Regulation of aldosterone synthesis

The effects of angiotensin II and ACTH on cyclic AMP and aldosterone synthesis were studied in cells isolated from the bovine adrenal cortex. Angiotensin is a more potent stimulus of aldosterone synthesis than ACTH and the action of ACTH on aldosterone synthesis in cells from the glomerulosa is augmented by the presence of cells from the fasciculata. Angiotensin stimulates aldosterone synthesis in the absence of detectable changes in cyclic AMP, but the cells do respond to dibutyryl cyclic AMP leaving open the possibility that a cyclic nucleotide may play a role in the steroidogenic action of this hormone in the outer zone of the bovine adrenal cortex.     

Invalidation of TASK1 potassium channels disrupts adrenal gland zonation and mineralocorticoid homeostasis

TASK1 (KCNK3) and TASK3 (KCNK9) are two-pore domain potassium channels highly expressed in adrenal glands. TASK1/TASK3 heterodimers are believed to contribute to the background conductance whose inhibition by angiotensin II stimulates aldosterone secretion. We used task1-/- mice to analyze the role of this channel in adrenal gland function. Task1-/- exhibited severe hyperaldosteronism independent of salt intake, hypokalemia, and arterial 'low-renin' hypertension. The hyperaldosteronism was fully remediable by glucocorticoids. The aldosterone phenotype was caused by an adrenocortical zonation defect. Aldosterone synthase was absent in the outer cortex normally corresponding to the zona glomerulosa, but abundant in the reticulo-fasciculata zone. The impaired mineralocorticoid homeostasis and zonation were independent of the sex in young mice, but were restricted to females in adults. Patch-clamp experiments on adrenal cells suggest that task3 and other K+ channels compensate for the task1 absence. Adrenal zonation appears as a dynamic process that even can take place in adulthood. The striking changes in the adrenocortical architecture in task1-/- mice are the first demonstration of the causative role of a potassium channel in development/differentiation.     

sn-1,2 dioctanoylglycerol mimics the effects of angiotensin II on aldosterone production and potassium permeability in isolated bovine glomerulosa cells

In order to elucidate the possible role in glomerulosa cells of diacylglycerol released by angiotensin II we have studied the action of a synthetic diacylglycerol, sn-1,2-dioctanoylglycerol (DiC8), on aldosterone production and potassium permeability in bovine adrenal cells. DiC8 elicited an increase in 86Rb efflux from cells previously equilibrated with the isotope. The action of DiC8 on the rate coefficient for 86Rb efflux was similar to that previously described for angiotensin II (Am. J. Physiol. 254 (1988) E144-149), i.e. DiC8 induced an immediate increase in 86Rb efflux followed by a sustained decrease in potassium permeability. This DiC8 induced inhibition was observed even in the presence of depolarizing concentrations of potassium. The effect of DiC8 on aldosterone secretion from adrenal glomerulosa cells was measured using a perifusion system. DiC8 (300 microM) caused a significant increase of aldosterone production, comparable to that seen with angiotensin II (100 nM). These results indicate that DiC8 has similar effects to angiotensin II on both potassium permeability and steroidogenesis, which suggests that activation of protein kinase C is involved in the changes of ionic permeability induced by this hormone in bovine adrenal glomerulosa cells.     

Calf adrenocortical fasciculata cells secrete aldosterone when placed in primary culture

