Corrigendum to "Interaction between goniothalamin and peroxisomal multifunctional enzyme type 2 triggering endoplasmic reticulum stress" [Heliyon 6 (10) (October 2020) e05200].

[This corrects the article DOI: 10.1016/j.heliyon.

Interaction between goniothalamin and peroxisomal multifunctional enzyme type 2 triggering endoplasmic reticulum stress.

Endoplasmic reticulum stress is one of the pathways involved in cell cytotoxicity. In this study, goniothalamin, one of styryllactone compounds found in plant ., was observed to trigger ER stress in HeLa cell line.

Effects of the protonation state of the catalytic residues and ligands upon binding and recognition in targeted proteins of HIV-1 and influenza viruses.

The determination of the protonation state of the functional groups of ligands, and the amino acid residues with electrically charged side chains (His, Lys, Arg, Asp and Glu) or the nucleotide bases of the nucleic acids that they interact with, is important for ligand binding and recognition, the enzyme activity and reaction mechanism, and protein folding/unfolding and stability. Herein, the effects of different protonation state assignments of the small substrate and inhibitors and the critical residues on the reverse transcriptase and protease of human immunodeficiency virus type 1 (HIV-1) and the M2 proton channel of influenza A virus are reviewed. Theoretical studies on these topics are summarized and compared with the experimental data.

Why amantadine loses its function in influenza m2 mutants: MD simulations.

Molecular dynamics simulations of the drug-resistant M2 mutants, A30T, S31N, and L26I, were carried out to investigate the inhibition of M2 activity using amantadine (AMT). The closed and open channel conformations were examined via non- and triply protonated H37. For the nonprotonated state, these mutants exhibited zero water density in the conducting region, and AMT was still bound to the channel pore.

Combined QM/MM mechanistic study of the acylation process in furin complexed with the H5N1 avian influenza virus hemagglutinin's cleavage site.

Combined quantum mechanical/molecular mechanical (QM/MM) techniques have been applied to investigate the detailed reaction mechanism of the first step of the acylation process by furin in which the cleavage site of the highly pathogenic avian influenza virus subtype H5N1 (HPH5) acts as its substrate. The energy profile shows a simultaneous mechanism, known as a concerted reaction, of the two subprocesses: the proton transfer from Ser368 to His194 and the nucleophilic attack on the carbonyl carbon of the scissile peptide of the HPH5 cleavage site with a formation of tetrahedral intermediate (INT). The calculated energy barrier for this reaction is 16.

Source of oseltamivir resistance in avian influenza H5N1 virus with the H274Y mutation.

Molecular dynamics simulations were carried out for the mutant oseltamivir-NA complex, to provide detailed information on the oseltamivir-resistance resulting from the H274Y mutation in neuraminidase (NA) of avian influenza H5N1 viruses. In contrast with a previous proposal, the H274Y mutation does not prevent E276 and R224 from forming the hydrophobic pocket for the oseltamivir bulky group. Instead, reduction of the hydrophobicity and size of pocket in the area around an ethyl moiety at this bulky group were found to be the source of the oseltamivir-resistance.

How amantadine and rimantadine inhibit proton transport in the M2 protein channel.

To understand how antiviral drugs inhibit the replication of influenza A virus via the M2 ion channel, molecular dynamics simulations have been applied to the six possible protonation states of the M2 ion channel in free form and its complexes with two commercial drugs in a fully hydrated lipid bilayer. Among the six different states of free M2 tetramer, water density was present in the pore of the systems with mono-protonated, di-protonated at adjacent position, tri-protonated and tetra-protonated systems. In the presence of inhibitor, water density in the channel was considerably better reduced by rimantadine than amantadine, agreed well with the experimental IC(50) values.

Source of high pathogenicity of an avian influenza virus H5N1: why H5 is better cleaved by furin.

The origin of the high pathogenicity of an emerging avian influenza H5N1 due to the -RRRKK- insertion at the cleavage loop of the hemagglutinin H5, was studied using the molecular dynamics technique, in comparison with those of the noninserted H5 and H3 bound to the furin (FR) active site. The cleavage loop of the highly pathogenic H5 was found to bind strongly to the FR cavity, serving as a conformation suitable for the proteolytic reaction. With this configuration, the appropriate interatomic distances were found for all three reaction centers of the enzyme-substrate complex: the arrangement of the catalytic triad, attachment of the catalytic Ser(368) to the reactive S1-Arg, and formation of the oxyanion hole.

Understanding of known drug-target interactions in the catalytic pocket of neuraminidase subtype N1.

To provide detailed information and insight into the drug-target interaction, structure, solvation, and dynamic and thermodynamic properties, the three known-neuraminidase inhibitors-oseltamivir (OTV), zanamivir (ZNV), and peramivir (PRV)-embedded in the catalytic site of neuraminidase (NA) subtype N1 were studied using molecular dynamics simulations. In terms of ligand conformation, there were major differences in the structures of the guanidinium and the bulky groups. The atoms of the guanidinium group of PRV were observed to form many more hydrogen bonds with the surrounded residues and were much less solvated by water molecules, in comparison with the other two inhibitors.

