Apparent mineralocorticoid excess, pseudohypoaldosteronism, and urinary electrolyte excretion: toward a redefinition of mineralocorticoid action

Patients with apparent mineralocorticoid excess (AME) have low or absent activity of the enzyme 11 beta OH steroid dehydrogenase (11SD), and inappropriately high intrarenal levels of cortisol resulting in Na+ retention and hypertension. Pseudohypoaldosteronism (PHA), in contrast, is characterized by salt wasting despite hyperaldosteronemia, reflecting low or absent mineralocorticoid receptors (MR). Although AME is presumed to reflect inappropriate cortisol occupancy of MR, several features also suggest inappropriate occupancy of glucocorticoid receptors (GR). To test this possibility, we administered carbenoxolone, which is known to block 11SD, to four patients with PHA, and observed marked mineralocorticoid effects, e.g., antinatriuresis and elevated plasma bicarbonate. To further test the possibility that occupancy of renal GR may induce a classical mineralocorticoid response, we administered the highly specific glucocorticoid RU 28362 to adrenalectomized rats and showed that it has profound antinatriuretic effects. Finally, by selectively blocking MR with RU 28318 or GR with RU 38486, we have shown that corticosterone, the physiologic glucocorticoid in rats, has an antinatriuretic effect in adrenalectomized rats via either MR or GR occupancy. Previous studies have clearly shown that MR are inherently nonselective and have equivalent intrinsic affinity for aldosterone, corticosterone, and cortisol. The present studies suggest that this nonselectivity includes the nuclear response element to which either MR or GR may bind to elicit a mineralocorticoid effect, and further underscore the importance of the enzyme 11SD in the specific mineralocorticoid action of aldosterone.     

The role of 11β-hydroxysteroid dehydrogenase type 2 in human hypertension

Cortisol and aldosterone have the same in vitro affinity for the mineralocorticoid receptor (MR), although in vivo only aldosterone acts as a physiologic agonist of the MR, despite circulating levels of cortisol in humans and corticosterone in rodents being three orders of magnitude higher than aldosterone levels. In mineralocorticoid target organs the enzyme 11β-hydroxysteroid dehydrogenase type 2 (11βHSD2) inactivates 11-hydroxy steroids, to their inactive keto-forms, thus protecting the nonselective MR from activation by glucocorticoids. The gene is highly expressed in all sodium-transporting epithelia, particularly in the kidney and colon, but also in human placenta and vascular wall. Mutations in the HSD11B2 gene cause a rare monogenic juvenile hypertensive syndrome called apparent mineralocorticoid excess (AME). In AME, compromised 11βHSD2 enzyme activity results in activation of the MR by cortisol, causing sodium retention, hypokalaemia, and salt-dependent hypertension. Whereas mutations or inhibition of 11βHSD2 by licorice have been clearly shown to produce a congenital or acquired syndrome of mineralocorticoid excess, the questions remaining are the extent to which subtle abnormalities in MR/11βHSD2 mechanisms may contribute to essential hypertension. Studies in patients with essential hypertension showed a prolonged half-life of cortisol and an increased ratio of urinary cortisol to cortisone metabolites, suggesting a deficient 11βHSD2 activity. These abnormalities may be genetically determined, as suggested by the association of a microsatellite flanking the HSD11B2 gene with hypertension in black patients with end-stage kidney disease and with salt sensitivity of blood pressure in healthy subjects. These findings indicate that variants of the HSD11B2 gene may contribute to the enhanced blood pressure response to salt and possibly to hypertension in humans.     

Glucocorticoid metabolism by 11-beta hydroxysteroid dehydrogenase type 2 modulates human mineralocorticoid receptor transactivation activity

The mineralocorticoid receptor (MR) binds aldosterone, but also glucocorticoid hormones (corticosterone in rodents, cortisol in humans), which largely prevail in the plasma. To prevent permanent and maximal occupancy of MR by glucocorticoid hormones in aldosterone-target cells, specific effects of aldosterone require metabolism of glucocorticoid hormones into 11-dehydroderivatives by 11-beta hydroxysteroid dehydrogenase (11-HSD2). We analyzed the effect of corticosterone or 11-dehydrocorticosterone (11-DHC) on the transactivation activity of the MR, transiently expressed in a new renal cell line expressing 11-HSD2. We show that, because of its metabolism by 11-HSD2, corticosterone is a poor activator of MR transactivation, except at micromolar concentrations, where the enzyme is saturated. We also show that high micromolar concentrations of 11 DHC are required to activate the MR. The weak antagonist property of 11-DHC on aldosterone-induced hMR transactivations is also documented. Such partial agonist activity of 11-DHC is discussed in the light of its positioning in a three-dimensional model of the MR ligand-binding domain.     

