Abstract
BackgroundThe coronavirus 3 chymotrypsin-like protease (3CLpro) is a validated target in the design of potential anticoronavirus inhibitors. The high degree of homology within the protease’s active site and substrate conservation supports the identification of broad spectrum lead compounds. A previous study identified the compound ML188, also termed 16R, as an inhibitor of the Severe Acute Respiratory Syndrome coronavirus (SARS-CoV) 3CLpro. This study will detail the generation of a homology model of the 3CLpro of the human coronavirus OC43 and determine the potential of 16R to form a broad-spectrum lead compound. MODELLER was used to generate a suitable three-dimensional model of the OC43 3CLpro and the Prime module of Schrӧdinger predicted the binding conformation and free energy of binding of 16R within the 3CLpro active site. Molecular dynamics further confirmed ligand stability and hydrogen bonding networks.ResultsA high quality homology model of the OC43 3CLpro was successfully generated in an active conformation. Further studies reproduced the binding pose of 16R within the active site of the generated model, where its free energy of binding was shown to equal that of the 3CLpro of SARS-CoV, a receptor it is experimentally proven to inhibit. The stability of the ligand was subsequently confirmed by molecular dynamics.ConclusionThe lead compound 16R may represent a broad-spectrum inhibitor of the 3CLpro of OC43 and potentially other coronaviruses. This study provides an atomistic structure of the 3CLpro of OC43 and supports further experimental validation of the inhibitory effects of 16R. These findings further confirm that the 3CLpro of coronaviruses can be inhibited by broad spectrum lead compounds.
Highlights
The coronavirus 3 chymotrypsin-like protease (3CLpro) is a validated target in the design of potential anticoronavirus inhibitors
Homology modelling of the OC43 3CLpro The 3CLpro structure of HKU1 [PDB: 3D23] displayed a high sequence identity of 82.3% to the 3CLpro of OC43, with an e-value of 0.0
Homology models were built with MODELLER (9v10) [22,23] where the lowest discrete optimized protein energy (DOPE) score corresponded to model five with a GA341 score of 1, indicating that the model quality corresponded with low resolution crystallographic structures
Summary
The coronavirus 3 chymotrypsin-like protease (3CLpro) is a validated target in the design of potential anticoronavirus inhibitors. The high degree of homology within the protease’s active site and substrate conservation supports the identification of broad spectrum lead compounds. During coronavirus replication the large open reading frame (ORF) 1a/1ab genes, located at the 5’ end of the genome, are responsible for expressing two large replicase polyproteins (pp) These are co- or post-translationally cleaved by the virally encoded 3CLpro and Papain-like protease to yield 16 non-structural proteins responsible for viral replication [9]. The active site is located in a chymotrypsin-like fold between domains I and II and contains a catalytic dyad of His, which acts as a proton acceptor, and Cys144/5, which undergoes nucleophilic attack on the carbonyl carbon of the substrate [8,13]. The P1 position has an absolute specificity for glutamine which stabilizes the S1 subsite via a hydrogen bond with the imidazole Nε2 of His162/3 and van der
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