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  • Absence of a robust mitotic timer mechanism in early preimplantation mouse embryos leads to chromosome instability.

Absence of a robust mitotic timer mechanism in early preimplantation mouse embryos leads to chromosome instability.

Development (Cambridge, England) (2022-07-01)
Adélaïde Allais, Greg FitzHarris
ABSTRACT

Preimplantation embryos often consist of a combination of euploid and aneuploid cells, suggesting that safeguards preventing the generation and propagation of aneuploid cells in somatic cells might be deficient in embryos. In somatic cells, a mitotic timer mechanism has been described, in which even a small increase in the duration of M phase can cause a cell cycle arrest in the subsequent interphase, preventing further propagation of cells that have undergone a potentially hazardously long M phase. Here, we report that cell divisions in the mouse embryo and embryonic development continue even after a mitotic prolongation of several hours. However, similar M-phase extensions caused cohesion fatigue, resulting in prematurely separated sister chromatids and the production of micronuclei. Only extreme prolongation of M phase caused a subsequent interphase arrest, through a mechanism involving DNA damage. Our data suggest that the simultaneous absence of a robust mitotic timer and susceptibility of the embryo to cohesion fatigue could contribute to chromosome instability in mammalian embryos. This article has an associated 'The people behind the papers' interview.

MATERIALS
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Sigma-Aldrich
KU-55933, ≥98% (HPLC)