AMP Aptamer Programs DNA Tile Cohesion without Canonical Base Pairing

Tile-based DNA self-assembly provides a versatile approach for the construction of a wide range of nanostructures for various applications such as nanomedicine and advanced materials. The inter-tile interactions are primarily programmed by base pairing, particularly Watson-Crick base pairing. To further expand the tool box for DNA nanotechnology, herein, we have designed DNA tiles that contain both ligands and aptamers. Upon ligand-aptamer binding, tiles associate into geometrically well-defined nanostructures. This strategy has been demonstrated by the assembly of a series of DNA nanostructures, which have been thoroughly characterized by gel electrophoresis and atomic force microscopy. This new inter-tile cohesion could bring new potentials to DNA self-assembly in the future. For example, the addition of free ligand could modulate the nanostructure formation. In the case of biological ligands, DNA self-assembly could be related to the presence of certain ligands.

Automated summary

Tile-based DNA self-assembly is a versatile method for constructing various nanostructures. By adding ligands and aptamers to DNA tiles, geometrically well-defined nanostructures can be formed through ligand-aptamer binding. This new inter-tile cohesion could have potential applications in DNA self-assembly.