TY - JOUR
T1 - Mechanotransduction-on-chip
T2 - Vessel-chip model of endothelial YAP mechanobiology reveals matrix stiffness impedes shear response
AU - Walther, Brandon K.
AU - Rajeeva Pandian, Navaneeth Krishna
AU - Gold, Karli A.
AU - Kiliç, Ecem S.
AU - Sama, Vineeth
AU - Gu, Jianhua
AU - Gaharwar, Akhilesh K.
AU - Guiseppi-Elie, Anthony
AU - Cooke, John P.
AU - Jain, Abhishek
N1 - Funding Information:
Research reported in this publication was supported by the NIBIB Award # R21EB025945, NSF CAREER Award #1944322 and Texas A&M University President's Excellence in Research Award (X-Grant) to A. J.; and by funding from the National Heart Lung and Blood Institute, 1R01HL148338 and 1R01HL133254 to J. P. C. Support provided by the consortium of the Center for Bioelectronics, Biosensors and Biochips (C3B®) and from ABTECH Scientific, Inc. The authors acknowledge the support of Texas Engineering Experiment Station (TEES) to A. J., A. K. G, and A. G.-E.: idea: B. K. W., A. J., J. P. C. and A. G.-E.; resources: A. J., A. K. G., J. P. C. and A. G.-E.; investigation: B. K. W., N. K. R. P., K. A. G., E. S. K., V. S., and J. G.; draft preparation, review, and editing: B. K. W., A. G.-E., A. J., J. P. C.
Publisher Copyright:
© The Royal Society of Chemistry.
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
PY - 2021/5/7
Y1 - 2021/5/7
N2 - Endothelial mechanobiology is a key consideration in the progression of vascular dysfunction, including atherosclerosis. However mechanistic connections between the clinically associated physical stimuli, vessel stiffness and shear stress, and how they interact to modulate plaque progression remain incompletely characterized. Vessel-chip systems are excellent candidates for modeling vascular mechanobiology as they may be engineered from the ground up, guided by the mechanical parameters present in human arteries and veins, to recapitulate key features of the vasculature. Here, we report extensive validation of a vessel-chip model of endothelial yes-associated protein (YAP) mechanobiology, a protein sensitive to both matrix stiffness and shearing forces and, importantly, implicated in atherosclerotic progression. Our model captures the established endothelial mechanoresponse, with endothelial alignment, elongation, reduction of adhesion molecules, and YAP cytoplasmic retention under high laminar shear. Conversely, we observed disturbed morphology, inflammation, and nuclear partitioning under low, high, and high oscillatory shear. Examining targets of YAP transcriptional co-activation, connective tissue growth factor (CTGF) is strongly downregulated by high laminar shear, whereas it is strongly upregulated by low shear or oscillatory flow. Ankyrin repeat domain 1 (ANKRD1) is only upregulated by high oscillatory shear. Verteporfin inhibition of YAP reduced the expression of CTGF but did not affect ANKRD1. Lastly, substrate stiffness modulated the endothelial shear mechanoresponse. Under high shear, softer substrates showed the lowest nuclear localization of YAP whereas stiffer substrates increased nuclear localization. Low shear strongly increased nuclear localization of YAP across stiffnesses. Together, we have validated a model of endothelial mechanobiology and describe a clinically relevant biological connection between matrix stiffness, shear stress, and endothelial activation via YAP mechanobiology.
AB - Endothelial mechanobiology is a key consideration in the progression of vascular dysfunction, including atherosclerosis. However mechanistic connections between the clinically associated physical stimuli, vessel stiffness and shear stress, and how they interact to modulate plaque progression remain incompletely characterized. Vessel-chip systems are excellent candidates for modeling vascular mechanobiology as they may be engineered from the ground up, guided by the mechanical parameters present in human arteries and veins, to recapitulate key features of the vasculature. Here, we report extensive validation of a vessel-chip model of endothelial yes-associated protein (YAP) mechanobiology, a protein sensitive to both matrix stiffness and shearing forces and, importantly, implicated in atherosclerotic progression. Our model captures the established endothelial mechanoresponse, with endothelial alignment, elongation, reduction of adhesion molecules, and YAP cytoplasmic retention under high laminar shear. Conversely, we observed disturbed morphology, inflammation, and nuclear partitioning under low, high, and high oscillatory shear. Examining targets of YAP transcriptional co-activation, connective tissue growth factor (CTGF) is strongly downregulated by high laminar shear, whereas it is strongly upregulated by low shear or oscillatory flow. Ankyrin repeat domain 1 (ANKRD1) is only upregulated by high oscillatory shear. Verteporfin inhibition of YAP reduced the expression of CTGF but did not affect ANKRD1. Lastly, substrate stiffness modulated the endothelial shear mechanoresponse. Under high shear, softer substrates showed the lowest nuclear localization of YAP whereas stiffer substrates increased nuclear localization. Low shear strongly increased nuclear localization of YAP across stiffnesses. Together, we have validated a model of endothelial mechanobiology and describe a clinically relevant biological connection between matrix stiffness, shear stress, and endothelial activation via YAP mechanobiology.
KW - Adaptor Proteins, Signal Transducing/metabolism
KW - Atherosclerosis
KW - Biophysics
KW - Humans
KW - Mechanotransduction, Cellular
KW - Transcription Factors/metabolism
UR - http://www.scopus.com/inward/record.url?scp=85105531774&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85105531774&partnerID=8YFLogxK
U2 - 10.1039/d0lc01283a
DO - 10.1039/d0lc01283a
M3 - Article
C2 - 33949409
AN - SCOPUS:85105531774
SN - 1473-0197
VL - 21
SP - 1738
EP - 1751
JO - Lab on a Chip
JF - Lab on a Chip
IS - 9
ER -