Mechanism of actin-based motility: a dynamic state diagram

doi:10.1529/biophysj.104.055822

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Biophys. J. BioFAST: First Published May 27, 2005. doi:10.1529/biophysj.104.055822
© 2005 by the Biophysical Society.

A more recent version of this article appeared on August 1, 2005.

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	Author home page(s): Anne Bernheim-Groswasser Jacques Prost Cécile Sykes


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CELL BIOPHYSICS

Mechanism of actin-based motility: a dynamic state diagram

Anne Bernheim-Groswasser ¹, Jacques Prost ² and Cécile Sykes ³^*

¹ Ben Gurion University
² INSTITUT Curie/CNRS UMR168
³ Institut Curie/CNRS

^* To whom correspondence should be addressed. E-mail: cecile.sykes{at}curie.fr.

Submitted on November 5, 2004
Revised on January 5, 2005
Accepted on 17 May 2005

Abstract
Cells move by a dynamical reorganization of their cytoskeleton,orchestrated by a cascade of biochemical reactions directedto the membrane. Designed objects or bacteria can hijack thismachinery to undergo actin-based propulsion inside cells orin a cell-like medium. These objects can explore the dynamicalregimes of actin-based propulsion, and display different regimesof motion, in a continuous or periodic fashion. We show thatbead movement can switch from one regime to the other by changingthe size of the beads, or the surface concentration of the proteinactivating actin polymerization. We experimentally obtain thestate diagram of the bead dynamics, in which the transitionsbetween the different regimes can be understood by a theoreticalapproach based on an elastic force opposing a friction force.Moreover, the experimental characteristics of the movement,such as the velocity and the characteristic times of the periodicmovement, are predicted by our theoretical analysis.

Key Words: Listeria, actin polymerization, force, motility, periodic motion, saltatory

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