Mechanochemical feedback underlies coexistence of qualitatively distinct Cell polarity patterns within diverse cell populations

Jinseok Park; William R. Holmes; Sung Hoon Lee; Hong Nam Kim; Deok Ho Kim; Moon Kyu Kwak; Chiaochun Joanne Wang; Leah Edelstein-Keshet; Andre Levchenko

doi:10.1073/pnas.1700054114

Mechanochemical feedback underlies coexistence of qualitatively distinct Cell polarity patterns within diverse cell populations

Jinseok Park, William R. Holmes, Sung Hoon Lee, Hong Nam Kim, Deok Ho Kim, Moon Kyu Kwak, Chiaochun Joanne Wang, Leah Edelstein-Keshet, Andre Levchenko

Research output: Contribution to journal › Article › peer-review

25 Scopus citations

Abstract

Cell polarization and directional cell migration can display random, persistent, and oscillatory dynamic patterns. However, it is not clear whether these polarity patterns can be explained by the same underlying regulatory mechanism. Here, we show that random, persistent, and oscillatory migration accompanied by polarization can simultaneously occur in populations of melanoma cells derived from tumors with different degrees of aggressiveness. We demonstrate that all of these patterns and the probabilities of their occurrence are quantitatively accounted for by a simple mechanism involving a spatially distributed, mechanochemical feedback coupling the dynamically changing extracellular matrix (ECM)-cell contacts to the activation of signaling downstream of the Rho-family small GTPases. This mechanism is supported by a predictive mathematical model and extensive experimental validation, and can explain previously reported results for diverse cell types. In melanoma, this mechanism also accounts for the effects of genetic and environmental perturbations, including mutations linked to invasive cell spread. The resulting mechanistic understanding of cell polarity quantitatively captures the relationship between population variability and phenotypic plasticity, with the potential to account for a wide variety of cell migration states in diverse pathological and physiological conditions.

Original language	English (US)
Pages (from-to)	E5750-E5759
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	114
Issue number	28
DOIs	https://doi.org/10.1073/pnas.1700054114
State	Published - Jul 11 2017
Externally published	Yes

Keywords

Cell migration
Cell polarization
Extracellular matrix
Mechanochemical feedback
Rho-family small GTPases

ASJC Scopus subject areas

General

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10.1073/pnas.1700054114

Cite this

Park, J., Holmes, W. R., Lee, S. H., Kim, H. N., Kim, D. H., Kwak, M. K., Wang, C. J., Edelstein-Keshet, L., & Levchenko, A. (2017). Mechanochemical feedback underlies coexistence of qualitatively distinct Cell polarity patterns within diverse cell populations. Proceedings of the National Academy of Sciences of the United States of America, 114(28), E5750-E5759. https://doi.org/10.1073/pnas.1700054114

Mechanochemical feedback underlies coexistence of qualitatively distinct Cell polarity patterns within diverse cell populations. / Park, Jinseok; Holmes, William R.; Lee, Sung Hoon et al.
In: Proceedings of the National Academy of Sciences of the United States of America, Vol. 114, No. 28, 11.07.2017, p. E5750-E5759.

Research output: Contribution to journal › Article › peer-review

Park, J, Holmes, WR, Lee, SH, Kim, HN, Kim, DH, Kwak, MK, Wang, CJ, Edelstein-Keshet, L & Levchenko, A 2017, 'Mechanochemical feedback underlies coexistence of qualitatively distinct Cell polarity patterns within diverse cell populations', Proceedings of the National Academy of Sciences of the United States of America, vol. 114, no. 28, pp. E5750-E5759. https://doi.org/10.1073/pnas.1700054114

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abstract = "Cell polarization and directional cell migration can display random, persistent, and oscillatory dynamic patterns. However, it is not clear whether these polarity patterns can be explained by the same underlying regulatory mechanism. Here, we show that random, persistent, and oscillatory migration accompanied by polarization can simultaneously occur in populations of melanoma cells derived from tumors with different degrees of aggressiveness. We demonstrate that all of these patterns and the probabilities of their occurrence are quantitatively accounted for by a simple mechanism involving a spatially distributed, mechanochemical feedback coupling the dynamically changing extracellular matrix (ECM)-cell contacts to the activation of signaling downstream of the Rho-family small GTPases. This mechanism is supported by a predictive mathematical model and extensive experimental validation, and can explain previously reported results for diverse cell types. In melanoma, this mechanism also accounts for the effects of genetic and environmental perturbations, including mutations linked to invasive cell spread. The resulting mechanistic understanding of cell polarity quantitatively captures the relationship between population variability and phenotypic plasticity, with the potential to account for a wide variety of cell migration states in diverse pathological and physiological conditions.",

