Evidence for increased endogenous dopaminergic inhibition of aldosterone secretion in prolactinoma

Aldosterone responsiveness to consecutive i.v. injections of metoclopramide 1 mg, 2.5 mg and 10 mg was studied in 8 patients with prolactinoma and normally preserved adrenal function and in 14 healthy volunteers. In the patients, aldosterone response to metoclopramide 1 mg was blunted. After metoclopramide 10 mg, aldosterone rose to the same levels in patients and volunteers. In the patients, however, percentage rise of aldosterone was enhanced, since the appropriate base line concentration of aldosterone was decreased. Thus, there is evidence for increased endogenous dopaminergic inhibition of aldosterone secretion in prolactinoma.     

Absent aldosterone response to metoclopramide in patients with high spinal cord transection: evidence that metoclopramide stimulates aldosterone secretion through central pathways

This study evaluates dopaminergic regulation of aldosterone secretion in 6 patients with high spinal cord transections. Administration of the dopamine antagonist metoclopramide resulted in a marked rise in plasma aldosterone and 18-hydroxycorticosterone levels in 12 normal individuals, but no change in plasma levels of these zona glomerulosa corticosteroid products in spinal cord patients. Spinal cord transected patients also did not have the rise in plasma renin activity that was observed in normals following metoclopramide administration. Basal levels of aldosterone, 18 hydroxycorticosterone, corticosterone and renin activity as well as the aldosterone responses to graded dose infusion of adrenocorticotropin were similar in the spinal cord patients and the normals. These data suggest that dopaminergic regulation of adrenal zona glomerulosa corticosteroid and renal renin secretion is absent in patients with high spinal cord transections, suggesting that intact neural pathways from the central nervous system are necessary for metoclopramide stimulation of aldosterone and renin secretion in men. Since basal plasma aldosterone levels were normal in spinal cord transected patients, it appears that the absence of dopaminergic control does not result in elevated secretion.     

A patient with a prolactinoma associated with an aldosterone producing adrenal adenoma: differences in dopaminergic regulation of PRL and aldosterone secretion.

A patient with a rare combination of prolactinoma and aldosterone producing adrenal adenoma (APA) was reported in relation to studies concerning dopaminergic regulation of PRL and aldosterone secretion. The patient is a 38-year-old female with plasma PRL and aldosterone concentrations (PAC) of 563 ng/ml and 54 ng/dl, respectively. A bolus of 10 mg of metoclopramide significantly increased plasma PRL in 6 normal subjects and in 4 patients with APA, whereas the responses were blunted in 7 patients with prolactinoma and in our patient. The response of aldosterone to metoclopramide was less than that of PRL, but similar in all studied subjects, indicating that the dopaminergic inhibition of aldosterone secretion is less than that of PRL in normal subjects and did not change in patients with APA or prolactinoma. Oral administration of 2.5 mg of bromocriptine suppressed plasma PRL significantly in all the subjects studied, but did not produce any consistent changes in PAC. Discrepancies in the response of PRL and aldosterone to metoclopramide and to bromocriptine suggest a difference in the dopaminergic regulation of PRL and aldosterone secretion in both normal subjects and patients with prolactinoma and APA. It is unlikely that reduced dopaminergic inhibition is the basis for hypersecretion of PRL and aldosterone in our patient.     

Plasma aldosterone response to metoclopramide is unmodified by hyperprolactinemia

