Human cerebral organoids capture the spatiotemporal complexity and disease dynamics of UBE3A

Human neurodevelopment and its associated diseases are complex and challenging to study. This has driven recent excitement for human cerebral organoids (hCOs) as research and screening tools. These models are steadily proving their utility; however, it remains unclear what limits they will face in recapitulating the complexities of neurodevelopment and disease. Here we show that their utility extends to key (epi)genetic and disease processes that are complex in space and time. Specifically, hCOs capture UBE3A9s dynamically imprinted expression and subcellular localization patterns. Furthermore, given UBE3A9s direct links to Angelman Syndrome and Autism Spectrum Disorder, we show that hCOs respond to candidate small molecule therapeutics. This work demonstrates that hCOs can provide important insights to focus the scope of mechanistic and therapeutic strategies including revealing difficult to access prenatal developmental time windows and cell types key to disease etiology.