Multiscale Simulations of SARS-CoV-2 3CL Protease Inhibition with Aldehyde Derivatives. Role of Protein and Inhibitor Conformational Changes in the Reaction Mechanism

Abstract: We here investigate the mechanism of SARS-CoV-2 3CL protease inhibition by one of the most promising families of inhibitors, those containing an aldehyde group as a warhead. These compounds are covalent inhibitors that inactivate the protease, forming a stable hemithioacetal complex. Inhibitor 11a is a potent inhibitor that has been already tested in vitro and in animals. Using a combination of classical and QM/MM simulations, we determined the binding mode of the inhibitor into the acti… Show more

“…The analysis of the calculated RMSD for the residue pair Cys145-His41 in both the Nδ and Nε forms (shown in Figure S3) allows us to observe that the spatial orientation of the dyad remains constant during the simulation time in the case of His41-Nδ, while a dissimilar trend assumes the RMSD value of His41-Nε. The major fluctuations observed in RMSD for His41-Nε could suggest different conformations of the Cys145 side chain also previously found in the ortholog protease of SARS-CoV [46,58].…”

“…Moreover, stimulated by the most recent literature regarding the inhibition mechanism of M pro enzyme [43,[45][46][47] we took into account the protonation state of the catalytic histidine (His41) [43,48,49]. Therefore, we have also performed computational simulations by using molecular docking and classical molecular dynamics (cMD) devoted to accurately model the structure and dynamics of M pro in both the Nδ and Nε protonated states of His41 to better evaluate their eventual influence on the covalent inhibition process by EBS.…”

“…They play a central role in the enzyme's activation [40,41] and also in deiodinase biomimetics [42]. So far the SARS-CoV-2 M pro inhibition mechanism has been studied by using Michael acceptor and peptidomimetic inhibitors at the QM-MM level of theory [43][44][45][46][47]. So, the mechanistic understanding of the Se-S covalent bond formation promoted by inhibitors, such as EBS and EBS-OH in the present study, could contribute to enlarge the molecular inhibition mechanism of SARS-CoV-2 M pro and stimulate the design of other similar drugs.…”

“…So, the mechanistic understanding of the Se-S covalent bond formation promoted by inhibitors, such as EBS and EBS-OH in the present study, could contribute to enlarge the molecular inhibition mechanism of SARS-CoV-2 M pro and stimulate the design of other similar drugs. Moreover, stimulated by the most recent literature regarding the inhibition mechanism of M pro enzyme [43,[45][46][47] we took into account the protonation state of the catalytic histidine (His41) [43,48,49]. Therefore, we have also performed computational simulations by using molecular docking and classical molecular dynamics (cMD) devoted to accurately model the structure and dynamics of M pro in both the Nδ and Nε protonated states of His41 to better evaluate their eventual influence on the covalent inhibition process by EBS.…”

The Se–S Bond Formation in the Covalent Inhibition Mechanism of SARS-CoV-2 Main Protease by Ebselen-like Inhibitors: A Computational Study

“…The analysis of the calculated RMSD for the residue pair Cys145-His41 in both the Nδ and Nε forms (shown in Figure S3) allows us to observe that the spatial orientation of the dyad remains constant during the simulation time in the case of His41-Nδ, while a dissimilar trend assumes the RMSD value of His41-Nε. The major fluctuations observed in RMSD for His41-Nε could suggest different conformations of the Cys145 side chain also previously found in the ortholog protease of SARS-CoV [46,58].…”

“…Moreover, stimulated by the most recent literature regarding the inhibition mechanism of M pro enzyme [43,[45][46][47] we took into account the protonation state of the catalytic histidine (His41) [43,48,49]. Therefore, we have also performed computational simulations by using molecular docking and classical molecular dynamics (cMD) devoted to accurately model the structure and dynamics of M pro in both the Nδ and Nε protonated states of His41 to better evaluate their eventual influence on the covalent inhibition process by EBS.…”

“…They play a central role in the enzyme's activation [40,41] and also in deiodinase biomimetics [42]. So far the SARS-CoV-2 M pro inhibition mechanism has been studied by using Michael acceptor and peptidomimetic inhibitors at the QM-MM level of theory [43][44][45][46][47]. So, the mechanistic understanding of the Se-S covalent bond formation promoted by inhibitors, such as EBS and EBS-OH in the present study, could contribute to enlarge the molecular inhibition mechanism of SARS-CoV-2 M pro and stimulate the design of other similar drugs.…”

“…So, the mechanistic understanding of the Se-S covalent bond formation promoted by inhibitors, such as EBS and EBS-OH in the present study, could contribute to enlarge the molecular inhibition mechanism of SARS-CoV-2 M pro and stimulate the design of other similar drugs. Moreover, stimulated by the most recent literature regarding the inhibition mechanism of M pro enzyme [43,[45][46][47] we took into account the protonation state of the catalytic histidine (His41) [43,48,49]. Therefore, we have also performed computational simulations by using molecular docking and classical molecular dynamics (cMD) devoted to accurately model the structure and dynamics of M pro in both the Nδ and Nε protonated states of His41 to better evaluate their eventual influence on the covalent inhibition process by EBS.…”

The Se–S Bond Formation in the Covalent Inhibition Mechanism of SARS-CoV-2 Main Protease by Ebselen-like Inhibitors: A Computational Study

“…6,7 Several inhibitors of SARS-CoV and SARS-CoV-2 M pro have been designed that interfere with the formation of the acyl-enzyme complex due to the promotion of a covalent bond between the thiol group of the catalytic cysteine and the inihibitor. 3,4,8 A similar approach has been exploited using zinc-coordinating inhibitors, 9,10 where the zinc ion plays a role in stabilizing the protein-inhibitor complex through a tetrahedral coordination shared by the active site cysteine and histidine with two donor atoms of the inhibitor. The solved experimental structures [9][10][11] however leave open interesting questions concerning the zinc binding ability of the protease in the cellular environment, even in the absence of a coordinating ligand, and the possible role of zinc ions in modulating its biological activity.…”

SARS-CoV-2 M^proinhibition by a zinc ion: structural features and hints for drug design

Inhibition Mechanism of SARS‐CoV‐2 Main Protease with Ketone‐Based Inhibitors Unveiled by Multiscale Simulations: Insights for Improved Designs**