Computational Screening of Phenylamino-Phenoxy-Quinoline Derivatives against the Main Protease of SARS-CoV-2 Using Molecular Docking and the ONIOM Method.

In the search for new anti-HIV-1 agents, two forms of phenylamino-phenoxy-quinoline derivatives have been synthesized, namely, 2-phenylamino-4-phenoxy-quinoline and 6-phenylamino-4-phenoxy-quinoline. In this study, the binding interactions of phenylamino-phenoxy-quinoline derivatives and six commercially available drugs (hydroxychloroquine, ritonavir, remdesivir, S-217622, N3, and PF-07321332) with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) main protease (Mpro) were investigated using molecular docking and the ONIOM method. The molecular docking showed the hydrogen bonding and hydrophobic interactions of all the compounds in the pocket of SARS-CoV-2 main protease (Mpro), which plays an important role for the division and proliferation of the virus into the cell. The binding free energy values between the ligands and Mpro ranged from -7.06 to -10.61 kcal/mol. The molecular docking and ONIOM results suggested that 4-(2',6'-dimethyl-4'-cyanophenoxy)-2-(4″-cyanophenyl)-aminoquinoline and 4-(4'-cyanophenoxy)-2-(4″-cyanophenyl)-aminoquinoline have low binding energy values and appropriate molecular properties; moreover, both compounds could bind to Mpro via hydrogen bonding and Pi-Pi stacking interactions with amino acid residues, namely, HIS41, GLU166, and GLN192. These amino acids are related to the proteolytic cleavage process of the catalytic triad mechanisms. Therefore, this study provides important information for further studies on synthetic quinoline derivatives as antiviral candidates in the treatment of SARS-CoV-2.

Structural insights into betaine aldehyde dehydrogenase (BADH2) from Oryza sativa explored by modeling and simulations.

Betaine aldehyde dehydrogenase 2 (BADH2) plays a key role in the accumulation of 2-acetyl-1-pyrroline (2AP), a fragrant compound in rice (Oryza sativa). BADH2 catalyses the oxidation of aminoaldehydes to carboxylic acids. An inactive BADH2 is known to promote fragrance in rice. The 3D structure and atomic level protein-ligand interactions are currently unknown. Here, the 3D dimeric structure of BADH2 was modeled using homology modeling. Furthermore, two 0.5 µs simulations were performed to explore the nature of BADH2 dimer structurally and dynamically. Each monomer comprises of 3 domains (substrate-binding, NAD+-binding, and oligomerization domains). The NAD+-binding domain is the most mobile. A scissor-like motion was observed between the monomers. Inside the binding pocket, N162 and E260 are tethered by strong hydrogen bonds to residues in close proximity. In contrast, the catalytic C294 is very mobile and interacts occasionally with N162. The flexibility of the nucleophilic C294 could facilitate the attack of free carbonyl on an aldehyde substrate. Key inter-subunit salt bridges contributing to dimerization were also identified. E487, D491, E492, K498, and K502 were found to form strong salt bridges with charged residues on the adjacent monomer. Specifically, the nearly permanent R430-E487 hydrogen bond (>90%) highlights its key role in dimer association. Structural and dynamic insights of BADH2 obtained here could play a role in the improvement of rice fragrance, which could lead to an enhancement in rice quality and market price.