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Literature DB >> 27230381

A force-generating machinery maintains the spindle at the cell center during mitosis.

Carlos Garzon-Coral¹, Horatiu A Fantana¹, Jonathon Howard².

Abstract

The position and orientation of the mitotic spindle is precisely regulated to ensure the accurate partition of the cytoplasm between daughter cells and the correct localization of the daughters within growing tissue. Using magnetic tweezers to perturb the position of the spindle in intact cells, we discovered a force-generating machinery that maintains the spindle at the cell center during metaphase and anaphase in one- and two-cell Caenorhabditis elegans embryos. The forces increase with the number of microtubules and are larger in smaller cells. The machinery is rigid enough to suppress thermal fluctuations to ensure precise localization of the mitotic spindle, yet compliant enough to allow molecular force generators to fine-tune the position of the mitotic spindle to facilitate asymmetric division.

Entities: Chemical Disease Gene Species

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Year: 2016 PMID： 27230381 PMCID： PMC6535051 DOI： 10.1126/science.aad9745

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

20 in total

1. The distribution of active force generators controls mitotic spindle position.

Authors: Stephan W Grill; Jonathon Howard; Erik Schäffer; Ernst H K Stelzer; Anthony A Hyman
Journal: Science Date: 2003-07-25 Impact factor: 47.728

2. Spindle positioning by cortical pulling forces.

Authors: Stephan W Grill; Anthony A Hyman
Journal: Dev Cell Date: 2005-04 Impact factor: 12.270

3. Elastic and damping forces generated by confined arrays of dynamic microtubules.

Authors: J Howard
Journal: Phys Biol Date: 2006-02-28 Impact factor: 2.583

4. Spindle oscillations during asymmetric cell division require a threshold number of active cortical force generators.

Authors: Jacques Pecreaux; Jens-Christian Röper; Karsten Kruse; Frank Jülicher; Anthony A Hyman; Stephan W Grill; Jonathon Howard
Journal: Curr Biol Date: 2006-11-07 Impact factor: 10.834

5. High-force magnetic tweezers with force feedback for biological applications.

Authors: Philip Kollmannsberger; Ben Fabry
Journal: Rev Sci Instrum Date: 2007-11 Impact factor: 1.523

6. Identification and characterization of factors required for microtubule growth and nucleation in the early C. elegans embryo.

Authors: Martin Srayko; Aynur Kaya; Joanne Stamford; Anthony A Hyman
Journal: Dev Cell Date: 2005-08 Impact factor: 12.270

7. Probing single-cell micromechanics in vivo: the microrheology of C. elegans developing embryos.

Authors: Brian R Daniels; Byron C Masi; Denis Wirtz
Journal: Biophys J Date: 2006-03-31 Impact factor: 4.033

8. Cortical microtubule contacts position the spindle in C. elegans embryos.

Authors: Cleopatra Kozlowski; Martin Srayko; Francois Nedelec
Journal: Cell Date: 2007-05-04 Impact factor: 41.582

9. Electron microscopy of the early Caenorhabditis elegans embryo.

Authors: T Müller-Reichert; J Mäntler; M Srayko; E O'Toole
Journal: J Microsc Date: 2008-05 Impact factor: 1.758

10. The forces that position a mitotic spindle asymmetrically are tethered until after the time of spindle assembly.

Authors: Jean-Claude Labbé; Erin K McCarthy; Bob Goldstein
Journal: J Cell Biol Date: 2004-10-18 Impact factor: 10.539

40 in total

Review 1. From isolated structures to continuous networks: A categorization of cytoskeleton-based motile engineered biological microstructures.

Authors: Rachel Andorfer; Joshua D Alper
Journal: Wiley Interdiscip Rev Nanomed Nanobiotechnol Date: 2019-02-11

2. Microtubule Feedback and LET-99-Dependent Control of Pulling Forces Ensure Robust Spindle Position.

Authors: Hélène Bouvrais; Laurent Chesneau; Sylvain Pastezeur; Danielle Fairbrass; Marie Delattre; Jacques Pécréaux
Journal: Biophys J Date: 2018-10-19 Impact factor: 4.033

3. Spherical spindle shape promotes perpendicular cortical orientation by preventing isometric cortical pulling on both spindle poles during C. elegans female meiosis.

Authors: Elizabeth Vargas; Karen P McNally; Daniel B Cortes; Michelle T Panzica; Brennan M Danlasky; Qianyan Li; Amy Shaub Maddox; Francis J McNally
Journal: Development Date: 2019-10-21 Impact factor: 6.868

4. Mechanisms of chromosome biorientation and bipolar spindle assembly analyzed by computational modeling.

Authors: Christopher Edelmaier; Adam R Lamson; Zachary R Gergely; Saad Ansari; Robert Blackwell; J Richard McIntosh; Matthew A Glaser; Meredith D Betterton
Journal: Elife Date: 2020-02-13 Impact factor: 8.140

Review 5. Non-equilibrium assembly of microtubules: from molecules to autonomous chemical robots.

Authors: H Hess; Jennifer L Ross
Journal: Chem Soc Rev Date: 2017-09-18 Impact factor: 54.564

Review 6. Microtubule-based force generation.

Authors: Ian A Kent; Tanmay P Lele
Journal: Wiley Interdiscip Rev Nanomed Nanobiotechnol Date: 2016-08-25

Review 7. Physical Limits on the Precision of Mitotic Spindle Positioning by Microtubule Pushing forces: Mechanics of mitotic spindle positioning.

Authors: Jonathon Howard; Carlos Garzon-Coral
Journal: Bioessays Date: 2017-09-28 Impact factor: 4.345