PGC‐1a inhibition promotes autophagy in induced pluripotent stem cell‐derived retinal pigment epithelial cells generated from age‐related macular degeneration patients

Abstract

Aims/Purpose: Dysfunctional protein clearance, oxidative stress, mitochondrial damage, and chronic inflammation cause retinal pigment epithelial (RPE) cell damage and the development of age‐related macular degeneration (AMD). PGC‐1α can alleviate oxidative stress, is a key player in mitochondrial quality control and could be considered as a treatment target in AMD. Here, we assessed the effect of PGC‐1α inhibition on induced pluripotent stem cell (iPSC)‐derived RPE cells exposed to hydroquinone‐induced oxidative stress.Methods: iPSC‐derived RPE cells from two neovascular AMD patients or one healthy age‐matched control were cultured for 8 weeks on transwell cell culture inserts until mature. Cells were exposed to the PGC‐1α inhibitor SR‐18292 for 1 h before an exposure to hydroquinone for an additional 4 h. Lactate dehydrogenase (LDH) was measured from collected medium samples to assess cellular viability. Cells were lysed in 3x Laemmli sample buffer for analysis by western blotting or subjected to RNA extraction, followed by RT‐PCR analysis.Results: Hydroquinone caused a robust increase in LDH release to the medium, which was not modulated by PGC‐1α inhibition. In neovascular AMD‐derived iPSC‐RPE cells, hydroquinone caused an accumulation of p62 and LC3‐II, an effect that was reversed by SR‐18292 pre‐treatment. In control iPSC‐RPE cells, neither hydroquinone nor SR‐18292 affected autophagic markers p62 or LC3. RT‐PCR analysis showed an increase in p62 mRNA levels following hydroquinone exposure in both control‐ and AMD‐derived iPSC‐RPE cells while no change was observed in the RNA levels of LC3B or mTOR.Conclusions: Increased oxidative stress caused autophagy dysregulation in AMD‐derived iPSC‐RPE cells but not in healthy age‐matched control cells. Interestingly, PGC‐1α inhibition promoted autophagy and the clearance of p62, but further studies are necessary to explore the underlying pathways and the disease‐specific differences observed between healthy and disease‐derived RPE cells.