Open AccessDesigning Uniquely Addressable Bio-orthogonal Synthetic Scaffolds for DNA and RNA Origami
Author(s) -
Jerzy Kozyra,
Alessandro Ceccarelli,
Emanuela Torelli,
Annunziata Lopiccolo,
Jing-Ying Gu,
Harold Fellermann,
Ulrich Stimming,
Natalio Krasnogor
Publication year - 2017
Publication title -
acs synthetic biology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.156
H-Index - 66
ISSN - 2161-5063
DOI - 10.1021/acssynbio.6b00271
Subject(s) - dna origami , synthetic biology , nanotechnology , dna nanotechnology , limiting , scaffold , dna , computational biology , computer science , biology , materials science , engineering , nanostructure , genetics , mechanical engineering , database
Nanotechnology and synthetic biology are rapidly converging, with DNA origami being one of the leading bridging technologies. DNA origami was shown to work well in a wide array of biotic environments. However, the large majority of extant DNA origami scaffolds utilize bacteriophages or plasmid sequences thus severely limiting its future applicability as a bio-orthogonal nanotechnology platform. In this paper we present the design of biologically inert (i.e., "bio-orthogonal") origami scaffolds. The synthetic scaffolds have the additional advantage of being uniquely addressable (unlike biologically derived ones) and hence are better optimized for high-yield folding. We demonstrate our fully synthetic scaffold design with both DNA and RNA origamis and describe a protocol to produce these bio-orthogonal and uniquely addressable origami scaffolds.
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