NAD(P)H oxidase inhibitor prevents blood pressure elevation and cardiovascular hypertrophy in aldosterone-infused rats

Increased bioavailability of reactive oxygen species (ROS) has been implicated in the pathogenesis of mineralocorticoid hypertension. To find out the source of ROS, we evaluated the role of NAD(P)H oxidase in blood pressure (BP) elevation, cardiovascular hypertrophy, and fibrosis in aldosterone-salt rats. Aldosterone infusion (0.75 microg/h) significantly increased BP, which is attenuated by apocynin (1.5 mmol/L). Cardiac hypertrophy developed by aldosterone infusion was also normalized with apocynin. Greater mRNA for p22phox and NAD(P)H oxidase activity (more than twofold) in aorta of aldosterone-infused rats was reduced in apocynin-treated rats. Aldosterone infusion increased marginally procollagen I and III expression in LV compared to controls and apocynin decreased procollagen. Masson's Trichrome stain showed increased cardiac perivascular fibrosis, which was reduced by apocynin. These results suggest that NAD(P)H oxidase plays an important role in cardiovascular damage associated with mineralocorticoid hypertension.     

RALES, EPHESUS and redox

In RALES, low doses of the mineralocorticoid receptor (MR) antagonist spironolactone, added to standard of care for severe heart failure, improved survival by 30% and lowered hospitalization by 35%. Animal studies with the selective MR antagonist eplerenone have similarly shown MR blockade to prevent the cerebral, renal and coronary vascular inflammatory response to elevated aldosterone levels. There is now general acceptance that aldosterone concentrations inappropriate for salt status have major deleterious effects on the cardiovascular system.

In many instances, however (e.g. Randomized Aldactone Evaluation Study (RALES), EPHESUS) aldosterone levels are normal and salt status unremarkable and yet MR blockade has unquestioned benefits. In these instances, there is increasing evidence that coronary and cardiac MR are activated by normal circulating cortisol levels, in the cellular context of generation of reactive oxygen species (ROS) and/or alteration in intracellular redox status.

MR in VSMC and cardiomyocytes are normally predominantly occupied by cortisol in tonic inhibitory mode. Blockade of 11β hydroxysteroid dehydrogenase type II (11βHSD2) or ROS generation both serve to activate cortisol–MR complexes, thus mimicking the effects of mineralocorticoid/salt imbalance on blood vessels and the heart. In RALES and EPHESUS, it is likely that the antagonists are blocking normal levels of cortisol, not aldosterone, from activating MR in the context of tissue damage and ROS generation. If this is the case, MR antagonists may be of wide therapeutic potential in cardiovascular disease and not confined to those characterized by aldosterone/salt excess. Finally, the pathophysiologic roles of always-occupied MR in ‘unprotected’ tissues such as cardiomyocytes or neurons in response to altered intracellular redox status remain to be explored.     

Tissue localization of 11 beta-hydroxysteroid dehydrogenase and its relationship to the glucocorticoid receptor.

11 beta-Hydroxysteroid dehydrogenase (11 beta-HSD) dictates specificity for the mineralocorticoid receptor (MR) by converting the active steroid cortisol to cortisone in man (corticosterone to 11-dehydrocorticosterone in rodents), leaving aldosterone to occupy the MR. However cortisol is the principal circulating glucocorticoid in man and 11 beta-HSD, distributed in a tissue specific fashion, may represent a powerful mechanism in regulating exposure of active steroid to the glucocorticoid receptor (GR). A detailed localization study of 11 beta-HSD gene expression and activity in numerous rat tissues has been performed and compared with the presence of GR mRNA. 11 beta-HSD mRNA (1.4 kB) measured by hybridization to a cDNA derived from hepatic 11 beta-HSD, and enzyme activity, measured by percentage conversion of [3H]corticosterone to [3H]11-dehydrocorticosterone by tissue homogenate, was widespread, present in all tissues studied except spleen, brain cortex and heart. There was a close correlation between tissue 11 beta-HSD mRNA levels and activity (r = 0.91, P less than 0.001) suggesting pretranslational regulation of the enzyme at a tissue level. There was also close co-localization of GR mRNA (7 kB), measured by hybridization to a rat GR cRNA probe, and enzyme mRNA/activity in every tissue studied except heart and brain cortex in which GR mRNA was found. In the mineralocorticoid target tissues kidney and colon, additional 11 beta-HSD mRNA bands were seen (kidney 1.8 kB, colon 3.4 kB), suggesting the presence of multiple dehydrogenase species. 11 beta-HSD is widely distributed and suitably placed to modulate ligand occupancy of the GR. The possibility of multiple dehydrogenase species in mineralocorticoid target tissues is consistent with the hypothesis that the ubiquitous 'native' 1.4 kB hepatic enzyme regulates the GR, and these separate dehydrogenases regulate the MR.     

