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Literature DB >> 29097549

Spindle asymmetry drives non-Mendelian chromosome segregation.

Takashi Akera¹, Lukáš Chmátal¹, Emily Trimm¹, Karren Yang¹, Chanat Aonbangkhen², David M Chenoweth², Carsten Janke^3,4, Richard M Schultz¹, Michael A Lampson⁵.

Abstract

Genetic elements compete for transmission through meiosis, when haploid gametes are created from a diploid parent. Selfish elements can enhance their transmission through a process known as meiotic drive. In female meiosis, selfish elements drive by preferentially attaching to the egg side of the spindle. This implies some asymmetry between the two sides of the spindle, but the molecular mechanisms underlying spindle asymmetry are unknown. Here we found that CDC42 signaling from the cell cortex regulated microtubule tyrosination to induce spindle asymmetry and that non-Mendelian segregation depended on this asymmetry. Cortical CDC42 depends on polarization directed by chromosomes, which are positioned near the cortex to allow the asymmetric cell division. Thus, selfish meiotic drivers exploit the asymmetry inherent in female meiosis to bias their transmission.

Entities: Chemical Disease Gene Species

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Year: 2017 PMID： 29097549 PMCID： PMC5906099 DOI： 10.1126/science.aan0092

Source DB: PubMed Journal: Science ISSN： 0036-8075 Impact factor: 47.728

36 in total

1. Spindle positioning in mouse oocytes relies on a dynamic meshwork of actin filaments.

Authors: Jessica Azoury; Karen W Lee; Virginie Georget; Pascale Rassinier; Benjamin Leader; Marie-Hélène Verlhac
Journal: Curr Biol Date: 2008-10-14 Impact factor: 10.834

2. Meiotic drive for B-chromosomes in the primary oocytes of Myrmeleotettix maculatus (Orthopera: Acrididae).

Authors: G M Hewitt
Journal: Chromosoma Date: 1976-07-30 Impact factor: 4.316

Review 3. Sex chromosome drive.

Authors: Quentin Helleu; Pierre R Gérard; Catherine Montchamp-Moreau
Journal: Cold Spring Harb Perspect Biol Date: 2014-12-18 Impact factor: 10.005

4. Ran GTPase promotes oocyte polarization by regulating ERM (Ezrin/Radixin/Moesin) inactivation.

Authors: Benoit Dehapiot; Guillaume Halet
Journal: Cell Cycle Date: 2013-05-08 Impact factor: 4.534

Review 5. The Ecology and Evolutionary Dynamics of Meiotic Drive.

Authors: Anna K Lindholm; Kelly A Dyer; Renée C Firman; Lila Fishman; Wolfgang Forstmeier; Luke Holman; Hanna Johannesson; Ulrich Knief; Hanna Kokko; Amanda M Larracuente; Andri Manser; Catherine Montchamp-Moreau; Varos G Petrosyan; Andrew Pomiankowski; Daven C Presgraves; Larisa D Safronova; Andreas Sutter; Robert L Unckless; Rudi L Verspoor; Nina Wedell; Gerald S Wilkinson; Tom A R Price
Journal: Trends Ecol Evol Date: 2016-02-23 Impact factor: 17.712

6. The structure of the cold-stable kinetochore fiber in metaphase PtK1 cells.

Authors: C L Rieder
Journal: Chromosoma Date: 1981 Impact factor: 4.316

7. Complete kinetochore tracking reveals error-prone homologous chromosome biorientation in mammalian oocytes.

Authors: Tomoya S Kitajima; Miho Ohsugi; Jan Ellenberg
Journal: Cell Date: 2011-08-19 Impact factor: 41.582

8. An improved culture medium supports development of random-bred 1-cell mouse embryos in vitro.

Authors: C L Chatot; C A Ziomek; B D Bavister; J L Lewis; I Torres
Journal: J Reprod Fertil Date: 1989-07

9. A new model for asymmetric spindle positioning in mouse oocytes.

Authors: Melina Schuh; Jan Ellenberg
Journal: Curr Biol Date: 2008-12-08 Impact factor: 10.834

10. A multi-megabase copy number gain causes maternal transmission ratio distortion on mouse chromosome 2.

Authors: John P Didion; Andrew P Morgan; Amelia M-F Clayshulte; Rachel C Mcmullan; Liran Yadgary; Petko M Petkov; Timothy A Bell; Daniel M Gatti; James J Crowley; Kunjie Hua; David L Aylor; Ling Bai; Mark Calaway; Elissa J Chesler; John E French; Thomas R Geiger; Terry J Gooch; Theodore Garland; Alison H Harrill; Kent Hunter; Leonard McMillan; Matt Holt; Darla R Miller; Deborah A O'Brien; Kenneth Paigen; Wenqi Pan; Lucy B Rowe; Ginger D Shaw; Petr Simecek; Patrick F Sullivan; Karen L Svenson; George M Weinstock; David W Threadgill; Daniel Pomp; Gary A Churchill; Fernando Pardo-Manuel de Villena
Journal: PLoS Genet Date: 2015-02-13 Impact factor: 5.917

72 in total

1. A cross-eyed geneticist's view III. Mouse chromosomes take a drive.

Authors: Durgadas P Kasbekar
Journal: J Biosci Date: 2019-06 Impact factor: 1.826

Review 2. Principles and mechanisms of asymmetric cell division.

Authors: Bharath Sunchu; Clemens Cabernard
Journal: Development Date: 2020-06-29 Impact factor: 6.868

3. Reversible Control of Protein Localization in Living Cells Using a Photocaged-Photocleavable Chemical Dimerizer.

Authors: Chanat Aonbangkhen; Huaiying Zhang; Daniel Z Wu; Michael A Lampson; David M Chenoweth
Journal: J Am Chem Soc Date: 2018-09-14 Impact factor: 15.419

4. Asymmetric Centromeres Differentially Coordinate with Mitotic Machinery to Ensure Biased Sister Chromatid Segregation in Germline Stem Cells.

Authors: Rajesh Ranjan; Jonathan Snedeker; Xin Chen
Journal: Cell Stem Cell Date: 2019-09-26 Impact factor: 24.633

10. Tuba8 Drives Differentiation of Cortical Radial Glia into Apical Intermediate Progenitors by Tuning Modifications of Tubulin C Termini.

Authors: Susana I Ramos; Eugene V Makeyev; Marcelo Salierno; Takashi Kodama; Yasuhiko Kawakami; Setsuko Sahara
Journal: Dev Cell Date: 2020-02-24 Impact factor: 12.270