Tension anisotropy drives fibroblast phenotypic transition by self-reinforcing cell–extracellular matrix mechanical feedback

Farid Alisafaei; Delaram Shakiba; Yuan Hong; Ghiska Ramahdita; Yuxuan Huang; Leanne E. Iannucci; Matthew D. Davidson; Mohammad Jafari; Jin Qian; Chengqing Qu; David Ju; Dashiell R. Flory; Yin Yuan Huang; Prashant Gupta; Shumeng Jiang; Aliza Mujahid; Srikanth Singamaneni; Kenneth M. Pryse; Pen hsiu Grace Chao; Jason A. Burdick; Spencer P. Lake; Elliot L. Elson; Nathaniel Huebsch; Vivek B. Shenoy; Guy M. Genin

doi:10.1038/s41563-025-02162-5

Tension anisotropy drives fibroblast phenotypic transition by self-reinforcing cell–extracellular matrix mechanical feedback

Farid Alisafaei, Delaram Shakiba, Yuan Hong, Ghiska Ramahdita, Yuxuan Huang, Leanne E. Iannucci, Matthew D. Davidson, Mohammad Jafari, Jin Qian, Chengqing Qu, David Ju, Dashiell R. Flory, Yin Yuan Huang, Prashant Gupta, Shumeng Jiang, Aliza Mujahid, Srikanth Singamaneni, Kenneth M. Pryse, Pen hsiu Grace Chao, Jason A. BurdickSpencer P. Lake, Elliot L. Elson, Nathaniel Huebsch, Vivek B. Shenoy, Guy M. Genin

Mechanical and Industrial Engr

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

Abstract

Mechanical factors such as stress in the extracellular environment affect the phenotypic commitment of cells. Stress fields experienced by cells in tissues are multiaxial, but how cells integrate such information is largely unknown. Here we report that the anisotropy of stress fields is a critical factor triggering a phenotypic transition in fibroblast cells, outweighing the role of stress amplitude, a factor previously described to modulate such a transition. Combining experimental and computational approaches, we identified a self-reinforcing mechanism in which cellular protrusions interact with collagen fibres to establish tension anisotropy. This anisotropy, in turn, stabilizes the protrusions and enhances their contractile forces. Disruption of this self-reinforcing process, either by reducing tension anisotropy or by inhibiting contractile protrusions, prevents the phenotypic conversion of fibroblasts to contractile myofibroblasts. Overall, our findings support stress anisotropy as a factor modulating cellular responses, expanding our understanding of the role of mechanical forces in biological processes.

Original language	English (US)
Article number	eabe9446
Journal	Nature Materials
DOIs	https://doi.org/10.1038/s41563-025-02162-5
State	Accepted/In press - 2025

All Science Journal Classification (ASJC) codes

General Chemistry
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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10.1038/s41563-025-02162-5

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Alisafaei, F., Shakiba, D., Hong, Y., Ramahdita, G., Huang, Y., Iannucci, L. E., Davidson, M. D., Jafari, M., Qian, J., Qu, C., Ju, D., Flory, D. R., Huang, Y. Y., Gupta, P., Jiang, S., Mujahid, A., Singamaneni, S., Pryse, K. M., Chao, P. H. G., ... Genin, G. M. (Accepted/In press). Tension anisotropy drives fibroblast phenotypic transition by self-reinforcing cell–extracellular matrix mechanical feedback. Nature Materials, Article eabe9446. https://doi.org/10.1038/s41563-025-02162-5

@article{ef96c06c0c0e4c3a837f06d08e89662a,

title = "Tension anisotropy drives fibroblast phenotypic transition by self-reinforcing cell–extracellular matrix mechanical feedback",

abstract = "Mechanical factors such as stress in the extracellular environment affect the phenotypic commitment of cells. Stress fields experienced by cells in tissues are multiaxial, but how cells integrate such information is largely unknown. Here we report that the anisotropy of stress fields is a critical factor triggering a phenotypic transition in fibroblast cells, outweighing the role of stress amplitude, a factor previously described to modulate such a transition. Combining experimental and computational approaches, we identified a self-reinforcing mechanism in which cellular protrusions interact with collagen fibres to establish tension anisotropy. This anisotropy, in turn, stabilizes the protrusions and enhances their contractile forces. Disruption of this self-reinforcing process, either by reducing tension anisotropy or by inhibiting contractile protrusions, prevents the phenotypic conversion of fibroblasts to contractile myofibroblasts. Overall, our findings support stress anisotropy as a factor modulating cellular responses, expanding our understanding of the role of mechanical forces in biological processes.",

