Molecular docking and dynamics simulations studies of OmpATb identifies four potential novel natural product-derived anti-Mycobacterium tuberculosis compounds
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Date
2020-05-03
Authors
Kwofie, S.K.
Adobor, C.
Quansah, E.
Bentil, J.
Ampadu, M.
Miller, W.A.
Wilson, M.D.
Journal Title
Journal ISSN
Volume Title
Publisher
Computers in Biology and Medicine
Abstract
The outer membrane protein A (OmpATb) of Mycobacterium tuberculosis is a virulence factor that neutralizes the
host pH to impede the uptake of hydrophilic antitubercular drugs. Identifying natural compounds with the
potential to inhibit OmpATb could allow circumvention of the porin-like activities of OmpATb. Four potential
leads comprising ZINC000003958185, ZINC000000157405, ZINC000000001392 and ZINC000034268676 were
obtained by virtual screening of 6394 diverse natural products. Characterization of the binding interactions of
the potential leads with OmpATb revealed nine critical residues comprising ARG86, LEU110, LEU113, LEU114,
ALA115, PHE142, SER145, VAL146, and PHE151. Molecular dynamics simulations also revealed very stable
protein-lead complexes. Most residues contributed lower binding energies to the overall molecular mechanics
Poisson–Boltzmann surface area (MM-PBSA) binding free energies of the interactions between the molecules and
OmpATb protein. Induced Fit Docking (IFD) of the compounds regenerated poses of the molecular docking using
AutoDock Vina. These molecules could be starting templates for designing inhibitors to bypass the pore mediating
activities of OmpATb. Based on structural similarity, ZINC000034268676 was suggested as a potential
scaffold for designing efflux pump inhibitors of the gate mediating activities of OmpATb and may enhance the
uptake of hydrophilic drugs to reduce the duration time of tuberculosis treatment. Furthermore, structurally
similar compounds available in the DrugBank database with a similarity threshold of 0.7 have been reported to
exhibit antitubercular and anti-mycobacterial activities. These biomolecules can be further characterized
experimentally to corroborate their antitubercular activity. Also, the skeletons of the molecules can be adopted as
sub-structures for the design of future anti-mycobacterial drugs.
Description
Research Article
Keywords
Mycobacterium tuberculosis OmpATb, Natural products, Virtual screening, Molecular docking, Molecular dynamics, MM-PBSA, Antitubercular compounds, Induced-fit docking