Abstract

Protein-based biomaterials have received significant attention for tissue engineering applications. For example, resilin-based protein gels have been produced with different cross-linking chemistries for applications in cartilage, cardiovascular, and vocal fold engineering. In this study, we investigate an alternative cross-linking chemistry to form resilin-based protein hydrogels and demonstrate the versatility of the gels for investigating cell response to matrix stiffness. Specifically, transglutaminase was used to cross-link proteins and resulted in gel surfaces more suitable for long-term cell attachment compared to those formed by a Mannich-type condensation reaction. Since matrix stiffness is an important determinant in modulating cell response, we first tuned matrix stiffness by varying total protein concentration. Next, we observed that matrix stiffness modulated cell spreading and endothelial differentiation of human mesenchymal stem cells. In particular, our results show that cells differentiated on our matrices, which have a stiffness similar to subendothelial layers, had statistically equivalent endothelial function compared to cells differentiated on hard glass surfaces. Thus, our protein-based matrix system is a promising tool to provide substrates favorable for long-term cell attachment and better mimics the native subendothelial environment compared to conventional hard culture substrates.