DNA rendering of polyhedral meshes at the nanoscale

Abstract: It was first suggested 1 more than 30 years ago that Watson-Crick base pairing might be used to rationally design nanoscale structures from nucleic acids. Since then, and especially since introduction of the origami technique 2 , DNA nanotechnology has seen astonishing developments and increasingly more complex structures are being produced [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] . But even though general approaches for creating DNA origami polygonal meshes and design software are available 1… Show more

“…6−14 New software also makes designing large nanostructures with tailored properties easier than ever. 15,16 Some of these synthetic structures are static and include crystals, 17−19 polyhedra, 12,20−25 wire-frame designs, 11,26,27 and topological structures such as mobius strips, 28 while others are "active" systems that include walkers, 29,30 gears and hinges, 31 robots, 32,33 and crank-sliders. 34 However, having total control over the structural as well as time-dependent properties of selfassembled DNA nanostructures remains a significant design challenge.…”

Characterizing DNA Star-Tile-Based Nanostructures Using a Coarse-Grained Model

“…6−14 New software also makes designing large nanostructures with tailored properties easier than ever. 15,16 Some of these synthetic structures are static and include crystals, 17−19 polyhedra, 12,20−25 wire-frame designs, 11,26,27 and topological structures such as mobius strips, 28 while others are "active" systems that include walkers, 29,30 gears and hinges, 31 robots, 32,33 and crank-sliders. 34 However, having total control over the structural as well as time-dependent properties of selfassembled DNA nanostructures remains a significant design challenge.…”

Characterizing DNA Star-Tile-Based Nanostructures Using a Coarse-Grained Model

“…This conventional design strategy was turned on its head last year by the first topdown software for building wireframe DNA nanoarchitectures 7 . The software vHelix 7 is based on selecting a target shape that fits to the length of the available scaffold and subsequently creating a polyhedral meshwork of the object-an approach well known in computer graphics.…”

“…1a). The wireframe motif is based on two interconnected DNA double helices (i.e., doublecrossover (DX) molecules), allowing more structural robustness than the previously reported topdown objects with single duplex edges 7 . After designing the shape and obtaining the sequences, researchers fabricate the structures using standard annealing routines.…”

Automated design of DNA origami

“…Almost at the same time, Högberg et al and Schmidt et al, independently, presented a general method to fold arbitrary 3D DNA structures with trigonal mesh elements, and most of the edges of the meshes were single duplexes (thus suitable for experiments in low ionic-strength environments). [49,50] More recently, Bathe et al demonstrated a generalizable top-down strategy towards an inverse sequence design of DNA origami based on a target shape ( Figure 4E). [51] This allows a fully automatic sequence generation by a computer program with significantly facilitated synthesis of nearly arbitrary wireframe DNA architectures.…”

“…This technique has offered DNA nanotechnologists unlimited imaginations to create nearly arbitrary shapes on the nanoscale towards various possible applications. [44][45][46][47][48][49][50][51] In addition, because the sequence of the scaffold M13 strand is known, intellectual burden during the design of a complex DNA structure is greatly reduced with the aid of a properly written computer program.…”

Supramolecular Wireframe DNA Polyhedra: Assembly and Applications