A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix

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A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix. / Owen, Leanna M.; Adhikari, Arjun S.; Patel, Mohak; Grimmer, Peter; Leijnse, Natascha; Kim, Min Cheol; Notbohm, Jacob; Franck, Christian; Dunn, Alexander R.

In: Molecular Biology of the Cell, Vol. 28, No. 14, 07.07.2017, p. 1959-1974.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Owen, LM, Adhikari, AS, Patel, M, Grimmer, P, Leijnse, N, Kim, MC, Notbohm, J, Franck, C & Dunn, AR 2017, 'A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix', Molecular Biology of the Cell, vol. 28, no. 14, pp. 1959-1974. https://doi.org/10.1091/mbc.E17-02-0102

APA

Owen, L. M., Adhikari, A. S., Patel, M., Grimmer, P., Leijnse, N., Kim, M. C., Notbohm, J., Franck, C., & Dunn, A. R. (2017). A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix. Molecular Biology of the Cell, 28(14), 1959-1974. https://doi.org/10.1091/mbc.E17-02-0102

Vancouver

Owen LM, Adhikari AS, Patel M, Grimmer P, Leijnse N, Kim MC et al. A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix. Molecular Biology of the Cell. 2017 Jul 7;28(14):1959-1974. https://doi.org/10.1091/mbc.E17-02-0102

Author

Owen, Leanna M. ; Adhikari, Arjun S. ; Patel, Mohak ; Grimmer, Peter ; Leijnse, Natascha ; Kim, Min Cheol ; Notbohm, Jacob ; Franck, Christian ; Dunn, Alexander R. / A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix. In: Molecular Biology of the Cell. 2017 ; Vol. 28, No. 14. pp. 1959-1974.

Bibtex

@article{7b571760afd44e05a8ee057785c91b12,
title = "A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix",
abstract = "The ability of cells to impart forces and deformations on their surroundings underlies cell migration and extracellular matrix (ECM) remodeling and is thus an essential aspect of complex, metazoan life. Previous work has resulted in a refined understanding, commonly termed the molecular clutch model, of how cells adhering to flat surfaces such as a microscope coverslip transmit cytoskeletally generated forces to their surroundings. Comparatively less is known about how cells adhere to and exert forces in soft, three-dimensional (3D), and structurally heterogeneous ECM environments such as occur in vivo. We used time-lapse 3D imaging and quantitative image analysis to determine how the actin cytoskeleton is mechanically coupled to the surrounding matrix for primary dermal fibroblasts embedded in a 3D fibrin matrix. Under these circumstances, the cytoskeletal architecture is dominated by contractile actin bundles attached at their ends to large, stable, integrin-based adhesions. Time-lapse imaging reveals that α-actinin-1 puncta within actomyosin bundles move more quickly than the paxillin-rich adhesion plaques, which in turn move more quickly than the local matrix, an observation reminiscent of the molecular clutch model. However, closer examination did not reveal a continuous rearward flow of the actin cytoskeleton over slower moving adhesions. Instead, we found that a subset of stress fibers continuously elongated at their attachment points to integrin adhesions, providing stable, yet structurally dynamic coupling to the ECM. Analytical modeling and numerical simulation provide a plausible physical explanation for this result and support a picture in which cells respond to the effective stiffness of local matrix attachment points. The resulting dynamic equilibrium can explain how cells maintain stable, contractile connections to discrete points within ECM during cell migration, and provides a plausible means by which fibroblasts contract provisional matrices during wound healing.",
author = "Owen, {Leanna M.} and Adhikari, {Arjun S.} and Mohak Patel and Peter Grimmer and Natascha Leijnse and Kim, {Min Cheol} and Jacob Notbohm and Christian Franck and Dunn, {Alexander R.}",
year = "2017",
month = jul,
day = "7",
doi = "10.1091/mbc.E17-02-0102",
language = "English",
volume = "28",
pages = "1959--1974",
journal = "Molecular Biology of the Cell",
issn = "1059-1524",
publisher = "American Society for Cell Biology",
number = "14",

}

RIS

TY - JOUR

T1 - A cytoskeletal clutch mediates cellular force transmission in a soft, three-dimensional extracellular matrix

AU - Owen, Leanna M.

