David Humphrey scite author profile

Entangled polymer solutions and melts exhibit elastic, solid-like resistance to quick deformations and a viscous, fluid-like response to slow deformations. This viscoelastic behaviour reflects the dynamics of individual polymer chains driven by brownian motion: since individual chains can only move in a snake-like fashion through the mesh of surrounding polymer molecules, their diffusive transport, described by reptation, is so slow that the relaxation of suddenly imposed stress is delayed. Entangled polymer solutions and melts therefore elastically resist deforming motions that occur faster than the stress relaxation time. Here we show that the protein myosin II permits active control over the viscoelastic behaviour of actin filament solutions. We find that when each actin filament in a polymerized actin solution interacts with at least one myosin minifilament, the stress relaxation time of the polymer solution is significantly shortened. We attribute this effect to myosin's action as a 'molecular motor', which allows it to interact with randomly oriented actin filaments and push them through the solution, thus enhancing longitudinal filament motion. By superseding reptation with sliding motion, the molecular motors thus overcome a fundamental principle of complex fluids: that only depolymerization makes an entangled, isotropic polymer solution fluid for quick deformations.

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Molecular Motor-Induced Instabilities and Cross Linkers Determine Biopolymer Organization

Smith

Ziebert

Humphrey

et al. 2007

Biophysical Journal

104

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All eukaryotic cells rely on the active self-organization of protein filaments to form a responsive intracellular cytoskeleton. The necessity of motility and reaction to stimuli additionally requires pathways that quickly and reversibly change cytoskeletal organization. While thermally driven order-disorder transitions are, from the viewpoint of physics, the most obvious method for controlling states of organization, the timescales necessary for effective cellular dynamics would require temperatures exceeding the physiologically viable temperature range. We report a mechanism whereby the molecular motor myosin II can cause near-instantaneous order-disorder transitions in reconstituted cytoskeletal actin solutions. When motor-induced filament sliding diminishes, the actin network structure rapidly and reversibly self-organizes into various assemblies. Addition of stable cross linkers was found to alter the architectures of ordered assemblies. These isothermal transitions between dynamic disorder and self-assembled ordered states illustrate that the interplay between passive crosslinking and molecular motor activity plays a substantial role in dynamic cellular organization.

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Interplay between crosslinkers and dynamic molecular motor-induced instabilities in the moderation of biopolymer organization

Smith¹,

Ziebert²,

Humphrey³

et al. 2006

Journal of Biomechanics

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Dynamics of Single Protein Polymers Visualized by Fluorescence Microscopy

Käs

Guck

Humphrey

1998

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David Humphrey

Active fluidization of polymer networks through molecular motors

Molecular Motor-Induced Instabilities and Cross Linkers Determine Biopolymer Organization

Interplay between crosslinkers and dynamic molecular motor-induced instabilities in the moderation of biopolymer organization

Dynamics of Single Protein Polymers Visualized by Fluorescence Microscopy

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