Pleiotropic actions of aldosterone and the effects of eplerenone, a selective mineralocorticoid receptor antagonist.

Aldosterone plays an important role in the pathogenesis of cardiovascular and renal disease that is independent of angiotensin II. Mineralocorticoid receptors are expressed in nonepithelial tissues such as the heart and blood vessels. Although mineralocorticoid receptor antagonism reduces mortality in patients with congestive heart failure, the progestational and antiandrogenic side effects of the nonspecific mineralocorticoid receptor antagonist, spironolactone, have limited its usefulness in the treatment of cardiovascular diseases. This review examines the expanding role of aldosterone, including its broad spectrum of non-classical effects, and the recent clinical and experimental trials with the selective mineralocorticoid receptor antagonist, eplerenone.     

Mineralocorticoid receptors in vascular function and disease

The mineralocorticoid receptor (MR), a member of the steroid receptor family, regulates blood pressure by mediating the effects of the hormone aldosterone (Aldo) on renal sodium handling. Over the past decade, it has become clear that MR is expressed in the cardiovascular system and interest has grown in understanding the direct role of the MR in regulating vascular function and contributing to cardiovascular disease. This interest stems from multiple clinical studies in which drugs that decrease MR activation also reduce the incidence of heart attacks, strokes, and mortality out of proportion to modest changes in systemic blood pressure. The presence of functional mineralocorticoid receptors in vascular smooth muscle and endothelial cells is now well established and, while still controversial, data supports the vasculature as an Aldo-responsive tissue. This review summarizes recent advances in our understanding of the role of vascular MR in regulating normal vascular function and in promoting vascular disease. In vitro data, in vivo animal studies, and human data are reviewed suggesting a role for MR-activation in promoting vascular oxidative stress, inhibiting vascular relaxation, and contributing to vessel inflammation, fibrosis, and remodeling. These detrimental vascular effects of MR activation appear to be independent of changes in blood pressure and are synergistic with the presence of endothelial dysfunction or damage. Thus, in humans with underlying cardiovascular disease or cardiovascular risk factors, vascular MR activation may promote vascular aging and atherosclerosis thereby contributing to the pathophysiology of heart attack, stroke, and possibly even hypertension. Further exploration of the molecular mechanisms for the detrimental vascular effects of MR activation has the potential to identify novel therapeutic targets to prevent or treat common cardiovascular disorders.     

The new biology of aldosterone

Classically, aldosterone is synthesised in the adrenal zona glomerulosa and binds to specific mineralocorticoid receptors located in the cytosol of target epithelial cells. Translocation of the resulting steroid receptor complex to the cell nucleus modulates gene expression and translation of specific 'aldosterone-induced' proteins that regulate electrolyte and fluid balance. However, non-epithelial and rapid non-genomic actions of aldosterone have also been described that account for a variety of actions of aldosterone that contribute to blood pressure homeostasis. These include key actions on endothelial cells and on cardiac tissue. There is also evidence that aldosterone can be synthesised in other tissues; the most convincing evidence relates to the central nervous system. However, suggestions that aldosterone is produced in the heart remain controversial, and adrenal derived aldosterone is the principal source of circulating and locally available hormone. Recent studies have shown major therapeutic benefits of mineralocorticoid receptor antagonism in cardiac failure, which emphasise the importance of aldosterone in causing adverse cardiovascular pathophysiological effects. Additional evidence demonstrates that aldosterone levels predict development of high blood pressure in normotensive subjects, while it is now clear that increased aldosterone action contributes to hypertension and cardiovascular damage in approximately 10% of patients with established hypertension. These new findings highlight the role of aldosterone as a key cardiovascular hormone and extend our understanding of its role in determining adverse cardiovascular outcomes.     

