Tuning the Roundabout of Four-Point-Star Tiles with the Core Arm Length of Three Half-Turns for 2D DNA Arrays.

By rationally adjusting the weaving modes of point-star tiles, the curvature inherent in the tiles can be changed, and various DNA nanostructures can be assembled, such as planar wireframe meshes, perforated wireframe tubes, and curved wireframe polyhedra. Based on the weaving and tiling architectures for traditional point-star tiles with the core arm length at two DNA half-turns, we improved the weaving modes of our newly reported four-point-star tiles with the core arm length at three half-turns to adjust their curvature and rigidity for assembling 2D arrays of DNA grids and tubes. Following our previous terms and methods to analyze the structural details of E-tiling tubes, we used the chiral indices (n,m) to describe the most abundant tube of typical assemblies; especially, we applied both one-locus and/or dual-locus biotin/streptavidin (SA) labelling strategies to define the configurations of two specific tubes, along with the absolute conformations of their component tiles. Such structural details of the DNA tubes composed of tiles with addressable concave and convex faces and packing directions should help us understand their physio-chemical and biological properties, and therefore promote their applications in drug delivery, biocatalysis, biomedicine, etc.

2D DNA lattices assembled from DX-coupled tiles.

HYPOTHESIS: Formation of coupled double crossovers (DXs) in a circular 106-mer oligonucleotide (c106nt) could generate stable tiles with the tile core span of 10 half turns. The large-span tiles with complicated curvatures and mechanics could assemble 2D lattices under different environments. Hence, 2D DNA lattice structures based on tile types and sequences, tile packing modes of corrugation and non-corrugation, and assembly media of solution and the substrate-solution interface are yet to be explored. EXPERIMENTS: Two c106nt scaffold strands with different sequences were synthesized. Four types of tiles, two rectilinear and two triangular tiles, were designed and their 2D assemblies were examined by atomic force microscopy (AFM). FINDINGS: The DX-coupled tiles provided fair strength and rigidity to assemble 2D lattices. Due to the complicated curvature and mechanics of tiles, the two-tile assemblies in solution displayed a few ripe lattices of ribbons, tubes, or polycrystalline aggregates as the minor products and tile oligomers as the major products; whereas the one-tile assemblies via substrate mediation exhibited well-organized monolayer lattices covering the whole mica disk. The herringbone packing patterns were first observed in DNA nanostructures. Based on the lattice constants and the surface coverages of lattices, we estimated the lattice yields for the substrate-mediated assemblies.