Unveiling DNA Origami Interaction Dynamics on Living Cell Surfaces by Single Particle Tracking

Due to the unique spatial addressability of DNA origami, targeting ligands (e.g. aptamers or antibodies) can be specifically positioned onto the surface of the nanostructure, constituting an essential tool for studying ligand-receptor interactions at the cell surface. While the design and ligand incorporation into DNA origami nanostructures are well-established, the study of cell surface interaction dynamics is still in the explorative phase, where in depth fundamental understanding on the molecular interactions remains underexplored. This study uniquely captures real-time encounters between DNA origami and cells in-situ using single particle tracking (SPT). Here, we functionalized DNA nanorods (NRs) with antibodies or aptamers specific to the epidermal growth factor receptor (EGFR) and used them to target EGFR-overexpressing cancer cells. SPT data revealed that ligand coated NRs selectively bound to the receptors expressed in target cancer cells, while non-functionalized NRs only display negligible cell interactions. Furthermore, we explored the effect of ligand density on the DNA origami, which revealed that aptamer-decorated NRs exhibit non-linear binding characteristics, whereas this effect in antibody-decorated NRs was less pronounced. This study provides new mechanistic insights into the fundamental understanding of DNA origami behaviour at the cell interface, with unprecedented spatiotemporal resolution, aiding the rational design of ligand-targeted DNA origami for biomedical applications.