Aldosterone: Role in the Cardiometabolic Syndrome and Resistant Hypertension

The prevalence of diabetes, hypertension, and cardiovascular disease (CVD) and chronic kidney disease (CKD) is increasing in concert with obesity. Insulin resistance, metabolic dyslipidemia, central obesity, albuminuria. and hypertension commonly cluster to comprise the cardiometabolic syndrome (CMS). Emerging evidence supports a shift in our understanding of the crucial role of elevated serum aldosterone in promoting insulin resistance and resistant hypertension. Aldosterone enhances tissue generation of oxygen free radicals and systemic inflammation. This increase in oxidative stress and inflammation, in turn, contributes to impaired insulin metabolic signaling, reduced endothelial-mediated vasorelaxation, and associated cardiovascular and renal structural and functional abnormalities. In this context, recent investigation indicates that hyperaldosteronism, which is often associated with obesity, contributes to impaired pancreatic β-cell function as well as diminished skeletal muscle insulin metabolic signaling. Accumulating evidence indicates that the cardiovascular and renal abnormalities associated with insulin resistance are mediated, in part, by aldosterone's nongenomic as well as genomic signaling through the mineralocorticoid receptor (MR). In the CMS, there are increased circulating levels of glucocorticoids, which can also activate MR signaling in cardiovascular, adipose, skeletal muscle, neuronal, and liver tissue. Furthermore, there is increasing evidence that fat tissue produces a lipid soluble factor that stimulates aldosterone production from the adrenal zona glomerulosa. Recently, we have learned that MR blockade improves pancreatic insulin release, insulin-mediated glucose utilization, and endothelium-dependent vasorelaxation as well as reduces the progression of CVD and CKD. In summary, aldosterone excess exerts detrimental metabolic effects that contribute to the development of the CMS and resistant hypertension as well as CVD and CKD.     

Aldosterone as a mediator in cardiovascular injury

The renin-angiotensin-aldosterone system plays a central role in the development of hypertension and the progression of end-organ damage. Although angiotensin-converting enzyme inhibitors and angiotensin II receptor antagonists can initially suppress plasma aldosterone, it is now well established that aldosterone escape may occur, whereby aldosterone levels return to or exceed baseline levels. The classic effects of aldosterone relate mainly to its action on epithelial cells to regulate water and electrolyte balance. However, blood pressure reduction or fluid loss could not account for the results of the Randomized Aldactone Evaluation Study, which showed that a low dose of spironolactone in addition to conventional therapy could decrease the overall risk of mortality by 30% among patients with severe congestive heart failure. The action of aldosterone at nonepithelial sites in the brain, heart, and vasculature is consistent with the presence of mineralocorticoid receptors in these tissues. Aldosterone has a number of deleterious effects on the cardiovascular system, including myocardial necrosis and fibrosis, vascular stiffening and injury, reduced fibrinolysis, endothelial dysfunction, catecholamine release, and production of cardiac arrhythmias. Several studies have now shown vascular and target-organ protective effects of aldosterone receptor antagonism in the absence of significant blood pressure lowering, consistent with a major role for endogenous mineralocorticoids as mediators of cardiovascular injury. The advent of selective aldosterone receptor antagonists such as eplerenone should prove of great therapeutic value in the prevention of cardiovascular disease and associated end-organ damage.     

Aldosterone and aldosterone antagonism in systemic hypertension

Aldosterone mediates both water and electrolyte balance by acting on the renal mineralocorticoid receptors. Recent experimental studies have also documented the presence of these receptors in other body organs, including the brain, blood vessels, and heart, suggesting that aldosterone plays a larger role in normal physiologic function and in cardiovascular diseases such as systemic hypertension and congestive heart failure (CHF). The nonspecific aldosterone inhibitor spironolactone, and the selective aldosterone inhibitor eplerenone, are both approved for clinical use in treating patients with hypertension and/or symptomatic CHF. Studies have shown that spironolactone lowers blood pressure, improves endothelial function, reduces myocardial hypertrophy and fibrosis, and lowers the incidence of fatal arrhythmias. Eplerenone, which is more specific for the mineralocorticoid receptor, appears to provide all the beneficial effects of spironolactone in hypertensive patients, with the potential to modify many of the side effects related to nonspecific steroidreceptor blockade. Hyperkalemia remains a potential problem with all aldosterone antagonists.     

