Abstract-Liddle syndrome, an inherited form of hypertension, is caused by gain-of-function mutations in the epithelial Na + channel (ENaC), the principal mediator of Na + reabsorption in the kidney. Accordingly, the disease pathology was ascribed to a primary renal mechanism. Whether this is the sole responsible mechanism, however, remains uncertain as dysregulation of ENaC in other tissues may also be involved. Previous work indicates that ENaC in the vascular endothelium is crucial for the regulation of cellular mechanics and thus vascular function. The hormone aldosterone has been shown to concomitantly increase ENaC surface expression and stiffness of the cell cortex in vascular endothelial cells. The latter entails a reduced release of the vasodilator nitric oxide, which eventually leads to an increase in vascular tone and blood pressure. Using atomic force microscopy, we have found a direct correlation between ENaC surface expression and the formation of cortical stiffness in endothelial cells. Stable knockdown of αENaC in endothelial cells evoked a reduced channel surface density and a lower cortical stiffness compared with the mock control. In turn, an increased αENaC expression induced an elevated cortical stiffness. More importantly, using ex vivo preparations from a mouse model for Liddle syndrome, we show that this disorder evokes enhanced ENaC expression and increased cortical stiffness in vascular endothelial cells in situ. We conclude that ENaC in the vascular endothelium determines cellular
This review is focused on the expression and regulation of amiloride-sensitive sodium channels in the epithelial cells of the aldosterone-sensitive distal nephron (ENaC) and amiloride-sensitive sodium channel activity in vascular endothelial and smooth muscle cells. Guyton’s hypothesis stated that blood pressure control is critically dependent on vascular tone and fluid handling by the kidney. With the study of Mendelian forms of hypertension and their corresponding transgenic mouse models, the main components of the aldosterone- and angiotensin-dependent sodium transporters have been identified over the past 20 years. Proteolytic processing of the ENaC external domain, and inhibition by increased sodium concentrations are important features of the ENaC complexes expressed in the distal nephron. In contrast, amiloride-sensitive sodium channels expressed in the vascular system are activated by increased external sodium concentrations, resulting in changes in the mechanical properties and function of endothelial cells. Mechano-sensitivity and shear stress affect both epithelial and vascular sodium channel activity. The synergistic effects and complementary regulation of the epithelial and vascular systems are consistent with the Guytonian model of volume and blood pressure regulation, and may reflect sequential evolution of the two systems. The integration of vascular tone, renal perfusion and regulation of renal sodium reabsorption is the central underpinning of the Guytonian model. We summarize the recent evidence in this review that describes the central role of amiloride-sensitive sodium channels in the efferent (e.g., vascular) and afferent (e.g., epithelial) arms of this homeostatic system.
A ldosterone via the activation of the mineralocorticoid receptor (MR) is a main actor of renal sodium reabsorption and water homeostasis. Extra-renal effects of the mineralocorticoid pathway have now been characterized, especially in the cardiovascular system, opening on new dimensions of the aldosterone/MR pathway in physiology, pathophysiology, and diseases. In the cardiovascular system, mineralocorticoid signaling has been shown to play an important role in the progression of cardiovascular diseases (CVDs). Previous reports using transgenic mouse models or pharmacological approaches demonstrated adverse effects of aldosterone on cardiac remodeling and fibrosis, inflammation, and hypertension.1 These features are prevented by the pharmacological blockade of the MR. In humans, several clinical studies showed the beneficial effects of MR antagonism in addition to standard care, to reduce mortality and morbidity in patients with severe 2 or mild heart failure (HF) 3 or after acute myocardial infarction. 