Conformational asymmetry of replicated human chromosomes

DNA replication creates two sister chromatids that must acquire specific three-dimensional conformations to support genome function and stability. This organization is largely mediated by cohesin complexes, which extrude intra-chromosomal loops and link two chromatids, thus forming “chromatid cohesion”. Although sister chromatids are genetically identical, the replication process is intrinsically asymmetric: each chromatid inherits a different parental DNA strand, while the new strands are synthesized using distinct “leading” and “lagging” mechanisms of the replication fork. Whether and how this molecular asymmetry impacts higher-order chromatin organization remains unknown. Using sister-chromatid-sensitive Hi-C, strand-specific FISH, and polymer modeling, we reveal a consistent, genome-wide shift in sister chromatid alignment, biased along the 5′-3′ direction of the inherited strands. This shift persists without loop extrusion but is lost upon disruption of cohesion, implicating cohesive cohesins in maintaining the displacement. Polymer simulations indicate that a modest (∼100 kb) misalignment of “cohesive” cohesins is responsible for the observed asymmetry. We propose two mechanistic models that explain how this displacement arises from replication fork asymmetry: either through the dislocation of cohesin during replication or through the asymmetric anchoring and subsequent random sliding of cohesin pairs. These findings reveal a previously unrecognized chromosome-scale asymmetry in sister chromatid organization, which has implications for homology search during DNA repair.