Effect of Aldosterone and MR Blockade on the Brain and the Kidney

The renin-angiotensin-aldosterone system (RAAS) plays a central role in the development of hypertension and the progression of end-organ damage. Although angiotensin-I converting enzyme (ACE) inhibitors and angiotensin II (Ang II) subtype-1 (AT₁) receptor antagonists can initially suppress plasma aldosterone, it is now well established that aldosterone escape may occur whereby aldosterone levels return to, or exceed, baseline levels. The classical effects of aldosterone relate mainly to its action on epithelial cells to regulate water and electrolyte balance. However, the presence of mineralocorticoid receptors (MR) at nonepithelial sites in the brain, heart and vasculature, is consonant with the fact that aldosterone also has direct effects in these tissues. Substantial evidence now exists that supports the action of aldosterone at non-epithelial sites which in turn provokes a number of deleterious effects on the cardiovascular system including necrosis and fibrosis of the vasculature and the heart, vascular stiffening and injury, reduced fibrinolysis, endothelial dysfunction, catecholamine release and production of cardiac arrhythmias. Several studies have now shown that vascular and target-organ protective effects of MR antagonism occurs in the absence of significant blood pressure lowering or fluid loss, which is consistent with a major role for endogenous mineralocorticoids as direct mediators of cardiovascular injury. Adverse cardiovascular effects may occur in response to aldosterone alone, activation of the RAAS or aldosterone escape during chronic ACE inhibition or AT₁ receptor antagonism. The specific blockade of aldosterone action should prove to be of great therapeutic value in the prevention of cerebral and renal vascular disease and associated end-organ damage.     

Aldosterone as an endogenous cardiovascular toxin and the options for its therapeutic management

In physiological, as well as pathological situations, aldosterone significantly influences volume, pressure and electrolyte balance. Primary hyperaldosteronism is caused by autonomous over-production, most frequently due to adrenal adenoma. Patients with primary hyperaldosteronism (Conn's syndrome) have more pronounced left ventricular hypertrophy and higher frequency of cardiovascular events than patients with essential hypertension (EH) with comparable blood pressure values. Consequently, there is an increased interest in the role ofaldosterone tissue function in cardiovascular disease. The aim of the present paper is to emphasise the pleiotropic actions of aldosterone on cardiovascular system and the options for their therapeutic management. Apart from the effects of circulating aldosterone on BP and its renal actions on water and electrolyte excretion, extra-renal effects are also been explored; paracrine affects through tissue mineralocorticoid receptors (MR) may impact on endothelial dysfunction, vascular elasticity, inflammatory changes in the myocardium, vessels and kidneys. Initial oxidative stress due to increased aldosterone concentrations may initiate subclinical endothelial changes and subsequent myocardial fibrosis. The effects on all three layers of vascular wall, together with increased blood coagulation and vascular thrombogenicity increases likelihood of microthrombosis and tissue microinfarctions. Slight increase in aldosterone concentrations in cardiac tissue adversely affects myofibrils as well as coronary artery function. Similar to peripheral vessels, it increases collagen content and changes vascular rigidity and the velocity of pulse wave and facilitates development of perivascular fibrosis. Higher salt intake may potentiate these pathophysiological effects of aldosterone, while higher intake of potassium may restrict them. Aldosterone vasculopathy together with perivascular fibrosis occurring at aldosterone concentrations seen with heart failure contributes to manifestation of heart failure. Consequently, aldosterone may rightly be called "cardiovascular toxin". The adverse effects of aldosterone in patients on long-term ACEI therapy are further facilitated by the aldosterone's ability to evade inhibitory effects of ACEI and parallel activation of renin-angiotensin system. To manage these situations, receptors of mineralcorticoids or direct renin inhibitor aliskiren are used. The positive effect of MR blockade is based on an increased release of nitric oxide (NO) with further improvement in endothelial functions. Detailed review of pleotropic effects of aldosterone helps to clarify a number of pathophysiological situations in essential hypertension, supports the view ofaldosterone as a potential cardiovascular toxin and indicates the use of mineralocorticoid receptor blockers in resistant hypertension and patients with cardiovascular or renal organ damage.     

