TCF4 trinucleotide repeat expansions and UV irradiation are associated with ferroptosis susceptibility in Fuchs endothelial corneal dystrophy

Abstract

ABSTRACTFuchs endothelial corneal dystrophy (FECD), a progressive polygenic disease that causes degeneration of the corneal endothelium, is the leading indication for corneal transplantation in the U.S. Characteristically, loss of corneal endothelial cells and formation of degenerative extracellular “guttae” result in failure to maintain appropriate corneal hydration through active ion pumping to counter the passive leakage of aqueous humor. FECD pathogenesis is linked to oxidative stress and environmental exposure to ultraviolet A (UVA), and impaired endogenous response to oxidative stress is common to the disease across multiple genotypes. UV irradiation is also known to cause cellular damage by ferroptosis, a nonapoptotic oxidative cell death resulting from iron-mediated lipid peroxidation. Although a possible role for ferroptosis in FECD has been postulated to account for the increased susceptibility to oxidative damage and lipid peroxidation, this has not been explored systematically. In this study, we investigated the roles of genetic background and UVA exposure in causing lipid membrane damage and endothelial cell degeneration in FECD. We first sought clinical evidence of iron-mediated lipid peroxidation in surgical samples obtained from FECD patients undergoing endothelial keratoplasty, and found increased levels of cytosolic ferrous iron (Fe2+) and evidence of lipid peroxidation were present in end-stage diseased tissues compared with healthy human donor corneas. Next, using immortalized (F35T) and primary cell cultures modeling the TCF4 intronic trinucleotide repeat expansion genotype, we found that alterations in gene and protein expression involved in ferroptosis were conserved in both cell culture and tissue models of FECD disease compared to controls, including elevated levels of the ferroptosis-specific marker transferrin receptor 1. F35T immortalized cells showed significantly higher basal lipid peroxidation than control HCEC-B4G12 cells, indicating higher susceptibility to ferroptosis attributable to genetic background. Then, we tested the impact of physiologically relevant doses of UVA irradiation on F35T cell cultures and found increased cytosolic Fe2+ iron levels indicating a role for ferroptosis in FECD disease progression. Finally, we tested the effects of inhibitory ferroptosis molecules. We found that F35T cells were more prone to RSL3 induced ferroptosis than healthy controls with deferoxamine chelation which indicated increased susceptibility in FECD cells, and cell death could be prevented after experimentally-induced ferroptosis using solubilized antioxidant ubiquinol indicating a role for anti-ferroptosis therapies. This investigation demonstrates that FECD genetic background and UVA exposure contribute to basal and incidental iron-mediated lipid peroxidation and cell death in FECD, and provides the basis for future investigations of ferroptosis-mediated oxidative damage and disease progression in FECD.