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Hydrogel Network Dynamics Regulate Vascular Morphogenesis.

Cell stem cell (2020-09-16)
Zhao Wei, Rahel Schnellmann, Hawley C Pruitt, Sharon Gerecht, Zhao Wei, Rahel Schnellmann, Hawley C Pruitt, Sharon Gerecht
RESUMEN

Matrix dynamics influence how individual cells develop into complex multicellular tissues. Here, we develop hydrogels with identical polymer components but different crosslinking capacities to enable the investigation of mechanisms underlying vascular morphogenesis. We show that dynamic (D) hydrogels increase the contractility of human endothelial colony-forming cells (hECFCs), promote the clustering of integrin β1, and promote the recruitment of vinculin, leading to the activation of focal adhesion kinase (FAK) and metalloproteinase expression. This leads to the robust assembly of vasculature and the deposition of new basement membrane. We also show that non-dynamic (N) hydrogels do not promote FAK signaling and that stiff D- and N-hydrogels are constrained for vascular morphogenesis. Furthermore, D-hydrogels promote hECFC microvessel formation and angiogenesis in vivo. Our results indicate that cell contractility mediates integrin signaling via inside-out signaling and emphasizes the importance of matrix dynamics in vascular tissue formation, thus informing future studies of vascularization and tissue engineering applications.

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Triton X-100, laboratory grade
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Sodium (meta)periodate, ≥99.0%
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Methacrylic anhydride, contains 2,000 ppm topanol A as inhibitor, ≥94%
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2-Hydroxy-4′-(2-hydroxyethoxy)-2-methylpropiophenone, 98%
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Anti-vinculina monoclonal antibody produced in mouse, clone hVIN-1, ascites fluid
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(−)-Blebbistatin, solid, synthetic
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Glycidyl methacrylate, 97%, contains 100 ppm monomethyl ether hydroquinone as inhibitor