Aldosterone and aldosterone antagonism in cardiovascular disease: focus on eplerenone (Inspra)

Aldosterone has long been known to mediate water and electrolyte balance by acting on mineralocorticoid receptors in the kidneys. However, recent studies have demonstrated the presence of these receptors in nonclassical locations, including the brain, blood vessels, and the heart. This finding suggests that aldosterone may play a larger role than once appreciated in normal physiologic function and cardiovascular disease. Some of the adverse cardiovascular effects that have been described include cardiac and vascular fibrosis, left ventricular hypertrophy, congestive heart failure, hypertension, endothelial dysfunction, reduced fibrinolysis, and cardiac arrhythmias. In light of these findings, aldosterone receptor blockers have become increasingly more important. This is especially true considering the fact that traditional therapies, such as angiotensin-converting enzyme inhibitors and angiotensin II-receptor blockers, may not be effective in maintaining long-term suppression of aldosterone. Therefore, a great deal of focus has been placed on spironolactone, which has proven to be an effective, albeit nonselective, aldosterone receptor blocker. The Randomized Aldactone Evaluation Study has shown that spironolactone results in a 30% reduction in mortality among patients with severe congestive heart failure. Other studies have shown spironolactone to lower high blood pressure, improve endothelial dysfunction, reduce left ventricular hypertrophy, and lower the incidence of fatal arrhythmias. However, spironolactone, because of its interaction with other steroid receptors, is not without its limitations, which include gynecomastia, breast tenderness, menstrual irregularities, and impotence. As a result, eplerenone (INSPRA), a selective aldosterone blocker, is currently being investigated for its efficacy and side-effect profile compared with spironolactone. Eplerenone has already been approved for the treatment of systemic hypertension, and several clinical trials are currently underway to identify other therapeutic uses for this agent in cardiovascular disease management.     

Aldosterone as a cardiovascular risk hormone

The pathophysiological role of aldosterone in the development of cardiovascular disease has long been considered to be due its potent volume expansion/hypertensive effect mainly via mineralocorticoid receptor (MR) expressed in renal tubular epithelial cells. However, recent accumulating lines of evidence from clinical and experimental studies have suggested that direct cardiovascular effect of aldosterone contributes to the development of cardiovascular injury via MRs in non-epithelial tissue. A series of recent clinical studies have revealed that patients with primary aldosteronism have higher incidence of cardiovascular and renal complications than those with essential hypertension, and that aldosterone antagonism has cardiovascular protective effect in patients with heart failure independent from blood pressure. Numerous experimental studies have shown that both inflammation and oxidative stress play an initial and key role in the development of aldosterone-induced cardiovascular injury via non-epithelial MR activation. In this review, we discuss recent research progress in aldosterone and MR effects, with special emphasis on the pathophysiological role of aldosterone in cardiovascular diseases and the possible molecular mechanism(s) of cardiovascular injury by non-epithelial MR activation.     

Aldosterone in Heart Disease

Numerous studies have now shown that sustained elevation of aldosterone levels induces cardiovascular damage independent from its effects on regulation of renal sodium and blood pressure. Increased aldosterone and cortisol levels in patients with heart failure independently predict the risk of mortality. Over the past decade, there has been increased interest in identifying the role of the receptor for aldosterone, the mineralocorticoid receptor (MR), following the results from the large clinical heart failure trials that showed low doses of MR antagonists reduced morbidity and mortality in heart failure and myocardial infarction, even though plasma levels of aldosterone were in the physiologic range. The mechanism for this cardioprotective action remains to be defined, although changes in the redox state have been shown to play a key role in MR-mediated cardiac damage. This review will highlight some of these studies and provide an update on the action of aldosterone in heart disease.     

