Literature DB >> 21765817

A POROELASTIC MODEL FOR CELL CRAWLING INCLUDING MECHANICAL COUPLING BETWEEN CYTOSKELETAL CONTRACTION AND ACTIN POLYMERIZATION.

L A Taber1, Y Shi, L Yang, P V Bayly.   

Abstract

Much is known about the biophysical mechanisms involved in cell crawling, but how these processes are coordinated to produce directed motion is not well understood. Here, we propose a new hypothesis whereby local cytoskeletal contraction generates fluid flow through the lamellipodium, with the pressure at the front of the cell facilitating actin polymerization which pushes the leading edge forward. The contraction, in turn, is regulated by stress in the cytoskeleton. To test this hypothesis, finite element models for a crawling cell are presented. These models are based on nonlinear poroelasticity theory, modified to include the effects of active contraction and growth, which are regulated by mechanical feedback laws. Results from the models agree reasonably well with published experimental data for cell speed, actin flow, and cytoskeletal deformation in migrating fish epidermal keratocytes. The models also suggest that oscillations can occur for certain ranges of parameter values.

Entities:  

Year:  2011        PMID: 21765817      PMCID: PMC3134831          DOI: 10.2140/jomms.2011.6.569

Source DB:  PubMed          Journal:  J Mech Mater Struct            Impact factor:   1.210


  53 in total

Review 1.  Mathematical models of cell motility.

Authors:  Brendan Flaherty; J P McGarry; P E McHugh
Journal:  Cell Biochem Biophys       Date:  2007       Impact factor: 2.194

2.  Continuum model of cell adhesion and migration.

Authors:  Esa Kuusela; Wolfgang Alt
Journal:  J Math Biol       Date:  2008-05-17       Impact factor: 2.259

Review 3.  Implications of a poroelastic cytoplasm for the dynamics of animal cell shape.

Authors:  T J Mitchison; G T Charras; L Mahadevan
Journal:  Semin Cell Dev Biol       Date:  2008-02-07       Impact factor: 7.727

4.  A numerical model of cellular blebbing: a volume-conserving, fluid-structure interaction model of the entire cell.

Authors:  Jennifer Young; Sorin Mitran
Journal:  J Biomech       Date:  2009-10-28       Impact factor: 2.712

5.  Stress-dependent finite growth in soft elastic tissues.

Authors:  E K Rodriguez; A Hoger; A D McCulloch
Journal:  J Biomech       Date:  1994-04       Impact factor: 2.712

6.  Rapid actin transport during cell protrusion.

Authors:  Daniel Zicha; Ian M Dobbie; Mark R Holt; James Monypenny; Daniel Y H Soong; Colin Gray; Graham A Dunn
Journal:  Science       Date:  2003-04-04       Impact factor: 47.728

7.  Myosin II contributes to cell-scale actin network treadmilling through network disassembly.

Authors:  Cyrus A Wilson; Mark A Tsuchida; Greg M Allen; Erin L Barnhart; Kathryn T Applegate; Patricia T Yam; Lin Ji; Kinneret Keren; Gaudenz Danuser; Julie A Theriot
Journal:  Nature       Date:  2010-05-20       Impact factor: 49.962

8.  Direct measurement of the lamellipodial protrusive force in a migrating cell.

Authors:  Marcus Prass; Ken Jacobson; Alex Mogilner; Manfred Radmacher
Journal:  J Cell Biol       Date:  2006-09-11       Impact factor: 10.539

9.  Force transmission in migrating cells.

Authors:  Maxime F Fournier; Roger Sauser; Davide Ambrosi; Jean-Jacques Meister; Alexander B Verkhovsky
Journal:  J Cell Biol       Date:  2010-01-25       Impact factor: 10.539

10.  Actin-myosin network reorganization breaks symmetry at the cell rear to spontaneously initiate polarized cell motility.

Authors:  Patricia T Yam; Cyrus A Wilson; Lin Ji; Benedict Hebert; Erin L Barnhart; Natalie A Dye; Paul W Wiseman; Gaudenz Danuser; Julie A Theriot
Journal:  J Cell Biol       Date:  2007-09-24       Impact factor: 10.539
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  9 in total

1.  Damped and persistent oscillations in a simple model of cell crawling.

Authors:  Philip V Bayly; Larry A Taber; Anders E Carlsson
Journal:  J R Soc Interface       Date:  2011-10-26       Impact factor: 4.118

2.  Biomechanics of Collective Cell Migration in Cancer Progression: Experimental and Computational Methods.

Authors:  Catalina-Paula Spatarelu; Hao Zhang; Dung Trung Nguyen; Xinyue Han; Ruchuan Liu; Qiaohang Guo; Jacob Notbohm; Jing Fan; Liyu Liu; Zi Chen
Journal:  ACS Biomater Sci Eng       Date:  2019-05-22

3.  Water permeation drives tumor cell migration in confined microenvironments.

Authors:  Kimberly M Stroka; Hongyuan Jiang; Shih-Hsun Chen; Ziqiu Tong; Denis Wirtz; Sean X Sun; Konstantinos Konstantopoulos
Journal:  Cell       Date:  2014-04-10       Impact factor: 41.582

4.  Cell Mechanical and Physiological Behavior in the Regime of Rapid Mechanical Compressions that Lead to Cell Volume Change.

Authors:  Anna Liu; Tong Yu; Katherine Young; Nicholas Stone; Srinivas Hanasoge; Tyler J Kirby; Vikram Varadarajan; Nicholas Colonna; Janet Liu; Abhishek Raj; Jan Lammerding; Alexander Alexeev; Todd Sulchek
Journal:  Small       Date:  2019-11-29       Impact factor: 13.281

Review 5.  Bioengineering paradigms for cell migration in confined microenvironments.

Authors:  Kimberly M Stroka; Zhizhan Gu; Sean X Sun; Konstantinos Konstantopoulos
Journal:  Curr Opin Cell Biol       Date:  2014-06-26       Impact factor: 8.382

6.  A time-dependent phenomenological model for cell mechano-sensing.

Authors:  Carlos Borau; Roger D Kamm; José Manuel García-Aznar
Journal:  Biomech Model Mechanobiol       Date:  2013-06-20

7.  Cell volume control in three dimensions: Water movement without solute movement.

Authors:  Frederick Sachs; Mettupalayam V Sivaselvan
Journal:  J Gen Physiol       Date:  2015-04-13       Impact factor: 4.086

8.  Active poroelastic two-phase model for the motion of physarum microplasmodia.

Authors:  Dirk Alexander Kulawiak; Jakob Löber; Markus Bär; Harald Engel
Journal:  PLoS One       Date:  2019-08-09       Impact factor: 3.240

Review 9.  Computational modeling of single-cell mechanics and cytoskeletal mechanobiology.

Authors:  Vijay Rajagopal; William R Holmes; Peter Vee Sin Lee
Journal:  Wiley Interdiscip Rev Syst Biol Med       Date:  2017-11-30
  9 in total

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