Strain Hardening of Actin Filament Networks

Mechanical stresses applied to the plasma membrane of an adherent cell induces strain hardening of the cytoskeleton, i.e. the elasticity of the cytoskeleton increases with its deformation. Strain hardening is thought to mediate the transduction of mechanical signals across the plasma membrane through the cytoskeleton. Here, we describe the strain dependence of a model system consisting of actin filaments (F-actin), a major component of the cytoskeleton, and the F-actin cross-linking protein α-actinin, which localizes along contractile stress fibers and at focal adhesions. We show that the amplitude and rate of shear deformations regulate the resilience of F-actin networks. At low temperatures, for which the lifetime of binding of α-actinin to F-actin is long, F-actin/α-actinin networks exhibit strong strain hardening at short time scales and soften at long time scales. For F-actin networks in the absence of α-actinin or for F-actin/α-actinin networks at high temperatures, strain hardening appears only at very short time scales. We propose a model of strain hardening for F-actin networks, based on both the intrinsic rigidity of F-actin and dynamic topological constraints formed by the cross-linkers located at filaments entanglements. This model offers an explanation for the origin of strain hardening observed when shear stresses are applied against the cellular membrane.

[1]  T D Pollard,et al.  Dynamic Cross-linking by α-Actinin Determines the Mechanical Properties of Actin Filament Networks* , 1998, The Journal of Biological Chemistry.

[2]  Denis Wirtz,et al.  Rheology and microrheology of semiflexible polymer solutions : Actin filament networks , 1998 .

[3]  J. Howard,et al.  Flexural rigidity of microtubules and actin filaments measured from thermal fluctuations in shape , 1993, The Journal of cell biology.

[4]  T. Pollard,et al.  Viscometric analysis of the gelation of Acanthamoeba extracts and purification of two gelation factors , 1980, The Journal of cell biology.

[5]  M. Huggins Viscoelastic Properties of Polymers. , 1961 .

[6]  T D Pollard,et al.  Actin and actin-binding proteins. A critical evaluation of mechanisms and functions. , 1986, Annual review of biochemistry.

[7]  J. Cooper,et al.  [29] Preparation of smooth muscle α-actinin , 1982 .

[8]  T. Pollard,et al.  Dependence of the mechanical properties of actin/α-actinin gels on deformation rate , 1987, Nature.

[9]  R. Nerem,et al.  Shear stress modulates endothelial cell morphology and F‐actin organization through the regulation of focal adhesion‐associated proteins , 1995, Journal of cellular physiology.

[10]  F. MacKintosh,et al.  Dynamic shear modulus of a semiflexible polymer network , 1998 .

[11]  K. Ayscough,et al.  In vivo functions of actin-binding proteins. , 1998, Current opinion in cell biology.

[12]  Clive R. Bagshaw,et al.  The kinetics of the interaction between the actin‐binding domain of α‐actinin and F‐actin , 1994 .

[13]  Thomas Kreis,et al.  Guidebook to cytoskeletal and motor proteins , 1999 .

[14]  S. Craig,et al.  Assembly of focal adhesions: progress, paradigms, and portents. , 1996, Current opinion in cell biology.

[15]  P. Janmey,et al.  Mechanical Effects of Neurofilament Cross-bridges , 1996, The Journal of Biological Chemistry.

[16]  F. C. MacKintosh,et al.  Determining Microscopic Viscoelasticity in Flexible and Semiflexible Polymer Networks from Thermal Fluctuations , 1997 .

[17]  C J Weijer,et al.  The role of the cortical cytoskeleton: F-actin crosslinking proteins protect against osmotic stress, ensure cell size, cell shape and motility, and contribute to phagocytosis and development. , 1996, Journal of cell science.

[18]  D. Wirtz,et al.  Linear viscoelastic moduli of concentrated DNA solutions , 1998 .

[19]  S. Chien,et al.  Role of integrins in cellular responses to mechanical stress and adhesion. , 1997, Current opinion in cell biology.

[20]  D. Ingber,et al.  Mechanotransduction across the cell surface and through the cytoskeleton , 1993 .

[21]  J. Condeelis Are all pseudopods created equal? , 1992, Cell motility and the cytoskeleton.

[22]  E. Sackmann,et al.  Measurement of local viscoelasticity and forces in living cells by magnetic tweezers. , 1999, Biophysical journal.

[23]  O. Thoumine,et al.  Time scale dependent viscoelastic and contractile regimes in fibroblasts probed by microplate manipulation. , 1997, Journal of cell science.

[24]  A. Palmer,et al.  Diffusing wave spectroscopy microrheology of actin filament networks. , 1999, Biophysical journal.

[25]  A. C. Maggs,et al.  Dynamics and rheology of actin solutions , 1996 .

