Crescentic glomerulonephritis (CGN) and focal segmental glomerulosclerosis (FSGS) are life-threatening diseases leading to irreversible renal failure. Increasing evidence supports the notion that glomerular parietal epithelial cells (PEC) are implicated in the formation of crescents in CGN and in glomerular scarring during FSGS. However, the mechanisms underlying the change in PEC phenotype remain unclear, as do those driving their oriented migration towards the glomerular tuft and their increased capacity to proliferate and form hypercellular and sclerotic lesions.

Aiming to identify factors underlying PEC activation, we revealed increased expression of CD9 using comparative deep RNA sequencing of mouse and human normal and diseased glomeruli, confirmed expression by immunohistochemistry, and investigated roles of this tetraspanin in CGN and FSGS pathogeny. As CD9 de novo expression in glomeruli was observed in PEC in human CGN and FSGS and, given the recognized role of PEC in the progression of extracapillary lesions, we generated mice with a specific Cd9 deletion in PEC (iPec-Cd9lox/lox mice) that were challenged in experimental CGN and FSGS models. Cd9 gene knock-down were performed in a PEC line to evaluate its influence on migration, spreading and proliferation.

During the CGN model, iPec-Cd9wt/wt control mice showed a rapid increase in albuminuria, renal failure and severe glomerular crescentic lesions. Conversely, iPec-Cd9lox/lox mice displayed marked renal protection. We challenged iPec-Cd9lox/lox mice with the DOCA-salt and unilateral nephrectomy FSGS model. Glomerular ultrastructure and function was preserved in iPec-Cd9lox/lox DOCA mice, whereas iPec-Cd9wt/wt DOCA mice exhibited flocculo-capsular synechiae and sclerosis. In vitro, we found that CD9 deficiency impairs the ability of PECs to proliferate and to migrate towards a steep gradient of chemoattractant in microfluidic channels.

These results indicate that de novo expression of CD9 in PECs participates in crescents in experimental CGN and is also critically involved in the development of glomerular lesions in FSGS.