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An autonomous chemically fuelled small-molecule motor

An autonomous chemically fuelled small-molecule motor
An autonomous chemically fuelled small-molecule motor
Molecular machines are among the most complex of all functional molecules and lie at the heart of nearly every biological process1. A number of synthetic small-molecule machines have been developed2, including molecular muscles3,4, synthesizers5,6, pumps7,8,9, walkers10, transporters11 and light-driven12,13,14,15,16 and electrically17,18 driven rotary motors. However, although biological molecular motors are powered by chemical gradients or the hydrolysis of adenosine triphosphate (ATP)1, so far there are no synthetic small-molecule motors that can operate autonomously using chemical energy (that is, the components move with net directionality as long as a chemical fuel is present)19. Here we describe a system in which a small molecular ring (macrocycle) is continuously transported directionally around a cyclic molecular track when powered by irreversible reactions of a chemical fuel, 9-fluorenylmethoxycarbonyl chloride. Key to the design is that the rate of reaction of this fuel with reactive sites on the cyclic track is faster when the macrocycle is far from the reactive site than when it is near to it. We find that a bulky pyridine-based catalyst promotes carbonate-forming reactions that ratchet the displacement of the macrocycle away from the reactive sites on the track. Under reaction conditions where both attachment and cleavage of the 9-fluorenylmethoxycarbonyl groups occur through different processes, and the cleavage reaction occurs at a rate independent of macrocycle location, net directional rotation of the molecular motor continues for as long as unreacted fuel remains. We anticipate that autonomous chemically fuelled molecular motors will find application as engines in molecular nanotechnology2,19,20.
0028-0836
235-240
Wilson, Miriam R.
4248988e-e9a4-44dc-bbab-aa5256813d59
Solà, Jordi
42208df7-9ba7-4389-beaf-5bf6c56cdbbe
Carlone, Armando
c79c1bdb-e400-4182-ac40-8af5c0cbf846
Goldup, Stephen M.
0a93eedd-98bb-42c1-a963-e2815665e937
Lebrasseur, Nathalie
e26275aa-f20f-4da3-902f-7808c027b949
Leigh, David A.
826353b6-267f-44cd-a7e7-adf0c34f66c9
Wilson, Miriam R.
4248988e-e9a4-44dc-bbab-aa5256813d59
Solà, Jordi
42208df7-9ba7-4389-beaf-5bf6c56cdbbe
Carlone, Armando
c79c1bdb-e400-4182-ac40-8af5c0cbf846
Goldup, Stephen M.
0a93eedd-98bb-42c1-a963-e2815665e937
Lebrasseur, Nathalie
e26275aa-f20f-4da3-902f-7808c027b949
Leigh, David A.
826353b6-267f-44cd-a7e7-adf0c34f66c9

Wilson, Miriam R., Solà, Jordi, Carlone, Armando, Goldup, Stephen M., Lebrasseur, Nathalie and Leigh, David A. (2016) An autonomous chemically fuelled small-molecule motor. Nature, 534 (7606), 235-240. (doi:10.1038/nature18013).

Record type: Article

Abstract

Molecular machines are among the most complex of all functional molecules and lie at the heart of nearly every biological process1. A number of synthetic small-molecule machines have been developed2, including molecular muscles3,4, synthesizers5,6, pumps7,8,9, walkers10, transporters11 and light-driven12,13,14,15,16 and electrically17,18 driven rotary motors. However, although biological molecular motors are powered by chemical gradients or the hydrolysis of adenosine triphosphate (ATP)1, so far there are no synthetic small-molecule motors that can operate autonomously using chemical energy (that is, the components move with net directionality as long as a chemical fuel is present)19. Here we describe a system in which a small molecular ring (macrocycle) is continuously transported directionally around a cyclic molecular track when powered by irreversible reactions of a chemical fuel, 9-fluorenylmethoxycarbonyl chloride. Key to the design is that the rate of reaction of this fuel with reactive sites on the cyclic track is faster when the macrocycle is far from the reactive site than when it is near to it. We find that a bulky pyridine-based catalyst promotes carbonate-forming reactions that ratchet the displacement of the macrocycle away from the reactive sites on the track. Under reaction conditions where both attachment and cleavage of the 9-fluorenylmethoxycarbonyl groups occur through different processes, and the cleavage reaction occurs at a rate independent of macrocycle location, net directional rotation of the molecular motor continues for as long as unreacted fuel remains. We anticipate that autonomous chemically fuelled molecular motors will find application as engines in molecular nanotechnology2,19,20.

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Rvsd 7Apr2016AutonRotaryMolMotor Nature.pdf - Accepted Manuscript
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Accepted/In Press date: 12 April 2016
e-pub ahead of print date: 8 June 2016
Organisations: Organic Chemistry: SCF

Identifiers

Local EPrints ID: 397244
URI: http://eprints.soton.ac.uk/id/eprint/397244
ISSN: 0028-0836
PURE UUID: d02cd6cb-327d-4dc7-b96a-6b121fc1090a
ORCID for Stephen M. Goldup: ORCID iD orcid.org/0000-0003-3781-0464

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Date deposited: 30 Jun 2016 11:13
Last modified: 15 Mar 2024 05:41

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Contributors

Author: Miriam R. Wilson
Author: Jordi Solà
Author: Armando Carlone
Author: Nathalie Lebrasseur
Author: David A. Leigh

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