Exploring Photoswitchable Binding Interactions with Small‐Molecule‐ and Peptide‐Based Inhibitors of Trypsin

The ability to photochemically activate a drug, both when and where needed, requires optimisation of the difference in biological activity between each isomeric state. As a step to this goal, we report small‐molecule‐ and peptide‐based inhibitors of the same protease—trypsin—to better understand how...

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Veröffentlicht in:	Chembiochem : a European journal of chemical biology 2023-10, Vol.24 (20), p.e202300453-n/a
Hauptverfasser:	Palasis, Kathryn A., Peddie, Victoria, Turner, Dion J. L., Zhang, Xiaozhou, Yu, Jingxian, Abell, Andrew D.
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Sprache:	eng
Schlagworte:	Binding Biological activity Drug development Drugs enzymes Inhibitors Irradiation Isomerization Molecular modelling Optimization Peptides photochemistry photoswitches Protease inhibitors Proteinase inhibitors Trypsin Trypsin inhibitors
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creator	Palasis, Kathryn A. Peddie, Victoria Turner, Dion J. L. Zhang, Xiaozhou Yu, Jingxian Abell, Andrew D.
description	The ability to photochemically activate a drug, both when and where needed, requires optimisation of the difference in biological activity between each isomeric state. As a step to this goal, we report small‐molecule‐ and peptide‐based inhibitors of the same protease—trypsin—to better understand how photoswitchable drugs interact with their biological target. The best peptidic inhibitor displayed a more than fivefold difference in inhibitory activity between isomeric states, whereas the best small‐molecule inhibitor only showed a 3.4‐fold difference. Docking and molecular modelling suggest this result is due to a large change in 3D structure in the key binding residues of the peptidic inhibitor upon isomerisation; this is not observed for the small‐molecule inhibitor. Hence, we demonstrate that significant structural changes in critical binding motifs upon irradiation are essential for maximising the difference in biological activity between isomeric states. This is an important consideration in the design of future photoswitchable drugs for clinical applications. Different for different states: Small‐molecule‐ and peptide‐based photoswitchable inhibitors of trypsin were investigated to better understand their binding interactions and hence optimise the difference in biological activity between isomeric states. The best peptidic inhibitor displayed a more than fivefold difference in inhibitory activity between isomeric states compared to the best small‐molecule inhibitor (3.4‐fold), due to a more significant 3D structural change upon switching.
doi_str_mv	10.1002/cbic.202300453
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subjects	Binding Biological activity Drug development Drugs enzymes Inhibitors Irradiation Isomerization Molecular modelling Optimization Peptides photochemistry photoswitches Protease inhibitors Proteinase inhibitors Trypsin Trypsin inhibitors
title	Exploring Photoswitchable Binding Interactions with Small‐Molecule‐ and Peptide‐Based Inhibitors of Trypsin
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