Microtubule-dependent orchestration of centriole amplification in brain multiciliated cells
Centriole number must be restricted to two in cycling cells to avoid pathological cell divisions. Multiciliated cells (MCC), however, need to produce a hundred or more centrioles to nucleate the same number of motile cilia required for fluid flow circulation. These centrioles are produced by highjac...
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Published in | bioRxiv |
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Main Authors | , , , , , , , , , , , , |
Format | Paper |
Language | English |
Published |
Cold Spring Harbor
Cold Spring Harbor Laboratory Press
12.02.2024
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Subjects | |
Online Access | Get full text |
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Summary: | Centriole number must be restricted to two in cycling cells to avoid pathological cell divisions. Multiciliated cells (MCC), however, need to produce a hundred or more centrioles to nucleate the same number of motile cilia required for fluid flow circulation. These centrioles are produced by highjacking cell cycle and centriole duplication programs. However, how the MCC progenitor handles such a massive number of centrioles to finally organize them in an apical basal body patch is unclear. Here, using new cellular models and high-resolution imaging techniques, we identify the microtubule network as the bandleader, and show how it orchestrates the process in space and in time. Organized by the pre-existing centrosome at the start of amplification, microtubules build a nest of centriolar components from which procentrioles emerge. When amplification is over, the centrosome's dominance is lost as new centrioles mature and become microtubule nucleators. Microtubules then drag all the centrioles to the nuclear membrane, assist their isotropic perinuclear disengagement and their subsequent collective apical migration. These results reveal that in brain MCC as in cycling cells, the same dynamics -from the centrosome to the cell pole via the nucleus- exists, is the result of a reflexive link between microtubules and the progressive maturation of new centrioles, and participates in the organized reshaping of the entire cytoplasm. On the other hand, new elements described in this work such as microtubule-driven organization of a nest, identification of a spatio-temporal progression of centriole growth and microtubule-assisted disengagement, may shed new light on the centriole duplication program.Competing Interest StatementThe authors have declared no competing interest. |
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DOI: | 10.1101/2024.02.09.579615 |