Browsing by Subject "mushroom tyrosinase"

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    Enzymatic crosslinking of dynamic hydrogels for in vitro cell culture
    (2018-04) Arkenberg, Matthew R.; Lin, Chien-Chi
    Stiffening and softening of extracellular matrix (ECM) are critical processes governing many aspects of biological processes. The most common practice used to investigate these processes is seeding cells on two-dimensional (2D) surfaces of varying stiffness. In recent years, cell-laden three-dimensional (3D) scaffolds with controllable properties are also increasingly used. However, current 2D and 3D culture platforms do not permit spatiotemporal controls over material properties that could influence tissue processes. To address this issue, four-dimensional (4D) hydrogels (i.e., 3D materials permitting time-dependent control of matrix properties) are proposed to recapitulate dynamic changes of ECM properties. The goal of this thesis was to exploit orthogonal enzymatic reactions for on-demand stiffening and/or softening of cell-laden hydrogels. The first objective was to establish cytocompatible hydrogels permitting enzymatic crosslinking and stiffening using enzymes with orthogonal reactivity. Sortase A (SrtA) and mushroom tyrosinase (MT) were used sequentially to achieve initial gelation and on-demand stiffening. In addition, hydrogels permitting reversible stiffening through SrtA-mediated peptide ligation were established. Specifically, poly(ethylene glycol) (PEG)-peptide hydrogels were fabricated with peptide linkers containing pendent SrtA substrates. The hydrogels were stiffened through incubation with SrtA, whereas gel softening was achieved subsequently via addition of SrtA and soluble glycine substrate. The second objective was to investigate the role of dynamic matrix stiffening on pancreatic cancer cell survival, spheroid formation, and drug responsiveness. The crosslinking of PEG-peptide hydrogels was dynamically tuned to evaluate the effect of matrix stiffness on cell viability and function. Specifically, dynamic matrix stiffening inhibited cell proliferation and spheroid formation, while softening the cell-laden hydrogels led to significant increase in spheroid sizes. Matrix stiffness also altered the expression of chemoresistance markers and responsiveness of cancer cells to gemcitabine treatment. markers and responsiveness of cancer cells to gemcitabine treatment.
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    Orthogonal enzymatic reactions for rapid crosslinking and dynamic tuning of PEG–peptide hydrogels
    (RSC, 2017-11) Arkenberg, Matthew R.; Lin, Chien-Chi; Biomedical Engineering, School of Engineering and Technology
    Stiffening of the extracellular matrix is a hallmark in cancer progression, embryonic development, and wound healing. To mimic this dynamic process, our work explored orthogonal enzymatic reactions capable of modulating the properties of poly(ethylene glycol) (PEG)–peptide hydrogels. A hepta-mutant bacterial transpeptidase sortase A (SrtA7M) was used to ligate two PEG–peptide macromers (i.e., PEG-YLPRTG and NH2-GGGG-PEG) into a primary hydrogel network. The hydrogels were dynamically stiffened using mushroom tyrosinase (MT), which oxidized tyrosine residues into di-tyrosine and led to increased matrix stiffness. After confirming the expression and enhanced catalytic activity of SrtA7M, we investigated the cytocompatibility of the enzymatic reaction with a mouse insulinoma cell line, MIN6. In addition, we altered peptide substrate concentrations and evaluated their influence on primary hydrogel network properties and MT-triggered stiffening. Using a pancreatic cancer cell line, COLO-357, the effect of MT-triggered stiffening on spheroid formation was investigated. We found that cell spheroids formed in hydrogels that were exposed to MT were significantly smaller than spheroids formed without MT incubation, suggesting that matrix stiffening played a crucial role in the sizes of cancer cell spheroids. Through utilizing highly specific and orthogonal enzymatic reactions, this hydrogel platform permits rapid and mild in situ cell encapsulation, as well as dynamic control of matrix stiffness for investigating the role of matrix stiffening on cell fate processes.