Oligodendroglial hypothesis of autism: the primary role of master regulator gene Baf155 [ChIP-Seq]

Autism spectrum disorders (ASD) are polyetiological neurodevelopmental disorders associated with both genetic and non-genetic risk factors with complex and heterogeneous clinical manifestations. A single susceptibility gene usually fails in triggering an intricate array of autistic symptoms, suggesting a primary mechanism may be required to integrate multiple susceptibility genes in casing the disease. Recent evidence highlights the role of myeline disruption in pathogenesis of ASD. However, neither the mechanisms of impaired myelination nor its contribution to ASD symptomatology are fully characterized. We demonstrate the loss of Baf155, a newly recognized autistic susceptibility gene that encodes a core member of the chromatin remodeling complex, affects oligodendroglial differentiation and myelination. BAF155 targets multiple synapse-related genes in oligodendrocyte precursor cells (OPCs), these genes being responsible for regulating the synaptic communication between OPCs and neurons. Heterogeneous target genes affected by BAF155 deficiency in OPCs across various brain regions leads to significant impairments in myelination which may contribute to the diverse manifestations observed ASD patients. Taken together, our findings reveal a primary mechanism that orchestrates multiple ASD susceptibility genes in instigating the disease. Overall design: ChIP-seq technology is used to determine BAF155 binding sites in primary oligodendrocyte precursor cell (OPC) culture on day 1 and day 5 during differentiation.