Investigation of ABCA4 Missense Variants and Potential Small Molecule Rescue in Retinal Organoids.

PURPOSE: ABCA4-related retinopathy is the most common monogenic eye disorder in the world and is currently untreatable. Missense variants in ABCA4 constitute ∼60% of causal ABCA4-related retinopathy variants, often resulting in misfolded or dysfunctional protein products. Despite their prevalence, the molecular mechanisms by which these missense mutations impair ABCA4 function are not fully understood, primarily due to limitations in suitable cellular models. In this study, we investigated the cellular and molecular consequences of ABCA4 missense variants using a human photoreceptor-like model system. METHODS: We used CRISPR/Cas9 technology to introduce two ABCA4 missense misfolding variants, T983A and R2077W, which are associated with ABCA4-associated retinopathy, into control induced pluripotent stem cells (iPSCs). The iPSCs were differentiated into retinal organoids, characterized and treated with small molecules. RESULTS: The expression level of ABCA4 missense proteins was reduced compared to WT ABCA4 suggesting the variants were degraded in a photoreceptor-like environment. The localization of the missense variants was also altered with negligible ABCA4 detectable in the retinal organoid outer segments compared to the isogenic control. Two small molecule compounds, AICAR and 4-PBA, previously identified as potential ABCA4 folding correctors in vitro, were tested for their ability to enhance ABCA4 traffic to the outer segment. The compounds did not appear to promote ABCA4 folding and traffic in photoreceptors and instead led to a decrease in ABCA4 transcript levels and protein. CONCLUSIONS: These data highlight that retinal organoids are an exquisite model to investigate pathogenic variants in ABCA4 and test small compounds for translation to the human retina.