AU - Adhikari, Arjun S.

AU - Patel, Mohak

AU - Grimmer, Peter

AU - Leijnse, Natascha

AU - Kim, Min Cheol

AU - Notbohm, Jacob

AU - Franck, Christian

AU - Dunn, Alexander R.

PY - 2017/7/7

Y1 - 2017/7/7

N2 - The ability of cells to impart forces and deformations on their surroundings underlies cell migration and extracellular matrix (ECM) remodeling and is thus an essential aspect of complex, metazoan life. Previous work has resulted in a refined understanding, commonly termed the molecular clutch model, of how cells adhering to flat surfaces such as a microscope coverslip transmit cytoskeletally generated forces to their surroundings. Comparatively less is known about how cells adhere to and exert forces in soft, three-dimensional (3D), and structurally heterogeneous ECM environments such as occur in vivo. We used time-lapse 3D imaging and quantitative image analysis to determine how the actin cytoskeleton is mechanically coupled to the surrounding matrix for primary dermal fibroblasts embedded in a 3D fibrin matrix. Under these circumstances, the cytoskeletal architecture is dominated by contractile actin bundles attached at their ends to large, stable, integrin-based adhesions. Time-lapse imaging reveals that α-actinin-1 puncta within actomyosin bundles move more quickly than the paxillin-rich adhesion plaques, which in turn move more quickly than the local matrix, an observation reminiscent of the molecular clutch model. However, closer examination did not reveal a continuous rearward flow of the actin cytoskeleton over slower moving adhesions. Instead, we found that a subset of stress fibers continuously elongated at their attachment points to integrin adhesions, providing stable, yet structurally dynamic coupling to the ECM. Analytical modeling and numerical simulation provide a plausible physical explanation for this result and support a picture in which cells respond to the effective stiffness of local matrix attachment points. The resulting dynamic equilibrium can explain how cells maintain stable, contractile connections to discrete points within ECM during cell migration, and provides a plausible means by which fibroblasts contract provisional matrices during wound healing.

AB - The ability of cells to impart forces and deformations on their surroundings underlies cell migration and extracellular matrix (ECM) remodeling and is thus an essential aspect of complex, metazoan life. Previous work has resulted in a refined understanding, commonly termed the molecular clutch model, of how cells adhering to flat surfaces such as a microscope coverslip transmit cytoskeletally generated forces to their surroundings. Comparatively less is known about how cells adhere to and exert forces in soft, three-dimensional (3D), and structurally heterogeneous ECM environments such as occur in vivo. We used time-lapse 3D imaging and quantitative image analysis to determine how the actin cytoskeleton is mechanically coupled to the surrounding matrix for primary dermal fibroblasts embedded in a 3D fibrin matrix. Under these circumstances, the cytoskeletal architecture is dominated by contractile actin bundles attached at their ends to large, stable, integrin-based adhesions. Time-lapse imaging reveals that α-actinin-1 puncta within actomyosin bundles move more quickly than the paxillin-rich adhesion plaques, which in turn move more quickly than the local matrix, an observation reminiscent of the molecular clutch model. However, closer examination did not reveal a continuous rearward flow of the actin cytoskeleton over slower moving adhesions. Instead, we found that a subset of stress fibers continuously elongated at their attachment points to integrin adhesions, providing stable, yet structurally dynamic coupling to the ECM. Analytical modeling and numerical simulation provide a plausible physical explanation for this result and support a picture in which cells respond to the effective stiffness of local matrix attachment points. The resulting dynamic equilibrium can explain how cells maintain stable, contractile connections to discrete points within ECM during cell migration, and provides a plausible means by which fibroblasts contract provisional matrices during wound healing.

UR - http://www.scopus.com/inward/record.url?scp=85022335240&partnerID=8YFLogxK

U2 - 10.1091/mbc.E17-02-0102

DO - 10.1091/mbc.E17-02-0102

M3 - Journal article

C2 - 28592635

AN - SCOPUS:85022335240

VL - 28

SP - 1959

EP - 1974

JO - Molecular Biology of the Cell

JF - Molecular Biology of the Cell

SN - 1059-1524

IS - 14

ER -

ID: 258630211