Defining Cis-regulatory Elements and Transcription Factors that Control Human Cortical Interneuron Development

Although human cortical interneurons are a minority population in the cerebral cortex, disruption of interneuron development is a frequent contributor to neurodevelopmental disorders. Here, we utilized a model for deriving cortical interneurons from human embryonic stem cells to profile chromatin state changes and generate an atlas of cis-regulatory elements controlling human cortical interneuron development. We used these data to define candidate transcription factors that may bind these cis-regulatory elements to regulate interneuron progenitor specification. Among these were RFX3 and RFX4, risk genes for autism spectrum disorder with uncharacterized roles in human neuronal development. Using RFX3 and RFX4 knockdown models, we demonstrated new requirements for both genes in interneuron progenitor specification, with RFX3 deficiency causing precocious neuronal differentiation while RFX4 deficiency instead resulted in cessation of progenitor cell proliferation. Together, this work both defined central features of cis-regulatory control and identified new transcription factor requirements for human interneuron development.