Insight into analysis of interactions of saquinavir with HIV-1 protease in comparison between the wild-type and G48V and G48V/L90M mutants based on QM and QM/MM calculations.

Saquinavir (SQV) was the first HIV-1 PR inhibitor licensed for clinical use and widely used for acquired immunodeficiency syndrome (AIDS) therapy. Its effectiveness, however, has been hindered by the emergence of resistant mutations. The two most important HIV-1 PR mutants are G48V and G48V/L90M.

Structural analysis of lead fullerene-based inhibitor bound to human immunodeficiency virus type 1 protease in solution from molecular dynamics simulations.

Molecular dynamics (MD) simulations of the HIV-1 protease (HIVP) complexed with lead fullerene-based inhibitor (diphenyl C60 alcohol) in the three protonated states, unprotonated (Un-), monoprotonated (Mono-), and diprotonated (Di-) states at Asp25 and Asp25' were performed. As the X-ray structure of the investigated complex is not available, it was built up starting with the X-ray crystallographic structure of the HIVP complexed with non-peptide inhibitor (PDB code: 1AID) and that of the diphenyl C60 alcohol optimized using the integrated ONIOM molecular orbital calculations. The inhibitor was, then, introduced into the enzyme pocket using a molecular docking method.

On the lower susceptibility of oseltamivir to influenza neuraminidase subtype N1 than those in N2 and N9.

Aiming to understand, at the molecular level, why oseltamivir (OTV) cannot be used for inhibition of human influenza neuraminidase subtype N1 as effectively as for subtypes N2 and N9, molecular dynamics simulations were carried out for the three complexes, OTV-N1, OTV-N2, and OTV-N9. The three-dimensional OTV-N2 and OTV-N9 initial structures were represented by the x-ray structures, whereas that of OTV-N1, whose x-ray structure is not yet solved, was built up using the aligned sequence of H5N1 isolated from humans in Thailand with the x-ray structure of the N2-substrate as the template. In comparison to the OTV-N2 and OTV-N9 complexes, dramatic changes were observed in the OTV conformation in the OTV-N1 complex in which two of its bulky side chains, N-acethyl (-NHAc) and 1-ethylproxy group (-OCHEt2), were rotated to adjust the size to fit into the N1 catalytic site.

Molecular dynamic and free energy studies of primary resistance mutations in HIV-1 protease-ritonavir complexes.

To understand the basis of drug resistance of the HIV-1 protease, molecular dynamic (MD) and free energy calculations of the wild-type and three primary resistance mutants, V82F, I84V, and V82F/I84V, of HIV-1 protease complexed with ritonavir were carried out. Analysis of the MD trajectories revealed overall structures of the protein and the hydrogen bonding of the catalytic residues to ritonavir were similar in all four complexes. Substantial differences were also found near the catalytic binding domain, of which the double mutant complex has the greatest impact on conformational changes of the protein and the inhibitor.

Structural and dynamical properties of different protonated states of mutant HIV-1 protease complexed with the saquinavir inhibitor studied by molecular dynamics simulations.

To understand the basis of drug resistance, particularly of the HIV-1 PR, three molecular dynamics (MD) simulations of HIV-1 PR mutant species, G48V, complexed with saquinavir (SQV) in explicit aqueous solution with three protonation states, diprotonation on Asp25 and Asp25' (Di-pro) and monoprotonation on each Asp residue (Mono-25 and Mono-25'). For all three states, H-bonds between saquinavir and HIV-1 PR were formed only in the two regions, flap and active site. It was found that conformation of P2 subsite of SQV in the Mono-25 state differs substantially from the other two states.

Structure, dynamics and solvation of HIV-1 protease/saquinavir complex in aqueous solution and their contributions to drug resistance: molecular dynamic simulations.

As it is known that the understanding of the basic properties of the enzyme/inhibitor complex leads directly to enhancing the capability in drug designing and drug discovery. Molecular dynamics simulations have been performed to examine detailed information on the structure and dynamical properties of the HIV-1 PR complexed with saquinavir in the three protonated states, monoprotonates at Asp25 (Mono-25) and Asp25'(Mono-25') and diprotonate (Di-Pro) at both Asp25 and Asp25'. The obtained results support clinical data which reveal that Ile84 and Gly48 are two of the most frequent residues where mutation toward a protease inhibitor takes place.

Insights into saquinavir resistance in the G48V HIV-1 protease: quantum calculations and molecular dynamic simulations.

The spread of acquired immune deficiency syndrome has increasingly become a great concern owing largely to the failure of chemotherapies. The G48V is considered the key signature residue mutation of HIV-1 protease developing with saquinavir therapy. Molecular dynamics simulations of the wild-type and the G48V HIV-1 protease complexed with saquinavir were carried out to explore structure and interactions of the drug resistance.