Establishment of chromatin architecture interplays with embryo hypertranscription

After fertilization, early embryos undergo dissolution of conventional chromatin organization including topologically associating domains (TADs). Zygotic genome activation then commences amid unusually slow de novo establishment of three-dimensional chromatin architecture. How chromatin organization is established and how it interplays with transcription in early mammalian embryos remain elusive. Here we show that CTCF occupies chromatin throughout mouse early development. By contrast, cohesin poorly binds chromatin in one-cell embryos, coinciding with TAD dissolution. Cohesin binding then progressively increases from two- to eight-cell embryos, accompanying TAD establishment. Unexpectedly, strong 'genic cohesin islands' (GCIs) emerge across gene bodies of active genes in this period. GCI genes enrich for cell identity and regulatory genes, exhibit broad H3K4me3 at promoters, and display strong binding of transcription factors and the cohesin loader NIPBL at nearby enhancers. We show that transcription is hyperactive in two- to eight-cell embryos and is required for GCI formation. Conversely, induced transcription can also create GCIs. Finally, GCIs can function as insulation boundaries and form contact domains with nearby CTCF sites, promoting both the transcription levels and stability of GCI genes. These data reveal a hypertranscription state in early embryos that both shapes and is fostered by the three-dimensional genome organization, revealing an intimate interplay between chromatin structure and transcription. Overall design: Examination of CTCF/Cohesin binding dynamics and 3D genome structures in mouse early embryos following transcription inhibition/cohesin KD/ADNP KO