It has been previously demonstrated that patients with hyperprolactinemia have impaired PRL response to dopaminergic blockade and increased TSH response. Since inhibitory dopaminergic modulation of aldosterone is well established, we have examined whether prolactinoma patients have an altered aldosterone response to dopaminergic blockade. To investigate this possibility we compared the plasma PRL, TSH and aldosterone responses to the dopamine (DA) antagonist metoclopramide (MCP; 10 mg i.v.) in 10 women with prolactinomas and 7 healthy female controls. Basal PRL levels in prolactinoma patients were elevated and showed a blunted rise following MCP. Although basal TSH levels were similar in the 2 groups of subjects, they significantly increased (p = 0.017) in prolactinoma patients while in contrast they did not significantly change in control subjects. Basal supine plasma aldosterone was similar in patients with prolactinomas (0.23 +/- 0.03 nmol/l) and in healthy subjects (0.25 +/- 0.04 nmol/l) and the increased aldosterone concentrations from 15 to 120 min following MCP were not significantly different in prolactinoma patients and in control subjects. It is concluded that in patients with prolactinomas, the alteration in the dopaminergic regulation is specifically related to the lactotroph.     

Mechanism of the central effects of dopamine and metoclopramide on aldosterone regulation in the rat

To investigate the mechanism of the central action of dopamine and its antagonist, metoclopramide, on the regulation of aldosterone, studies were performed in 54 conscious rats with and without bilateral nephrectomy. In normal and sham-operated rats, intracerebroventricular injection of dopamine resulted in a significant suppression of plasma renin activity and plasma aldosterone at 30 min, and intracerebroventricular injection of metoclopramide resulted in a significant elevation of plasma renin activity and plasma aldosterone at 30 min without altering the plasma corticosterone and potassium levels. In bilaterally nephrectomized rats, the plasma renin activity was significantly reduced and it did not respond to dopamine or metoclopramide. In these rats, intracerebroventricular injection of metoclopramide exerted no effect on the plasma aldosterone, but intracerebroventricular injection of dopamine increased the plasma aldosterone slightly. However, this increase was not statistically significant. These findings suggest that the dopaminergic system in the brain is involved in the regulation of aldosterone secretion, mainly with changes in the peripheral renin-angiotensin axis in rats.     

Dopaminergic modulation of salt sensitivity in patients with essential hypertension

The present study was designed to investigate the possible role of dopaminergic mechanisms in contributing to the pathogenesis of hypertension in salt sensitive patients. Eighteen patients with essential hypertension were studied while under a diet ranging from low salt to high salt, which enabled a classification in "salt-sensitive" (SS) and "nonsalt-sensitive" (NSS) groups based on a tentative criteria of a 10% increase of mean blood pressure with high salt diet. The SS patients showed reduced urinary excretion of sodium as compared with that from NSS patients. Urinary norepinephrine excretion in all patients with salt loading was suppressed, but urinary excretion of epinephrine showed a tendency to increase in SS patients after salt loading. Urinary excretion of dopamine increased in NSS patients with salt loading, but did not change in SS patients. To further evaluate the role of dopaminergic mechanisms in salt-sensitive hypertension, metoclopramide, a dopamine antagonist, was injected intravenously to all patients. With salt loading, plasma aldosterone levels increased after injection of metoclopramide in NSS patients, but did not change in SS patients. These results suggest that salt-sensitive hypertension is modulated by dopaminergic activity, which in turn is attenuated in SS patients. Decreased dopaminergic activity induced sodium retention both by a direct effect on the kidney as well as indirectly via relatively increased aldosterone secretion. Both mechanisms would help to increase intravascular volume and blood pressure in salt-sensitive hypertension.     

Dopamine control of aldosterone secretion in end-stage renal failure

The role of the tonic inhibitory effect of dopamine on aldosterone secretion has been investigated in 10 patients with chronic renal failure (CRF) on hemodialysis, in 8 normotensive renal transplant recipients (Tx) with normal renal function and in 8 normotensive volunteers (NV). The following tests were performed: the response of plasma aldosterone (PA) to metoclopramide administration; the response of plasma prolactin (PRL) to TRH administration, and the changes induced by Lisuride (a dopaminergic agonist, on the values of PA and PRL). The basal values of PA and PRL were higher in CRF than in NV and Tx. The inverse was true for plasma renin activity (PRA) values. The response of PA and PRL to metoclopramide showed blunted increases in CRF when compared to NV, in the absence of changes of PRA, cortisol and potassium. After TRH administration, PRL increase in CRF was also inferior. Lisuride induced a decrease of both PA and PRL both in CRF and NV. In Tx, basal values of PA and PRL were similar to NV. Nevertheless, the response to metoclopramide and TRH were partially blunted when compared to that of NV. These results point to the existence of a deranged dopaminergic regulation of aldosterone secretion in end-stage renal failure patients. The alterations are partially corrected by a well-functioning kidney graft.     

