Issue 24, 2024

Hierarchical assembly and modeling of DNA nanotube networks using Y-shaped DNA origami seeds

Abstract

DNA nanotechnology offers many means to synthesize custom nanostructured materials from the ground up in a hierarchical fashion. While the assembly of DNA nanostructures from small (nanometer-scale) monomeric components has been studied extensively, how the hierarchical assembly of rigid or semi-flexible units produces multi-micron scale structures is less understood. Here we demonstrate a mechanism for assembling micron-scale semi-flexible DNA nanotubes into extended structures. These nanotubes assemble from nanometer-scale tile monomers into materials via heterogeneous nucleation from rigid, Y-shaped DNA origami seeds to form Y-seeded nanotube architectures. These structures then assemble into networks via nanotube end-to-end joining. We measure the kinetics of network growth and find that the assembly of networks can be approximated by a model of hierarchical assembly that assumes a single joining rate between DNA nanotube ends. Because the number of nucleation sites on Y-seeds and their spatial arrangement can be systematically varied by design, this hierarchical assembly process could be used to form a wide variety of networks and to understand the assembly mechanisms that lead to different types of material architectures at length scales of tens to hundreds of microns.

Graphical abstract: Hierarchical assembly and modeling of DNA nanotube networks using Y-shaped DNA origami seeds

Supplementary files

Article information

Article type
Paper
Submitted
12 Mar 2024
Accepted
23 May 2024
First published
29 May 2024

Nanoscale, 2024,16, 11688-11695

Hierarchical assembly and modeling of DNA nanotube networks using Y-shaped DNA origami seeds

Y. Jiang, M. S. Pacella, S. Lee, J. Zhang, J. A. Gunn, P. Vallejo, P. Singh, T. Hou, E. Liu and R. Schulman, Nanoscale, 2024, 16, 11688 DOI: 10.1039/D4NR01066C

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