Attractive Interactions among Intermediate Filaments Determine Network Mechanics In Vitro
Author(s) -
Paul Pawelzyk,
Norbert Mücke,
Harald Herrmann,
Norbert Willenbacher
Publication year - 2014
Publication title -
plos one
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.99
H-Index - 332
ISSN - 1932-6203
DOI - 10.1371/journal.pone.0093194
Subject(s) - microrheology , stiffening , protein filament , rheometry , chemical physics , persistence length , strain (injury) , materials science , biophysics , polymer , crystallography , chemistry , viscoelasticity , composite material , biology , anatomy
Mechanical and structural properties of K8/K18 and vimentin intermediate filament (IF) networks have been investigated using bulk mechanical rheometry and optical microrheology including diffusing wave spectroscopy and multiple particle tracking. A high elastic modulus G 0 at low protein concentration c , a weak concentration dependency of G 0 ( G 0 ∼ c 0.5±0.1 ) and pronounced strain stiffening are found for these systems even without external crossbridgers. Strong attractive interactions among filaments are required to maintain these characteristic mechanical features, which have also been reported for various other IF networks. Filament assembly, the persistence length of the filaments and the network mesh size remain essentially unaffected when a nonionic surfactant is added, but strain stiffening is completely suppressed, G 0 drops by orders of magnitude and exhibits a scaling G 0 ∼ c 1.9±0.2 in agreement with microrheological measurements and as expected for entangled networks of semi-flexible polymers. Tailless K8Δ/K18ΔT and various other tailless filament networks do not exhibit strain stiffening, but still show high G 0 values. Therefore, two binding sites are proposed to exist in IF networks. A weaker one mediated by hydrophobic amino acid clusters in the central rod prevents stretched filaments between adjacent cross-links from thermal equilibration and thus provides the high G 0 values. Another strong one facilitating strain stiffening is located in the tail domain with its high fraction of hydrophobic amino acid sequences. Strain stiffening is less pronounced for vimentin than for K8/K18 due to electrostatic repulsion forces partly compensating the strong attraction at filament contact points.
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