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Seeding the Self-Assembly of DNA Origamis at Surfaces

Huan H. Cao, Gary R. Abel, Qufei Gu, Gloria-Alexandra V. Gueorguieva, Yehan Zhang, Warren A. Nanney, Eric T. Provencio, Tao Ye

2020ACS Nano26 citationsDOIOpen Access PDF

Abstract

Unlike supramolecular self-assembly methods that can organize many distinct components into designer shapes in a homogeneous solution (e.g., DNA origami), only relatively simple, symmetric structures consisting of a few distinct components have been self-assembled at solid surfaces. As the self-assembly process is confined to the surface/interface by mostly nonspecific attractive interactions, an open question is how these interfacial interactions affect multicomponent self-assembly. To gain a mechanistic understanding of the roles of the surface environment in DNA origami self-assembly, here we studied the oligonucleotide-assisted folding of a long single-stranded DNA (ssDNA scaffold) that was end-tethered to a dynamic surface, which could actively regulate the DNA-surface interactions. The results showed that even weak surface attractions can lead to defective structures by inhibiting the merging of multiple domains into complete structures. A combination of surface anchoring and deliberate regulation of DNA-surface interactions allowed us to depart from the existing paradigm of surface confinement via nonspecific interactions and enabled DNA origami folding to proceed in a solution-like environment. Importantly, our strategy retains the key advantages of surface-mediated self-assembly. For example, surface-anchored oligonucleotides could sequence-specifically initiate the growth of DNA origamis of specific sizes and shapes. Our work enables information to be encoded into a surface and expressed into complex DNA surface architectures for potential nanoelectronic and nanophotonic applications. In addition, our approach to surface confinement may facilitate the 2D self-assembly of other molecular components, such as proteins, as maintaining conformational freedom may be a general challenge in the self-assembly of complex structures at surfaces.

Topics & Concepts

DNA origamiSelf-assemblyNanotechnologyFolding (DSP implementation)OligonucleotideDNADNA nanotechnologySupramolecular chemistryMaterials scienceSurface (topology)ChemistryNanostructureCrystallographyCrystal structureGeometryMathematicsElectrical engineeringBiochemistryEngineeringAdvanced biosensing and bioanalysis techniquesRNA Interference and Gene DeliveryPlasmonic and Surface Plasmon Research
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