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A bio-mechanical model for coupling cell contractility with focal adhesion formation |
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| Authors: | Vikram S Deshpande Milan Mrksich Anthony G Evans |
| Institution: | a Department of Engineering, University of Cambridge, Trumpington Street, Cambridge CB2 1PZ, UK b Howard Hughes Medical Institute/Department of Chemistry, University of Chicago, Chicago, IL 60637, USA c Mechanical Engineering Department and Materials Department, University of California, Santa Barbara, CA 93106, USA |
| Abstract: | Focal adhesions (FAs) are large, multi-protein complexes that provide a mechanical link between the cytoskeletal contractile machinery and the extracellular matrix. They exhibit mechanosensitive properties; they self-assemble upon application of pulling forces and dissociate when these forces are decreased. We rationalize this mechano-sensitivity from thermodynamic considerations and develop a continuum framework in which the cytoskeletal contractile forces generated by stress fibers drive the assembly of the FA multi-protein complexes. The FA model has three essential features: (i) the low and high affinity integrins co-exist in thermodynamic equilibrium, (ii) the low affinity integrins within the plasma membrane are mobile, and (iii) the contractile forces generated by the stress fibers are in mechanical equilibrium and change the free energies of the integrins. A general two-dimensional framework is presented and the essential features of the model illustrated using one-dimensional examples. Consistent with observations, the coupled stress fiber and FA model predict that (a) the FAs concentrate around the periphery of the cell; (b) the fraction of the cell covered by FAs increases with decreasing cell size while the total FA intensity increases with increasing cell size; and (c) the FA intensity decreases substantially when cell contractility is curtailed. |
| Keywords: | Mechano-sensitivity Self-assembly Focal adhesions Stress fibers Myosin |
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