Dynamics of the 4D genome during in vivo lineage specification and differentiation.

Mammalian gene expression patterns are controlled by regulatory elements, which interact within topologically associating domains (TADs). The relationship between activation of regulatory elements, formation of structural chromatin interactions and gene expression during development is unclear. Here, we present Tiled-C, a low-input chromosome conformation capture (3C) technique. We use this approach to study chromatin architecture at high spatial and temporal resolution through in vivo mouse erythroid differentiation. Integrated analysis of chromatin accessibility and single-cell expression data shows that regulatory elements gradually become accessible within pre-existing TADs during early differentiation. This is followed by structural re-organization within the TAD and formation of specific contacts between enhancers and promoters. Our high-resolution data show that these enhancer-promoter interactions are not established prior to gene expression, but formed gradually during differentiation, concomitant with progressive upregulation of gene activity. Together, these results provide new insight into the close, interdependent relationship between chromatin architecture and gene regulation during development. The relationship between regulatory elements, chromatin interactions and gene expression during development remains poorly understood. Here the authors present Tiled-C, a low-input 3C approach to study genome architecture at high resolution, and apply it to mouse erythroid differentiation in vivo, finding that enhancer-promoter interactions are formed gradually during differentiation, concomitant with progressive upregulation of gene activity.