Mineralocorticoid receptor interaction with SP1 generates a new response element for pathophysiologically relevant gene expression.

The mineralocorticoid receptor (MR) is a ligand-induced transcription factor belonging to the steroid receptor family and involved in water-electrolyte homeostasis, blood pressure regulation, inflammation and fibrosis in the renocardiovascular system. The MR shares a common hormone-response-element with the glucocorticoid receptor but nevertheless elicits MR-specific effects including enhanced epidermal growth factor receptor (EGFR) expression via unknown mechanisms. The EGFR is a receptor tyrosine kinase that leads to activation of MAP kinases, but that can also function as a signal transducer for other signaling pathways. In the present study, we mechanistically investigate the interaction between a newly discovered MR- but not glucocorticoid receptor- responsive-element (=MRE1) of the EGFR promoter, specificity protein 1 (SP1) and MR to gain general insights into MR-specificity. Biological relevance of the interaction for EGFR expression and consequently for different signaling pathways in general is demonstrated in human, rat and murine vascular smooth muscle cells and cells of EGFR knockout mice. A genome-wide promoter search for identical binding regions followed by quantitative PCR validation suggests that the identified MR-SP1-MRE1 interaction might be applicable to other genes. Overall, a novel principle of MR-specific gene expression is explored that applies to the pathophysiologically relevant expression of the EGFR and potentially also to other genes.

The mineralocorticoid receptor leads to increased expression of EGFR and T-type calcium channels that support HL-1 cell hypertrophy.

The EGF receptor (EGFR) has been extensively studied in tumor biology and recently a role in cardiovascular pathophysiology was suggested. The mineralocorticoid receptor (MR) is an important effector of the renin-angiotensin-aldosterone-system and elicits pathophysiological effects in the cardiovascular system; however, the underlying molecular mechanisms are unclear. Our aim was to investigate the importance of EGFR for MR-mediated cardiovascular pathophysiology because MR is known to induce EGFR expression. We identified a SNP within the EGFR promoter that modulates MR-induced EGFR expression. In RNA-sequencing and qPCR experiments in heart tissue of EGFR KO and WT mice, changes in EGFR abundance led to differential expression of cardiac ion channels, especially of the T-type calcium channel CACNA1H. Accordingly, CACNA1H expression was increased in WT mice after in vivo MR activation by aldosterone but not in respective EGFR KO mice. Aldosterone- and EGF-responsiveness of CACNA1H expression was confirmed in HL-1 cells by Western blot and by measuring peak current density of T-type calcium channels. Aldosterone-induced CACNA1H protein expression could be abrogated by the EGFR inhibitor AG1478. Furthermore, inhibition of T-type calcium channels with mibefradil or ML218 reduced diameter, volume and BNP levels in HL-1 cells. In conclusion the MR regulates EGFR and CACNA1H expression, which has an effect on HL-1 cell diameter, and the extent of this regulation seems to depend on the SNP-216 (G/T) genotype. This suggests that the EGFR may be an intermediate for MR-mediated cardiovascular changes and that SNP analysis can help identify subgroups of patients that will benefit most from MR antagonists.

Modulation of transcriptional mineralocorticoid receptor activity by nitrosative stress.

The mineralocorticoid receptor (MR) plays an important role in salt and water homeostasis and pathological tissue modifications, such as cardiovascular and renal fibrosis. Importantly, MR activation by aldosterone per se is not sufficient for the deleterious effects but requires the additional presence of a certain pathological milieu. Phenomenologically, this milieu could be generated by enhanced nitrosative stress. However, little is known regarding the modulation of MR transcriptional activity in a pathological milieu. The glucocorticoid receptor (GR), the closest relative of the MR, binds to the same hormone-response element but elicits protective effects on the cardiovascular system. To investigate the possible modulation of MR and GR by nitrosative stress under controlled conditions we used human embryonic kidney (HEK) cells and measured MR and GR transactivation after stimulation with the nitric oxide (NO)-donor SNAP and the peroxynitrite-donor Sin-1. In the presence of corticosteroids NO led to a general reduced corticosteroid receptor activity by repression of corticosteroid receptor-DNA interaction. The NO-induced diminished transcriptional MR activity was most pronounced during stimulation with physiological aldosterone concentrations, suggesting that NO treatment prevented its pathophysiological overactivation. In contrast, single peroxynitrite administration specifically induced the MR transactivation activity whereas genomic GR activity remained unchanged. Mechanistically, peroxynitrite permitted nuclear MR translocation whereas the cytosolic GR distribution was unaffected. Consequently, peroxynitrite represents a MR-specific aldosterone mimetic. In summary, our data indicate that the genomic function of corticosteroid receptors can be modulated by nitrosative stress which may induce the shift from physiological toward pathophysiological MR effects.