Abstract

Summary The focal attachment of the kinetochore to the centromere is essential for genome maintenance, yet the highly repetitive nature of satellite regional centromeres, such as those in humans, limits our understanding of their chromatin organization. We demonstrate that single-molecule chromatin fiber sequencing (Fiber-seq) can uniquely co-resolve kinetochore and surrounding chromatin architectures along point centromeres, revealing largely homogeneous single-molecule kinetochore occupancy along each chromosome. In contrast, extension of Fiber-seq to regional satellite centromeres exposed marked per-molecule heterogeneity in their chromatin organization. Regional CENP-A-marked centromere cores uniquely contain a dichotomous chromatin organization (dichromatin) composed of compacted nucleosome arrays punctuated with highly accessible chromatin patches. CENP-B occupancy phases dichromatin to the underlying alpha-satellite repeat within centromere cores, but is not necessary for dichromatin formation. Centromere core dichromatin is a conserved feature between humans despite the marked divergence of their underlying alpha-satellite organization and is similarly a conserved feature along regional centromeres that lack satellite repeats in gibbon. Overall, the chromatin organization of regional centromeres is defined by marked per-molecule heterogeneity, likely buffering kinetochore attachment against sequence and structural variability within regional centromeres. Highlights Dichotomous accessible and compacted chromatin (dichromatin) marks centromere cores Highly accessible chromatin patches punctuate sites of kinetochore attachment Dichromatin can form irrespective of CENP-B occupancy Conservation within centromeres is mediated at the level of chromatin, not DNA