Studies on Cyclic Nucleotides in the Adrenal Gland. XI. Adrenergic Regulation of Adenylate Cyclase Activity in the Adrenal Cortex*

Shima, Sumio; Komoriyama, K; Hirai, Masanao; Kouyama, Hiroshi

doi:10.1210/endo-114-2-325

Cited by 38 publications

(14 citation statements)

References 30 publications

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“…The a-agonist phenylephrine does not stimulate steroid release from isolated perfused pig adrenals, suggesting that the stimulatory effect of epinephrine is mediated by a b-adrenergic mechanism. Consistent with these results, in bovine (Ehrhart- and rat adrenocortical cells (Pratt et al, 1985;Shima et al, 1984) the stimulatory effects of epinephrine are not influenced by a-blockade, whereas the effect is completely abolished by the b-adrenergic antagonist propranolol. Therefore, the catecholamines released in large amounts are further possible transmitters which could be responsible for the observed stimulation of the functions of the mammalian adrenal gland by activation of the sympathoadrenal system.…”

Section: Second Pathwaysupporting

confidence: 74%

Morphological and functional studies of the paracrine interaction between cortex and medulla in the adrenal gland

Bornstein

Ehrhart‐Bornstein

Scherbaum

1997

Microsc. Res. Tech.

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Section: Second Pathwaysupporting

confidence: 74%

Morphological and functional studies of the paracrine interaction between cortex and medulla in the adrenal gland

Bornstein

Ehrhart‐Bornstein

Scherbaum

1997

Microsc. Res. Tech.

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“…The question as to whether the catecholamines are able to influence aldosterone secretion was not directly addressed by the present study, as there is already much evidence to support the contention that adrenergic agonists stimulate aldosterone secretion in a variety of different rat adrenal preparations, including adrenal slices (Andreis et al 1995), capsular preparations in vitro (Shima et al 1984, Pratt et al 1985, Pratt & McAteer 1989, the isolated perfused adrenal preparation ( J P Hinson, unpublished observations) and dispersed zona glomerulosa cell preparations (Horiuchi et al 1987). The question of the physiological role of the VIP-catecholamine system in the regulation of zona glomerulosa function remains unclear.…”

Section: Discussionmentioning

confidence: 81%

Actions of vasoactive intestinal peptide on the rat adrenal zona glomerulosa

Hinson

Puddefoot²,

Kapas³

1999

Journal of Endocrinology

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Previous studies, by this group and others, have shown that vasoactive intestinal peptide (VIP) stimulates aldosterone secretion, and that the actions of VIP on aldosterone secretion by the rat adrenal cortex are blocked by adrenergic antagonists, suggesting that VIP may act by the local release of catecholamines. The present studies were designed to test this hypothesis further, by measuring catecholamine release by adrenal capsular tissue in response to VIP stimulation.Using intact capsular tissue it was found that VIP caused a dose-dependent increase in aldosterone secretion, with a concomitant increase in both adrenaline and noradrenaline release. The effects of VIP on aldosterone secretion were inhibited by atenolol, a 1 adrenergic antagonist, but not by ICI-118,551, a 2 adrenergic antagonist. Binding studies were carried out to investigate VIP receptors. It was found that adrenal zona glomerulosa tissue from control rats contained specific VIP binding sites (B max 853 101 fmol/mg protein; K d 2·26 0·45 nmol/l). VIP binding was not displaced by ACTH, angiotensin II or by either of the adrenergic antagonists.The response to VIP in adrenals obtained from rats fed a low sodium diet was also investigated. Previous studies have found that adrenals from animals on a low sodium diet exhibit increased responsiveness to VIP. Specific VIP binding sites were identified, although the concentration or affinity of binding sites in the low sodium group was not significantly different from the controls. In the low sodium group VIP was found to increase catecholamine release to the same extent as in the control group, however, in contrast to the control group, the adrenal response to VIP was not altered by adrenergic antagonists in the low sodium group.These data provide strong support for the hypothesis that VIP acts by the local release of catecholamines in adrenal zona glomerulosa tissue in normal animals. It does not appear that VIP acts through the same mechanism in animals maintained on a low sodium diet. The mechanism by which VIP stimulates aldosterone in this group remains to be determined.