Identification of ligand-selective peptide antagonists of the mineralocorticoid receptor using phage display

The mineralocorticoid receptor (MR) is a member of the nuclear receptor superfamily. Pathological activation of the MR causes cardiac fibrosis and heart failure, but clinical use of MR antagonists is limited by the renal side effect of hyperkalemia. The glucocorticoid cortisol binds the MR with equivalent affinity to that of the mineralocorticoids aldosterone and deoxycorticosterone. In nonepithelial tissues, including the myocardium, which do not express the cortisol-inactivating enzyme 11β hydroxysteroid dehydrogenase 2, cortisol has been implicated in the activation of MR. The mechanisms for ligand- and tissue-specific actions of the MR are undefined. Over the past decade, it has become clear that coregulator proteins are critical for nuclear receptor-mediated gene expression. A subset of these coregulators may confer specificity to MR-mediated responses. To evaluate whether different physiological ligands can induce distinct MR conformations that underlie differential coregulator recruitment and ligand-specific gene regulation, we utilized phage display technology to screen 10(8) 19mer peptides for their interaction with the MR in the presence of agonist ligands. We identified ligand-selective MR-interacting peptides that acted as potent antagonists of MR-mediated transactivation. This represents a novel mechanism of MR antagonism that may be manipulated in the rational design of a ligand- or tissue-selective MR modulator to treat diseases like heart failure without side effects such as hyperkalemia.     

The Mineralocorticoid Receptor Promotes Fibrotic Remodeling in Atrial Fibrillation

We studied the role of the mineralocorticoid receptor (MR) in the signaling that promotes atrial fibrosis. Left atrial myocardium of patients with atrial fibrillation (AF) exhibited 4-fold increased hydroxyproline content compared with patients in sinus rhythm. Expression of MR was similar, as was 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2), which also increased. 11β-HSD2 converts cortisol to receptor-inactive metabolites allowing aldosterone occupancy of MR. 11β-HSD2 was up-regulated by arrhythmic pacing in cultured cardiomyocytes and in a mouse model of spontaneous AF (RacET). In cardiomyocytes, aldosterone induced connective tissue growth factor (CTGF) in the absence but not in the presence of cortisol. Hydroxyproline expression was increased in cardiac fibroblasts exposed to conditioned medium from aldosterone-treated cardiomyocytes but not from cardiomyocytes treated with both cortisol and aldosterone. Aldosterone increased connective tissue growth factor and hydroxyproline expression in cardiac fibroblasts, which were prevented by BR-4628, a dihydropyridine-derived selective MR antagonist, and by spironolactone. Aldosterone activated RhoA GTPase. Rho kinase inhibition by Y-27632 prevented CTGF and hydroxyproline, whereas the RhoA activator CN03 increased CTGF expression. Aldosterone and CTGF increased lysyl oxidase, and aldosterone enhanced miR-21 expression. MR antagonists reduced the aldosterone but not the CTGF effect. In conclusion, MR signaling promoted fibrotic remodeling. Increased expression of 11β-HSD2 during AF leads to up-regulation of collagen and pro-fibrotic mediators by aldosterone, specifically RhoA activity as well as CTGF, lysyl oxidase, and microRNA-21 expression. The MR antagonists BR-4628 and spironolactone prevent these alterations. MR inhibition may, therefore, represent a potential pharmacologic target for the prevention of fibrotic remodeling of the atrial myocardium.     

