Computational model for amoeboid motion: Coupling membrane and cytosol dynamics

Computational model for amoeboid motion: Coupling membrane and cytosol dynamics

A distinguishing feature of amoeboid motion is that the migrating cell undergoes large deformations, caused by the emergence and retraction of actin-rich protrusions, called pseudopods. Here, we propose a cell motility model that represents pseudopod dynamics, as well as its interaction with membran...

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Veröffentlicht in:Physical review. E 2016-10, Vol.94 (4-1), p.042423-042423, Article 042423
Hauptverfasser: Moure, Adrian, Gomez, Hector
Format: Artikel
Sprache:eng
Schlagworte:
Actins - metabolism
Amoeba - physiology
Cell Membrane - physiology
Cytosol - metabolism
Environment
Models, Biological
Motor Activity - physiology
Signal Transduction
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Zusammenfassung:A distinguishing feature of amoeboid motion is that the migrating cell undergoes large deformations, caused by the emergence and retraction of actin-rich protrusions, called pseudopods. Here, we propose a cell motility model that represents pseudopod dynamics, as well as its interaction with membrane signaling molecules. The model accounts for internal and external forces, such as protrusion, contraction, adhesion, surface tension, or those arising from cell-obstacle contacts. By coupling the membrane and cytosol interactions we are able to reproduce a realistic picture of amoeboid motion. The model results are in quantitative agreement with experiments and show how cells may take advantage of the geometry of their microenvironment to migrate more efficiently.
ISSN:2470-0045
2470-0053
DOI:10.1103/physreve.94.042423