The Influence of a Heparin-Like Compound on Hypertension,Electrolytes and Aldosterone in Man

The mechanisms of the aldosterone-inhibiting and antihypertensive actions of heparin and certain other sulfated mucopolysaccharides were investigated in 13 hypertensive patients. N-formyl chitosan polysulfuric acid (RO 1-8307) was used rather than heparin because of its low anticoagulant activity. RO 1-8307 lowered aldosterone secretion in one patient with proved and one with probable primary aldosteronism; this indicates that the mucopolysaccharide does not inhibit aldosterone secretion via the renin-angiotensin mechanism. In six hypertensive patients RO 1-8307 caused a fall in the secretion of aldosterone and its probable immediate precursor, 18-hydroxycorticosterone; therefore it does not act at the last step in the synthesis of aldosterone. RO 1-8307 produced a prolonged clinical and biochemical remission in the two patients considered to have primary aldosteronism but did not influence blood pressure in five of seven patients in whom excessive aldosterone was probably not a major factor in the hypertension. It is concluded that the antihypertensive action of RO 1-8307, and perhaps of heparin as well, is largely due to suppression of aldosterone secretion.     

Predictive factors of left ventricular mass changes after treatment of primary aldosteronism

A variety of abnormalities that occur in patients with primary aldosteronism indicate the capability of elevated aldosterone to induce cardiac damage over that induced by hypertension itself. This study investigates factors that can predict structural and functional changes of the heart after treatment of primary aldosteronism in a post-hoc analysis of 54 patients who were enrolled in a long-term follow-up study that was conducted after either adrenalectomy or treatment with spironolactone. Cardiac ultrasound assessment was performed before treatment and after with an average follow-up of 6.4 years. During follow-up, blood pressure decreased significantly and comparably in both treatment groups. In both treatment groups, left ventricular mass decreased significantly with a trend to improved diastolic filling profile and no changes in ventricular geometry. At univariate analysis, changes in left ventricular mass induced by treatment of primary aldosteronism were directly related with changes in systolic blood pressure and pretreatment plasma aldosterone levels measured both at baseline and after an intravenous saline load. This relationship was maintained when patients treated with adrenalectomy and spironolactone were analyzed separately. Multivariate regression analysis showed that changes in systolic blood pressure and pretreatment aldosterone levels were independent predictors of left ventricular mass changes after treatment. This study strongly supports a role of aldosterone in promoting left ventricular hypertrophy that is independent of the hypertension-related hemodynamic load and suggests a practical way to predict left ventricular mass changes following surgical and medical treatment of primary aldosteronism.     

Human alpha atrial natriuretic peptide inhibits angiotensin stimulated aldosterone biosynthesis in bovine adrenal glands

The behaviour of aldosterone output was evaluated in isolated and superfused bovine adrenal glands during superfusion with human alpha atrial natriuretic peptide on its own or with angiotensin II or a antagonist dopaminergic drug: metoclopramide. H alpha-ANP even in high concentrations did not reduce the basal amount of aldosterone released from bovine adrenal glands, nor did it modify aldosterone response to metoclopramide, but it partially inhibited aldosterone stimulation by angiotensin II. These data suggest that atrial natriuretic factor may affect sodium secretion through the modulation of aldosterone secretion.     

Regulation of aldosterone secretion in primary aldosteronism.

