Author: ["Xavier Trepat","Michael R. Wasserman","Thomas E. Angelini","Emil Millet","David A. Weitz","James P. Butler","Jeffrey J. Fredberg"]
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Abstract
It has been thought that sheets of cells move by traction forces exerted by the cells at the leading edge of the sheet. Using traction microscopy to create a map of physical forces, it is now shown that in fact it is cells many rows from the front that do most of the work. Fundamental biological processes including morphogenesis, tissue repair and tumour metastasis require collective cell motions1,2,3, and to drive these motions cells exert traction forces on their surroundings4. Current understanding emphasizes that these traction forces arise mainly in ‘leader cells’ at the front edge of the advancing cell sheet5,6,7,8,9. Our data are contrary to that assumption and show for the first time by direct measurement that traction forces driving collective cell migration arise predominately many cell rows behind the leading front edge and extend across enormous distances. Traction fluctuations are anomalous, moreover, exhibiting broad non-Gaussian distributions characterized by exponential tails10,11,12. Taken together, these unexpected findings demonstrate that although the leader cell may have a pivotal role in local cell guidance, physical forces that it generates are but a small part of a global tug-of-war involving cells well back from the leading edge.Cite this article
Trepat, X., Wasserman, M., Angelini, T. et al. Physical forces during collective cell migration. Nature Phys 5, 426–430 (2009). https://doi.org/10.1038/nphys1269 