Abstract
Podocyte injury is a characteristic feature of focal segmental glomerulosclerosis (FSGS) that leads to the development of nephrosis as its loss causes proteinuria and progressive glomerulosclerosis. The physiological function of podocytes is critically dependent on proper intracellular calcium levels; an excess or shortage of calcium influx in these cells may result in foot process effacement, apoptosis, and nephron degeneration. A key protein responsible for the regulation of calcium flux is the canonical transient receptor potential 6 (TRPC6) expressed in podocytes. Several mutations in the TRPC6 gene have been associated with FSGS. Here we present a systematically optimized inducible FSGS model system in human induced pluripotent stem cells (hiPSCs). We generated and phenotypically characterized three transgenic hiPSC lines with regulatable overexpression of TRPC6 wild-type and FSGS-associated gain-of-function (GoF, P112Q) and loss-of-function (LoF, G757D) mutations. Moreover, these cell lines were differentiated into induced podocytes (ipodocytes). We assessed the impact of TRPC6 GoF and LoF mutants on calcium influx in combination with TRPC6 agonists and antagonists. Our data showed relative calcium responses consistent with the GoF and LoF phenotypes. Transgenic iPSC-based models, like the one presented here, are instrumental to studying disease mechanisms in vitro and investigating the outcomes of, and possible therapeutic interventions for, this complex disease.