Retinoic acid drives cell fate specification, maturation and retinal regionality in human retinal organoids.
Benjamin Y Lim, Carissa Chen, Anna Fredericks, Elham Nilli, Santiago Mesa Mora, Megan Weatherstone, To Ha Loi, Peter Newman, Nader Aryamanesh, Hala Zreiqat, Patrick Tam, Pengyi Yang, Anai Gonzalez-Cordero
Abstract
Retinoic acid (RA) is a key morphogen in human retinal development, activating transcriptional programs that drive retinal progenitor differentiation and photoreceptor development, ensuring proper spatial organisation within the neural retina, essential for vision. Despite its well-established role in retinal patterning, the concentration-dependent effects of RA on human retinal cell fate specification and the regional definition of the primate macula and peripheral retina remain poorly understood. Here, we show that temporal and dosage-dependant modulation of RA during human retinal organoid differentiation induces distinct changes in retinal cell abundance, maturation, and organisation. Single-cell transcriptomics and protein analysis reveal that RA dosage influences the relative abundance and maturation of photoreceptors and retinal interneurons. Spatial transcriptomics analyses demonstrates that low RA levels biases retinal organoids toward a macular-like regional identity, whereas high RA levels promotes peripheral-like development. Collectively, our findings emphasise the critical role of RA signalling in retinal maturation and regional specification. This study elucidates mechanisms involved in human retinal development and we anticipate that controlled RA modulation in retinal organoids provides a strategy to refine disease modelling of inherited retinal disorders and enhance the specific generation of photoreceptors suitable for transplantation and regenerative therapies.