Mechanical tension mobilizes Lgr6+ epidermal stem cells to drive skin growth

Yingchao Xue; Chenyi Lyu; Ainsley Taylor; Amy Van Ee; Ashley Kiemen; Younggeun Choi; Nima Khavanian; Dominic Henn; Chaewon Lee; Lisa Hwang; Eric Wier; Saifeng Wang; Sam Lee; Ang Li; Charles Kirby; Gaofeng Wang; Pei Hsun Wu; Denis Wirtz; Luis A. Garza; Sashank K. Reddy

doi:10.1126/sciadv.abl8698

Mechanical tension mobilizes Lgr6+ epidermal stem cells to drive skin growth

Yingchao Xue, Chenyi Lyu, Ainsley Taylor, Amy Van Ee, Ashley Kiemen, Younggeun Choi, Nima Khavanian, Dominic Henn, Chaewon Lee, Lisa Hwang, Eric Wier, Saifeng Wang, Sam Lee, Ang Li, Charles Kirby, Gaofeng Wang, Pei Hsun Wu, Denis Wirtz, Luis A. Garza, Sashank K. Reddy

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

Abstract

Uniquely among mammalian organs, skin is capable of marked size change in adults, yet the mechanisms underlying this notable capacity are unclear. Here, we use a system of controlled tissue expansion in mice to uncover cellular and molecular determinants of skin growth. Through machine learning-guided three-dimensional tissue reconstruction, we capture morphometric changes in growing skin. We find that most growth is driven by the proliferation of the epidermis in response to mechanical tension, with more limited changes in dermal and subdermal compartments. Epidermal growth is achieved through preferential activation and differentiation of Lgr6+ stem cells of the epidermis, driven in part by the Hippo pathway. By single-cell RNA sequencing, we uncover further changes in mechanosensitive and metabolic pathways underlying growth control in the skin. These studies point to therapeutic strategies to enhance skin growth and establish a platform for understanding organ size dynamics in adult mammals.

Original language	English (US)
Article number	eabl8698
Journal	Science Advances
Volume	8
Issue number	17
DOIs	https://doi.org/10.1126/sciadv.abl8698
State	Published - Apr 2022

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Xue, Y., Lyu, C., Taylor, A., Van Ee, A., Kiemen, A., Choi, Y., Khavanian, N., Henn, D., Lee, C., Hwang, L., Wier, E., Wang, S., Lee, S., Li, A., Kirby, C., Wang, G., Wu, P. H., Wirtz, D., Garza, L. A., & Reddy, S. K. (2022). Mechanical tension mobilizes Lgr6+ epidermal stem cells to drive skin growth. Science Advances, 8(17), Article eabl8698. https://doi.org/10.1126/sciadv.abl8698

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title = "Mechanical tension mobilizes Lgr6+ epidermal stem cells to drive skin growth",

abstract = "Uniquely among mammalian organs, skin is capable of marked size change in adults, yet the mechanisms underlying this notable capacity are unclear. Here, we use a system of controlled tissue expansion in mice to uncover cellular and molecular determinants of skin growth. Through machine learning-guided three-dimensional tissue reconstruction, we capture morphometric changes in growing skin. We find that most growth is driven by the proliferation of the epidermis in response to mechanical tension, with more limited changes in dermal and subdermal compartments. Epidermal growth is achieved through preferential activation and differentiation of Lgr6+ stem cells of the epidermis, driven in part by the Hippo pathway. By single-cell RNA sequencing, we uncover further changes in mechanosensitive and metabolic pathways underlying growth control in the skin. These studies point to therapeutic strategies to enhance skin growth and establish a platform for understanding organ size dynamics in adult mammals.",

author = "Yingchao Xue and Chenyi Lyu and Ainsley Taylor and {Van Ee}, Amy and Ashley Kiemen and Younggeun Choi and Nima Khavanian and Dominic Henn and Chaewon Lee and Lisa Hwang and Eric Wier and Saifeng Wang and Sam Lee and Ang Li and Charles Kirby and Gaofeng Wang and Wu, {Pei Hsun} and Denis Wirtz and Garza, {Luis A.} and Reddy, {Sashank K.}",

year = "2022",

month = apr,

doi = "10.1126/sciadv.abl8698",

language = "English (US)",

volume = "8",

journal = "Science Advances",

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publisher = "American Association for the Advancement of Science",

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AU - Xue, Yingchao

AU - Lyu, Chenyi

AU - Taylor, Ainsley

AU - Van Ee, Amy

AU - Kiemen, Ashley

AU - Choi, Younggeun

AU - Khavanian, Nima

AU - Henn, Dominic

AU - Lee, Chaewon

AU - Hwang, Lisa

AU - Wier, Eric

AU - Wang, Saifeng

AU - Lee, Sam

AU - Li, Ang

AU - Kirby, Charles

AU - Wang, Gaofeng

AU - Wu, Pei Hsun

AU - Wirtz, Denis

AU - Garza, Luis A.

AU - Reddy, Sashank K.

PY - 2022/4

Y1 - 2022/4

N2 - Uniquely among mammalian organs, skin is capable of marked size change in adults, yet the mechanisms underlying this notable capacity are unclear. Here, we use a system of controlled tissue expansion in mice to uncover cellular and molecular determinants of skin growth. Through machine learning-guided three-dimensional tissue reconstruction, we capture morphometric changes in growing skin. We find that most growth is driven by the proliferation of the epidermis in response to mechanical tension, with more limited changes in dermal and subdermal compartments. Epidermal growth is achieved through preferential activation and differentiation of Lgr6+ stem cells of the epidermis, driven in part by the Hippo pathway. By single-cell RNA sequencing, we uncover further changes in mechanosensitive and metabolic pathways underlying growth control in the skin. These studies point to therapeutic strategies to enhance skin growth and establish a platform for understanding organ size dynamics in adult mammals.

AB - Uniquely among mammalian organs, skin is capable of marked size change in adults, yet the mechanisms underlying this notable capacity are unclear. Here, we use a system of controlled tissue expansion in mice to uncover cellular and molecular determinants of skin growth. Through machine learning-guided three-dimensional tissue reconstruction, we capture morphometric changes in growing skin. We find that most growth is driven by the proliferation of the epidermis in response to mechanical tension, with more limited changes in dermal and subdermal compartments. Epidermal growth is achieved through preferential activation and differentiation of Lgr6+ stem cells of the epidermis, driven in part by the Hippo pathway. By single-cell RNA sequencing, we uncover further changes in mechanosensitive and metabolic pathways underlying growth control in the skin. These studies point to therapeutic strategies to enhance skin growth and establish a platform for understanding organ size dynamics in adult mammals.

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Mechanical tension mobilizes Lgr6+ epidermal stem cells to drive skin growth

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