Softness, strength and self-repair in intermediate filament networks

Softness, strength and self-repair in intermediate filament networks

One cellular function of intermediate filaments is to provide cells with compliance to small deformations while strengthening them when large stresses are applied. How IFs accomplish this mechanical role is revealed by recent studies of the elastic properties of single IF protein polymers and by vis...

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Bibliographic Details
Published in:Experimental cell research Vol. 313; no. 10; pp. 2228 - 2235
Main Authors: Wagner, Oliver I., Rammensee, Sebastian, Korde, Neha, Wen, Qi, Leterrier, Jean-Francois, Janmey, Paul A.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 10-06-2007
Elsevier BV
Subjects:
Animals
Biomechanical Phenomena
Cellular biology
Elasticity
Gels - chemistry
Humans
Intermediate Filament Proteins - chemistry
Intermediate Filament Proteins - physiology
Intermediate Filaments - chemistry
Intermediate Filaments - physiology
Molecular biology
Network
Neurofilament
Polyelectrolyte
Protein Binding - physiology
Proteins
Stress, Mechanical
Tensile Strength - physiology
Viscoelasticity
Viscosity
Viscoelasticity
Polyelectrolyte
NFH
Neurofilament
NFM
Network
AFM
NF
Elasticity
IF
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Summary:One cellular function of intermediate filaments is to provide cells with compliance to small deformations while strengthening them when large stresses are applied. How IFs accomplish this mechanical role is revealed by recent studies of the elastic properties of single IF protein polymers and by viscoelastic characterization of the networks they form. IFs are unique among cytoskeletal filaments in withstanding large deformations. Single filaments can stretch to more than 3 times their initial length before breaking, and gels of IF withstand strains greater than 100% without damage. Even after mechanical disruption of gels formed by crossbridged neurofilaments, the elastic modulus of these gels rapidly recovers under conditions where gels formed by actin filaments are irreversibly ruptured. The polyelectrolyte properties of IFs may enable crossbridging by multivalent counterions, but identifying the mechanisms by which IFs link into bundles and networks in vivo remains a challenge.
ISSN:0014-4827
1090-2422
DOI:10.1016/j.yexcr.2007.04.025