Aldosterone production occurs in the outer area of the adrenal cortex, the zona glomerulosa. The glucocortocoids cortisol and corticosterone, depending upon the species, are synthesized in the inner cortex, the zona fasciculata. Calf zona glomerulosa cells rapidly lose the ability to synthesize aldosterone when placed in primary culture unless they are incubated in the presence of the antioxidants butylated hydroxyanisol and selenous acid, the radioprotectant DMSO, and the cytochrome P-450 inhibitor metyrapone. In the presence of these additives, calf zona fasciculata cells in primary culture synthesize aldosterone at rates which can approach those from cells isolated from the zona glomerulosa. Calf zona glomerulosa and fasciculata cells both responded well to ACTH and angiotensin II, but the zona fasciculata cells respond very poorly compared to glomerulosa cells to increased potassium in the media. Rat zona fasciculata cells in primary culture under similar conditions did not synthesize aldesterone, suggesting that the regulation of the expression of the enzymes responsible for the biosynthesis of aldosterone in the two species is different. Two distinct cytochrome P-450 cDNAs which hydroxylate deoxycorticosterone at the 11β position have been described in the rat, human and mouse. Both cytochrome P-450 cDNAs have been cloned and expressed in non-steroidogenic cells, but only one is expressed in the zona glomerulosa and only this glomerulosa cytochrome P450 can further hydroxylate deoxycorticosterone to generate aldosterone. Two bovine adrenal cDNAs have been described with 11β-hydroxylase activity and their expression products in transiently transfected COS cells can convert deoxycorticosterone into aldosterone. Both enzymes are expressed in all zones of the adrenal cortex. Zonal regulation of aldosterone synthesis in the bovine adrenal gland may be due to an 11β-hydroxylase with aldosterone synthesizing capacity which has not yet been isolated. Alternatively, a single enzyme might be responsible for the several hydroxylations in the pathway between deoxycorticosterone and aldosterone and zonal synthesis might be controlled by unknown factors regulating the expression of C-18 hydroxylation. The incubation of zona fasciculata with antioxidants and metyrapone results in atypical expression of this activity by an unclear mechanism.     

An examination of possible mechanisms of angiotensin II-stimulated steroidogenesis.

Dog and rat adrenal glomerulosa cells and subcellular fractions have been utilized to evaluate the mechanism of angiotensin II- and angiotensin III-induced aldosterone production. The effects of angiotensin, ACTH, and potassium have been compared on cyclic AMP and cyclic GMP in isolated glomerulosa cells and adenylate cyclase activity in subcellular fractions. The effect of angiotensin II has also been assessed on Na+-K+-activated ATPase of plasma membrane enriched fractions of dog and rat adrenals. We have demonstrated no effect of angiotensin II or angiotensin III on either adenylate cyclase, cyclic AMP, cyclic GMP, or Na+-K+-dependent ATPase activity over a wide range of concentrations. Potassium ion in concentrations that stimulate significant aldosterone production was also without effect. The negative effects of angiotensin and potassium were contrasted against a positive correlation between an ACTH-induced effect on aldosterone production, adenylate cyclase, and cyclic AMP accumulation. These studies have served to demonstrate that neither adenylate cyclase, cyclic AMP, cyclic GMP, or Na+-K+-activated ATPase seem to be directly involved in the mechanism of action of angiotensins on aldosterone production in the rat and dog adrenal glomerulosa.     

18-Ethynyl-deoxycorticosterone inhibition of steroid production is different in freshly isolated compared to cultured calf zona glomerulosa cells

The inhibiting effects of 18-ethynyl-deoxycorticosterone (18-E-DOC) as a mechanism-based inhibitor on the late-steps of the aldosterone biosynthetic pathway were examined in calf adrenal zona glomerulosa cells in primary culture and in freshly isolated calf zona glomerulosa cells. 18-E-DOC inhibited the stimulated secretion of aldosterone and 18-hydroxycorticosterone in a similar dose-response and time fashion. No significant differences were found between the inhibition in cultured and freshly isolated cells (K_i of 0.25 vs 0.26 μM) Corticosterone secretion stimulated by ACTH or angiotensin II was also cultured in freshly isolated zona glomerulosa and fasciculata cells, but was not inhibited in cultured calf adrenal cells. Cortisol secretion stimulated by ACTH was not inhibited by 18-E-DOC in cultured zona fasciculata adrenal cells, but was inhibited in freshly isolated zona fasciculata cells with a K_i of 48 μM. The secretion of 18-hydroxyDOC or 19-hydroxyDOC stimulated by ACTH was not inhibited by 18-E-DOC. The bovine adrenal has been reported to have cytochrome P-450 11β-hydroxylases that can perform the various hydroxylations required for the synthesis of cortisol and aldosterone in the different areas of the adrenal. In other species a distinct 11β-hydroxylase which participates in the biosynthesis of aldosterone and is located in the zona glomerulosa has been described. These studies with the mechanism-based inhibitor, 18-E-DOC, suggest that the bovine adrenal functions in a manner very similar to that of other species and raises the possibility that a distinct 11β-hydroxylase with aldosterone synthase activity might be present, but has not been cloned as yet.     

