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Chemical Evolution of Antivirals Against Enterovirus D68 through Protein‐Templated Knoevenagel Reactions

Carolin Tauber, Rebekka Wamser, Christoph Arkona, Marisa Tügend, Umer Bin Abdul Aziz, Szymon Pach, Robert Schulz, Dirk Jochmans, Gerhard Wolber, Johan Neyts, Jörg Rademann

2021Angewandte Chemie International Edition17 citationsDOIOpen Access PDF

Abstract

The generation of bioactive molecules from inactive precursors is a crucial step in the chemical evolution of life, however, mechanistic insights into this aspect of abiogenesis are scarce. Here, we investigate the protein-catalyzed formation of antivirals by the 3C-protease of enterovirus D68. The enzyme induces aldol condensations yielding inhibitors with antiviral activity in cells. Kinetic and thermodynamic analyses reveal that the bioactivity emerges from a dynamic reaction system including inhibitor formation, alkylation of the protein target by the inhibitors, and competitive addition of non-protein nucleophiles to the inhibitors. The most active antivirals are slowly reversible inhibitors with elongated target residence times. The study reveals first examples for the chemical evolution of bio-actives through protein-catalyzed, non-enzymatic C-C couplings. The discovered mechanism works under physiological conditions and might constitute a native process of drug development.

Topics & Concepts

ChemistryAldol reactionNucleophileProteaseKnoevenagel condensationEnzymeCombinatorial chemistryChemical biologySmall moleculeBiochemistryCatalysisRNA and protein synthesis mechanismsMonoclonal and Polyclonal Antibodies ResearchClick Chemistry and Applications
Chemical Evolution of Antivirals Against Enterovirus D68 through Protein‐Templated Knoevenagel Reactions | Litcius