Endothelial Metabolism of Angiotensin II to Angiotensin III, not Angiotensin (1–7), Augments the Vasorelaxation Response in Adrenal Cortical Arteries

Hyperaldosteronism is linked to the development and progression of several different cardiovascular diseases. Angiotensin (Ang) II increases aldosterone secretion and adrenal blood flow. Ang II peptide fragments are produced by various peptidases, and these Angs have diverse and vital physiologic roles. Due to the uncharacteristic vasorelaxation of adrenal arteries by Ang II, we tested the hypothesis that Ang II metabolism contributes to its relaxant activity in adrenal arteries. Metabolism of Angs by bovine adrenal cortical arteries and isolated bovine adrenal vascular cells was measured by liquid chromatography-mass spectrometry. The primary Ang metabolites of adrenal arteries are Ang III and Ang (1–7), with Ang IV produced to a lesser extent. Bovine microvascular endothelial cells produced a similar metabolic profile to adrenal arteries, whereas bovine adrenal artery smooth muscle cells exhibited less metabolism. In preconstricted adrenal arteries, Ang II caused relaxation in picomolar concentrations and constrictions at 10nM. Ang-converting enzyme 2 inhibition augmented this relaxation response, whereas aminopeptidase inhibition did not. Ang III was equipotent to Ang II in relaxing adrenal arteries. Ang IV did not cause relaxation. Nitric oxide synthase inhibition enhanced Ang II-induced constriction of adrenal arteries. Aminopeptidase inhibition increased the concentration range for Ang II-induced constriction of adrenal arteries. Ang III and Ang IV did not change the basal tone but caused constriction of adrenal arteries with nitric oxide synthase inhibition. These data indicate that Ang II metabolism modulates the vascular effects of Ang II in the adrenal vasculature.

Effect of acetylcholine infusion on adrenal vasculature and catecholamine secretion

To evaluate effects of cholinergic receptor stimulation on regional adrenal blood flow (Q, radiolabeled microspheres) and catecholamine secretion, acetylcholine (ACh) was infused into pentobarbital-anesthetized, ventilated dogs. Unilateral adrenal denervation and placement of lumboadrenal catheters preceded intra-aortic infusion of 1) ACh alone (n = 6), 2) ACh plus hexamethonium (Hex) 20 mg/kg (n = 6), or 3) ACh plus atropine (Atr) (0.5 mg/kg) and Hex. ACh alone and in combination with Hex elicited similar dose-related (2, 20, and 100 mumol/min) increases in catecholamine secretion (181 +/- 61 to 1,055 +/- 229, 31,644 +/- 9,411, and 179,181 +/- 69,659 ng.min-1 x g medulla-1), whereas Hex and Atr together inhibited ACh-induced secretion by 95%. ACh caused marked medullary vasodilation (0.71 +/- 0.05 to 0.14 +/- 0.03 mmHg.ml-1 x min.100 g) in all three groups. To determine whether medullary vasodilation was due to incomplete muscarinic blockade, Hex-pretreated animals (n = 4) received ACh (100 mumol/min) and three increasing doses of Atr (0.5, 5, and 25 mg/kg). Catecholamine secretion was inhibited by all doses of Atr; however, vasodilation was blocked only by the two higher doses of Atr. These data suggest possible different mechanisms of muscarinic receptor-mediated catecholamine secretion and vasodilation.

Effects of stimulation on steroid output and perfusion medium flow rate in the isolated perfused rat adrenal gland in situ

ABSTRACT Using the in-situ, isolated, perfused rat adrenal system, the actions of adrenal stimulants on steroidogenesis and perfusion medium flow rates (under constant perfusion pump conditions) have been studied. In a series of 100 experiments, initial rates of corticosterone output and flow rates were found to be positively correlated, although there was no such relationship between initial rates of aldosterone output and flow rates. Furthermore, in stable perfusion conditions, bolus injections of ACTH increased both flow rate and steroid output in a dose-related manner. In individual experiments there was a clear correlation between corticosterone and flow, but the association between aldosterone secretion rate and flow was less evident. It is possible that this discrepancy arises because of temporal differences in the responses of these two steroids. Flow was also stimulated by dibutyryl cyclic AMP (dbcAMP), with correlations with steroid output similar to ACTH, but the specific zona glomerulosa stimulants angiotensin II amide and potassium ions had, if anything, inhibitory effects on flow, but only at high concentrations. The data suggest that ACTH and dbcAMP evoke specific responses in the adrenal vasculature, resulting in relatively decreased intraglandular vascular resistance. They furthermore suggest that the secretory functions of the inner adrenocortical zones are subject to the additional control of vascular elements in the intact gland. J. Endocr. (1986) 109, 279–285

Ca antagonists do not alter aldosterone secretion during established Na depletion

Conscious sheep whose sole adrenal gland had been transplanted to the neck to allow access to the adrenal vasculature were used to study the effect of calcium antagonists on aldosterone secretion. All animals were sodium depleted by uncompensated loss of parotid saliva. The drugs EDTA, verapamil, methoxyverapamil, nisoldipine, lanthanum, propylmethylenedioxyindene, and ryanodine were infused on separate occasions in three or four increasing dose levels. All infusions were made to produce known concentrations directly into the adrenal arterial blood supply. None of these infusions had any significant effect on aldosterone secretion rate, cortisol secretion rate, and little or no effect on plasma [Na], [K], or blood pressure. At high infusion rates some agents (verapamil, methoxyverapamil) caused tachycardia. In contrast, angiotensin II stimulation of aldosterone secretion is inhibited by both verapamil and nisoldipine. The data demonstrate that the sustained elevation of aldosterone secretion caused by sodium depletion is not dependent on a sustained alteration in transmembrane calcium flux. Furthermore, if circulating angiotensin II is the primary stimulus to aldosterone during sodium depletion, its mechanism of action appears to switch to one which is not dependent on calcium alone.