Programmable soft DNA hydrogels stimulate cellular endocytic pathways and proliferation

Abstract

AbstractHydrogels are pivotal in tissue engineering, regenerative medicine, and drug delivery applications. DNA molecules stand out among various biomaterials due to their unparalleled precision, programmability, and customization. In this study, we introduce a palate of novel cellular scaffolding platforms made of pure DNA-based hydrogel systems while improving the shortcomings of the existing platforms. DNA strands can form complex supramolecular branched structures essential for designing novel functional materials by its precise sequence-based self-assembly. These unique geometric scaffolds offer a soft, cushiony platform, ideal for culturing cells to mimic the complex native in vivo environments better. Each hydrogel comprises repeating units of branched DNA supramolecular structures, each possessing a distinct number of branching arms. The epithelial cells grown over these hydrogels show dynamic changes at multiple levels, from morphology to protein expression patterns, enhanced membrane traffic, and proliferation. The DNA hydrogels explored here are mechanically weak and soft and thus appropriate for applications in cell biology. This research lays the groundwork for developing a DNA hydrogel system with a higher dynamic range of stiffness, which will open exciting avenues for tissue engineering and beyond.Graphical abstract illustrating diverse branched DNA supramolecular architectures forming DNA hydrogels of various geometric profiles, each put to use in the cell culture applications.