ACTH-induced inhibition of the action of angiotensin II in bovine zona glomerulosa cells. A modulatory effect of cyclic AMP on the angiotensin II receptor.

Both angiotensin II and adrenocorticotropic hormone (ACTH) are well known to play a crucial role on the regulation of aldosterone production in adrenal glomerulosa cells. Recent observations suggest that the steroidogenic action of ACTH is mediated via the cAMP messenger system, whereas angiotensin II acts mainly through the phosphoinositide pathway. However, there have been no reports concerning the interaction between the cAMP messenger system activated by ACTH and the Ca2+ messenger system induced by angiotensin II. Both ACTH and angiotensin II simultaneously act on adrenal cells for regulating steroidogenesis under physiological conditions. Thus the present experiments were performed to examine the effect of ACTH on the action of angiotensin II by measuring angiotensin II receptor activity, cytosolic Ca2+ movement, and aldosterone production. The major findings of the present study are that short-term exposure to a high dose of ACTH (10(-7) M) inhibited 125I-angiotensin II binding to bovine adrenal glomerulosa cells, decreased the initial spike phase of [Ca2+]i induced by angiotensin II, and inhibition of angiotensin II-induced aldosterone production. Low dose of ACTH (10(-10) M), which did not increase cAMP formation, did not affect angiotensin II receptor activity. These studies have shown that angiotensin II receptors of bovine adrenal glomerulosa cells can be down-regulated by 1 mM dibutyryl cyclic AMP, as well as by effectors which are able to activate cAMP formation (10(-7) M ACTH and 10(-5) M forskolin). The rapid decrease in angiotensin II receptors induced by 10(-7)M ACTH was associated with a decreased steroidogenic responsiveness and a decreased rise in the [Ca2+]i response induced by angiotensin II. These studies show that the cAMP-dependent processes activated by ACTH have the capacity to interfere with signal transduction mechanisms initiated by receptors for angiotensin II.     

Angiotensin stimulates both early and late steps in aldosterone biosynthesis in isolated bovine glomerulosa cells

The present study was designed to examine the effect of angiotensin on both the early and the late phases of aldosterone biosynthesis. In order to isolate the early phase (the formation of pregnelone). it was necessary to identify an agent that would inhibit the 3β-hydroxysteroid dehydrogenase, 4–5 eneisomerase enzyme system which facilitates the conversion of pregnenolone to progesterone. Such an agent was found in trilostane. Treatment of zona glomerulosa cells with trilostane resulted in accumulation of pregnenolone, and the addition of angiotensin increased the accumulation of pregnenolone still further. This observation demonstrates that angiotensin stimulates aldosterone biosynthesis at a point prior to pregnenolone formation.The late phase of aldosterone biosynthesis was isolated by using aminoglutethimide to inhibit the formation of pregnenolone by cells of the zona glomerulosa. Aldosterone was formed when aldosterone precursors occurring in the biosynthetic pathway from pregnenolone onward were added. When angiotensin was added along with deoxycorticosterone, the conversion of deoxycorticosterone to aldosterone was enhanced (P < 0.05). This observation demonstrates that angiotensin stimulates aldosterone formation at a point distal to deoxycorticosterone formation. Thus, angiotensin stimulates aldosterone biosynthesis at at least 2 independent points, one early and one late in the biosynthetic pathway.     