Plasma aldosterone, plasma renin activity and plasma cortisol were determined in patients with primary aldosteronism in response to posture and at short-time intervals overnight while the patient were supine. In the 5 patients with an aldosterone-producing adenoma postural changes in plasma aldosterone were paralleled by those in cortisol while plasma renin activity was generally undetectable indicating an ACTH-dependent secretion of aldosterone. This concept was supported by the observation that in 3 of these patients who were tested overnight 1. episodic secretion of plasma aldosterone was paralleled by those of cortisol and 2. episodic secretion of plasma aldosterone could be blunted by dexamethasone. In the patient with idiopathic adrenal hyperplasia concomittant changes in plasma aldosterone and plasma renin activity occurred. The assumption that in this patient the fluctuations in plasma aldosterone were mediated through changes in renal renin secretion was supported by the finding that episodic secretion of plasma aldosterone persisted under suppression of ACTH-secretion by dexamethasone. Our results indicate, that the described procedures may all serve as diagnostic criteria to differentiate between aldosterone-producing adenoma and idiopathic adrenal hyperplasia.     

Glucocorticoid suppression enhances the 18-hydroxycorticosterone and aldosterone response to metoclopramide in man

18-Hydroxycorticosterone (18-OHB) is a precursor of aldosterone and is the only corticosteroid, other than aldosterone, that is synthesized predominantly in the zona glomerulosa. Administration of the dopamine antagonist, metoclopramide results in parallel rises in plasma 18-OHB and aldosterone levels without affecting the plasma levels of other aldosterone precursors. However, 18-OHB is a product of the zona fasciculata as well as the glomerulosa. Thus, it is possible that metoclopramide may stimulate zona fasciculata secretion of 18-OHB. In order to more selectively examine dopaminergic regulation of zona glomerulosa secretion of 18-OHB we have examined the effect of glucocorticoid suppression of the fasciculata on the 18-OHB and aldosterone responses to metoclopramide, 10 mg iv in 6 normal volunteers. Dexamethasone, 2 mg every 6 hours for 5 days, suppressed basal levels of cortisol, corticosterone, 18-OHB and aldosterone. Dexamethasone treatment had no effect on basal levels of PRA or PRA responses to metoclopramide. The 18-OHB and aldosterone responses to metoclopramide were enhanced (p less than .05) by dexamethasone suppression. The results suggest that dopaminergic mechanisms selectively suppress glomerulosa production of 18-OHB. Endogenous ACTH may inhibit zona glomerulosa production of 18-OHB and aldosterone in response to the dopamine antagonist, metoclopramide.     

Effect of verapamil on the aldosterone-stimulating properties of metoclopramide: in vitro and in vivo studies

The role of calcium in the regulation of aldosterone secretion has been recently clarified. Angiotensin II and potassium stimulate aldosterone secretion through a calcium-entry dependent mechanism, while ACTH action is both calcium and cyclic AMP dependent. To establish whether also the so-called aldosterone dopaminergic regulatory system is calcium-dependent we have studied, in vitro and in vivo, the effect of verapamil, a calcium entry blocker agent, on the aldosterone-stimulating properties of the antidopaminergic drug, metoclopramide. In the rat adrenal cells perfusion system, verapamil blocked both angiotensin II and metoclopramide-stimulated aldosterone. This effect on metoclopramide action seems to be present also in vivo in normal subjects: in fact aldosterone response was slightly but significantly reduced after pretreatment with verapamil. In conclusion the results suggest that also the dopaminergic system could regulate aldosterone secretion through calcium-mediated mechanisms.     

Dopaminergic modulation of aldosterone secretion: effect of sodium balance and postural changes

The influence of an increased endogenous production of angiotensin II and of sodium homeostasis upon the response of plasma aldosterone to metoclopramide administration has been investigated in 5 normal volunteers. Our results show that the increase of plasma aldosterone after metoclopramide administration is independent of angiotensin II, ACTH and potassium, and that it increases even further due to the endogenous production of angiotensin II induced by postural changes. The state of sodium balance seems to influence the response of plasma aldosterone to metoclopramide administration as it occurs with other stimuli of aldosterone secretion.     

