Independent control over cell patterning and adhesion on hydrogel substrates for tissue interface mechanobiology

Abstract

Replicating organizational principles that establish fine-scale tissue structure is critical to our capacity for building functional replacement tissues. Tissue boundaries such as epithelial-mesenchymal interfaces are engines for morphogenesis in vivo. However, despite a wealth of micropatterning approaches available to control tissue size, shape, and mechanical environment in vitro, fine-scale spatial control of cell composition within tissue constructs remains an engineering challenge. To address this, we augment DNA “velcro” technology for selective patterning of ssDNA-labeled cells with long-term culture on mechanically defined polyacrylamide hydrogels. We co-functionalize photoactive benzophenone-containing polyacrylamide gels (BP-PA gels) with spatially precise ssDNA features that confer temporary cell adhesion and with extracellular matrix (ECM) proteins that confer long-term adhesion. We find that co-functionalization does not compromise ssDNA patterning fidelity or cell capture, nor hydrogel mechanical properties or mechanosensitive fibroblast spreading, enabling mechanobiology studies of precise cell interfaces. We then co-pattern colonies of fibroblasts and epithelial cells to study interface formation and extracellular signal-related kinase (ERK) activity at cellular contacts. Combining DNA velcro and ECM functionalization approaches provides independent control of initial cell placement, adhesion, and mechanical environment, constituting a new tool for studying biological interfaces and for programming multicellular interactions in engineered tissues.