Angiotensin II and aldosterone regulation

The circulating renin-angiotensin system is a major regulator of the secretion of the adrenocortical hormone, aldosterone. This renin-angiotensin aldosterone system is important in the control of salt and water balance and blood pressure. This review describes the historical background leading to the discovery of aldosterone in the 1950s and the recognition in the 1960s that angiotensin II was involved in its control. Although angiotensin II is important in the regulation of aldosterone secretion, its action is influenced by multiple other factors, especially potassium and atrial natriuretic peptide. In addition to the circulating renin-angiotensin system, a local renin-angiotensin system is present in the zona glomerulosa cell. This local system also appears to be involved in the regulation of aldosterone production. The mechanism by which angiotensin II stimulates the adrenal zona glomerulosa cell is described in some detail. Angiotensin II interacts with the angiotensin receptor (AT1) membrane receptor that is coupled to cellular second messengers. Specific AT1 receptor antagonists are now clinically used to block angiotensin II's action on various target organs, including the adrenal gland.     

The PI3K/AKT/mTOR Signaling Pathway Is Overactivated in Primary Aldosteronism

Background

To date, the available non-invasive remedies for primary aldosteronism are not satisfactory in clinical practice. The phosphoinositide 3-kinase (PI3Ks)/protein kinase B (PKB or AKT)/mammalian target of rapamycin (mTOR) signaling pathway is essential for tumorigenesis and metastasis in many types of human tumors, including renal cancer, adrenal carcinoma and pheochromocytoma. The possibility that this pathway is also necessary for the pathogenesis of primary aldosteronism has not yet been explored. To answer this question, we investigated the activity of the PI3K/AKT/mTOR signaling pathway in normal adrenal glands (NAGs), primary aldosteronism (PA) patients and NCI-H295R cells.

Methodology/Principal Findings

Between January 2005 and December 2011, we retrospectively reviewed the records of 45 patients with PA. We compared clinical characteristics (age, gender and biochemical data) and the expression of phospho-AKT (p-AKT), phospho-mTOR (p-mTOR), phospho-S6 (p-S6) and vascular endothelial growth factor (VEGF) by immunohistochemical staining and western blotting, analyzing 30 aldosterone-producing adenomas (APAs), 15 idiopathic hyperaldosteronism (IHA) tissues and 12 NAGs following nephrectomy for renal tumors (control group). Compared with the control group, most of the PA patients presented with polydipsia, polyuria, resistant hypertension, profound hypokalemia, hyperaldosteronemia and decreased plasma renin activity. Compared with normal zona glomerulosa, the levels of p-AKT, p-mTOR, p-S6 and VEGF were significantly upregulated in APA and IHA. No significant differences were found between APA and IHA in the expression of these proteins. Additionally, positive correlations existed between the plasma aldosterone levels and the expression of p-AKT and p-mTOR. In vitro studies showed that mTOR inhibitor rapamycin could inhibit cell proliferation in NCI-H295R cells in a dose- and time-dependent manner. Furthermore, this inhibitor also decreased aldosterone secretion.

Conclusions

Our data suggest that the PI3K/AKT/mTOR signaling pathway, which was overactivated in APA and IHA compared with normal zona glomerulosa, may mediate aldosterone hypersecretion and participate in the development of PA.     

The reciprocal pool model for the measurement of gluconeogenesis by use of [U-(13)C]glucose

The present study was designed to assess whether citrate stimulates aldosterone production by isolated bovine adrenal glomerulosa cells in vitro. When the cells were incubated with graded concentrations of citrate up to 4.0 mM, basal aldosterone production was significantly elevated, with a gradual reduction of extracellular ionized calcium concentration. Without citrate, however, adding increasing amounts of calcium chloride to a calcium-free medium did not reproduce the citrate's effect on basal aldosterone production. Genistein, an inhibitor of tyrosine kinases, inhibited the citrate (4 mM)-induced aldosterone production in a dose-dependent manner, with 89.8% of inhibition at a concentration of 10 microM. When the cells were exposed to citrate (4 mM) for 5, 10, and 30 min, tyrosine in Mr 105,000 endogenous protein was dominantly phosphorylated. This study demonstrates for the first time that citrate stimulates aldosterone production in bovine adrenal glomerulosa cells in vitro and also suggests a crucial involvement of protein tyrosine kinase in the steroidogenic action of citrate in the cells.     

Angiotensin II negatively modulates L-type calcium channels through a pertussis toxin-sensitive G protein in adrenal glomerulosa cells.

