Metastasis begins with the escape, or dissemination, of cancer cells from the primary tumor. We recently demonstrated that tumors preferentially disseminate into collagen I and not into basement membrane protein gels (Matrigel). In this study, we used synthetic polymer systems to define material properties that could induce dissemination into Matrigel. We first specifically varied rigidity by varying the crosslinking density of poly(ethylene glycol) (PEG) networks within Matrigel scaffolds. Increased microenvironmental rigidity limited epithelial growth but did not promote dissemination. We next incorporated adhesive signals into the PEG network using peptide-conjugated cyclodextrin (α-CDYRGDS) rings. The α-CDYRGDS rings threaded along the PEG polymers, enabling independent control of matrix mechanics, adhesive peptide composition, and adhesive density. Adhesive PEG networks induced dissemination of normal and malignant mammary epithelial cells at intermediate values of adhesion and rigidity. Our data reveal that microenvironmental signals can induce dissemination of normal and malignant epithelial cells without requiring the fibrillar structure of collagen I or containing collagen I-specific adhesion sequences. Finally, the nanobiomaterials and assays developed in this study are generally useful both in 3D culture of primary mammalian tissues and in the systematic evaluation of the specific role of mechanical and adhesive inputs on 3D tumor growth, invasion, and dissemination.
The osteochondral microenvironment involves a complex milieu of cues that facilitate proper tissue development, homeostasis, and repair. This environment is disrupted in disease states such as osteoarthritis. Mesenchymal stem cells (MSCs) are under clinical investigation for the treatment of osteoarthritis given their capacity to differentiate into chondrocytes as well as to secrete a wide array of biologically active factors that support cell proliferation and tissue formation. In fact, the therapeutic action of these cells in many clinical applications is now thought to be at least partially dependent on their secretory capacity. Previous work demonstrated that MSCs were capable of stimulating chondrocyte growth and tissue production, whereas tissue-derived osteoblasts were not stimulatory. This study investigated the stimulatory capacity of MSCs during osteogenesis and the impact of MSC phenotype on cartilage stimulation. Cell interactions were examined in 3 coculture systems to confirm that trends were not dependent on material: traditional cell culture insert coculture, bilayered poly(ethylene glycol) gels, and a scaffold comprised of a layer of poly(ethylene glycol) polymerized onto a poly(lactic-co-glycolic) acid-based scaffold. Results demonstrated that MSCs predifferentiated toward an osteogenic phenotype for 3 days exhibited enhanced stimulation of chondrocyte extracellular matrix production, whereas longer periods of predifferentiation decreased the magnitude of observed stimulation. Further, tissue formation by the MSCs themselves showed greater dependence on the coculture system than the presence of other cells or length of predifferentiation.
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