Multiomics analysis reveals extensive epigenome remodeling during cortical development

Abstract Despite huge advances in stem-cell, single-cell and epigenetic technologies, the precise molecular mechanisms that determine lineage specification remain largely unknown. Applying an integrative multiomics approach, e.g. combining single-cell RNA-seq, single-cell ATAC-seq together with cell-type-specific DNA methylation and 3D genome measurements, we systematically map the regulatory landscape in the mouse neocortex in vivo. Our analysis identifies thousands of novel enhancer-gene pairs associated with dynamic changes in chromatin accessibility and gene expression along the differentiation trajectory. Crucially, we provide evidence that epigenetic remodeling generally precedes transcriptional activation, yet true priming appears limited to a subset of lineage-determining enhancers. Notably, we reveal considerable heterogeneity in both contact strength and dynamics of the generally cell-type-specific enhancer-promoter contacts. Finally, our work suggests a so far unrecognized function of several key transcription factors which act as putative “molecular bridges” and facilitate the dynamic reorganization of the chromatin landscape accompanying lineage specification in the brain.