Author: Tauber, Carolin; Wamser, Rebekka; Arkona, Christoph; Tügend, Marisa; Abdul Aziz, Umer Bin; Pach, Szymon; Schulz, Robert; Jochmans, Dirk; Wolber, Gerhard; Neyts, Johan; Rademann, Jörg
Title: Chemical Evolution of Antivirals Against Enterovirus D68 through Proteinâ€Templated Knoevenagel Reactions Cord-id: 0dg0bily Document date: 2021_5_6
ID: 0dg0bily
Snippet: 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 proteinâ€catalyzed formation of antivirals by the 3Câ€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 inclu
Document: 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 proteinâ€catalyzed formation of antivirals by the 3Câ€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 nonâ€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 bioâ€actives through proteinâ€catalyzed, nonâ€enzymatic C−C couplings. The discovered mechanism works under physiological conditions and might constitute a native process of drug development.
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