Optical Voltage Sensing Using DNA Origami

Elisa A. Hemmig; Clare Fitzgerald; Christopher Maffeo; Lisa Hecker; Sarah E. Ochmann; Aleksei Aksimentiev; Philip Tinnefeld; Ulrich F. Keyser

doi:10.1021/acs.nanolett.7b05354

Optical Voltage Sensing Using DNA Origami

Elisa A. Hemmig, Clare Fitzgerald, Christopher Maffeo, Lisa Hecker, Sarah E. Ochmann, Aleksei Aksimentiev, Philip Tinnefeld, Ulrich F. Keyser

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

Abstract

We explore the potential of DNA nanotechnology for developing novel optical voltage sensing nanodevices that convert a local change of electric potential into optical signals. As a proof-of-concept of the sensing mechanism, we assembled voltage responsive DNA origami structures labeled with a single pair of FRET dyes. The DNA structures were reversibly immobilized on a nanocapillary tip and underwent controlled structural changes upon application of an electric field. The applied field was monitored through a change in FRET efficiency. By exchanging the position of a single dye, we could tune the voltage sensitivity of our DNA origami structure, demonstrating the flexibility and versatility of our approach. The experimental studies were complemented by coarse-grained simulations that characterized voltage-dependent elastic deformation of the DNA nanostructures and the associated change in the distance between the FRET pair. Our work opens a novel pathway for determining the mechanical properties of DNA origami structures and highlights potential applications of dynamic DNA nanostructures as voltage sensors.

Original language	English (US)
Pages (from-to)	1962-1971
Number of pages	10
Journal	Nano letters
Volume	18
Issue number	3
DOIs	https://doi.org/10.1021/acs.nanolett.7b05354
State	Published - Mar 14 2018

ASJC Scopus subject areas

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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10.1021/acs.nanolett.7b05354

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title = "Optical Voltage Sensing Using DNA Origami",

abstract = "We explore the potential of DNA nanotechnology for developing novel optical voltage sensing nanodevices that convert a local change of electric potential into optical signals. As a proof-of-concept of the sensing mechanism, we assembled voltage responsive DNA origami structures labeled with a single pair of FRET dyes. The DNA structures were reversibly immobilized on a nanocapillary tip and underwent controlled structural changes upon application of an electric field. The applied field was monitored through a change in FRET efficiency. By exchanging the position of a single dye, we could tune the voltage sensitivity of our DNA origami structure, demonstrating the flexibility and versatility of our approach. The experimental studies were complemented by coarse-grained simulations that characterized voltage-dependent elastic deformation of the DNA nanostructures and the associated change in the distance between the FRET pair. Our work opens a novel pathway for determining the mechanical properties of DNA origami structures and highlights potential applications of dynamic DNA nanostructures as voltage sensors.",

author = "Hemmig, {Elisa A.} and Clare Fitzgerald and Christopher Maffeo and Lisa Hecker and Ochmann, {Sarah E.} and Aleksei Aksimentiev and Philip Tinnefeld and Keyser, {Ulrich F.}",

note = "E.H. acknowledges financial support from the Swiss National Science Foundation (SNF). S.O.\u2019s Ph.D. is supported by the Deutsche Forschungsgesellschaft DFG (TI 329/10-1). P.T. is grateful for support by the DFG (TI 329/10-1), the nanosystems initiative Munich (NIM), and the center for integrated protein science Munich (CIPSM). E.H., C.F., and U.F.K. were supported by a grant from the EPSRC Graphted EP/K016636/1 and ERC Consolidator Grant DesignerPores (647144). A.A. and C.M. acknowledge support from the National Science Foundation under Grants DMR-1507985 and PHY-1430124, National Institutes of Health Grant P41-GM104601 and the supercomputer time provided through XSEDE Allocation Grant MCA05S028 and the Blue Waters petascale supercomputer system (UIUC).",

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AU - Aksimentiev, Aleksei

AU - Tinnefeld, Philip

AU - Keyser, Ulrich F.

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N2 - We explore the potential of DNA nanotechnology for developing novel optical voltage sensing nanodevices that convert a local change of electric potential into optical signals. As a proof-of-concept of the sensing mechanism, we assembled voltage responsive DNA origami structures labeled with a single pair of FRET dyes. The DNA structures were reversibly immobilized on a nanocapillary tip and underwent controlled structural changes upon application of an electric field. The applied field was monitored through a change in FRET efficiency. By exchanging the position of a single dye, we could tune the voltage sensitivity of our DNA origami structure, demonstrating the flexibility and versatility of our approach. The experimental studies were complemented by coarse-grained simulations that characterized voltage-dependent elastic deformation of the DNA nanostructures and the associated change in the distance between the FRET pair. Our work opens a novel pathway for determining the mechanical properties of DNA origami structures and highlights potential applications of dynamic DNA nanostructures as voltage sensors.

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Optical Voltage Sensing Using DNA Origami

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