Author: Yuce, Merve; Cicek, Erdem; Inan, Tugce; Dag, Aslihan Basak; Kurkcuoglu, Ozge; Sungur, Fethiye Aylin
Title: Repurposing of FDAâ€approved drugs against active site and potential allosteric drugâ€binding sites of COVIDâ€19 main protease Cord-id: bv3u06t2 Document date: 2021_7_5
ID: bv3u06t2
Snippet: The novel coronavirus disease 2019 (COVIDâ€19) caused by severe acute respiratory syndrome coronavirus 2 (SARSâ€CoVâ€2) still has serious negative effects on health, social life, and economics. Recently, vaccines from various companies have been urgently approved to control SARSâ€CoVâ€2 infections. However, any specific antiviral drug has not been confirmed so far for regular treatment. An important target is the main protease (M(pro)), which plays a major role in replication of the virus.
Document: The novel coronavirus disease 2019 (COVIDâ€19) caused by severe acute respiratory syndrome coronavirus 2 (SARSâ€CoVâ€2) still has serious negative effects on health, social life, and economics. Recently, vaccines from various companies have been urgently approved to control SARSâ€CoVâ€2 infections. However, any specific antiviral drug has not been confirmed so far for regular treatment. An important target is the main protease (M(pro)), which plays a major role in replication of the virus. In this study, Gaussian and residue network models are employed to reveal two distinct potential allosteric sites on M(pro) that can be evaluated as drug targets besides the active site. Then, Food and Drug Administration (FDA)â€approved drugs are docked to three distinct sites with flexible docking using AutoDock Vina to identify potential drug candidates. Fourteen best molecule hits for the active site of M(pro) are determined. Six of these also exhibit high docking scores for the potential allosteric regions. Fullâ€atom molecular dynamics simulations with MMâ€GBSA method indicate that compounds docked to active and potential allosteric sites form stable interactions with high binding free energy (∆G (bind)) values. ∆G (bind) values reach −52.06 kcal/mol for the active site, −51.08 kcal/mol for the potential allosteric site 1, and − 42.93 kcal/mol for the potential allosteric site 2. Energy decomposition calculations per residue elucidate key binding residues stabilizing the ligands that can further serve to design pharmacophores. This systematic and efficient computational analysis successfully determines ivermectine, diosmin, and selinexor currently subjected to clinical trials, and further proposes bromocriptine, elbasvir as M(pro) inhibitor candidates to be evaluated against SARSâ€CoVâ€2 infections.
Search related documents:
Co phrase search for related documents- Try single phrases listed below for: 1
Co phrase search for related documents, hyperlinks ordered by date