Jolien J. E. van Hooff scite author profile

During eukaryotic cell division, the sister chromatids of duplicated chromosomes are pulled apart by microtubules, which connect via kinetochores. The kinetochore is a multiprotein structure that links centromeres to microtubules, and that emits molecular signals in order to safeguard the equal distribution of duplicated chromosomes over daughter cells. Although microtubule‐mediated chromosome segregation is evolutionary conserved, kinetochore compositions seem to have diverged. To systematically inventory kinetochore diversity and to reconstruct its evolution, we determined orthologs of 70 kinetochore proteins in 90 phylogenetically diverse eukaryotes. The resulting ortholog sets imply that the last eukaryotic common ancestor (LECA) possessed a complex kinetochore and highlight that current‐day kinetochores differ substantially. These kinetochores diverged through gene loss, duplication, and, less frequently, invention and displacement. Various kinetochore components co‐evolved with one another, albeit in different manners. These co‐evolutionary patterns improve our understanding of kinetochore function and evolution, which we illustrated with the RZZ complex, TRIP13, the MCC, and some nuclear pore proteins. The extensive diversity of kinetochore compositions in eukaryotes poses numerous questions regarding evolutionary flexibility of essential cellular functions.

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A structural model for microtubule minus-end recognition and protection by CAMSAP proteins

Atherton

Jiang

Stangier

et al. 2017

Nat Struct Mol Biol

151

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CAMSAP and Patronin family members regulate microtubule minus-end stability and localization and thus organize non-centrosomal microtubule networks, which are essential for cell division, polarization and differentiation. Here, we show that the C-terminal CKK domain of CAMSAPs is widely present among eukaryotes and autonomously recognizes microtubule minus ends. Through a combination of structural approaches, we uncover how mammalian CKK binds between two tubulin dimers at the inter-protofilament interface on the outer microtubule surface. In vitro reconstitution assays combined with high resolution fluorescence microscopy and cryo-electron tomography suggest that CKK preferentially associates with the transition zone between curved protofilaments and the regular microtubule lattice. We propose that minus-end-specific features of the inter-protofilament interface at this site form the basis for CKK’s minus-end preference. The steric clash between microtubule-bound CKK and kinesin motors explains how CKK protects microtubule minus ends against kinesin-13-induced depolymerization and thus controls the stability of free microtubule minus ends.

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Jolien J. E. van Hooff

Evolutionary dynamics of the kinetochore network in eukaryotes as revealed by comparative genomics

A structural model for microtubule minus-end recognition and protection by CAMSAP proteins

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