Kinetochore individualization in meiosis I is required for centromeric cohesin removal in meiosis II.

Partitioning of the genome in meiosis occurs through two highly specialized cell divisions, named meiosis I and meiosis II. Step-wise cohesin removal is required for chromosome segregation in meiosis I, and sister chromatid segregation in meiosis II. In meiosis I, mono-oriented sister kinetochores appear as fused together when examined by high-resolution confocal microscopy, whereas they are clearly separated in meiosis II, when attachments are bipolar. It has been proposed that bipolar tension applied by the spindle is responsible for the physical separation of sister kinetochores, removal of cohesin protection, and chromatid separation in meiosis II. We show here that this is not the case, and initial separation of sister kinetochores occurs already in anaphase I independently of bipolar spindle forces applied on sister kinetochores, in mouse oocytes. This kinetochore individualization depends on separase cleavage activity. Crucially, without kinetochore individualization in meiosis I, bivalents when present in meiosis II oocytes separate into chromosomes and not sister chromatids. This shows that whether centromeric cohesin is removed or not is determined by the kinetochore structure prior to meiosis II. © 2021 The Authors. Published under the terms of the CC BY NC ND 4.0 license.

Citation

Yulia Gryaznova, Leonor Keating, Sandra A Touati, Damien Cladière, Warif El Yakoubi, Eulalie Buffin, Katja Wassmann. Kinetochore individualization in meiosis I is required for centromeric cohesin removal in meiosis II. The EMBO journal. 2021 Apr 01;40(7):e106797

Mesh Tags

Substances

PMID: 33644892

search → result