DNA Origami with Complex Curvatures in Three-Dimensional Space

Dongran Han(Arizona State University), Suchetan Pal(Arizona State University), Jeanette Nangreave(Arizona State University), Zhengtao Deng(Arizona State University), Yan Liu(Arizona State University), Hao Yan(Arizona State University)
Science
April 14, 2011
10.1126/science.1202998
Cited by 1,222

Abstract

We present a strategy to design and construct self-assembling DNA nanostructures that define intricate curved surfaces in three-dimensional (3D) space using the DNA origami folding technique. Double-helical DNA is bent to follow the rounded contours of the target object, and potential strand crossovers are subsequently identified. Concentric rings of DNA are used to generate in-plane curvature, constrained to 2D by rationally designed geometries and crossover networks. Out-of-plane curvature is introduced by adjusting the particular position and pattern of crossovers between adjacent DNA double helices, whose conformation often deviates from the natural, B-form twist density. A series of DNA nanostructures with high curvature--such as 2D arrangements of concentric rings and 3D spherical shells, ellipsoidal shells, and a nanoflask--were assembled.

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