In silico reconstitution of Listeria propulsion exhibits nano-saltation

To understand how the actin-polymerization-mediated movements in cells emerge from myriad individual protein-protein interactions, we developed a computational model of Listeria monocytogenes propulsion that explicitly simulates a large number of monomer-scale biochemical and mechanical interactions...

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Bibliographic Details
Published in:PLoS biology 2004-12, Vol.2 (12), p.e412-e412
Main Authors: Alberts, Jonathan B, Odell, Garrett M
Format: Article
Language:English
Subjects:
Actins - chemistry
Actins - metabolism
Behavior
Bioinformatics/Computational Biology
Biophysical Phenomena
Biophysics
Cell Biology
Computational Biology - methods
Computer Simulation
Computers
Cytoskeletal Proteins
Cytoskeleton
Eubacteria
Experiments
Listeria
Listeria monocytogenes
Listeria monocytogenes - metabolism
Listeria monocytogenes - physiology
Models, Biological
Models, Theoretical
Motility
Movement
Probability
Protein Binding
Proteins
Pseudopodia - metabolism
Software
Time Factors
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Summary:To understand how the actin-polymerization-mediated movements in cells emerge from myriad individual protein-protein interactions, we developed a computational model of Listeria monocytogenes propulsion that explicitly simulates a large number of monomer-scale biochemical and mechanical interactions. The literature on actin networks and L. monocytogenes motility provides the foundation for a realistic mathematical/computer simulation, because most of the key rate constants governing actin network dynamics have been measured. We use a cluster of 80 Linux processors and our own suite of simulation and analysis software to characterize salient features of bacterial motion. Our "in silico reconstitution" produces qualitatively realistic bacterial motion with regard to speed and persistence of motion and actin tail morphology. The model also produces smaller scale emergent behavior; we demonstrate how the observed nano-saltatory motion of L. monocytogenes,in which runs punctuate pauses, can emerge from a cooperative binding and breaking of attachments between actin filaments and the bacterium. We describe our modeling methodology in detail, as it is likely to be useful for understanding any subcellular system in which the dynamics of many simple interactions lead to complex emergent behavior, e.g., lamellipodia and filopodia extension, cellular organization, and cytokinesis.
ISSN:1545-7885
1544-9173
1545-7885
DOI:10.1371/journal.pbio.0020412