Frontiers in Cellular and Infection Microbiology (May 2023)

Mechanistic inhibition of Monkeypox and Marburg virus infection by O-rhamnosides and Kaempferol-o-rhamnosides derivatives: a new-fangled computational approach

  • Md. Abdullah Al Mashud,
  • Ajoy Kumer,
  • Nobendu Mukerjee,
  • Nobendu Mukerjee,
  • Akhel Chandro,
  • Swastika Maitra,
  • Unesco Chakma,
  • Unesco Chakma,
  • Abhijit Dey,
  • Shopnil Akash,
  • Athanasiosis Alexiou,
  • Athanasiosis Alexiou,
  • Azmat Ali Khan,
  • Amer M. Alanazi,
  • Arabinda Ghosh,
  • Kow-Tong Chen,
  • Kow-Tong Chen,
  • Rohit Sharma

DOI
https://doi.org/10.3389/fcimb.2023.1188763
Journal volume & issue
Vol. 13

Abstract

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The increasing incidence of Monkeypox virus (Mpox) and Marburg virus (MARV) infections worldwide presents a significant challenge to global health, as limited treatment options are currently available. This study investigates the potential of several O-rhamnosides and Kaempferol-O-rhamnosides as Mpox and MARV inhibitors using molecular modeling methods, including ADMET, molecular docking, and molecular dynamics/MD simulation. The effectiveness of these compounds against the viruses was assessed using the Prediction of Activity Spectra for Substances (PASS) prediction. The study’s primary focus is molecular docking prediction, which demonstrated that ligands (L07, L08, and L09) bind to Mpox (PDB ID: 4QWO) and MARV (PDB ID: 4OR8) with binding affinities ranging from -8.00 kcal/mol to -9.5 kcal/mol. HOMO-LUMO based quantum calculations were employed to determine the HOMO-LUMO gap of frontier molecular orbitals (FMOs) and to estimate chemical potential, electronegativity, hardness, and softness. Drug similarity and ADMET prediction assessments of pharmacokinetic properties revealed that the compounds were likely non-carcinogenic, non-hepatotoxic, and rapidly soluble. Molecular dynamic (MD) modeling was used to identify the most favorable docked complexes involving bioactive chemicals. MD simulations indicate that varying types of kaempferol-O-rhamnoside are necessary for successful docking validation and maintaining the stability of the docked complex. These findings could facilitate the discovery of novel therapeutic agents for treating illnesses caused by the Mpox and MARV viruses.

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