Condensin reorganizes centromeric chromatin during mitotic entry into a bipartite structure stabilized by cohesin

Abstract The Structural Maintenance of Chromosomes (SMC) complexes cohesin and condensin establish the 3D organization of mitotic chromosomes 1–3 . Cohesin is essential to maintain sister chromatid pairing until anaphase onset 4 , while condensin is important for mitotic centromere structure and elastic resistance to spindle forces 5–8 . Both complexes are also important to form productive kinetochore-spindle attachments 6, 8, 9 . How condensin and cohesin work together to shape the mitotic centromere to ensure faithful chromosome segregation remains unclear. Here we show by super-resolution imaging, Capture-C analysis and polymer modeling that vertebrate centromeres are partitioned into two distinct condensin-dependent subdomains during mitosis. This bipartite sub-structure is found in human, mouse and chicken centromeres and also in human neocentromeres devoid of satellite repeats, and is therefore a fundamental feature of vertebrate centromere identity. Super-resolution imaging reveals that bipartite centromeres assemble bipartite kinetochores with each subdomain capable of binding a distinct microtubule bundle. Cohesin helps to link the centromere subdomains, limiting their separation in response to mitotic spindle forces. In its absence, separated bipartite kinetochores frequently engage in merotelic spindle attachments. Consistently, uncoupling of centromere subdomains is a common feature of lagging chromosomes in cancer cells. The two-domain structure of vertebrate regional centromeres described here incorporates architectural roles for both condensin and cohesin and may have implications for avoiding chromosomal instability in cancer cells.