Central infusion of aldosterone synthase inhibitor prevents sympathetic hyperactivity and hypertension by central Na+ in Wistar rats

In Wistar rats, increasing cerebrospinal fluid (CSF) Na+ concentration ([Na+]) by intracerebroventricular (ICV) infusion of hypertonic saline causes sympathetic hyperactivity and hypertension that can be prevented by blockade of brain mineralocorticoid receptors (MR). To assess the role of aldosterone produced locally in the brain in the activation of MR in the central nervous system (CNS), Wistar rats were infused ICV with artificial CSF (aCSF), Na+ -rich (800 mmol/l) aCSF, aCSF plus the aldosterone synthase inhibitor FAD286 (100 microg x kg(-1) x day(-1)), or Na+ -rich aCSF plus FAD286. After 2 wk of infusion, rats treated with Na+ -rich aCSF exhibited significant increases in aldosterone and corticosterone content in the hypothalamus but not in the hippocampus, as well as increases in resting blood pressure (BP) and sympathoexcitatory responses to air stress, and impairment of arterial baroreflex function. Concomitant ICV infusion of FAD286 prevented the Na+ -induced increase in hypothalamic aldosterone but not corticosterone and prevented most of the increases in resting BP and sympathoexcitatory and pressor responses to air stress and the baroreflex impairment. FAD286 had no effects in rats infused with ICV aCSF. In another set of rats, 24-h BP and heart rate were recorded via telemetry before and during a 14-day ICV infusion of Na+ -rich aCSF with or without FAD286. Na+ -rich aCSF without FAD286 caused sustained increases ( approximately 10 mmHg) in resting mean arterial pressure that were absent in the rats treated with FAD286. These data suggest that in Wistar rats, an increase in CSF [Na+] may increase the biosynthesis of corticosterone and aldosterone in the hypothalamus, and mainly aldosterone activates MR in the CNS leading to sympathetic hyperactivity and hypertension.     

Mineralocorticoid receptors: Emerging complexity and functional diversity

Mineralocorticoid receptor (MR) activation in renal epithelial cells in response to the binding of aldosterone has long been implicated in the maintenance of body salt and fluid homeostasis and blood pressure control. 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2) is believed to confer specificity on aldosterone to activate MR by inactivating 11β-hydroxyglucocorticoids (corticosterone, cortisol) that are 100-1000 times more abundant in plasma than aldosterone and that can also bind and activate MR. Increasing evidence, however, challenges such a simple view of MR activation as well as its interaction with glucocorticoids and 11β-HSDs. In non-epithelial tissues including brain, cardiomyocytes and macrophages, 11β-hydroxyglucocorticoids seem to act as MR antagonists, and redox changes and signaling events may play pivotal roles for receptor activation in these tissues. This review addresses the emerging new view of the complex mechanisms underlying MR specificity of action, with a diversity of physiological roles and functions in different mineralocorticoid-responsive tissues.     

Mineralocorticoids act centrally to regulate blood-borne tumor necrosis factor-alpha in normal rats

Excessive mineralocorticoid receptor (MR) stimulation induces neurohumoral excitation and cardiac and vascular fibrosis. In heart failure (HF) rats, with excessive neurohumoral drive, central infusion of the MR antagonist spironolactone (SL) decreases blood-borne TNF-alpha. This study aimed to determine whether DOCA, a precursor of aldosterone, acts centrally to stimulate TNF-alpha production in normal rats. DOCA (5 mg sc daily for 8 days) induced a progressive increase in TNF-alpha beginning on day 3 and increased tissue TNF-alpha in hypothalamus, pituitary, and heart but not in other brain and peripheral tissues harvested on day 9. A continuous intracerebroventricular infusion of SL (100 ng/h) blocked the plasma TNF-alpha response. Oral SL (1 mg/kg) blocked the plasma and tissue TNF-alpha responses. Thus DOCA increases TNF-alpha in brain, heart, and blood in normal rats. Activation of brain MR appears to account for the increase in plasma TNF-alpha. These findings have important implications for the understanding of pathophysiological states (e.g., HF, hypertension) characterized by high circulating levels of aldosterone.     

The epidermal growth factor receptor is involved in angiotensin II but not aldosterone/salt-induced cardiac remodelling

Experimental and clinical studies have shown that aldosterone/mineralocorticoid receptor (MR) activation has deleterious effects in the cardiovascular system; however, the signalling pathways involved in the pathophysiological effects of aldosterone/MR in vivo are not fully understood. Several in vitro studies suggest that Epidermal Growth Factor Receptor (EGFR) plays a role in the cardiovascular effects of aldosterone. This hypothesis remains to be demonstrated in vivo. To investigate this question, we analyzed the molecular and functional consequences of aldosterone exposure in a transgenic mouse model with constitutive cardiomyocyte-specific overexpression of a mutant EGFR acting as a dominant negative protein (DN-EGFR). As previously reported, Angiotensin II-mediated cardiac remodelling was prevented in DN-EGFR mice. However, when chronic MR activation was induced by aldosterone-salt-uninephrectomy, cardiac hypertrophy was similar between control littermates and DN-EGFR. In the same way, mRNA expression of markers of cardiac remodelling such as ANF, BNF or β-Myosin Heavy Chain as well as Collagen 1a and 3a was similarly induced in DN-EGFR mice and their CT littermates. Our findings confirm the role of EGFR in AngII mediated cardiac hypertrophy, and highlight that EGFR is not involved in vivo in the damaging effects of aldosterone on cardiac function and remodelling.     

