Cell–matrix feedback controls stretch-induced cellular memory and fibroblast activation

Yuan Hong; Xiangjun Peng; Haomin Yu; Mohammad Jafari; Delaram Shakiba; Yuxuan Huang; Chengqing Qu; Ermia E. Melika; Andrew K. Tawadros; Aliza Mujahid; Yin Yuan Huang; Jacob A. Sandler; Kenneth M. Pryse; Justin M. Sacks; Elliot L. Elson; Guy M. Genin; Farid Alisafaei

doi:10.1073/pnas.2322762122

Cell–matrix feedback controls stretch-induced cellular memory and fibroblast activation

Yuan Hong, Xiangjun Peng, Haomin Yu, Mohammad Jafari, Delaram Shakiba, Yuxuan Huang, Chengqing Qu, Ermia E. Melika, Andrew K. Tawadros, Aliza Mujahid, Yin Yuan Huang, Jacob A. Sandler, Kenneth M. Pryse, Justin M. Sacks, Elliot L. Elson, Guy M. Genin, Farid Alisafaei

Mechanical and Industrial Engr

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

1 Scopus citations

Abstract

Mechanical stretch can activate long-lived changes in fibroblasts, increasing their contractility and initiating phenotypic transformations. This activation, critical to wound healing and procedures such as skin grafting, increases with mechanical stimulus for cells cultured in two-dimensional but is highly variable in cells in three-dimensional (3D) tissue. Here, we show that static mechanical stretch of cells in 3D tissues can either increase or decrease fibroblast activation depending upon recursive cell–extracellular matrix (ECM) feedback and demonstrate control of this activation through integrated in vitro and mathematical models. ECM viscoelasticity, signaling dynamics, and cell mechanics combine to yield a predictable, but nonmonotonic, relationship between mechanical stretch and long-term cell activation. Results demonstrate that feedback between cells and ECM determine how cells retain memory of mechanical stretch and have direct implications for improving outcomes in skin grafting procedures.

Original language	English (US)
Article number	e2322762122
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	122
Issue number	12
DOIs	https://doi.org/10.1073/pnas.2322762122
State	Published - Mar 25 2025

All Science Journal Classification (ASJC) codes

General

Keywords

cell-matrix feedback
fibroblasts
mechanical memory
mechanobiology
mechanotransduction

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10.1073/pnas.2322762122

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Hong, Y., Peng, X., Yu, H., Jafari, M., Shakiba, D., Huang, Y., Qu, C., Melika, E. E., Tawadros, A. K., Mujahid, A., Huang, Y. Y., Sandler, J. A., Pryse, K. M., Sacks, J. M., Elson, E. L., Genin, G. M., & Alisafaei, F. (2025). Cell–matrix feedback controls stretch-induced cellular memory and fibroblast activation. Proceedings of the National Academy of Sciences of the United States of America, 122(12), Article e2322762122. https://doi.org/10.1073/pnas.2322762122

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title = "Cell–matrix feedback controls stretch-induced cellular memory and fibroblast activation",

abstract = "Mechanical stretch can activate long-lived changes in fibroblasts, increasing their contractility and initiating phenotypic transformations. This activation, critical to wound healing and procedures such as skin grafting, increases with mechanical stimulus for cells cultured in two-dimensional but is highly variable in cells in three-dimensional (3D) tissue. Here, we show that static mechanical stretch of cells in 3D tissues can either increase or decrease fibroblast activation depending upon recursive cell–extracellular matrix (ECM) feedback and demonstrate control of this activation through integrated in vitro and mathematical models. ECM viscoelasticity, signaling dynamics, and cell mechanics combine to yield a predictable, but nonmonotonic, relationship between mechanical stretch and long-term cell activation. Results demonstrate that feedback between cells and ECM determine how cells retain memory of mechanical stretch and have direct implications for improving outcomes in skin grafting procedures.",

keywords = "cell-matrix feedback, fibroblasts, mechanical memory, mechanobiology, mechanotransduction",