Mineralocorticoid receptors and pathophysiological roles for aldosterone in the cardiovascular system

For almost 40 years since its discovery in 1953, the mineralocorticoid hormone, aldosterone, was considered to affect blood volume, and thus blood pressure, by its action to retain sodium at epithelial tissues. Over the past decade, direct effects of aldosterone on the heart and blood vessels, and on the cerebral control of blood pressure, have been established in experimental animals. Simultaneously, the incidence of primary aldosteronism in essential hypertension is now acknowledged to be 10-20%, rather than 相似文献   

Interactions of high salt intake and the response of the cardiovascular system to aldosterone

High salt intake contributes to the risk of hypertension, and this effect is in part mediated by the physiologic action of aldosterone on renal mineralocorticoid receptors. However, the actions of aldosterone are not restricted to the kidneys, because aldosterone can bind to mineralocorticoid receptors in the heart, vasculature, and brain to produce structural and functional changes that lead to target organ damage. Experimental and clinical studies show that, in the setting of high salt intake, blocking aldosterone at the mineralocorticoid receptor reduces progression to target organ damage and preserves vascular function. In many cases, these benefits are independent of changes in blood pressure. Angiotensin-converting enzyme inhibitors and angiotensin receptor blockers have short-term effects on reducing aldosterone levels, but frequently aldosterone levels return to pretreatment levels during long-term therapy. Aldosterone blockade may be more completely achieved with mineralocorticoid receptor antagonists. Spironolactone has been shown to have substantial and significant benefits in experimental and clinical studies of cardiac dysfunction. Eplerenone is a selective aldosterone blocker with a greater binding affinity for mineralocorticoid receptors than for androgen and progesterone receptors. Eplerenone has similarly demonstrated significant benefits in experimental animals and in patients with left ventricular dysfunction after myocardial infarction. Thus, aldosterone blockade with mineralocorticoid receptor antagonists offers target organ protection and may blunt some of the adverse effects of chronic high salt intake.     

Eplerenone: A Selective Aldosterone Receptor Antagonist (SARA)

Aldosterone, the final product of the renin‐angiotensin‐aldosterone system (RAAS), is a mineralocorticoid hormone that classically acts, via the mineralocorticoid (aldosterone) receptor, on epithelia of the kidneys, colon, and sweat glands to maintain electrolyte homeostasis. Aldosterone has also been shown to act at nonepithelial sites where it can contribute to cardiovascular disease such as hypertension, stroke, malignant nephrosclerosis, cardiac fibrosis, ventricular hypertrophy, and myocardial necrosis. Although angiotensin‐converting enzyme (ACE) inhibitors and angiotensin type 1 (AT₁) receptor antagonists act to suppress the RAAS, these agents do not adequately control plasma aldosterone levels — a phenomenon termed “aldosterone synthesis escape.” Spironolactone, a nonselective aldosterone receptor antagonist, is an effective agent to suppress the actions of aldosterone; its use is, however, associated with progestational and antiandrogenic side effects due to its promiscuous binding to other steroid receptors. For these reasons, eplerenone — the first agent of a new class of drugs known as the selective aldosterone receptor antagonists (SARAs) — is under development. In rodent models, eplerenone provides marked protection against vascular injury in the kidney and heart. In phase II clinical trials, eplerenone demonstrates 24‐h control of blood pressure with once or twice daily dosing, and is safe and well tolerated in patients with heart failure when given with standard of care agents. Pharmacokinetic studies reveal that eplerenone has good bioavailability with low protein binding, good plasma exposure, and is highly metabolized to inactive metabolites and excreted principally in the bile. Eplerenone is well tolerated in acute and chronic safety pharmacology studies. Ongoing phase III trials of eplerenone in the treatment of hypertension and heart failure are underway. These studies will extend our understanding of selective aldosterone receptor antagonism in the treatment of chronic cardiovascular disease.     