Renal 11-beta-hydroxysteroid dehydrogenase: a mechanism ensuring mineralocorticoid specificity

In vitro studies with mineralocorticoid receptors (MR) have shown that they are non-specific and do not distinguish between glucocorticoids (cortisol in man, corticosterone in rodents) and aldosterone. These findings contrast with in vivo aldosterone selectivity. Our studies on the congenital deficiency of the enzyme 11 beta-hydroxysteroid dehydrogenase (11 beta-OHSD; which converts cortisol to cortisone or corticosterone to 11-dehydrocorticosterone) and acquired deficiency secondary to liquorice or carbenoxolone indicate that this enzyme plays a crucial role in protecting the MR from glucocorticoid exposure. The localisation of 11 beta-OHSD in both the proximal and distal nephron suggests that it has both an autocrine and a paracrine role. The presence of this protective mechanism in the toad bladder suggests that it is at least 300 million years old.     

Elevated cardiac tissue level of aldosterone and mineralocorticoid receptor in diastolic heart failure: Beneficial effects of mineralocorticoid receptor blocker

Cardiac aldosterone levels have not been evaluated in diastolic heart failure (DHF), and its roles in this type of heart failure remain unclear. This study aimed to detect cardiac aldosterone by use of a liquid chromatographic-mass spectrometric method and to assess the effects of mineralocorticoid receptor blockade on hypertensive DHF. Dahl salt-sensitive rats fed 8% NaCl diet from 7 wk (hypertensive DHF model) were divided at 13 wk into three groups: those treated with subdepressor doses of eplerenone (12.5 or 40 mg x kg(-1) x day(-1)) and an untreated group. Dahl salt-sensitive rats fed 0.3% NaCl diet served as controls. Cardiac aldosterone was detected in the DHF rats but not in the control rats, with increased ventricular levels of mineralocorticoid receptor. Cardiac levels of 11-deoxycorticosterone, corticosterone, and 11-dehydrocorticosterone were not different between the control and DHF rats, but the tissue level of corticosterone that has an affinity to mineralocorticoid receptor was 1,000 times as high as that of aldosterone. Aldosterone synthase activity and CYP11B2 mRNA were undetectable in the ventricular tissue of the DHF rats. Administration of eplerenone attenuated ventricular hypertrophy, ventricular fibrosis, myocardial stiffening, and relaxation abnormality, leading to the prevention of overt DHF. In summary, the myocardial aldosterone level increased in the DHF rats. However, its value was extremely low compared with corticosterone, and no evidence for enhancement of intrinsic myocardial aldosterone production was found. The upregulation of mineralocorticoid receptor may play a central role in the pathogenesis of DHF, and blockade of mineralocorticoid receptor is likely an effective therapeutic regimen of DHF.     

Differential effects of mineralocorticoid blockade on the hypothalamo-pituitary-adrenal axis in pregnant and nonpregnant ewes

During pregnancy, plasma ACTH and cortisol are chronically increased; this appears to occur through a reset of hypothalamo-pituitary-adrenal (HPA) activity. We have hypothesized that differences in mineralocorticoid receptor activity in pregnancy may alter feedback inhibition of the HPA axis. We tested the effect of MR antagonism in pregnant and nonpregnant ewes infused for 4 h with saline or the MR antagonist canrenoate. Pregnancy significantly increased plasma ACTH, cortisol, angiotensin II, and aldosterone. Infusion of canrenoate increased plasma ACTH, cortisol, and aldosterone in both pregnant and nonpregnant ewes; however, the temporal pattern of these responses differed between these two reproductive states. In nonpregnant ewes, plasma ACTH and cortisol transiently increased at 1 h of infusion, whereas in pregnant ewes the levels gradually increased and were significantly elevated from 2 to 4 h of infusion. MR blockade increased plasma aldosterone from 2 to 4 h in the pregnant ewes but only at 4 h in the nonpregnant ewes. In both pregnant and nonpregnant ewes, the increase in plasma aldosterone was significantly related to the timing and magnitude of the increase in plasma potassium. The results indicate a differential effect of MR activity in pregnant and nonpregnant ewes and suggest that the slow changes in ACTH, cortisol, and aldosterone are likely to be related to blockade of MR effects in the kidney rather than to effects of MR blockade in hippocampus or hypothalamus.     