author = "Yuan Hong and Xiangjun Peng and Haomin Yu and Mohammad Jafari and Delaram Shakiba and Yuxuan Huang and Chengqing Qu and Melika, {Ermia E.} and Tawadros, {Andrew K.} and Aliza Mujahid and Huang, {Yin Yuan} and Sandler, {Jacob A.} and Pryse, {Kenneth M.} and Sacks, {Justin M.} and Elson, {Elliot L.} and Genin, {Guy M.} and Farid Alisafaei",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 the Author(s).",

year = "2025",

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day = "25",

doi = "10.1073/pnas.2322762122",

language = "English (US)",

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Hong, Y, Peng, X, Yu, H, Jafari, M, Shakiba, D, Huang, Y, Qu, C, Melika, EE, Tawadros, AK, Mujahid, A, Huang, YY, Sandler, JA, Pryse, KM, Sacks, JM, Elson, EL, Genin, GM & Alisafaei, F 2025, 'Cell–matrix feedback controls stretch-induced cellular memory and fibroblast activation', Proceedings of the National Academy of Sciences of the United States of America, vol. 122, no. 12, e2322762122. https://doi.org/10.1073/pnas.2322762122

TY - JOUR

T1 - Cell–matrix feedback controls stretch-induced cellular memory and fibroblast activation

AU - Hong, Yuan

AU - Peng, Xiangjun

AU - Yu, Haomin

AU - Jafari, Mohammad

AU - Shakiba, Delaram

AU - Huang, Yuxuan

AU - Qu, Chengqing

AU - Melika, Ermia E.

AU - Tawadros, Andrew K.

AU - Mujahid, Aliza

AU - Huang, Yin Yuan

AU - Sandler, Jacob A.

AU - Pryse, Kenneth M.

AU - Sacks, Justin M.

AU - Elson, Elliot L.

AU - Genin, Guy M.

AU - Alisafaei, Farid

PY - 2025/3/25

Y1 - 2025/3/25

N2 - Mechanical stretch can activate long-lived changes in fibroblasts, increasing their contractility and initiating phenotypic transformations. This activation, critical to wound healing and procedures such as skin grafting, increases with mechanical stimulus for cells cultured in two-dimensional but is highly variable in cells in three-dimensional (3D) tissue. Here, we show that static mechanical stretch of cells in 3D tissues can either increase or decrease fibroblast activation depending upon recursive cell–extracellular matrix (ECM) feedback and demonstrate control of this activation through integrated in vitro and mathematical models. ECM viscoelasticity, signaling dynamics, and cell mechanics combine to yield a predictable, but nonmonotonic, relationship between mechanical stretch and long-term cell activation. Results demonstrate that feedback between cells and ECM determine how cells retain memory of mechanical stretch and have direct implications for improving outcomes in skin grafting procedures.

AB - Mechanical stretch can activate long-lived changes in fibroblasts, increasing their contractility and initiating phenotypic transformations. This activation, critical to wound healing and procedures such as skin grafting, increases with mechanical stimulus for cells cultured in two-dimensional but is highly variable in cells in three-dimensional (3D) tissue. Here, we show that static mechanical stretch of cells in 3D tissues can either increase or decrease fibroblast activation depending upon recursive cell–extracellular matrix (ECM) feedback and demonstrate control of this activation through integrated in vitro and mathematical models. ECM viscoelasticity, signaling dynamics, and cell mechanics combine to yield a predictable, but nonmonotonic, relationship between mechanical stretch and long-term cell activation. Results demonstrate that feedback between cells and ECM determine how cells retain memory of mechanical stretch and have direct implications for improving outcomes in skin grafting procedures.

KW - cell-matrix feedback

KW - fibroblasts

KW - mechanical memory

KW - mechanobiology

KW - mechanotransduction

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M1 - e2322762122

ER -

Cell–matrix feedback controls stretch-induced cellular memory and fibroblast activation

Abstract

All Science Journal Classification (ASJC) codes

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