In bovine adrenal glomerulosa cells, angiotensin II and extracellular K+ stimulate aldosterone secretion in a calcium-dependent manner. In these cells, physiological concentrations of extracellular potassium activate both T-type (low threshold) and L-type (high threshold) voltage-operated calcium channels. Paradoxically, the cytosolic calcium response to 9 mM K+ is inhibited by angiotensin II. Because K+-induced calcium changes observed in the cytosol are almost exclusively due to L-type channel activity, we therefore studied the mechanisms of L-type channel regulation by angiotensin II. Using the patch-clamp method in its perforated patch configuration, we observed a marked inhibition (by 63%) of L-type barium currents in response to angiotensin II. This effect of the hormone was completely prevented by losartan, a specific antagonist of the AT1 receptor subtype. Moreover, this inhibition was strongly reduced when the cells were previously treated for 1 night with pertussis toxin. An effect of pertussis toxin was also observed on the modulation by angiotensin II of the K+ (9 mM)-induced cytosolic calcium response in fura-2-loaded cells, as well as on the angiotensin II-induced aldosterone secretion, at both low (3 mM) and high (9 mM) K+ concentrations. Finally, the expression of both Go and Gi proteins in bovine glomerulosa cells was detected by immunoblotting. Altogether, these results strongly suggest that in bovine glomerulosa cells, a pertussis toxin-sensitive G protein is involved in the inhibition of L-type channel activity induced by angiotensin II.     

An ultrastructural study of the adrenal cortex in Cushing's syndrome without and with hyperaldosteronism]

This paper reports ultrastructural comparision of the adrenal gland zones of a rare case of a combination from Cushing's syndrome and hyperaldosteronism with a pure Cushing's syndrom and with a normal human adrenal gland. Whilst between the zona glomerulosa of the normal adrenal gland and of the Cushing's syndrom there are no differences, the morphological state of the glomerulosa cells of the Cushing's syndrom in combination with hyperaldosteronism is interpreted as an inhibition of the activity of these cells. In the cells of the hyperplastic zona fasciculata of Cushing's syndrom in combination with hyperaldosteronism, there are no electronmicroscopical characteristics, who are morphological equivalent of the production of aldosterone. The abundant quantity of steroid producing organells in these cells point to a high function. The cells of the adenoma of Cushing's syndrom contain abundant vacuols of lipids, in which presumable are stored steroid hormones.     

Mild adrenal 3 beta-hydroxysteroid dehydrogenase deficiency with hyperaldosteronism

The patient was admitted to our hospital at 19 and again at 22-yr of age for hirsutism and hypertension. Her baseline and ACTH-stimulated plasma 17-hydroxy pregnenolone, dehydroepiandrosterone and dehydroepiandrosterone sulfate were increased whereas plasma 17-hydroxy progesterone and androstenedione were normal and responded poorly to ACTH. Plasma deoxycorticosterone, corticosterone and cortisol baseline levels were normal, and they responded normally to ACTH. The plasma aldosterone concentration (PAC) was always high and responded well to ACTH, angiotensin III and furosemide-upright stimulation. However, plasma renin activity (PRA) was normal or slightly high, and responded normally to furosemide-upright stimulation and fluorohydrocortisone suppression. Dexamethasone (2 mg/day) for 1-2 weeks suppressed the androgens, cortisol and corticosterone levels. PRA and PAC were suppressed temporally, but PRA returned to normal and PAC to be a high level after 2 weeks of dexamethasone administration. Blood pressure was also reduced temporally but returned to a high level after 2 weeks of dexamethasone. These results indicate that primary aldosteronism and dexamethasone-suppressible hyperaldosteronism were not likely to be present, and unknown aldosterone stimulating factors which potentiated the action of endogenous angiotensin II or ACTH might be responsible for the hyperaldosteronism in this patient. We conclude that this patient had a mild and non-salt losing 3 beta-HSD deficiency in the zona reticularis with normal fasciculata and high glomerulosa function.     

