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Regulated changes in material properties underlie centrosome disassembly during mitotic exit

Matthäus Mittasch, Vanna M. Tran, Manolo U. Rios, Anatol W. Fritsch, Stephen J. Enos, Beatriz Ferreira Gomes, Alec Bond, Moritz Kreysing, Jeffrey B. Woodruff

2020The Journal of Cell Biology75 citationsDOIOpen Access PDF

Abstract

Centrosomes must resist microtubule-mediated forces for mitotic chromosome segregation. During mitotic exit, however, centrosomes are deformed and fractured by those same forces, which is a key step in centrosome disassembly. How the functional material properties of centrosomes change throughout the cell cycle, and how they are molecularly tuned, remain unknown. Here, we used optically induced flow perturbations to determine the molecular basis of centrosome strength and ductility in C. elegans embryos. We found that both properties declined sharply at anaphase onset, long before natural disassembly. This mechanical transition required PP2A phosphatase and correlated with inactivation of PLK-1 (Polo kinase) and SPD-2 (Cep192). In vitro, PLK-1 and SPD-2 directly protected centrosome scaffolds from force-induced disassembly. Our results suggest that, before anaphase, PLK-1 and SPD-2 respectively confer strength and ductility to the centrosome scaffold so that it can resist microtubule-pulling forces. In anaphase, centrosomes lose PLK-1 and SPD-2 and transition to a weak, brittle state that enables force-mediated centrosome disassembly.

Topics & Concepts

CentrosomeAnaphaseCell biologyMitosisCentrosome cycleMicrotubuleBiologySpindle apparatusMitotic exitChemistryPLK1Cell divisionCell cycleCellGeneticsMicrotubule and mitosis dynamicsCellular Mechanics and InteractionsReproductive Biology and Fertility
Regulated changes in material properties underlie centrosome disassembly during mitotic exit | Litcius