author = "Farid Alisafaei and Delaram Shakiba and Yuan Hong and Ghiska Ramahdita and Yuxuan Huang and Iannucci, {Leanne E.} and Davidson, {Matthew D.} and Mohammad Jafari and Jin Qian and Chengqing Qu and David Ju and Flory, {Dashiell R.} and Huang, {Yin Yuan} and Prashant Gupta and Shumeng Jiang and Aliza Mujahid and Srikanth Singamaneni and Pryse, {Kenneth M.} and Chao, {Pen hsiu Grace} and Burdick, {Jason A.} and Lake, {Spencer P.} and Elson, {Elliot L.} and Nathaniel Huebsch and Shenoy, {Vivek B.} and Genin, {Guy M.}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

year = "2025",

doi = "10.1038/s41563-025-02162-5",

language = "English (US)",

journal = "Nature Materials",

issn = "1476-1122",

publisher = "Nature Publishing Group",

}

Alisafaei, F, Shakiba, D, Hong, Y, Ramahdita, G, Huang, Y, Iannucci, LE, Davidson, MD, Jafari, M, Qian, J, Qu, C, Ju, D, Flory, DR, Huang, YY, Gupta, P, Jiang, S, Mujahid, A, Singamaneni, S, Pryse, KM, Chao, PHG, Burdick, JA, Lake, SP, Elson, EL, Huebsch, N, Shenoy, VB & Genin, GM 2025, 'Tension anisotropy drives fibroblast phenotypic transition by self-reinforcing cell–extracellular matrix mechanical feedback', Nature Materials. https://doi.org/10.1038/s41563-025-02162-5

TY - JOUR

T1 - Tension anisotropy drives fibroblast phenotypic transition by self-reinforcing cell–extracellular matrix mechanical feedback

AU - Alisafaei, Farid

AU - Shakiba, Delaram

AU - Hong, Yuan

AU - Ramahdita, Ghiska

AU - Huang, Yuxuan

AU - Iannucci, Leanne E.

AU - Davidson, Matthew D.

AU - Jafari, Mohammad

AU - Qian, Jin

AU - Qu, Chengqing

AU - Ju, David

AU - Flory, Dashiell R.

AU - Huang, Yin Yuan

AU - Gupta, Prashant

AU - Jiang, Shumeng

AU - Mujahid, Aliza

AU - Singamaneni, Srikanth

AU - Pryse, Kenneth M.

AU - Chao, Pen hsiu Grace

AU - Burdick, Jason A.

AU - Lake, Spencer P.

AU - Elson, Elliot L.

AU - Huebsch, Nathaniel

AU - Shenoy, Vivek B.

AU - Genin, Guy M.

PY - 2025

Y1 - 2025

N2 - Mechanical factors such as stress in the extracellular environment affect the phenotypic commitment of cells. Stress fields experienced by cells in tissues are multiaxial, but how cells integrate such information is largely unknown. Here we report that the anisotropy of stress fields is a critical factor triggering a phenotypic transition in fibroblast cells, outweighing the role of stress amplitude, a factor previously described to modulate such a transition. Combining experimental and computational approaches, we identified a self-reinforcing mechanism in which cellular protrusions interact with collagen fibres to establish tension anisotropy. This anisotropy, in turn, stabilizes the protrusions and enhances their contractile forces. Disruption of this self-reinforcing process, either by reducing tension anisotropy or by inhibiting contractile protrusions, prevents the phenotypic conversion of fibroblasts to contractile myofibroblasts. Overall, our findings support stress anisotropy as a factor modulating cellular responses, expanding our understanding of the role of mechanical forces in biological processes.

AB - Mechanical factors such as stress in the extracellular environment affect the phenotypic commitment of cells. Stress fields experienced by cells in tissues are multiaxial, but how cells integrate such information is largely unknown. Here we report that the anisotropy of stress fields is a critical factor triggering a phenotypic transition in fibroblast cells, outweighing the role of stress amplitude, a factor previously described to modulate such a transition. Combining experimental and computational approaches, we identified a self-reinforcing mechanism in which cellular protrusions interact with collagen fibres to establish tension anisotropy. This anisotropy, in turn, stabilizes the protrusions and enhances their contractile forces. Disruption of this self-reinforcing process, either by reducing tension anisotropy or by inhibiting contractile protrusions, prevents the phenotypic conversion of fibroblasts to contractile myofibroblasts. Overall, our findings support stress anisotropy as a factor modulating cellular responses, expanding our understanding of the role of mechanical forces in biological processes.

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U2 - 10.1038/s41563-025-02162-5

DO - 10.1038/s41563-025-02162-5

M3 - Article

AN - SCOPUS:105000704174

SN - 1476-1122

JO - Nature Materials

JF - Nature Materials

M1 - eabe9446

ER -

Tension anisotropy drives fibroblast phenotypic transition by self-reinforcing cell–extracellular matrix mechanical feedback

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