Deeply hidden genome organization directly mediated by SATB1

Abstract

AbstractMammalian genomes are organized by multi-layered chromatin folding. Whether and how three-dimensional genome organization contributes to cell-type specific transcription remains unclear. Here we uncover genome architecture formed by specialized sequences, base-unpairing regions (BURs), bound to a nuclear architectural protein, SATB1. SATB1 regulates cell-type specific transcription that underlies changes in cellular phenotypes. We developed a modified ChIP-seq protocol that stringently purifies genomic DNA only with its directly-associated proteins and unmasked previously-hidden BURs as direct SATB1 targets genome-wide. These SATB1-bound BURs are mutually exclusive from CTCF binding sites, and SATB1 is dispensable for CTCF/cohesion-mediated topologically associated domains (TADs). Instead, BURs largely overlap with lamina associated domains (LADs), and the fraction of BURs tethered to the SATB1 protein network in the nuclear interior is cell type-dependent. Our results reveal TAD-independent chromatin folding mediated by BUR sequences which serve as genome architecture landmarks for direct targeting by cell type-specific gene regulator, SATB1.One-Sentence SummaryGenome-wide chromatin folding by direct tethering of base-unpairing regions to SATB1 nuclear architecture is unveiled.