Literature DB >> 10692348

Growing an actin gel on spherical surfaces.

V Noireaux1, R M Golsteyn, E Friederich, J Prost, C Antony, D Louvard, C Sykes.   

Abstract

Inspired by the motility of the bacteria Listeria monocytogenes, we have experimentally studied the growth of an actin gel around spherical beads grafted with ActA, a protein known to be the promoter of bacteria movement. On ActA-grafted beads F-actin is formed in a spherical manner, whereas on the bacteria a "comet-like" tail of F-actin is produced. We show experimentally that the stationary thickness of the gel depends on the radius of the beads. Moreover, the actin gel is not formed if the ActA surface density is too low. To interpret our results, we propose a theoretical model to explain how the mechanical stress (due to spherical geometry) limits the growth of the actin gel. Our model also takes into account treadmilling of actin. We deduce from our work that the force exerted by the actin gel on the bacteria is of the order of 10 pN. Finally, we estimate from our theoretical model possible conditions for developing actin comet tails.

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Year:  2000        PMID: 10692348      PMCID: PMC1300761          DOI: 10.1016/S0006-3495(00)76716-6

Source DB:  PubMed          Journal:  Biophys J        ISSN: 0006-3495            Impact factor:   4.033


  34 in total

1.  Cooperative symmetry-breaking by actin polymerization in a model for cell motility.

Authors:  A van Oudenaarden; J A Theriot
Journal:  Nat Cell Biol       Date:  1999-12       Impact factor: 28.824

2.  L. monocytogenes-induced actin assembly requires the actA gene product, a surface protein.

Authors:  C Kocks; E Gouin; M Tabouret; P Berche; H Ohayon; P Cossart
Journal:  Cell       Date:  1992-02-07       Impact factor: 41.582

Review 3.  Bioenergetics and kinetics of microtubule and actin filament assembly-disassembly.

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Journal:  Int Rev Cytol       Date:  1982

Review 4.  On the crawling of animal cells.

Authors:  T P Stossel
Journal:  Science       Date:  1993-05-21       Impact factor: 47.728

5.  Direct observation of motion of single F-actin filaments in the presence of myosin.

Authors:  T Yanagida; M Nakase; K Nishiyama; F Oosawa
Journal:  Nature       Date:  1984 Jan 5-11       Impact factor: 49.962

6.  Actin polymerization is induced by Arp2/3 protein complex at the surface of Listeria monocytogenes.

Authors:  M D Welch; A Iwamatsu; T J Mitchison
Journal:  Nature       Date:  1997-01-16       Impact factor: 49.962

7.  Actin depolymerizing factor (ADF/cofilin) enhances the rate of filament turnover: implication in actin-based motility.

Authors:  M F Carlier; V Laurent; J Santolini; R Melki; D Didry; G X Xia; Y Hong; N H Chua; D Pantaloni
Journal:  J Cell Biol       Date:  1997-03-24       Impact factor: 10.539

8.  Actin-based bacterial motility: towards a definition of the minimal requirements.

Authors:  I Lasa; P Cossart
Journal:  Trends Cell Biol       Date:  1996-03       Impact factor: 20.808

9.  A novel bacterial virulence gene in Listeria monocytogenes required for host cell microfilament interaction with homology to the proline-rich region of vinculin.

Authors:  E Domann; J Wehland; M Rohde; S Pistor; M Hartl; W Goebel; M Leimeister-Wächter; M Wuenscher; T Chakraborty
Journal:  EMBO J       Date:  1992-05       Impact factor: 11.598

10.  How Listeria exploits host cell actin to form its own cytoskeleton. II. Nucleation, actin filament polarity, filament assembly, and evidence for a pointed end capper.

Authors:  L G Tilney; D J DeRosier; A Weber; M S Tilney
Journal:  J Cell Biol       Date:  1992-07       Impact factor: 10.539
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  46 in total

1.  Clamped-filament elongation model for actin-based motors.

Authors:  Richard B Dickinson; Daniel L Purich
Journal:  Biophys J       Date:  2002-02       Impact factor: 4.033

2.  Force generation by actin polymerization II: the elastic ratchet and tethered filaments.

Authors:  Alex Mogilner; George Oster
Journal:  Biophys J       Date:  2003-03       Impact factor: 4.033

3.  The effect of diffusion, depolymerization and nucleation promoting factors on actin gel growth.

Authors:  Julie Plastino; Ioannis Lelidis; Jacques Prost; Cécile Sykes
Journal:  Eur Biophys J       Date:  2003-12-09       Impact factor: 1.733

4.  Compression forces generated by actin comet tails on lipid vesicles.

Authors:  Paula A Giardini; Daniel A Fletcher; Julie A Theriot
Journal:  Proc Natl Acad Sci U S A       Date:  2003-05-08       Impact factor: 11.205

5.  Probing polymerization forces by using actin-propelled lipid vesicles.

Authors:  Arpita Upadhyaya; Jeffrey R Chabot; Albina Andreeva; Azadeh Samadani; Alexander van Oudenaarden
Journal:  Proc Natl Acad Sci U S A       Date:  2003-03-25       Impact factor: 11.205

6.  Role of tensile stress in actin gels and a symmetry-breaking instability.

Authors:  K Sekimoto; J Prost; F Jülicher; H Boukellal; A Bernheim-Grosswasser
Journal:  Eur Phys J E Soft Matter       Date:  2004-03       Impact factor: 1.890

7.  Forces generated during actin-based propulsion: a direct measurement by micromanipulation.

Authors:  Yann Marcy; Jacques Prost; Marie-France Carlier; Cécile Sykes
Journal:  Proc Natl Acad Sci U S A       Date:  2004-04-12       Impact factor: 11.205

8.  Biophysical parameters influence actin-based movement, trajectory, and initiation in a cell-free system.

Authors:  Lisa A Cameron; Jennifer R Robbins; Matthew J Footer; Julie A Theriot
Journal:  Mol Biol Cell       Date:  2004-03-05       Impact factor: 4.138

9.  Impact of branching on the elasticity of actin networks.

Authors:  Thomas Pujol; Olivia du Roure; Marc Fermigier; Julien Heuvingh
Journal:  Proc Natl Acad Sci U S A       Date:  2012-06-11       Impact factor: 11.205

10.  Force generation of curved actin gels characterized by combined AFM-epifluorescence measurements.

Authors:  Stephan Schmidt; Emmanuèle Helfer; Marie-France Carlier; Andreas Fery
Journal:  Biophys J       Date:  2010-05-19       Impact factor: 4.033
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