Symmetry-breaking in mammalian cell cohort migration during tissue pattern formation: Role of random-walk persistence

Coordinated, cohort cell migration plays an important role in the morphogenesis of tissue patterns in metazoa. However, individual cells intrinsically move in a random walk‐like fashion when studied in vitro. Hence, in the absence of an external orchestrating influence or template, the emergence of...

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Bibliographic Details
Published in:Cell motility and the cytoskeleton 2005-08, Vol.61 (4), p.201-213
Main Authors: Huang, S., Brangwynne, C.P., Parker, K.K., Ingber, D.E.
Format: Article
Language:English
Subjects:
Animals
Cattle
Cell Movement - physiology
Cells, Cultured
Computational Biology
development
endothelial cell
Endothelial Cells - physiology
Mice
microfabrication
Microscopy, Phase-Contrast
Models, Biological
morphogenesis
motility
NIH 3T3 Cells
Rotation
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Summary:Coordinated, cohort cell migration plays an important role in the morphogenesis of tissue patterns in metazoa. However, individual cells intrinsically move in a random walk‐like fashion when studied in vitro. Hence, in the absence of an external orchestrating influence or template, the emergence of cohort cell migration must involve a symmetry‐breaking event. To study this process, we used a novel experimental system in which multiple capillary endothelial cells exhibit spontaneous and robust cohort migration in the absence of chemical gradients when cultured on micrometer‐scale extracellular matrix islands fabricated using microcontact printing. A computational model suggested that directional persistence of random‐walk and dynamic mechanical coupling of adjacent cells are the critical control parameters for this symmetry‐breaking behavior that is induced in spatially‐constrained cell ensembles. The model predicted our finding that fibroblasts, which exhibit a much shorter motility persistence time than endothelial cells, failed to undergo symmetry breaking or produce cohort migration on the matrix islands. These findings suggest that cells have intrinsic motility characteristics that are tuned to match their role in tissue patterning. Our results underscore the importance of studying cell motility in the context of cell populations, and the need to address emergent features in multicellular organisms that arise not only from cell‐cell and cell‐matrix interactions, but also from properties that are intrinsic to individual cells. Cell Motil. Cytoskeleton 61:201–213, 2005. © 2005 Wiley‐Liss, Inc.
ISSN:0886-1544
1097-0169
DOI:10.1002/cm.20077