Aldosterone and the heart: from basic research to clinical evidence

Recent views suggest that long-term exposure to elevated aldosterone concentrations might result in cardiac, vascular, renal, and metabolic sequelae that occur independent of the blood pressure level. Indirect evidence of the untoward effects of aldosterone on the heart has been clearly established in clinical studies that have tested the effects of mineralocorticoid receptor antagonists in the treatment of systolic heart failure. As it has become clear in recent years, the interaction between aldosterone and the heart has to deal with additional actions of the hormone on specific cell types, cellular mechanisms, and molecules that are involved in regulation of tissue responses, leading to hypertrophy, remodeling, and fibrosis. The majority of these effects are mediated by activation of the mineralocorticoid receptors that are expressed in cardiomyocytes and cardiac fibroblasts, and mediate the genomic effects of the hormone. Evidence of interactions between aldosterone and the heart that occur independent of the renal effects of aldosterone, however, is not limited to the context of systolic heart failure and observations obtained in other disease states have led, together with findings of animal studies, to a better understanding of the potential benefits of aldosterone antagonists. In this narrative overview, we highlight the most recent findings that have been obtained in experimental animal models and in clinical conditions that include, in addition to systolic heart failure, primary aldosteronism, essential hypertension, diastolic heart failure, and arrhythmia.     

Molecular biology of 11β-hydroxylase and 11β-hydroxysteroid dehydrogenase enzymes

There are two steroid 11β-hydroxylase isozymes encoded by the CYP11B1 and CYP11B2 genes on human chromosome 8q. The first is expressed at high levels in the normal adrenal gland, has 11β-hydroxylase activity and is regulated by ACTH. Mutations in the corresponding gene cause congenital adrenal hyperplasia due to 11β-hydroxylase deficiency; thus, this isozyme is required for cortisol biosynthesis. The second isozyme is expressed at low levels in the normal adrenal gland but at higher levels in aldosterone-secreting tumors, and has 11β-hydroxylase, 18-hydroxylase and 18-oxidase activities. The corresponding gene is regulated by angiotensin II, and mutations in this gene are found in persons who are unable to synthesize aldosterone due to corticosterone methyloxidase II deficiency. Thus, this isozyme is required for aldosterone biosynthesis.

Cortisol and aldosterone are both effective ligands of the “mineralocorticoid” receptor in vitro, but only aldosterone is a potent mineralocorticoid in vivo. This apparent specificity occurs because 11β-hydroxysteroid dehydrogenase in the kidney converts cortisol to cortisone, which is not a ligand for the receptor. This enzyme is a “short-chain” dehydrogenase which is encoded by a single gene on human chromosome 1. It is possible that mutations in this gene cause a form of childhood hypertension called apparent mineralocorticoid excess, in which the mineralocorticoid receptor is not protected from high concentrations of cortisol.     

The role of progesterone metabolism and androgen synthesis in renal blood pressure regulation.

11beta-hydroxysteroid dehydrogenase type 2 (11beta-HSD2) plays a crucial role in converting hormonally active cortisol into inactive cortisone, conferring specificity onto the human mineralocorticoid receptor (MR). Progesterone binds with even higher affinity to the MR, but acts as an MR antagonist. How aldosterone is able to keep its function as predominant MR ligand in clinical situations with high progesterone concentrations, such as pregnancy, is not clear. We have shown in vitro that the human kidney possesses an effective enzyme system that metabolizes progesterone to inactive metabolites in a process similar to the inactivation of cortisol by 11beta-HSD2. In studies on patients with adrenal insufficiency, we have shown that the in vivo anti-mineralocorticoid activity of progesterone is diminished by inactivating metabolism of progesterone, local formation of the deoxycorticosterone mineralocorticoid from progesterone, and inhibition of 11beta-HSD2 by progesterone and its metabolites resulting in decreased inactivation of cortisol and hence increased MR binding by cortisol. The enzymes involved in progesterone metabolism are also responsible for the capability of the human kidney to convert pregnenolone to DHEA and androstenedione leading to the formation of active androgens, testosterone and 5alpha-DH-testosterone. Locally produced androgens might be responsible for the observed difference in blood pressure between men and women and higher susceptibility to hypertension in men.