Differences between adrenal adenoma causing primary aldosteronism and other adrenal tissues in the incorporation of labeled steroid precursors into their products

The incorporation and conversion of several labeled steroid precursors into their products were examined in slices of adrenal tissue from two patients with primary aldosteronism and compared with that in “normal” adrenal tissue and adrenal tissues from a patient with Gushing's syndrome. The products of the incorporation were separated by Sephadex LH-20 column chromatography. The major products of conversion in the adenomatous tissue of primary aldosteronism were 18-hydroxycorticosterone and lesser amounts of aldosterone. Smaller amounts of 18-hydroxycorticosterone were isolated from all other adrenal tissues studied. No aldosterone could be recovered after incubating any of the adrenal tissue studied with labeled 18-hydroxy-11-deoxycorticosterone or 18-hydroxycorticosterone as precursor steroid. These $\text{in vitro}$ results seem to suggest that there is increased 18-hydroxylation in the adenoma of primary aldosteronism compared with other tissues and that relatively more 18-hydroxycorticosterone is produced in such tissue than aldosterone.     

New aspects on primary aldosteronism

The adrenal cortex synthesizes and releases steroid hormones, mainly mineralocorticoids and glucocorticoids. There is a functional zonation of the adrenal cortex and steroid synthesis is thoroughly regulated. Overproduction of aldosterone, primary aldosteronism, may be much more common than previously known and may be responsible for 10% of essential hypertension. Primary aldosteronism is characterized by autonomous production of aldosterone, suppressed renin activity, hypokalemia, and hypertension. The two most common forms are unilateral adenoma and bilateral hyperplasia. In spite of thorough clinical workup and careful histopathology it is often difficult to differentiate between adenoma and hyperplasia. The gene CYP11B2 encodes the steroid synthesizing enzymes for aldosterone production, while the genes CYP17 and CYP11B1 are needed for cortisol production. Most normal controls show expression of CYP11B2 in zona glomerulosa. Expression of CYP11B1 and CYP17 is seen in zona fasciculata and reticularis, whereas the expression of CYP21 is present in all three cortical layers. Adenomas from patients with primary aldosteronism show considerable variation in the expression of CYP11B2. Adenomas from patients with Cushing's syndrome have a strong expression of CYP11B1 and CYP17. In a patient material of 29 cases of primary aldosteronism, 4 patients had small nodules detected with expression of CYP11B2 gene. These nodules were not visualized on CT, whereas adrenal masses seen on CT in these patients showed CYP11B1 and CYP17 gene expression. This suggests that these small nodules are responsible for the aldosterone production and this is characteristic of nodular hyperplasia in patients with primary aldosteronism. In conclusion, this method to visualize mRNA gene expression of steroidogenic enzymes, and especially expression of CYP11B2, has increased the knowledge of adrenal pathophysiology. The results emphasize the value to include functional studies (venous sampling and/or scintigraphy) in the preoperative work up of patients with primary aldosteronism.     

Alpha-h-ANP injection in normals, low renin hypertension and primary aldosteronism

Atrial natriuretic peptide, a hormone secreted by the heart, is involved in salt and fluid homeostasis and also exerts an inhibitory effect on aldosterone production in vitro. In order to elucidate if this effect is also present in man, 6 normal volunteers, 5 low renin hypertensive patients (LRH) and 7 patients with primary aldosteronism (PA) have received 100 micrograms of alpha-h-Anp as bolus i.v. (The decrease in blood pressure was mild and transient in all groups, whereas a marked diuretic effect was observed in all hypertensives even in PA where high levels of endogenous ANP have been found. In normals we observed a significant decrease of plasma aldosterone values while in PA and LRH this effect was not evident. This phenomenon associated with a greater natriuretic effect in LRH and PA, as compared with normals, demonstrates the lack of the correlation between ANP-induced diuresis and aldosterone inhibiting properties.     

