978, Circulation research,
D A Powis, and D E Donald
Role of renal alpha-adrenoceptors mediating renin secretion.
June 1982, The American journal of physiology,
D A Powis, and D E Donald
Analysis of beta-adrenoceptors mediating renin release produced by isoproterenol in conscious dogs.
May 1980, The American journal of physiology,
D A Powis, and D E Donald
Interaction between perfusion pressure and sympathetic nerves in renin release by carotid baroreflex in conscious dogs.
January 1981, The Journal of physiology,
D A Powis, and D E Donald
Resetting of pressure-dependent renin release by intrarenal alpha 1-adrenoceptors in conscious dogs.
January 1989, Pflugers Archiv : European journal of physiology,
D A Powis, and D E Donald
Evidence for prostaglandin-independent mechanisms in renin release mediated by alpha adrenoceptors during renal nerve stimulation in anesthetized dogs.
May 1984, The Journal of pharmacology and experimental therapeutics,
D A Powis, and D E Donald
Effects of blockades of alpha and beta adrenoceptors and dopamine receptors on renal nerve stimulation-induced prostaglandin E2 and renin release in anesthetized dogs.
November 1985, The Journal of pharmacology and experimental therapeutics,
D A Powis, and D E Donald
Carotid sinus baroreflex control of beta-endorphin release in anesthetized dogs.
February 1989, The American journal of physiology,
Copied contents to your clipboard!