4 Understanding the molecular mechanisms of mineralocorticoid activation pathway in cardiovascular pathophysiology remains incomplete. Indeed, a better knowledge of the underlying mechanisms may highlight novel mediators of the MR signaling cascade. These newly identified intermediates could be good candidates as biotargets for novel pharmacological approaches, especially in diseases where the aldosterone/MR pathway is involved. Moreover, these biotargets may as well be considered as potent biomarkers of MR activation, Abstract-Activation of the mineralocorticoid receptor has been shown to be deleterious in cardiovascular diseases (CVDs).We have recently shown that lipocalin 2 (Lcn2), or neutrophil gelatinase-associated lipocalin (NGAL), is a primary target of aldosterone/mineralocorticoid receptor in the cardiovascular system. Lcn2 is a circulating protein, which binds matrix metalloproteinase 9 and modulates its stability. We hypothesized that Lcn2 could be a mediator of aldosterone/ mineralocorticoid receptor profibrotic effects in the cardiovascular system. Correlations between aldosterone and profibrotic markers, such as procollagen type I N-terminal peptide, were investigated in healthy subjects and subjects with abdominal obesity. The implication of Lcn2 in the mineralocorticoid pathway was studied using Lcn2 knockout mice subjected to a nephrectomy/aldosterone/salt (NAS) challenge for 4 weeks. In human subjects, NGAL/matrix metalloproteinase 9 was positively correlated with plasma aldosterone and fibrosis biomarkers. In mice, loss of Lcn2 prevented the NAS-induced increase of plasma procollagen type I N-terminal peptide, as well as the increase of collagen fibers deposition and collagen I expression in the coronary vessels and the aorta. The lack of Lcn2 also blunted the NAS-induced increase in systolic blood pressure. Ex vivo, treatment of human fibroblasts with recombinant Lcn2 induced the expression of collagen I and the profibrotic galectin-3 and cardiotrophin-1 molecules. allowing a better selectio...
The Epithelial Sodium Channel (ENaC) is a key player in renal sodium homeostasis. The expression of α β γ ENaC subunits has also been described in the endothelium and vascular smooth muscle, suggesting a role in vascular function. We recently demonstrated that endothelial ENaC is involved in aldosterone-modulated endothelial stiffness. Here we explore the functional role of the endothelial αENaC subunit in vascular function in vivo. Compared to littermates, mice with conditional αENaC subunit gene inactivation in the endothelium only (endo-αENaC Knock Out mice) had no difference in their physiological parameters such as systolic blood pressure or heart rate. Acute and long-term renal Na+ handlings were not affected, indicating that endothelial αENaC subunit is not involved in renal sodium balance. Pharmacological inhibition of ENaC with benzamil blunted acetylcholine-induced nitric oxide production in mesenteric arteries from wild type mice but not in endo-αENaC KO mice, suggesting a critical role of endothelial ENaC in agonist-induced nitric oxide production. In endo-αENaC KO mice, compensatory mechanisms occurred and steady state vascular function was not altered except for flow-mediated dilation. Our data suggest that endothelial αENaC contributes to vascular endothelial function in vivo.
Inappropriate mineralocorticoid receptor (MR) activation is involved in cardiac diseases. Whether and how aldosterone is involved in the deleterious effects of cardiac mineralocorticoid activation is still unclear. Mice overexpressing MR in cardiomyocytes and their controls were treated for 7 days with aldosterone, and cardiac transcriptome was analyzed. Aldosterone regulated 265 genes in cardiomyocyte-targeted MR overexpression mice. Forty three of these genes were also differentially expressed between untreated cardiomyocyte-targeted MR overexpression and controls mice, thus representing putative aldosterone-regulated genes in cardiomyocytes. Among these genes, we focused on connective tissue growth factor (CTGF). In vivo, in cardiomyocyte-targeted MR overexpression mice, aldosterone (but not corticosterone) induced CTGF expression (mRNA and protein) in cardiomyocytes. Ex vivo, aldosterone induced the binding of mineralocorticoid receptor to CTGF promoter and increased the expression of its transcript. Aldosterone induction of CTGF synthesis in cardiomyocytes seems pathologically relevant as the increase in CTGF observed in a model of heart failure (transverse aortic constriction) in rats was prevented by eplerenone, a mineralocorticoid receptor blocker. This study demonstrates that aldosterone specifically regulates gene expression in cardiomyocytes despite large prevalence of glucocorticoids in plasma.
