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Augmin-dependent microtubule self-organization drives kinetochore fiber maturation in mammals

Ana C. Almeida, Joana Soares-de-Oliveira, Danica Drpic, Liam P. Cheeseman, Joana Damas, Harris A. Lewin, Denis M. Larkin, Paulo Aguiar, António J. Pereira, Hélder Maiato

2022Cell Reports22 citationsDOIOpen Access PDF

Abstract

Chromosome segregation in mammals relies on the maturation of a thick bundle of kinetochore-attached microtubules known as k-fiber. How k-fibers mature from initial kinetochore microtubule attachments remains a fundamental question. By combining molecular perturbations and phenotypic analyses in Indian muntjac fibroblasts containing the lowest known diploid chromosome number in mammals (2N = 6) and distinctively large kinetochores, with fixed/live-cell super-resolution coherent-hybrid stimulated emission depletion (CH-STED) nanoscopy and laser microsurgery, we demonstrate a key role for augmin in kinetochore microtubule self-organization and maturation, regardless of pioneer centrosomal microtubules. In doing so, augmin promotes kinetochore and interpolar microtubule turnover and poleward flux. Tracking of microtubule growth events within individual k-fibers reveals a wide angular dispersion, consistent with augmin-mediated branched microtubule nucleation. Augmin depletion reduces the frequency of kinetochore microtubule growth events and hampers efficient repair after acute k-fiber injury by laser microsurgery. Together, these findings underscore the contribution of augmin-mediated microtubule amplification for k-fiber self-organization and maturation in mammals.

Topics & Concepts

KinetochoreMicrotubuleCell biologyAstral microtubulesBiologyMitosisChromosomeGeneticsGeneMicrotubule and mitosis dynamicsProtist diversity and phylogenyGenomics and Chromatin Dynamics