Issue 47, 2021

DNA nanostructures directed by RNA clamps

Abstract

DNA chains can be folded rationally by using DNA staples, and the programmed structures are of great potential in nanomaterial studies. However, due to the short DNA staples forming duplexes and displaying limitations in structural diversity and stability, the folded DNA nanostructures are usually generated with structural mis-formations, low yields and poor efficiencies, which can restrict their folding patterns and applications. To overcome these problems, we set out to use RNA as a clamp to form polygons, and herein demonstrated the ability to use a structural RNA—but not its corresponding DNA—to fold DNA chains into nanostructures with high efficiency (up to a 95.1% yield). Furthermore, we discovered that the 2′-methylated version of the RNA can, compared to the unmodified RNA, even more efficiently fold DNA chains (up to a 98.5% yield). Interestingly, the RNA clamp can fold DNA scaffolds with one, two or four folding units into the same square shape. Furthermore, the RNA can direct the DNA chains with three, four and five folding units into triangular, square and pentagonal nano-shapes, respectively. In addition, we confirmed their enlarged nano-shapes by performing electron microscopy (EM) imaging. These formed nanostructures revealed the potential cooperation between the DNA scaffold and RNA clamp. Moreover, our research demonstrated a novel strategy, involving using RNA clamps displaying structural diversity and duplex stability, for folding DNA into diverse nanostructures.

Graphical abstract: DNA nanostructures directed by RNA clamps

Supplementary files

Article information

Article type
Communication
Submitted
17 Jun 2021
Accepted
07 Sep 2021
First published
26 Nov 2021

Nanoscale, 2021,13, 19870-19874

DNA nanostructures directed by RNA clamps

J. Lyu, M. Yang, C. Zhang, Y. Luo, T. Qin, Z. Su and Z. Huang, Nanoscale, 2021, 13, 19870 DOI: 10.1039/D1NR03919A

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