Aldosterone biosynthesis in mitochondria of isolated zones of adrenal cortex

An assumption that the aldosterone-synthesizing enzyme exists only in zona glomerulosa cells apparently contradicts our recent findings that a purified bovine adrenocortical cytochrome P-45011 beta catalyzes the aldosterone formation and the enzyme exists in both zones of the adrenal cortex. To gain more insight into the zone specificity of aldosterone production, the aldosterone-synthesizing activity of mitochondria prepared from the isolated zones of adrenal cortex of various animal species was investigated. The intact mitochondria from the bovine or porcine zonae fasciculata-reticularis could not produce aldosterone whereas those from the zona glomerulosa produced it at a significant rate. When the mitochondria from the zonae fasciculata-reticularis were solubilized by the addition of cholate, they produced aldosterone from corticosterone at a rate comparable to that of those from the zona glomerulosa. The presence of specific factor(s) in the zonae fasciculata-reticularis mitochondria inhibiting expression of the aldosterone synthetic activity is discussed. The mitochondria of the rat zonae fasciculata-reticularis could hardly catalyze aldosterone synthesis under the detergent-solubilized conditions, whereas those of the zona glomerulosa could. Immunoblot analysis revealed that the mitochondria of the zonae fasciculata-reticularis contained a protein of Mr 51,000 which was immunocrossreactive with a monoclonal antibody directed against P-45011 beta, whereas those of the zona glomerulosa contained two immunocrossreactive proteins of Mr 51,000 and 49,000. These results suggest that in the case of rat adrenal cortex, a specific aldosterone-synthesizing enzyme exists in the zona glomerulosa.     

Angiotensin-II-directed glomerulosa cell function in fetal adrenal cells

These studies were undertaken to examine the role of angiotensin II (A-II) in the regulation of adrenal glomerulosa cell differentiation. We were interested particularly in the ability of A-II to support aldosterone production in fetal adrenal cells. Many in vitro studies on acute A-II stimulation of aldosterone synthesis in adrenocortical cells have been documented. However, it is the long-term modification of steroid-metabolizing enzyme expression that leads to the formation and release of specific adrenal steroids. Herein, we used primary cultures of fetal bovine adrenal (FBA) cells to examine the effects of A-II on aldosterone production and the expression of aldosterone synthase cytochrome P450 (P450c18). A-II treatment caused the primary cultures to maintain glomerulosa cell functions. Cells treated for 3 days with A-II increased aldosterone production by 10-fold. A-II stimulation of aldosterone production occurred rapidly (within 30 min) and in a dose-dependent manner. In addition, A-II enhanced the activity of P450c18, the enzyme responsible for conversion of corticosterone to aldosterone. A-II also suppressed ACTH-promoted cortisol production, while increasing ACTH-stimulated release of aldosterone. It appears that these effects of chronic treatment with A-II were mediated through an A-II type 1 (AT₁) receptor since the AT₁ receptor antagonist, Dup753, blocked aldosterone production and the increased P450c18 activity. Receptor binding studies suggest that FBA cells possess approx. 110,000 AT₁ binding sites/cell with K_d = 1.8 × 10⁻⁹ M. Via AT₁ receptors, A-II was able to stimulate both inositol phosphates and cAMP production. The stimulation of cAMP production, however, was much less than seen following ACTH treatment. These data give support to the hypothesis that A-II is involved in the differentiation of fetal adrenal cells into glomerulosa cells. This process appears to be mediated through regulation of steroid-metabolizing enzyme expression and the activation of steroid production.     

Contrasting effects of sn-1,2-dioctanoyl glycerol as compared to other protein kinase C activators in adrenal glomerulosa cells

