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Reconfigurable, braced, three-dimensional DNA nanostructures.

Abstract:
DNA nanotechnology makes use of the exquisite self-recognition of DNA in order to build on a molecular scale. Although static structures may find applications in structural biology and computer science, many applications in nanomedicine and nanorobotics require the additional capacity for controlled three-dimensional movement. DNA architectures can span three dimensions and DNA devices are capable of movement, but active control of well-defined three-dimensional structures has not been achieved. We demonstrate the operation of reconfigurable DNA tetrahedra whose shapes change precisely and reversibly in response to specific molecular signals. Shape changes are confirmed by gel electrophoresis and by bulk and single-molecule Förster resonance energy transfer measurements. DNA tetrahedra are natural building blocks for three-dimensional construction; they may be synthesized rapidly with high yield of a single stereoisomer, and their triangulated architecture conveys structural stability. The introduction of shape-changing structural modules opens new avenues for the manipulation of matter on the nanometre scale.
Publication status:
Published

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Publisher copy:
10.1038/nnano.2008.3

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Journal:
Nature nanotechnology More from this journal
Volume:
3
Issue:
2
Pages:
93-96
Publication date:
2008-02-01
DOI:
EISSN:
1748-3395
ISSN:
1748-3387


Language:
English
Keywords:
Pubs id:
pubs:16414
UUID:
uuid:c34ae51b-e514-4904-a952-1c48bac7fd56
Local pid:
pubs:16414
Source identifiers:
16414
Deposit date:
2012-12-19
ARK identifier:

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