DNA origami-based nanoribbons: Assembly, length distribution, and twist

Ralf Jungmann; Max Scheible; Anton Kuzyk; Günther Pardatscher; Carlos E. Castro; Friedrich C. Simmel

doi:10.1088/0957-4484/22/27/275301

DNA origami-based nanoribbons: Assembly, length distribution, and twist

Ralf Jungmann, Max Scheible, Anton Kuzyk, Günther Pardatscher, Carlos E. Castro, Friedrich C. Simmel

Chair of Physics of Synthetic Biological Systems

Research output: Contribution to journal › Article › peer-review

55 Scopus citations

Abstract

A variety of polymerization methods for the assembly of elongated nanoribbons from rectangular DNA origami structures are investigated. The most efficient method utilizes single-stranded DNA oligonucleotides to bridge an intermolecular scaffold seam between origami monomers. This approach allows the fabrication of origami ribbons with lengths of several micrometers, which can be used for long-range ordered arrangement of proteins. It is quantitatively shown that the length distribution of origami ribbons obtained with this technique follows the theoretical prediction for a simple linear polymerization reaction. The design of flat single layer origami structures with constant crossover spacing inevitably results in local underwinding of the DNA helix, which leads to a global twist of the origami structures that also translates to the nanoribbons.

Original language	English
Article number	275301
Journal	Nanotechnology
Volume	22
Issue number	27
DOIs	https://doi.org/10.1088/0957-4484/22/27/275301
State	Published - 8 Jul 2011

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abstract = "A variety of polymerization methods for the assembly of elongated nanoribbons from rectangular DNA origami structures are investigated. The most efficient method utilizes single-stranded DNA oligonucleotides to bridge an intermolecular scaffold seam between origami monomers. This approach allows the fabrication of origami ribbons with lengths of several micrometers, which can be used for long-range ordered arrangement of proteins. It is quantitatively shown that the length distribution of origami ribbons obtained with this technique follows the theoretical prediction for a simple linear polymerization reaction. The design of flat single layer origami structures with constant crossover spacing inevitably results in local underwinding of the DNA helix, which leads to a global twist of the origami structures that also translates to the nanoribbons.",

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AU - Simmel, Friedrich C.

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DNA origami-based nanoribbons: Assembly, length distribution, and twist

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