Clamped-Filament Elongation Model for Actin-Based Motors

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Clamped-Filament Elongation Model for Actin-Based Motors

Richard B. Dickinson^* and Daniel L. Purich

Department of ^*Chemical Engineering, University of Florida College of Engineering, and Department of Biochemistry & Molecular Biology, University of Florida College of Medicine, Gainesville, Florida 32610-0245 USA

Although actin-based motility drives cell crawling and intracellular locomotion of organelles and certain pathogens, the underlyingmechanism of force generation remains a mystery. Recent experimentsdemonstrated that Listeria exhibit episodes of 5.4-nm stepwisemotion corresponding to the periodicity of the actin filamentsubunits, and extremely small positional fluctuations during theintermittent pauses [S. C. Kuo and J. L. McGrath. 2000. Nature.407:1026-1029]. These findings suggest that motile bacteria remainfirmly bound to actin filament ends as they elongate, a behaviorthat appears to rule out previous models for actin-based motility.We propose and analyze a new mechanochemical model (called the"Lock, Load & Fire" mechanism) for force generation by means ofaffinity-modulated, clamped-filament elongation. During the lockingstep, the filament's terminal ATP-containing subunit binds tightlyto a clamp situated on the surface of a motile object; in theloading step, actin·ATP monomer(s) bind to the filament end, anevent that triggers the firing step, wherein ATP hydrolysis onthe clamped subunit attenuates the filament's affinity for theclamp. This last step initiates translocation of the new ATP-containingterminus to the clamp, whereupon another cycle begins anew. Thismodel explains how surface-tethered filaments can grow while exertingflexural or tensile force on the motile surface. Moreover, stochasticsimulations of the model reproduce the signature motions of Listeria.This elongation motor, which we term actoclampin, exploits actin'sintrinsic ATPase activity to provide a simple, high-fidelity enzymaticreaction cycle for force production that does not require elongatingfilaments to dissociate from the motile surface. This mechanismmay operate whenever actin polymerization is called upon to generatethe forces that drive cell crawling or intracellular organellemotility.

Biophys J, February 2002, p. 605-617, Vol. 82, No. 2
© 2002 by the Biophysical Society 0006-3495/02/02/605/13 $2.00

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				M. Bindschadler and J. L. McGrath Formin' new ideas about actin filament generation PNAS, October 12, 2004; 101(41): 14685 - 14686. [Full Text] [PDF]

				R. B. Dickinson, L. Caro, and D. L. Purich Force Generation by Cytoskeletal Filament End-Tracking Proteins Biophys. J., October 1, 2004; 87(4): 2838 - 2854. [Abstract] [Full Text] [PDF]

				M. Van Troys, K. Ono, D. Dewitte, V. Jonckheere, N. De Ruyck, J. Vandekerckhove, S. Ono, and C. Ampe TetraThymosin{beta} Is Required for Actin Dynamics in Caenorhabditis elegans and Acts via Functionally Different Actin-binding Repeats Mol. Biol. Cell, October 1, 2004; 15(10): 4735 - 4748. [Abstract] [Full Text] [PDF]

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				A. Mogilner and G. Oster Force Generation by Actin Polymerization II: The Elastic Ratchet and Tethered Filaments Biophys. J., March 1, 2003; 84(3): 1591 - 1605. [Abstract] [Full Text] [PDF]

				M. I. Garcia Arguinzonis, A. B. Galler, U. Walter, M. Reinhard, and A. Simm Increased Spreading, Rac/p21-activated Kinase (PAK) Activity, and Compromised Cell Motility in Cells Deficient in Vasodilator-stimulated Phosphoprotein (VASP) J. Biol. Chem., November 15, 2002; 277(47): 45604 - 45610. [Abstract] [Full Text] [PDF]

				M. Nyakern-Meazza, K. Narayan, C. E. Schutt, and U. Lindberg Tropomyosin and Gelsolin Cooperate in Controlling the Microfilament System J. Biol. Chem., August 2, 2002; 277(32): 28774 - 28779. [Abstract] [Full Text] [PDF]