Nucleobase pairing and photodimerization in a biologically derived metal-organic framework nanoreactor
Nucleobase pairing and photodimerization in a biologically derived metal-organic framework nanoreactor
Biologically derived metal-organic frameworks (bio-MOFs), a subclass of MOFs made of biologically derived ligands and metal ions, are of great importance as they can be used as models for bio-mimicking and in catalysis, allowing us to gain insights into how large biological molecules function. Through rational design, here we report the synthesis of a novel bio-MOF featuring unobstructed Watson-Crick faces of adenine (Ade) pointing towards the MOF cavities. We show, through a combined experimental and computational approach, that thymine (Thy) molecules diffuse through the pores of the MOF and become base-paired with Ade. The Ade-Thy pair binding at 40-45% loading reveals that Thy molecules are packed within the channels in a way that fulfill both the Woodward-Hoffmann and Schmidt rules, and upon UV irradiation, Thy molecules dimerize into Thy<>Thy. This study highlights the utility of accessible functional groups within the pores of MOFs, and their ability to ‘lock’ molecules in specific positions that can be subsequently dimerized upon light irradiation, extending the use of MOFs as nanoreactors for the synthesis of molecules that are otherwise challenging to isolate.
Anderson, Samantha L.
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Boyd, Peter G.
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Gładysiak, Andrzej
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Nguyen, Tu N.
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Palgrave, Robert G.
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Kubicki, Dominik Kubicki
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Emsley, Lyndon
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Bradshaw, Darren
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Rosseinsky, Matthew J.
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Smit, Berend
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Stylianou, Kyriakos C.
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Anderson, Samantha L.
e8863704-0750-48e2-9380-e40e75b54d79
Boyd, Peter G.
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Gładysiak, Andrzej
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Nguyen, Tu N.
40cdfa0f-b248-4eac-95fa-c31e5e1e6e2b
Palgrave, Robert G.
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Kubicki, Dominik Kubicki
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Emsley, Lyndon
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Bradshaw, Darren
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Rosseinsky, Matthew J.
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Smit, Berend
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Stylianou, Kyriakos C.
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Anderson, Samantha L., Boyd, Peter G., Gładysiak, Andrzej, Nguyen, Tu N., Palgrave, Robert G., Kubicki, Dominik Kubicki, Emsley, Lyndon, Bradshaw, Darren, Rosseinsky, Matthew J., Smit, Berend and Stylianou, Kyriakos C.
(2019)
Nucleobase pairing and photodimerization in a biologically derived metal-organic framework nanoreactor.
Nature Communications, 10, [1612].
(doi:10.1038/s41467-019-09486-2).
Abstract
Biologically derived metal-organic frameworks (bio-MOFs), a subclass of MOFs made of biologically derived ligands and metal ions, are of great importance as they can be used as models for bio-mimicking and in catalysis, allowing us to gain insights into how large biological molecules function. Through rational design, here we report the synthesis of a novel bio-MOF featuring unobstructed Watson-Crick faces of adenine (Ade) pointing towards the MOF cavities. We show, through a combined experimental and computational approach, that thymine (Thy) molecules diffuse through the pores of the MOF and become base-paired with Ade. The Ade-Thy pair binding at 40-45% loading reveals that Thy molecules are packed within the channels in a way that fulfill both the Woodward-Hoffmann and Schmidt rules, and upon UV irradiation, Thy molecules dimerize into Thy<>Thy. This study highlights the utility of accessible functional groups within the pores of MOFs, and their ability to ‘lock’ molecules in specific positions that can be subsequently dimerized upon light irradiation, extending the use of MOFs as nanoreactors for the synthesis of molecules that are otherwise challenging to isolate.
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Anderson et al._manuscript_130319_accepted
- Accepted Manuscript
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s41467-019-09486-2
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Accepted/In Press date: 13 March 2019
e-pub ahead of print date: 8 April 2019
Identifiers
Local EPrints ID: 431019
URI: http://eprints.soton.ac.uk/id/eprint/431019
ISSN: 2041-1723
PURE UUID: 69e80e07-3309-475f-b609-87d253cec13c
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Date deposited: 21 May 2019 16:30
Last modified: 16 Mar 2024 07:43
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Contributors
Author:
Samantha L. Anderson
Author:
Peter G. Boyd
Author:
Andrzej Gładysiak
Author:
Tu N. Nguyen
Author:
Robert G. Palgrave
Author:
Dominik Kubicki Kubicki
Author:
Lyndon Emsley
Author:
Matthew J. Rosseinsky
Author:
Berend Smit
Author:
Kyriakos C. Stylianou
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