Summary information and primary citation

PDB-id
7u41; DSSR-derived features in text and JSON formats
Class
DNA
Method
X-ray (7.24 Å)
Summary
[f234] self-assembling tensegrity triangle with two turns, three turns and four turns of DNA per axis by extension with p1 symmetry
Reference
Woloszyn K, Vecchioni S, Ohayon YP, Lu B, Ma Y, Huang Q, Zhu E, Chernovolenko D, Markus T, Jonoska N, Mao C, Seeman NC, Sha R (2022): "Augmented DNA Nanoarchitectures: A Structural Library of 3D Self-Assembling Tensegrity Triangle Variants." Adv Mater, 34, e2206876. doi: 10.1002/adma.202206876.
Abstract
The DNA tensegrity triangle is known to reliably self-assemble into a 3D rhombohedral crystalline lattice via sticky-end cohesion. Here, we expand the library of accessible motifs through (1) covalent extensions of inter-triangle regions and (2) sticky-end coordinated linkages of adjacent triangles with double helical segments using both geometrically symmetric and asymmetric configurations. We report the molecular structures of eighteen self-assembled architectures at resolutions of 3.32-9.32 Å; the observed cell dimensions, cavity sizes, and cross-sectional areas agree with theoretical expectations. These data demonstrate that fine control over triclinic and rhombohedral crystal parameters and the customizability of more complex 3D DNA lattices are attainable via rational design. We anticipate that augmented DNA architectures may be fine-tuned for the self-assembly of designer nano-cages, guest-host complexes, and proscriptive 3D nanomaterials, as originally envisioned. Finally, designer asymmetric crystalline building blocks can be seen as a first step toward controlling and encoding information in three dimensions. This article is protected by copyright. All rights reserved.

Cartoon-block schematics in six views (download the tarball)

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