Neuronal Hyperactivity in Neurons Derived from Individuals with Grey Matter Heterotopia
Periventricular heterotopia (PH), a common form of grey matter heterotopia associated with developmental delay and drug-resistant seizures, poses a challenge in understanding its neurophysiological basis. Human cerebral organoids (hCOs) derived from patients with causative mutations in FAT4 or DCHS1 mimic PH features. However, neuronal activity in these 3D models has not yet been investigated. Here, silicon probe recordings revealed exaggerated spontaneous spike activity in FAT4 and DCHS1 hCOs, suggesting functional changes in neuronal networks. Transcriptome and proteome analyses identified changes in gene ontology terms associated with neuronal morphology and synaptic function. Furthermore, patch-clamp recordings revealed a decreased spike threshold specifically in DCHS1 neurons, likely due to increased somatic voltage-gated sodium channels. Morphological reconstructions and immunostainings revealed greater morphological complexity of PH neurons and synaptic alterations contributing to hyperactivity, with morphological rescue observed in DCHS1 neurons by wild-type DCHS1 expression. Overall, we provide new comprehensive insights into the cellular changes underlying symptoms of grey matter heterotopia.