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“…Similar experiments have not been done using dog adrenals. Beta-adrenergic agonists stimulate aldosterone and corticosterone release from rat and bovine zona glomerulosa cells [34,35]. However, corticosterone release from rat zona fasciculata cells was not affected [36].…”

Section: Discussionmentioning

confidence: 99%

“…Catecholamines would act on the adrenal cortex to elicit a stero idogenic response. This possibility also seems unlikely since there is little evidence for an adrenergic influence on cortico steroid secretion from the zona fascieulata [34]. However, further experiments are required to determine if blockade of adrenergic receptors affects the steroid responses observed after nerve stimulation.…”

Section: Discussionmentioning

confidence: 99%

Splanchnic Nerve Stimulation Modulates Steroid Secretion in Hypophysectomized Dogs

Engeland

Gann²

1989

Neuroendocrinology

101

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To test whether or not splanchnic neural input to the adrenal gland affects secretion of steroids from the adrenal cortex, the thoracic splanchnic nerve was electrically stimulated in pentobarbital-anesthetized dogs after hypophysectomy and replacement with physiological concentrations of ACTH. An adrenal vein cannula was placed to permit measurement of cortisol, corticosterone, 11 -deoxycortisol, epinephrine and norepinephrine secretion rates and adrenal blood flow. Plasma ACTH was measured and the presentation rate of ACTH was calculated as the product of plasma ACTH concentration and adrenal plasma flow. Dogs were infused initially with ACTH for 60 min at 2 ng/min followed by infusion for 60 min at 10 ng/min. Within each infusion period, the distal end of the nerve was stimulated (20 V; 0.5-ms pulse duration) at 4 and at 20 Hz for 10 min each. Nerve stimulation resulted in a frequency-dependent increase in mean arterial pressure, in epinephrine and norepinephrine secretion and in adrenal blood flow. Arterial ACTH remained constant during nerve stimulation; however, increased adrenal blood flow resulted in increased presentation rate of ACTH to the adrenal. Cortisol secretion increased in response to nerve stimulation at 4 and 20 Hz during infusion of 2 and 10 ng/min ACTH and occurred prior to changes in presentation rate of ACTH. Corticosterone secretion also increased after stimulation at both frequencies, but the response was observed only during infusion of 10 ng/min ACTH. In contrast, 11-deoxycortisol decreased after nerve stimulation at 4 Hz but showed no response after stimulation at 20 Hz during infusion of 2 and 10 ng/min ACTH. Steroid ratios were calculated to assess the possible involvement of specific steroidogenic enzymes in the observed responses. The cortisol to 11-deoxycortisol ratio was increased, whereas the cortisol to corticosterone ratio was not affected by nerve stimulation, suggesting a change in 11-β-hydroxylase activity. These data show that splanchnic nerve stimulation can increase cortisol secretion independently of changes in arterial ACTH. The effect of splanchnic nerve activity on cortisol secretion may result from increasing vascular delivery of ACTH to the adrenal, from release of a non pituitary humoral factor with steroidogenic activity or from direct stimulation of steroidogenesis by an adrenal neurotransmitter substance.

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Studies on Cyclic Nucleotides in the Adrenal Gland. XI. Adrenergic Regulation of Adenylate Cyclase Activity in the Adrenal Cortex*

Cited by 38 publications

References 30 publications

Morphological and functional studies of the paracrine interaction between cortex and medulla in the adrenal gland

Morphological and functional studies of the paracrine interaction between cortex and medulla in the adrenal gland

Actions of vasoactive intestinal peptide on the rat adrenal zona glomerulosa

Splanchnic Nerve Stimulation Modulates Steroid Secretion in Hypophysectomized Dogs

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