Near Quantitative Ligation Results in Resistance of DNA Origami Against Nuclease and Cell Lysate.

There have been limited efforts to ligate the staple nicks in DNA origami which is crucial for their stability against thermal and mechanical treatments, and chemical and biological environments. Here, two near quantitative ligation methods are demonstrated for the native backbone linkage at the nicks in origami: i) a cosolvent dimethyl sulfoxide (DMSO)-assisted enzymatic ligation and ii) enzyme-free chemical ligation by CNBr. Both methods achieved over 90% ligation in 2D origami, only CNBr-method resulted in ≈80% ligation in 3D origami, while the enzyme-alone yielded 31-55% (2D) or 22-36% (3D) ligation.

Topologically-Interlocked Minicircles as Probes of DNA Topology and DNA-Protein Interactions.

Invited for the cover of this issue are Prof. Takashi Morii and co-workers at Kyoto University and Ewha Womans University. The cover image depicts the graphical design and atomic force microscopic (AFM) images of the synthesized topologically-interlocked DNA catenane and rotaxanes inside a frame-shaped DNA origami.

Topologically-Interlocked Minicircles as Probes of DNA Topology and DNA-Protein Interactions.

DNA minicircles exist in biological contexts, such as kinetoplast DNA, and are promising components for creating functional nanodevices. They have been used to mimic the topological features of nucleosomal DNA and to probe DNA-protein interactions such as HIV-1 and PFV integrases, and DNA gyrase. Here, we synthesized the topologically-interlocked minicircle rotaxane and catenane inside a frame-shaped DNA origami.

Stabilization and structural changes of 2D DNA origami by enzymatic ligation.

The low thermal stability of DNA nanostructures is the major drawback in their practical applications. Most of the DNA nanotubes/tiles and the DNA origami structures melt below 60°C due to the presence of discontinuities in the phosphate backbone (i.e.