Molecular dynamics simulations and experimental studies reveal differential permeability of withaferin-A and withanone across the model cell membrane

Molecular dynamics simulations and experimental studies reveal differential permeability of withaferin-A and withanone across the model cell membrane

Poor bioavailability due to the inability to cross the cell membrane is one of the major reasons for the failure of a drug in clinical trials. We have used molecular dynamics simulations to predict the membrane permeability of natural drugs—withanolides (withaferin-A and withanone) that have similar...

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Bibliographic Details
Published in:Scientific reports Vol. 11; no. 1; p. 2352
Main Authors: Wadhwa, Renu, Yadav, Neetu Singh, Katiyar, Shashank P., Yaguchi, Tomoko, Lee, Chohee, Ahn, Hyomin, Yun, Chae-Ok, Kaul, Sunil C., Sundar, Durai
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 27-01-2021
Nature Publishing Group
Nature Portfolio
Subjects:
631/114
631/1647
631/57
Bioavailability
Cell membranes
Clinical trials
Computer applications
Cytotoxicity
Drug development
Free energy
Humanities and Social Sciences
Membrane permeability
Membranes
Molecular dynamics
multidisciplinary
Permeability
Phospholipids
Science
Science (multidisciplinary)
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Summary:Poor bioavailability due to the inability to cross the cell membrane is one of the major reasons for the failure of a drug in clinical trials. We have used molecular dynamics simulations to predict the membrane permeability of natural drugs—withanolides (withaferin-A and withanone) that have similar structures but remarkably differ in their cytotoxicity. We found that whereas withaferin-A, could proficiently transverse through the model membrane, withanone showed weak permeability. The free energy profiles for the interaction of withanolides with the model bilayer membrane revealed that whereas the polar head group of the membrane caused high resistance for the passage of withanone, the interior of the membrane behaves similarly for both withanolides. The solvation analysis further revealed that the high solvation of terminal O5 oxygen of withaferin-A was the major driving force for its high permeability; it interacted with the phosphate group of the membrane that led to its smooth passage across the bilayer. The computational predictions were tested by raising and recruiting unique antibodies that react to withaferin-A and withanone. The time-lapsed analyses of control and treated cells demonstrated higher permeation of withaferin-A as compared to withanone. The concurrence between the computation and experimental results thus re-emphasised the use of computational methods for predicting permeability and hence bioavailability of natural drug compounds in the drug development process.
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ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-021-81729-z