We describe the potential anti coronavirus disease 2019 (COVID-19) action of the methide quinone inhibitor, celastrol. The related methide quinone dexamethasone is, so far, among COVID-19 medications perhaps the most effective drug for patients with severe symptoms. We observe a parallel redox biology behavior between the antioxidant action of celastrol when scavenging the superoxide radical, and the adduct formation of celastrol with the main COVID-19 protease. The related molecular mechanism is envisioned using molecular mechanics and dynamics calculations. It proposes a covalent bond between the S(Cys145) amino acid thiolate and the celastrol A ring, assisted by proton transfers by His164 and His41 amino acids, and a π interaction from Met49 to the celastrol B ring. Specifically, celastrol possesses two moieties that are able to independently scavenge the superoxide radical: the carboxylic framework located at ring E, and the methide-quinone ring A. The latter captures the superoxide electron, releasing molecular oxygen, and is the feature of interest that correlates with the mechanism of COVID-19 inhibition. This unusual scavenging of the superoxide radical is described using density functional theory (DFT) methods, and is supported experimentally by cyclic voltammetry and X-ray diffraction.
【저자키워드】 COVID-19, protease, celastrol, methide quinone, thiolate, cyclic voltammetry, 【초록키워드】 Dexamethasone, coronavirus disease, oxygen, molecular mechanism, antioxidant, Patient, amino acids, molecular, medication, inhibitor, mechanism, Amino acid, Interaction, X-ray diffraction, severe symptoms, transfer, His41, scavenging, covalent bond, effective, HIS164, observé, described, supported, functional, 【제목키워드】 3CL pro, Superoxide, root, quinone, scavenger, Act, Radical,