Perivascular cells function as key mediators of mechanical and structural changes in vascular capillaries

Cristiane M. Franca; Maria Elisa Lima Verde; Alice Correa Silva-Sousa; Amin Mansoorifar; Avathamsa Athirasala; Ramesh Subbiah; Anthony Tahayeri; Mauricio Sousa; May Anny Fraga; Rahul M. Visalakshan; Aaron Doe; Keith Beadle; McKenna Finley; Emilios Dimitriadis; Jennifer Bays; Marina Uroz; Kenneth M. Yamada; Christopher Chen; Luiz E. Bertassoni

doi:10.1126/sciadv.adp3789

Perivascular cells function as key mediators of mechanical and structural changes in vascular capillaries

Cristiane M. Franca, Maria Elisa Lima Verde, Alice Correa Silva-Sousa, Amin Mansoorifar, Avathamsa Athirasala, Ramesh Subbiah, Anthony Tahayeri, Mauricio Sousa, May Anny Fraga, Rahul M. Visalakshan, Aaron Doe, Keith Beadle, McKenna Finley, Emilios Dimitriadis, Jennifer Bays, Marina Uroz, Kenneth M. Yamada, Christopher Chen, Luiz E. Bertassoni

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Abstract

A hallmark of chronic and inflammatory diseases is the formation of a fibrotic and stiff extracellular matrix (ECM), typically associated with abnormal, leaky microvascular capillaries. Mechanisms explaining how the microvasculature responds to ECM alterations remain unknown. Here, we used a microphysiological model of capillaries on a chip mimicking the characteristics of healthy or fibrotic collagen to test the hypothesis that perivascular cells mediate the response of vascular capillaries to mechanical and structural changes in the human ECM. Capillaries engineered in altered fibrotic collagen had abnormal migration of perivascular cells, reduced pericyte differentiation, increased leakage, and higher regulation of inflammatory/remodeling genes, all regulated via NOTCH3, a known mediator of endothelial-perivascular cell communication. Capillaries engineered either with endothelial cells alone or with perivascular cells silenced for NOTCH3 expression showed a minimal response to ECM alterations. These findings reveal a previously unknown mechanism of vascular response to changes in the ECM in health and disease.

Original language	English (US)
Article number	eadp3789
Journal	Science Advances
Volume	11
Issue number	2
DOIs	https://doi.org/10.1126/sciadv.adp3789
State	Published - Jan 10 2025

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Franca, C. M., Verde, M. E. L., Silva-Sousa, A. C., Mansoorifar, A., Athirasala, A., Subbiah, R., Tahayeri, A., Sousa, M., Fraga, M. A., Visalakshan, R. M., Doe, A., Beadle, K., Finley, M., Dimitriadis, E., Bays, J., Uroz, M., Yamada, K. M., Chen, C., & Bertassoni, L. E. (2025). Perivascular cells function as key mediators of mechanical and structural changes in vascular capillaries. Science Advances, 11(2), Article eadp3789. https://doi.org/10.1126/sciadv.adp3789

Franca, CM, Verde, MEL, Silva-Sousa, AC, Mansoorifar, A, Athirasala, A, Subbiah, R, Tahayeri, A, Sousa, M, Fraga, MA, Visalakshan, RM, Doe, A, Beadle, K, Finley, M, Dimitriadis, E, Bays, J, Uroz, M, Yamada, KM, Chen, C & Bertassoni, LE 2025, 'Perivascular cells function as key mediators of mechanical and structural changes in vascular capillaries', Science Advances, vol. 11, no. 2, eadp3789. https://doi.org/10.1126/sciadv.adp3789