Diabetic nephropathy is a leading cause of end-stage kidney failure. Reduced angiopoietin-TIE2 receptor tyrosine kinase signaling in the vasculature leads to increased vascular permeability, inflammation, and endothelial cell loss and is associated with the development of diabetic complications. Here, we identified a mechanism to explain how TIE2 signaling is attenuated in diabetic animals. Expression of vascular endothelial protein tyrosine phosphatase VE-PTP (also known as PTPRB), which dephosphorylates TIE2, is robustly up-regulated in the renal microvasculature of diabetic rodents, thereby reducing TIE2 activity. Increased VE-PTP expression was dependent on hypoxia-inducible factor transcriptional activity in vivo. Genetic deletion of VE-PTP restored TIE2 activity independent of ligand availability and protected kidney structure and function in a mouse model of severe diabetic nephropathy. Mechanistically, inhibition of VE-PTP activated endothelial nitric oxide synthase and led to nuclear exclusion of the FOXO1 transcription factor, reducing expression of pro-inflammatory and pro-fibrotic gene targets. In sum, we identify inhibition of VE-PTP as a promising therapeutic target to protect the kidney from diabetic injury.
The role of epithelial sodium channel (ENaC) activity in the regulation of endothelial function is not clear. Here, we analyze the role of ENaC in the regulation of endothelium-dependent vasodilation and endothelial permeability in vivo in mice with conditional αENaC subunit gene inactivation in the endothelium (endo-αENaCKO mice) using unique MRI-based analysis of acetylcholine-, flow-mediated dilation and vascular permeability. Mice were challenged or not with lipopolysaccharide (LPS, from Salmonella typhosa, 10 mg/kg, i.p.). In addition, changes in vascular permeability in ex vivo organs were analyzed by Evans Blue assay, while changes in vascular permeability in perfused mesenteric artery were determined by a FITC-dextran-based assay. In basal conditions, Ach-induced response was completely lost, flow-induced vasodilation was inhibited approximately by half but endothelial permeability was not changed in endo-αENaCKO vs. control mice. In LPS-treated mice, both Ach- and flow-induced vasodilation was more severely impaired in endo-αENaCKO vs. control mice. There was also a dramatic increase in permeability in lungs, brain and isolated vessels as evidenced by in vivo and ex vivo analysis in endotoxemic endo-αENaCKO vs. control mice. The impaired endothelial function in endotoxemia in endo-αENaCKO was associated with a decrease of lectin and CD31 endothelial staining in the lung as compared with control mice. In conclusion, the activity of endothelial ENaC in vivo contributes to endothelial-dependent vasodilation in the physiological conditions and the preservation of endothelial barrier integrity in endotoxemia.
Aldosterone binds to the mineralocorticoid receptor (MR) and exerts pleiotropic effects beyond enhancing renal sodium reabsorption. Excessive mineralocorticoid signaling is deleterious during the evolution of cardiac failure, as evidenced by the benefits provided by adding MR antagonists (MRA) to standard care in humans. In animal models of cardiovascular diseases, MRA reduce cardiac fibrosis. Interestingly diuretics such as torasemide also appear efficient to improve cardiovascular morbidity and mortality, through several mechanisms. Among them, it has been suggested that torasemide could block aldosterone binding to the MR. To evaluate whether torasemide acts as a MRA in cardiomyocytes, we compared its effects with a classic MRA such as spironolactone. We monitored ligand-induced nuclear translocation of MR-GFP and MR transactivation activity in the cardiac-like cell line H9C2 using a reporter gene assay and known endogenous aldosterone-regulated cardiac genes. Torasemide did not modify MR nuclear translocation. Aldosterone-induced MR transactivation activity was reduced by the MRA spironolactone, not by torasemide. Spironolactone blocked the induction by aldosterone of endogenous MR-responsive genes (Sgk-1, PAI-1, Orosomucoid-1, Rgs-2, Serpina-3, Tenascin-X), while torasemide was ineffective. These results show that torasemide is not an MR antagonist; its association with MRA in heart failure may however be beneficial, through actions on complementary pathways.
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