Evidence for direct inhibitory effects of dopamine on zona glomerulosa secretion of 18-hydroxycorticosterone in rhesus monkeys

This study was designed to more selectively investigate the dopaminergic regulation of 18-hydroxycorticosterone (18-OHB) and aldosterone production by the adrenal zona glomerulosa. Mature rhesus monkeys received either an infusion of dopamine (2 micrograms/kg/min) or 5% dextrose (0.2 ml/min) over a 60 min period (N=6). Dopamine had no effect on plasma levels of renin activity, cortisol, corticosterone, aldosterone or blood pressure. However, dopamine suppressed (p less than 0.05) plasma 18-OHB levels from a baseline of 31.6 +/- 3.5 ng/dl to 23.6 +/- 2.1 ng/dl at 60 min after onset of infusion. This observation is in agreement with some studies in humans but differs from others in which no depression in 18-OHB was observed following dopamine infusion. Dopamine infusion markedly (p less than 0.001) suppressed plasma PRL levels by 30 min after onset of infusion. Corticosteroid responses to metoclopramide (200 micrograms/kg) after dexamethasone 1 mg im every 6 h X 5 days or placebo treatment (vehicle im every 6 h X 5 days) was then evaluated. Dexamethasone significantly suppressed basal cortisol, corticosterone, 18-OHB and aldosterone. Although dexamethasone blunted the prolactin response, it did not inhibit the aldosterone response to metoclopramide. The 18-OHB response to metoclopramide was increased (p less than 0.01) following dexamethasone treatment. Following dexamethasone suppression, 18-OHB levels were still lowered (p less than 0.05) by dopamine infusion. These results suggest that dopamine selectively inhibits zona glomerulosa production of 18-OHB and aldosterone in rhesus monkeys.     

Determination of aldosterone by sephadex LH-20 chromatography and radioimmunoassay

A method for the determination of urinary aldosterone has been developed which appears to be applicable for the clinical laboratory. Ten ml of urine were used for analysis. The purification of aldosterone consisted of hydrolysis at pH 1.0; CH₂Cl₂ extraction and column chromatography on Sephadex LH-20. Recovery of added 4-¹⁴C-D-aldosterone was 44.7 + 7.1 (2 SD) % for 60 experiments. The extraction was followed by a rapid radioimmunoassay analysis of aldosterone. The sensitivity of the overall assay was 1.6 μg aldosterone, the accuracy 92.0 ±3.4 %. The coefficient of variation was within one assay 14 % for a given sample (n = 19) and 20 % for multiple assays. Excretion of aldosterone as determined in 17 healthy individuals on an uncontrolled diet was 9.5 ± 3.6 (SD) μg per 24 hours. Patients suffering from renal arterial stenosis or from essential hypertension presented an increase of aldosterone excretion upon sodium restriction. An increased excretion of aldosterone without any response to reduced sodium uptake was found in patients with primary aldosteronism.     

A case of primary aldosteronism with chronic renal failure undergoing hemodialysis treatment

A 56-year-old man with primary aldosteronism and chronic renal failure undergoing hemodialysis is described. He complained of numbness of the extremities and showed persistent hypopotassemia in spite of anuria. In the endocrinological examination, a very high plasma aldosterone concentration was observed, while plasma renin activity was within the normal range. From the abdominal Computed Tomography (CT), adrenal scintigraphy, and segmental venous sampling data, he was diagnosed as primary aldosteronism due to left adrenocortical adenoma. In this case, hypopotassemia could not be explained by potassium loss through the kidneys, which suggests potassium excretion in the gastrointestinal tract as the mechanism of hypopotassemia. This was clearly shown from a potassium-balance study and the results of spironolactone administration. Our report is on the first case showing hypopotassemia due to primary aldosteronism in spite of anuria. If a patient treated with maintenance dialysis should have persistent hypopotassemia, as in the present report, it is necessary to consider an association with primary aldosteronism.