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title = "Perivascular cells function as key mediators of mechanical and structural changes in vascular capillaries",

abstract = "A hallmark of chronic and inflammatory diseases is the formation of a fibrotic and stiff extracellular matrix (ECM), typically associated with abnormal, leaky microvascular capillaries. Mechanisms explaining how the microvasculature responds to ECM alterations remain unknown. Here, we used a microphysiological model of capillaries on a chip mimicking the characteristics of healthy or fibrotic collagen to test the hypothesis that perivascular cells mediate the response of vascular capillaries to mechanical and structural changes in the human ECM. Capillaries engineered in altered fibrotic collagen had abnormal migration of perivascular cells, reduced pericyte differentiation, increased leakage, and higher regulation of inflammatory/remodeling genes, all regulated via NOTCH3, a known mediator of endothelial-perivascular cell communication. Capillaries engineered either with endothelial cells alone or with perivascular cells silenced for NOTCH3 expression showed a minimal response to ECM alterations. These findings reveal a previously unknown mechanism of vascular response to changes in the ECM in health and disease.",

author = "Franca, \{Cristiane M.\} and Verde, \{Maria Elisa Lima\} and Silva-Sousa, \{Alice Correa\} and Amin Mansoorifar and Avathamsa Athirasala and Ramesh Subbiah and Anthony Tahayeri and Mauricio Sousa and Fraga, \{May Anny\} and Visalakshan, \{Rahul M.\} and Aaron Doe and Keith Beadle and McKenna Finley and Emilios Dimitriadis and Jennifer Bays and Marina Uroz and Yamada, \{Kenneth M.\} and Christopher Chen and Bertassoni, \{Luiz E.\}",

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doi = "10.1126/sciadv.adp3789",

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AU - Franca, Cristiane M.

AU - Verde, Maria Elisa Lima

AU - Silva-Sousa, Alice Correa

AU - Mansoorifar, Amin

AU - Athirasala, Avathamsa

AU - Subbiah, Ramesh

AU - Tahayeri, Anthony

AU - Sousa, Mauricio

AU - Fraga, May Anny

AU - Visalakshan, Rahul M.

AU - Doe, Aaron

AU - Beadle, Keith

AU - Finley, McKenna

AU - Dimitriadis, Emilios

AU - Bays, Jennifer

AU - Uroz, Marina

AU - Yamada, Kenneth M.

AU - Chen, Christopher

AU - Bertassoni, Luiz E.

PY - 2025/1/10

Y1 - 2025/1/10

N2 - A hallmark of chronic and inflammatory diseases is the formation of a fibrotic and stiff extracellular matrix (ECM), typically associated with abnormal, leaky microvascular capillaries. Mechanisms explaining how the microvasculature responds to ECM alterations remain unknown. Here, we used a microphysiological model of capillaries on a chip mimicking the characteristics of healthy or fibrotic collagen to test the hypothesis that perivascular cells mediate the response of vascular capillaries to mechanical and structural changes in the human ECM. Capillaries engineered in altered fibrotic collagen had abnormal migration of perivascular cells, reduced pericyte differentiation, increased leakage, and higher regulation of inflammatory/remodeling genes, all regulated via NOTCH3, a known mediator of endothelial-perivascular cell communication. Capillaries engineered either with endothelial cells alone or with perivascular cells silenced for NOTCH3 expression showed a minimal response to ECM alterations. These findings reveal a previously unknown mechanism of vascular response to changes in the ECM in health and disease.

AB - A hallmark of chronic and inflammatory diseases is the formation of a fibrotic and stiff extracellular matrix (ECM), typically associated with abnormal, leaky microvascular capillaries. Mechanisms explaining how the microvasculature responds to ECM alterations remain unknown. Here, we used a microphysiological model of capillaries on a chip mimicking the characteristics of healthy or fibrotic collagen to test the hypothesis that perivascular cells mediate the response of vascular capillaries to mechanical and structural changes in the human ECM. Capillaries engineered in altered fibrotic collagen had abnormal migration of perivascular cells, reduced pericyte differentiation, increased leakage, and higher regulation of inflammatory/remodeling genes, all regulated via NOTCH3, a known mediator of endothelial-perivascular cell communication. Capillaries engineered either with endothelial cells alone or with perivascular cells silenced for NOTCH3 expression showed a minimal response to ECM alterations. These findings reveal a previously unknown mechanism of vascular response to changes in the ECM in health and disease.

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Perivascular cells function as key mediators of mechanical and structural changes in vascular capillaries

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