Filament rigidity causes F-actin depletion from nonbinding surfaces

Fisher, Charles I.; Kuo, Scot C.

doi:10.1073/pnas.0804991106

Cited by 9 publications

(10 citation statements)

References 51 publications

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“…To prevent nonspecific membrane adhesion of actin, we included 5 mol % PEGylated lipids in the lipid mixture, which act as a steric brush. The membranes were indeed passivated successfully, as shown by confocal imaging (Figure A): while the actin network (green) is homogeneous throughout the liposome, near the membrane (red) an empty depletion zone devoid of actin is observed, as expected for rigid actin filaments near nonbinding surfaces . The depletion of actin close to the membrane is clearly visible in a fluorescence intensity cross-section of the liposome, as shown in Figure B.…”

Section: Resultsmentioning

confidence: 63%

“…The membranes were indeed passivated successfully, as shown by confocal imaging (Figure 5A): while the actin network (green) is homogeneous throughout the liposome, near the membrane (red) an empty depletion zone devoid of actin is observed, as expected for rigid actin filaments near nonbinding surfaces. 69 The depletion of actin close to the membrane is clearly visible in a fluorescence intensity cross-section of the liposome, as shown in Figure 5B. To create well-defined actinÀmembrane anchoring, we used biotinÀstreptavidin bonds, which are nearly permanent.…”

Section: Resultsmentioning

confidence: 99%

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Encapsulation of Active Cytoskeletal Protein Networks in Cell-Sized Liposomes

2011

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We demonstrate that cytoskeletal actin-myosin networks can be encapsulated with high efficiency in giant liposomes by hydration of lipids in an agarose hydrogel. The liposomes have cell-sized diameters of 10-20 μm and a uniform actin content. We show by measurements of membrane fluorescence intensity and bending rigidity that the majority of liposomes are unilamellar. We further demonstrate that the actin network can be specifically anchored to the membrane by biotin-streptavidin linkages. These protein-filled liposomes are useful model systems for quantitative studies of the physical mechanisms by which the cytoskeleton actively controls cell shape and mechanics. In a broader context, this new preparation method should be widely applicable to encapsulation of proteins and polymers, for instance, to create polymer-reinforced liposomes for drug delivery.

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Section: Resultsmentioning

confidence: 63%

Section: Resultsmentioning

confidence: 99%

Encapsulation of Active Cytoskeletal Protein Networks in Cell-Sized Liposomes

2011

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“…The purified actin monomers were equilibrated with G-buffer (2 mM Tris-HCl, pH 8.0, 0.2 mM ATP, 0.5 mM DTT, and 0.2 mM CaCl 2 ). The protein was rapidly frozen in liquid nitrogen and stored at À80 C. Alexa 488-labeled G-actin was prepared according to the procedure in Fisher and Kuo (33), using Alexa 488-succinimidyl ester (Invitrogen, Carlsbad, CA). ADF/cofilin and the verprolin central acidic domain (VCA) of N-WASP were purchased from Cytoskeleton (Denver, CO).…”

Section: Proteins and Extractsmentioning

confidence: 99%

Observation and Kinematic Description of Long Actin Tracks Induced by Spherical Beads

Kang

Perlmutter

Shenoy

et al. 2010

Biophysical Journal

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We report an in vitro study comparing the growth of long actin tails induced by spherical beads coated with the verprolin central acidic domain of the polymerization enzyme N-WASP to that induced by Listeria monocytogenes in similar cellular extracts. The tracks behind the beads show characteristic differences in shape and curvature from those left by the bacteria, which have an elongated shape and a similar polymerization-inducing enzyme distributed only on the rear surface of the cell. The experimental tracks are simulated using a generalized kinematic model, which incorporates three modes of bead rotation with respect to the tail. The results show that the trajectories of spherical beads are mechanically deterministic rather than random, as suggested by stochastic models. Assessment of the bead rotation and its mechanistic basis offers insights into the biological function of actin-based motility.

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“…Naturally, the corresponding Euler buckling load of cofilin-decorated filaments is also reduced fivefold with respect to native filaments, which may have consequences for force generation, motility and filament turnover under load. The depletion of filaments from non-binding surfaces (Fisher and Kuo 2009) will also be affected.…”

Section: Introductionmentioning

confidence: 99%

How cofilin severs an actin filament

2009

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The actin regulatory protein, cofilin, promotes actin assembly dynamics by severing filaments and increasing the number of ends from which subunits add and dissociate. Recent studies provide biophysical descriptions of cooperative filament interactions in energetic, mechanical and structural terms. A one-dimensional Ising model with nearest-neighbor interactions permits thermodynamic analysis of cooperative binding and indicates that one or a few cofilin molecules can sever a filament. Binding and cooperative interactions are entropically driven. A significant fraction of the binding free energy results from the linked dissociation of filament-associated ions (polyelectrolyte effect), which modulate filament structure, stability and mechanics. The remaining binding free energy and essentially all of the cooperative free energy arise from the enhanced conformational dynamics of the cofilactin complex. Filament mechanics are modulated by cofilin such that cofilin-saturated filaments are approximately 10- to 20-fold more compliant in bending and twisting than bare filaments. Cofilin activity is well described by models in which discontinuities in topology, mechanics and conformational dynamics generate stress concentration and promote fracture at junctions of bare and decorated segments, analogous to the grain boundary fracture of crystalline materials and the thermally driven formation of shear transformation zones in colloidal glass.

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Filament rigidity causes F-actin depletion from nonbinding surfaces

Cited by 9 publications

References 51 publications

Encapsulation of Active Cytoskeletal Protein Networks in Cell-Sized Liposomes

Encapsulation of Active Cytoskeletal Protein Networks in Cell-Sized Liposomes

Observation and Kinematic Description of Long Actin Tracks Induced by Spherical Beads

How cofilin severs an actin filament

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