Ultrafast CTCF dynamics control cohesin barrier function

CCCTC-binding transcription factor (CTCF) and the cohesin complex shape the genome into loops and topologically associating domains (TADs), yet the mechanisms linking CTCF dynamic behavior to its function as a cohesin barrier remain unclear. Using integrated experimental and computational approaches, we demonstrate that individual CTCF-DNA complexes are intrinsically mobile over distances and timescales compatible with cohesin capture during loop extrusion, driven by the dynamic rearrangements of zinc finger (ZF) domains. Genome-wide single-molecule accessibility and sequencing analyses further reveal that these dynamics occur in cells. This intrinsic flexibility is modulated by DNA sequence, methylation, and nucleosome positioning, and enables a previously uncharacterized single-stranded DNA binding state. Through biochemical dissection of cohesin components, we find that a negative regulator of loop extrusion, PDS5, remodels ZF dynamics and imparts exceptional mechanical stability to CTCF on DNA. Our findings reveal that the conformational dynamics of a transcription factor constitute a fundamental regulatory property that bridges base pair-scale molecular motions to megabase-scale genome organization, offering a kinetic explanation for how CTCF establishes and regulates TAD boundaries.