keywords = "Cell migration, Cell polarization, Extracellular matrix, Mechanochemical feedback, Rho-family small GTPases",

author = "Jinseok Park and Holmes, {William R.} and Lee, {Sung Hoon} and Kim, {Hong Nam} and Kim, {Deok Ho} and Kwak, {Moon Kyu} and Wang, {Chiaochun Joanne} and Leah Edelstein-Keshet and Andre Levchenko",

note = "Funding Information: We thank R. Alani (Boston University) for sharing melanoma cell lines and J. Zhang (University of California, San Diego) for sharing plasmids; J.P. is a recipient of a Samsung scholarship. This work was also supported NIH Grants U54 CA209992 and U01 CA155758 (to A.L.), Natural Sciences and Engineering Research Council of Canada Grant RGPIN-41870 (to L.E.-K.), and NSF Grant DMS-1562078 (to W.R.H.). C.J.W.'s contribution to this work occurred while she was employed by the Johns Hopkins University and does not reflect the views or policies of her current employer, the US Food and Drug Administration.",

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AU - Holmes, William R.

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AU - Kim, Deok Ho

AU - Kwak, Moon Kyu

AU - Wang, Chiaochun Joanne

AU - Edelstein-Keshet, Leah

AU - Levchenko, Andre

N1 - Funding Information: We thank R. Alani (Boston University) for sharing melanoma cell lines and J. Zhang (University of California, San Diego) for sharing plasmids; J.P. is a recipient of a Samsung scholarship. This work was also supported NIH Grants U54 CA209992 and U01 CA155758 (to A.L.), Natural Sciences and Engineering Research Council of Canada Grant RGPIN-41870 (to L.E.-K.), and NSF Grant DMS-1562078 (to W.R.H.). C.J.W.'s contribution to this work occurred while she was employed by the Johns Hopkins University and does not reflect the views or policies of her current employer, the US Food and Drug Administration.

PY - 2017/7/11

Y1 - 2017/7/11

N2 - Cell polarization and directional cell migration can display random, persistent, and oscillatory dynamic patterns. However, it is not clear whether these polarity patterns can be explained by the same underlying regulatory mechanism. Here, we show that random, persistent, and oscillatory migration accompanied by polarization can simultaneously occur in populations of melanoma cells derived from tumors with different degrees of aggressiveness. We demonstrate that all of these patterns and the probabilities of their occurrence are quantitatively accounted for by a simple mechanism involving a spatially distributed, mechanochemical feedback coupling the dynamically changing extracellular matrix (ECM)-cell contacts to the activation of signaling downstream of the Rho-family small GTPases. This mechanism is supported by a predictive mathematical model and extensive experimental validation, and can explain previously reported results for diverse cell types. In melanoma, this mechanism also accounts for the effects of genetic and environmental perturbations, including mutations linked to invasive cell spread. The resulting mechanistic understanding of cell polarity quantitatively captures the relationship between population variability and phenotypic plasticity, with the potential to account for a wide variety of cell migration states in diverse pathological and physiological conditions.

AB - Cell polarization and directional cell migration can display random, persistent, and oscillatory dynamic patterns. However, it is not clear whether these polarity patterns can be explained by the same underlying regulatory mechanism. Here, we show that random, persistent, and oscillatory migration accompanied by polarization can simultaneously occur in populations of melanoma cells derived from tumors with different degrees of aggressiveness. We demonstrate that all of these patterns and the probabilities of their occurrence are quantitatively accounted for by a simple mechanism involving a spatially distributed, mechanochemical feedback coupling the dynamically changing extracellular matrix (ECM)-cell contacts to the activation of signaling downstream of the Rho-family small GTPases. This mechanism is supported by a predictive mathematical model and extensive experimental validation, and can explain previously reported results for diverse cell types. In melanoma, this mechanism also accounts for the effects of genetic and environmental perturbations, including mutations linked to invasive cell spread. The resulting mechanistic understanding of cell polarity quantitatively captures the relationship between population variability and phenotypic plasticity, with the potential to account for a wide variety of cell migration states in diverse pathological and physiological conditions.

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Mechanochemical feedback underlies coexistence of qualitatively distinct Cell polarity patterns within diverse cell populations

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Keywords

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