Abstract
Summary The kinetochore is an essential structure for the faithful chromosome segregation during mitosis. The 16-protein complex known as the constitutive centromere-associated network (CCAN) localizes the kinetochore throughout the cell cycle and forms the basis of the kinetochore. Although a structural model of an individual CCAN unit has been proposed through cryo-electron microscopy analysis, little is known about how multiple CCAN units are organized within cells. Here, using in silico and in vivo analyses, we demonstrate that multiple CCAN units form a spherical, shell-like structure in interphase DT40 kinetochores. CENP-T and CENP-N localize to the CCAN shell, and the CENP-C cupin domain clusters at the center. Molecular dynamics simulations of CCAN assembly suggest that CENP-C contributes to the orientation of CCAN units, leading to the formation of a spherical shell-like structure via CENP-C oligomerization. Super-resolution imaging reveals the spherical shell-like structure at DT40 kinetochores, and knocking out CENP-C abolishes the structure, supporting the reliability of the predicted models. These findings provide important insights into the spatial organization of functional kinetochores within cells.
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Summary
The kinetochore is an essential structure for the faithful chromosome segregation during mitosis. The 16-protein complex known as the constitutive centromere-associated network (CCAN) localizes the kinetochore throughout the cell cycle and forms the basis of the kinetochore. Although a structural model of an individual CCAN unit has been proposed through cryo-electron microscopy analysis, little is known about how multiple CCAN units are organized within cells. Here, using in silico and in vivo analyses, we demonstrate that multiple CCAN units form a spherical, shell-like structure in interphase DT40 kinetochores. CENP-T and CENP-N localize to the CCAN shell, and the CENP-C cupin domain clusters at the center. Molecular dynamics simulations of CCAN assembly suggest that CENP-C contributes to the orientation of CCAN units, leading to the formation of a spherical shell-like structure via CENP-C oligomerization. Super-resolution imaging reveals the spherical shell-like structure at DT40 kinetochores, and knocking out CENP-C abolishes the structure, supporting the reliability of the predicted models. These findings provide important insights into the spatial organization of functional kinetochores within cells.
Competing Interest Statement
The authors have declared no competing interest.
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