Angiotensin II acts on adrenal glomerulosa cells to induce the phospholipase C-mediated generation of inositol trisphosphate and sn-1,2-diacylglycerol as the major products of inositol phospholipid breakdown. This last product is known to activate protein kinase C, but its role in the action of angiotensin II on steroidogenesis has not been defined. We report herein that, in bovine adrenal glomerulosa cells, protein kinase C activators, such as phorbol 12,13-dibutyrate, 12-O-tetradecanoylphorbol-13-acetate, mezerein and sn 1,2 oleoyl acetoylglycerol, each failed to increase steroidogenesis. These results contrast with our recent report on the enhancement of aldosterone output by sn-1,2-dioctanoylglycerol (DiC8) [J. Steroid Biochem. 35 (1990) 19-33]. In addition, the difference between DiC8 and the other protein kinase activators was also observed in the pattern of 86Rb efflux from preloaded glomerulosa cells; only DiC8 mimicked the effect of angiotensin II on ion fluxes. Furthermore, staurosporine, a potent inhibitor of protein kinase C, was capable of amplifying the aldosterone output induced by a maximally effective concentration of DiC8 or angiotensin II. These data suggest that the effect of the cell permeant DiC8 on aldosterone biosynthesis either is not mediated by protein kinase C activation, or is mediated by a phorbol ester-insensitive isoenzyme of protein kinase C.     

The synthesis of aldosterone by the adrenal cortex. Two zones (fasciculata and glomerulosa) possess one enzyme for 11 beta-, 18-hydroxylation, and aldehyde synthesis

In order to establish the nature of the aldosterone synthetase activity in the adrenal cortex, we have used porcine adrenal, bovine adrenal cortex, highly purified bovine and porcine 11 beta-/18-hydroxylase, and antibodies raised against the latter enzyme. Mitochondria from two zones (glomerulosa and fasciculata) of the bovine cortex synthesize aldosterone, but those from glomerulosa are much more active than those from fasciculata. Partially purified (cholate-extracted plus ammonium sulfate-precipitated) extracts of mitochondria from the two zones are equally active in catalyzing all three steps in the conversion of 11-deoxycorticosterone to aldosterone. 18-Hydroxylase and aldehyde synthetase activities (18-hydroxycorticosterone----aldosterone) were completely precipitated from cholate extracts of mitochondria from bovine adrenal by antibodies to the pure porcine enzyme. No activity corresponding to any of the three steps in the conversion of 11-deoxycorticosterone to aldosterone was found in extramitochondrial fractions of the bovine cortex. Synthesis of aldosterone by the pure porcine enzyme was inhibited by antibodies to this enzyme and by metyrapone (an inhibitor of 11 beta-/18-hydroxylase). When fractions of porcine adrenal, resulting from purification of the enzyme from mitochondria, were exhaustively tested for any of the enzyme activities required for the synthesis of aldosterone, activity was found only in those fractions containing the 11 beta-/18-hydroxylase, i.e. no additional enzyme was discarded during the purification procedure. It is concluded that the only adrenocortical enzyme capable of synthesizing aldosterone in bovine and porcine adrenal is the well known 11 beta-hydroxylase, that the conversion of 18-hydroxycorticosterone to aldosterone is catalyzed by this cytochrome P-450, and that this step (aldehyde synthetase) requires the heme of the P-450 as demonstrated by the photochemical action spectrum.     

Differential redistribution of protein kinase C in human aldosteronoma cells and adjacent adrenal cells stimulated with ACTH and angiotensin II

We have examined protein kinase C activity and hormone secretion in aldosteronoma cells derived from adrenocortical glomerulosa cells and in adjacent adrenal cells containing adrenocortical fasciculata-reticularis cells. When aldosteronoma cells were stimulated with ACTH or angiotensin II, protein kinase C activity gradually decreased in cytosol whereas it increased in membrane. Coincident with the changes of protein kinase C activity, there was enhancement of secretion of aldosterone. On the other hand, incubation of adjacent adrenal fasciculata-reticularis cells with ACTH induced cortisol secretion and an increase in cytosolic protein kinase C activity, accompanied by a decrease in the enzyme activity in membrane. Upon stimulation with angiotensin II, adjacent adrenal fasciculata-reticularis cells did not secrete cortisol and no significant changes of protein kinase C activities were observed in either cytosolic or membrane fractions. These results indicate that both ACTH and angiotensin II stimulate aldosterone secretion and cause translocation of protein kinase C from cytosol to membranes in aldosteronoma cells, whereas, in fasciculata-reticularis cells, only ACTH stimulates cortisol secretion and this is associated with translocation of protein kinase C in the opposite direction, viz., from membrane to cytosol.