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Enzyme-like acyl transfer catalysis in a bifunctional organic cage

Enzyme-like acyl transfer catalysis in a bifunctional organic cage
Enzyme-like acyl transfer catalysis in a bifunctional organic cage

Amide-based organic cage cavities are, in principle, ideal enzyme active site mimics. Yet, cage-promoted organocatalysis has remained elusive, in large part due to synthetic accessibility of robust and functional scaffolds. Herein, we report the acyl transfer catalysis properties of robust, hexaamide cages in organic solvent. Cage structural variation reveals that esterification catalysis with an acyl anhydride acyl carrier occurs only in bifunctional cages featuring internal pyridine motifs and two crucial antipodal carboxylic acid groups. 1H NMR data and X-ray crystallography show that the acyl carrier is rapidly activated inside the cavity as a covalent mixed-anhydride intermediate with an internal hydrogen bond. Michaelis-Menten (saturation) kinetics suggest weak binding (KM = 0.16 M) of the alcohol pronucleophile close to the internal anhydride. Finally, activation and delivery of the alcohol to the internal anhydride by the second carboxylic acid group forms ester product and releases the cage catalyst. Eyring analysis indicates a strong enthalpic stabilization of the transition state (5.5 kcal/mol) corresponding to a rate acceleration of 104 over background acylation, and an ordered, associative rate-determining attack by the alcohol, supported by DFT calculations. We conclude that internal bifunctional organocatalysis specific to the cage structural design is responsible for the enhancement over the background reaction. These results pave the way for organic-phase enzyme mimicry in self-assembled cavities with the potential for cavity elaboration to enact selective acylations.

0002-7863
17887
Andrews, Keith G.
8236a586-cd06-4ffa-9ba0-863ba1a2cb47
Piskorz, Tomasz K.
beff3548-c273-4740-b988-b4c320229a03
Horton, Peter N.
154c8930-bfc3-495b-ad4a-8a278d5da3a5
Coles, Simon J.
3116f58b-c30c-48cf-bdd5-397d1c1fecf8
Andrews, Keith G.
8236a586-cd06-4ffa-9ba0-863ba1a2cb47
Piskorz, Tomasz K.
beff3548-c273-4740-b988-b4c320229a03
Horton, Peter N.
154c8930-bfc3-495b-ad4a-8a278d5da3a5
Coles, Simon J.
3116f58b-c30c-48cf-bdd5-397d1c1fecf8

Andrews, Keith G., Piskorz, Tomasz K., Horton, Peter N. and Coles, Simon J. (2024) Enzyme-like acyl transfer catalysis in a bifunctional organic cage. Journal of the American Chemical Society, 146 (26), 17887. (doi:10.1021/jacs.4c03560).

Record type: Article

Abstract

Amide-based organic cage cavities are, in principle, ideal enzyme active site mimics. Yet, cage-promoted organocatalysis has remained elusive, in large part due to synthetic accessibility of robust and functional scaffolds. Herein, we report the acyl transfer catalysis properties of robust, hexaamide cages in organic solvent. Cage structural variation reveals that esterification catalysis with an acyl anhydride acyl carrier occurs only in bifunctional cages featuring internal pyridine motifs and two crucial antipodal carboxylic acid groups. 1H NMR data and X-ray crystallography show that the acyl carrier is rapidly activated inside the cavity as a covalent mixed-anhydride intermediate with an internal hydrogen bond. Michaelis-Menten (saturation) kinetics suggest weak binding (KM = 0.16 M) of the alcohol pronucleophile close to the internal anhydride. Finally, activation and delivery of the alcohol to the internal anhydride by the second carboxylic acid group forms ester product and releases the cage catalyst. Eyring analysis indicates a strong enthalpic stabilization of the transition state (5.5 kcal/mol) corresponding to a rate acceleration of 104 over background acylation, and an ordered, associative rate-determining attack by the alcohol, supported by DFT calculations. We conclude that internal bifunctional organocatalysis specific to the cage structural design is responsible for the enhancement over the background reaction. These results pave the way for organic-phase enzyme mimicry in self-assembled cavities with the potential for cavity elaboration to enact selective acylations.

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Accepted/In Press date: 10 June 2024
Published date: 24 June 2024

Identifiers

Local EPrints ID: 492729
URI: http://eprints.soton.ac.uk/id/eprint/492729
DOI: doi:10.1021/jacs.4c03560
ISSN: 0002-7863
PURE UUID: 29547e23-ac00-4960-8b35-624e28e17162
ORCID for Peter N. Horton: ORCID iD orcid.org/0000-0001-8886-2016
ORCID for Simon J. Coles: ORCID iD orcid.org/0000-0001-8414-9272

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Date deposited: 13 Aug 2024 16:35
Last modified: 14 Aug 2024 01:36

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Contributors

Author: Keith G. Andrews
Author: Tomasz K. Piskorz
Author: Peter N. Horton ORCID iD
Author: Simon J. Coles ORCID iD

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