Litcius/Paper detail

Forebrain assembloids support the development of fast-spiking human PVALB+ cortical interneurons and uncover schizophrenia-associated defects

Ryan Walsh, Gregg W. Crabtree, Kriti Kalpana, Luz Jubierre, So Yeon Koo, Gabriele Ciceri, Joseph A. Gogos, Ilya Kruglikov, Lorenz Studer

2025Neuron15 citationsDOIOpen Access PDF

Abstract

Disruption of parvalbumin positive (PVALB+) cortical interneurons is implicated in the pathogenesis of schizophrenia. However, how these defects emerge during development remains poorly understood. The protracted, postnatal maturation of PVALB+ cortical interneurons has complicated human pluripotent stem cell (hPSC)-based models for studying their role in neuropsychiatric disease. Here, we present a forebrain assembloid system yielding PVALB+ cortical interneurons that match the molecular identity and distinctive electrophysiology of primary PVALB+ interneurons. We further established a series of isogenic hPSC lines carrying structural variants associated with schizophrenia and identified variant-specific phenotypes affecting cortical interneuron migration, the molecular profile of PVALB+ cortical interneurons, and their ability to regulate cortical network activity, including γ-band oscillations. These findings offer plausible mechanisms for how the disruption of cortical interneuron development may impact schizophrenia risk and provide a human experimental platform to study PVALB+ cortical interneurons in health and disease.

Topics & Concepts

ForebrainNeuroscienceSchizophrenia (object-oriented programming)PsychologyBiologyHuman brainBrain developmentCommunicationPsychiatryCentral nervous systemReceptor Mechanisms and SignalingSingle-cell and spatial transcriptomicsCongenital heart defects research