[26]  Daniel Choquet,et al.  Extracellular Matrix Rigidity Causes Strengthening of Integrin–Cytoskeleton Linkages , 1997, Cell.

[27]  D. Wirtz,et al.  Keratin Filament Suspensions Show Unique Micromechanical Properties* , 1999, The Journal of Biological Chemistry.

[28]  D. Ingber Tensegrity: the architectural basis of cellular mechanotransduction. , 1997, Annual review of physiology.

[29]  Kenneth M. Yamada,et al.  Integrin transmembrane signaling and cytoskeletal control. , 1995, Current opinion in cell biology.

[30]  R. Yasuda,et al.  Strength and lifetime of the bond between actin and skeletal muscle alpha-actinin studied with an optical trapping technique. , 1996, Biochimica et biophysica acta.

[31]  T D Pollard,et al.  Mechanical properties of actin filament networks depend on preparation, polymerization conditions, and storage of actin monomers. , 1998, Biophysical journal.

[32]  P. Janmey,et al.  Thiol oxidation of actin produces dimers that enhance the elasticity of the F-actin network. , 1999, Biophysical journal.

[33]  Kenneth M. Yamada,et al.  Synergistic roles for receptor occupancy and aggregation in integrin transmembrane function , 1995, Science.

[34]  D. Lauffenburger,et al.  Cell Migration: A Physically Integrated Molecular Process , 1996, Cell.

[35]  W. Stafford,et al.  Calponin interaction with alpha-actinin-actin: evidence for a structural role for calponin. , 1999, Biophysical journal.

[36]  Robert E. Buxbaum,et al.  Direct Observations of the Mechanical Behaviors of the Cytoskeleton in Living Fibroblasts , 1999, The Journal of cell biology.

[37]  D. Wirtz,et al.  The 'ins' and 'outs' of intermediate filament organization. , 2000, Trends in cell biology.

[38]  E. Sackmann,et al.  Entanglement, Elasticity, and Viscous Relaxation of Actin Solutions , 1998 .

[39]  Paul A. Janmey,et al.  Resemblance of actin-binding protein/actin gels to covalently crosslinked networks , 1990, Nature.

[40]  G. Fredrickson The theory of polymer dynamics , 1996 .

[41]  K Konstantopoulos,et al.  Perspectives Series: Cell Adhesion in Vascular Biology Effects of Fluid Dynamic Forces on Vascular Cell Adhesion , 1996 .

[42]  Donald E. Ingber,et al.  The structural and mechanical complexity of cell-growth control , 1999, Nature Cell Biology.

[43]  E. Fedorov,et al.  Multiple-particle tracking measurements of heterogeneities in solutions of actin filaments and actin bundles. , 2000, Biophysical journal.

[44]  D. Wirtz,et al.  Mechanics of living cells measured by laser tracking microrheology. , 2000, Biophysical journal.

[45]  J. Spudich,et al.  The regulation of rabbit skeletal muscle contraction. I. Biochemical studies of the interaction of the tropomyosin-troponin complex with actin and the proteolytic fragments of myosin. , 1971, The Journal of biological chemistry.

[46]  David C. Morse,et al.  VISCOELASTICITY OF TIGHTLY ENTANGLED SOLUTIONS OF SEMIFLEXIBLE POLYMERS , 1998 .

[47]  K. Fujiwara,et al.  Macromolecular composition of stress fiber-plasma membrane attachment sites in endothelial cells in situ. , 1996, Circulation research.

[48]  R. Nerem,et al.  Elongation of confluent endothelial cells in culture: the importance of fields of force in the associated alterations of their cytoskeletal structure. , 1995, Experimental cell research.

[49]  D H Wachsstock,et al.  Cross-linker dynamics determine the mechanical properties of actin gels. , 1994, Biophysical journal.

[50]  B. Geiger,et al.  Interaction of fibronectin-coated beads with attached and spread fibroblasts. Binding, phagocytosis, and cytoskeletal reorganization. , 1986, Experimental cell research.

[51]  H. Isambert,et al.  Flexibility of actin filaments derived from thermal fluctuations. Effect of bound nucleotide, phalloidin, and muscle regulatory proteins , 1995, The Journal of Biological Chemistry.

[52]  T. Pollard,et al.  Affinity of alpha-actinin for actin determines the structure and mechanical properties of actin filament gels. , 1993, Biophysical journal.

[53]  T. Mitchison,et al.  Actin-dependent motile forces and cell motility. , 1994, Current opinion in cell biology.

[54]  D Lerche,et al.  The mechanical properties of actin gels. Elastic modulus and filament motions. , 1994, The Journal of biological chemistry.

[55]  Denis Wirtz,et al.  High-frequency viscoelasticity of crosslinked actin filament networks measured by diffusing wave spectroscopy , 1998 .