A Bipedal DNA Brownian Motor with Coordinated Legs
Abstract
A substantial challenge in engineering molecular motors is designing mechanisms to coordinate the motion between multiple domains of the motor so as to bias random thermal motion. For bipedal motors, this challenge takes the form of coordinating the movement of the biped's legs so that they can move in a synchronized fashion. To address this problem, we have constructed an autonomous DNA bipedal walker that coordinates the action of its two legs by cyclically catalyzing the hybridization of metastable DNA fuel strands. This process leads to a chemically ratcheted walk along a directionally polar DNA track. By covalently cross-linking aliquots of the walker to its track in successive walking states, we demonstrate that this Brownian motor can complete a full walking cycle on a track whose length could be extended for longer walks. We believe that this study helps to uncover principles behind the design of unidirectional devices that can function without intervention. This device should be able to fulfill roles that entail the performance of useful mechanical work on the nanometer scale.
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We thank C. Mao, H. Yan, and N. Jonoska for critical reading of the manuscript. This research has been supported by grants to N.C.S. from the National Institute of General Medical Sciences, NSF, the Army Research Office, the Office of Naval Research, the New York Nano-Bio-Molecular Information Technology Incubator program of the Department of Energy, and the W. M. Keck Foundation.
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Published In
Science
Volume 324 | Issue 5923
3 April 2009
3 April 2009
Copyright
American Association for the Advancement of Science.
Submission history
Received: 29 December 2008
Accepted: 10 February 2009
Published in print: 3 April 2009
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Supporting Online Material
www.sciencemag.org/cgi/content/full/324/5923/67/DC1
Materials and Methods
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Figs. S1 to S14
Table S1
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