Drug Insight: eplerenone, a mineralocorticoid-receptor antagonist

Increasing recognition of the role of aldosterone in cardiovascular disease has been supported by a significant body of evidence from animal models. This evidence has been translated into clinical practice, and large-scale, randomized, placebo-controlled trials have confirmed the beneficial effects of mineralocorticoid blockade in patients with heart failure. As a consequence, there has been a resurgence in the use of mineralocorticoid-receptor antagonists in clinical practice that has prompted the search for a potent and specific antagonist without the sexual side effects of spironolactone. Eplerenone, a mineralocorticoid-receptor antagonist with minimal binding to the progesterone and androgen receptors, is now licensed for treatment of heart failure in Europe and heart failure and hypertension in the US; it has also been proposed as a treatment for a variety of cardiovascular conditions. This article reviews the current concepts of the actions of aldosterone at a cellular level. Recent findings regarding its role as a cardiovascular hormone, both in animal models and human studies, are discussed. We also describe the development of mineralocorticoid-receptor blockers following the isolation of aldosterone and discuss the subsequent search for a specific mineralocorticoid antagonist. In addition we detail the effects of eplerenone in a number of clinical situations and outline its potential future applications.     

Minireview: aldosterone and the cardiovascular system: genomic and nongenomic effects

There is clear evidence for rapid nongenomic effects of aldosterone in the cardiovascular system in addition to its well characterized effects of unidirectional transepithelial sodium transport. Many of these effects are mediated by the classical mineralocorticoid receptors, although others may be exerted independently. Given that mineralocorticoid receptors are largely constitutively occupied but not activated by physiological glucocorticoids, effects of aldosterone administered in vitro or in vivo may or may not equate with true physiological mineralocorticoid roles. In many systems (e.g. blood pressure regulation and cardiac fibrosis), the time course of effects is such that it is not possible, and perhaps not important, to distinguish between rapid nongenomic and classical genomic effects in the context of homeostatic physiology.     

The use of aldosterone receptor blockers in the treatment of hypertension

The emerging role of aldosterone in hypertension and cardiovascular diseases has prompted a renewal of interest in therapeutic approaches designed to interfere with the action of this mineralocorticoid hormone. While spironolactone has long been used for this purpose, side effects, largely attributable to the interaction of this agent with non-mineralocorticoid steroid receptors, has reduced the enthusiasm for its use. Eplerenone, a specific aldosterone receptor blocker with a lower incidence of the sex hormone-related side effects than spironolactone, has been used in several recent clinical trials in hypertension and congestive heart failure. This review will highlight the major findings from these studies.     

Transgenic model of aldosterone-driven cardiac hypertrophy and heart failure

Aldosterone classically promotes unidirectional transepithelial sodium transport, thereby regulating blood volume and blood pressure. Recently, both clinical and experimental studies have suggested additional, direct roles for aldosterone in the cardiovascular system. To evaluate aldosterone activation of cardiomyocyte mineralocorticoid receptors, transgenic mice overexpressing 11beta-hydroxysteroid dehydrogenase type 2 in cardiomyocytes were generated using the mouse alpha-myosin heavy chain promoter. This enzyme converts glucocorticoids to receptor-inactive metabolites, allowing aldosterone occupancy of cardiomyocyte mineralocorticoid receptors. Transgenic mice were normotensive but spontaneously developed cardiac hypertrophy, fibrosis, and heart failure and died prematurely on a normal salt diet. Eplerenone, a selective aldosterone blocker, ameliorated this phenotype. These studies confirm the deleterious consequences of inappropriate activation of cardiomyocyte mineralocorticoid receptors by aldosterone and reveal a tonic inhibitory role of glucocorticoids in preventing such outcomes under physiological conditions. In addition, these data support the hypothesis that aldosterone blockade may provide additional therapeutic benefit in the treatment of heart failure.