Abstract
Coronaviruses are viral infections that have a significant ability to impact human health. Coronaviruses have produced two pandemics and one epidemic in the last two decades. The current pandemic has created a worldwide catastrophe threatening the lives of over 15 million as of July 2020. Current research efforts have been focused on producing a vaccine or repurposing current drug compounds to develop a therapeutic. There is, however, a need to study the active site preferences of relevant targets, such as the SARS-CoV-2 main protease (SARS-CoV-2 Mpro), to determine ways to optimize these drug compounds. The ensemble docking and characterization work described in this article demonstrates the multifaceted features of the SARS-CoV-2 Mpro active site, molecular guidelines to improving binding affinity, and ultimately the optimization of drug candidates. A total of 220 compounds were docked into both the 5R7Z and 6LU7 SARS-CoV-2 Mpro crystal structures. Several key preferences for strong binding to the four subsites (S1, S1′, S2, and S4) were identified, such as accessing hydrogen binding hotspots, hydrophobic patches, and utilization of primarily aliphatic instead of aromatic substituents. After optimization efforts using the design guidelines developed from the molecular docking studies, the average docking score of the parent compounds was improved by 6.59 −log10(Kd) in binding affinity which represents an increase of greater than six orders of magnitude. Using the optimization guidelines, the SARS-CoV-2 Mpro inhibitor cinanserin was optimized resulting in an increase in binding affinity of 4.59 −log10(Kd) and increased protease inhibitor bioactivity. The results of molecular dynamic (MD) simulation of cinanserin-optimized compounds CM02, CM06, and CM07 revealed that CM02 and CM06 fit well into the active site of SARS-CoV-2 Mpro [Protein Data Bank (PDB) accession number 6LU7] and formed strong and stable interactions with the key residues, Ser-144, His-163, and Glu-166. The enhanced binding affinity produced demonstrates the utility of the design guidelines described. The work described herein will assist scientists in developing potent COVID-19 antivirals.
Highlights
Coronaviruses cause upper respiratory tract illnesses and can infect multiple species [1]
Coronaviruses typically have several binding pockets within their protease which makes up the active site
Two methods can be successfully employed for drug compounds to access the S2 subsite: the inclusion of hydrophobic substituents that can interact with Met-49, or the inclusion of hydrogen bonding donor or acceptors atoms, which can access the hydrogen bonding hotspot formed by the backbone of residues Asp-187, Arg-188, Gln-189, and the side chain of Tyr-54
Summary
Coronaviruses cause upper respiratory tract illnesses and can infect multiple species [1]. After the emergence of MERS-CoV, researchers expressed the importance of developing future therapeutic interventions for coronaviruses [5]. The current coronavirus which emerged in 2019 is a result of a new strain of severe acute respiratory syndrome-coronavirus 2. This new strain has resulted in a pandemic, termed COVID-19, and has infected almost 15 million individuals worldwide, upending the way of life of individuals across the globe. This COVID-19 pandemic has resulted in over 600,000 deaths between late 2019 and July 2020 [7]
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