YAP-dependent mechanotransduction is required for proliferation and migration on native-like substrate topography

Shamik Mascharak; Patrick L. Benitez; Amy C. Proctor; Christopher M. Madl; Kenneth H. Hu; Ruby E. Dewi; Manish J. Butte; Sarah C. Heilshorn

doi:10.1016/j.biomaterials.2016.11.019

YAP-dependent mechanotransduction is required for proliferation and migration on native-like substrate topography

Shamik Mascharak, Patrick L. Benitez, Amy C. Proctor, Christopher M. Madl, Kenneth H. Hu, Ruby E. Dewi, Manish J. Butte, Sarah C. Heilshorn

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

52 Scopus citations

Abstract

Native vascular extracellular matrices (vECM) consist of elastic fibers that impart varied topographical properties, yet most in vitro models designed to study the effects of topography on cell behavior are not representative of native architecture. Here, we engineer an electrospun elastin-like protein (ELP) system with independently tunable, vECM-mimetic topography and demonstrate that increasing topographical variation causes loss of endothelial cell-cell junction organization. This loss of VE-cadherin signaling and increased cytoskeletal contractility on more topographically varied ELP substrates in turn promote YAP activation and nuclear translocation, resulting in significantly increased endothelial cell migration and proliferation. Our findings identify YAP as a required signaling factor through which fibrous substrate topography influences cell behavior and highlights topography as a key design parameter for engineered biomaterials.

Original language	English (US)
Pages (from-to)	155-166
Number of pages	12
Journal	Biomaterials
Volume	115
DOIs	https://doi.org/10.1016/j.biomaterials.2016.11.019
State	Published - Jan 1 2017
Externally published	Yes

Keywords

Cell matrix interactions
Electrospinning
Mechanotransduction signaling
Substrate topography

ASJC Scopus subject areas

Biophysics
Bioengineering
Ceramics and Composites
Biomaterials
Mechanics of Materials

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10.1016/j.biomaterials.2016.11.019

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title = "YAP-dependent mechanotransduction is required for proliferation and migration on native-like substrate topography",

abstract = "Native vascular extracellular matrices (vECM) consist of elastic fibers that impart varied topographical properties, yet most in vitro models designed to study the effects of topography on cell behavior are not representative of native architecture. Here, we engineer an electrospun elastin-like protein (ELP) system with independently tunable, vECM-mimetic topography and demonstrate that increasing topographical variation causes loss of endothelial cell-cell junction organization. This loss of VE-cadherin signaling and increased cytoskeletal contractility on more topographically varied ELP substrates in turn promote YAP activation and nuclear translocation, resulting in significantly increased endothelial cell migration and proliferation. Our findings identify YAP as a required signaling factor through which fibrous substrate topography influences cell behavior and highlights topography as a key design parameter for engineered biomaterials.",

keywords = "Cell matrix interactions, Electrospinning, Mechanotransduction signaling, Substrate topography",

author = "Shamik Mascharak and Benitez, {Patrick L.} and Proctor, {Amy C.} and Madl, {Christopher M.} and Hu, {Kenneth H.} and Dewi, {Ruby E.} and Butte, {Manish J.} and Heilshorn, {Sarah C.}",

note = "Funding Information: This work was supported by the following grants: NIH F31-HL114315-01 (P.L.B.), Stanford Bio-X Undergraduate Summer Research Program (S.M.), National Defense Science and Engineering Graduate Fellowship (A.C.P.), NIH F31 EB020502-01 (C.M.M.), NSF DMR 1508006 , NIH R21 EB018407 , NIH U19 AI116484 , (S.C.H.), NIH T32 GM008294 (K.H.H.), and NIH R01 GM110482 (M.J.B.). Publisher Copyright: {\textcopyright} 2016 Elsevier Ltd",

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doi = "10.1016/j.biomaterials.2016.11.019",

language = "English (US)",

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TY - JOUR

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AU - Mascharak, Shamik

AU - Benitez, Patrick L.

AU - Proctor, Amy C.

AU - Madl, Christopher M.

AU - Hu, Kenneth H.

AU - Dewi, Ruby E.

AU - Butte, Manish J.

AU - Heilshorn, Sarah C.

N1 - Funding Information: This work was supported by the following grants: NIH F31-HL114315-01 (P.L.B.), Stanford Bio-X Undergraduate Summer Research Program (S.M.), National Defense Science and Engineering Graduate Fellowship (A.C.P.), NIH F31 EB020502-01 (C.M.M.), NSF DMR 1508006 , NIH R21 EB018407 , NIH U19 AI116484 , (S.C.H.), NIH T32 GM008294 (K.H.H.), and NIH R01 GM110482 (M.J.B.). Publisher Copyright: © 2016 Elsevier Ltd

PY - 2017/1/1

Y1 - 2017/1/1

N2 - Native vascular extracellular matrices (vECM) consist of elastic fibers that impart varied topographical properties, yet most in vitro models designed to study the effects of topography on cell behavior are not representative of native architecture. Here, we engineer an electrospun elastin-like protein (ELP) system with independently tunable, vECM-mimetic topography and demonstrate that increasing topographical variation causes loss of endothelial cell-cell junction organization. This loss of VE-cadherin signaling and increased cytoskeletal contractility on more topographically varied ELP substrates in turn promote YAP activation and nuclear translocation, resulting in significantly increased endothelial cell migration and proliferation. Our findings identify YAP as a required signaling factor through which fibrous substrate topography influences cell behavior and highlights topography as a key design parameter for engineered biomaterials.

AB - Native vascular extracellular matrices (vECM) consist of elastic fibers that impart varied topographical properties, yet most in vitro models designed to study the effects of topography on cell behavior are not representative of native architecture. Here, we engineer an electrospun elastin-like protein (ELP) system with independently tunable, vECM-mimetic topography and demonstrate that increasing topographical variation causes loss of endothelial cell-cell junction organization. This loss of VE-cadherin signaling and increased cytoskeletal contractility on more topographically varied ELP substrates in turn promote YAP activation and nuclear translocation, resulting in significantly increased endothelial cell migration and proliferation. Our findings identify YAP as a required signaling factor through which fibrous substrate topography influences cell behavior and highlights topography as a key design parameter for engineered biomaterials.

KW - Cell matrix interactions

KW - Electrospinning

KW - Mechanotransduction signaling

KW - Substrate topography

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YAP-dependent mechanotransduction is required for proliferation and migration on native-like substrate topography

Abstract

Keywords

ASJC Scopus subject areas

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