#417 Targeting parietal epithelial cell activation with mineralocorticoid receptor antagonism controls FSGS and crescentic glomerulonephritis

Abstract

Abstract Background and Aims We have recently demonstrated that targeting specific pathways in parietal epithelial cells (PEC) can markedly alleviate experimental extracapillary glomerular injury [1]. Accumulating evidence has indicated the potential contributions of the mineralocorticoid receptor (MR) to the pathophysiology of chronic kidney disease. MR is expressed in endothelial cells, glomerular mesangial cells, podocytes, and distal tubular cells. Previous studies have shown that administering mineralocorticoid receptor antagonists has beneficial effects in various renal injury animal models, the role of the MR in extracapillary glomerulopathies is still elusive and mechanistically unclear. Methods To investigate the cell-specific role of the MR in PEC in the course of focal segmental glomerulosclerosis (FSGS) and crescentic glomerulonephritis (GN), we generated chimeric mice specifically lacking MR (Pec Cre Nr3c2lox/lox) in PECs using an inducible Cre recombinase system. Maladaptive FSGS was induced by combining a high-salt diet and deoxycorticosterone acetate (DOCA) with unilateral nephrectomy (DOCA-UniN). Crescentic glomerulonephritis (GN) was induced using the anti-glomerular basement membrane nephrotoxic serum (NTS) model. Results At baseline, Pec Cre Nr3c2wt/wt and Pec Cre Nr3c2lox/lox mice displayed no kidney morphology and function differences. When challenged by DOCA-UniN, PEC-selective Nr3c2 targeting significantly inhibited the expression of PEC activation markers Ki67, CD44, and FSGS lesions. Importantly, Pec Cre Nr3c2lox/lox mice showed less albuminuria and preserved renal function compared to Pec Cre Nr3c2 wt/wt counterparts. Likewise, Pec Cre Nr3c2lox/lox mice showed less albuminuria and preserved renal function in the NTS-induced CGN model. Crescents were also more numerous and organised in Pec Cre Nr3c2wt/wt mice than in Pec Cre Nr3c2lox/lox animals. Next, we examined whether pharmacological MR inhibition could alleviate the severity of crescentic GN. When Pec Cre Nr3c2wt/wt mice were orally given eplerenone for 14 days after the onset of the crescentic GN, they were significantly protected from renal injury and failure (decreased proteinuria, normal BUN and reduced number of crescent). Such global action was associated with less expression of the CD44 activation marker on PECs. Thus, genetic disruption of MR in PEC and pharmacological inhibition using eplerenone reduced glomerular expression of CD44 and crescent formation. Furthermore, kidney biopsies of individuals diagnosed with crescentic glomerulonephritis displayed increased expression of MR in PEC within FSGS and crescents. We next evaluated PEC migration under various conditions (DMSO, HB-EGF, Eplerenone, or HB-EGF+Eplerenone) for 24 hours. Eplerenone fully abrogated HB-EGF-induced PEC migration and Pcna, Snai1, and Vim mRNA expressions. Conclusion Altogether, these results indicate the critical role of MR in PEC activation during crescentic glomerulonephritis, along with the recently discovered CD9/EGFR/PDGFR [1] and CLDN1 pathways. This further supports the idea that the PEC phenotype switch is not a bystander event but plays a targetable critical active pathogenic role in FGSS and, more surprisingly, in crescentic GN. MR modulation using eplerenone may be a new therapeutic option for the management of such severe disease.