In silico and saturation transfer difference NMR approaches to unravel the binding mode of an andrographolide derivative to K-Ras oncoprotein

In silico and saturation transfer difference NMR approaches to unravel the binding mode of an andrographolide derivative to K-Ras oncoprotein

Andrographolide and its benzylidene derivatives, SRJ09 and SRJ23, potentially bind oncogenic K-Ras to exert anticancer activity. Their molecular interactions with K-Ras oncoproteins that lead to effective biological activity are of major interest. docking and molecular dynamics simulation were perfo...

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Bibliographic Details
Published in:Future medicinal chemistry Vol. 12; no. 18; pp. 1611 - 1631
Main Authors: Quah, Shun Ying, Tan, Michelle Siying, Ho, Kok Lian, Manan, Nizar Abdul, Gorfe, Alemayehu Abebe, Deb, Pran Kishore, Sagineedu, Sreenivasa Rao, Stanslas, Johnson
Format: Journal Article
Language:English
Published: England Newlands Press 01-09-2020
Subjects:
Amino acids
Antitumor activity
Apoptosis
Binding sites
Biological activity
Cancer
Cell cycle
Hydrophobicity
K-Ras protein
Ligands
Molecular dynamics
Mutation
NMR
Nuclear magnetic resonance
Oncoproteins
Operating systems
Proteins
Protons
Random access memory
Signal transduction
Spectrum analysis
Tumors
binding pocket
docking
Desmond
SRJ23
STD-NMR
K-Ras oncoprotein
molecular dynamics
Glide
anticancer
andrographolide
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Summary:Andrographolide and its benzylidene derivatives, SRJ09 and SRJ23, potentially bind oncogenic K-Ras to exert anticancer activity. Their molecular interactions with K-Ras oncoproteins that lead to effective biological activity are of major interest. docking and molecular dynamics simulation were performed using Glide and Desmond, respectively; while saturation transfer difference NMR was performed using GDP-bound K-RasG12V. SRJ23 was found to bind strongly and selectively to K-RasG12V, by anchoring to a binding pocket (namely p2) principally via hydrogen bond and hydrophobic interactions. The saturation transfer difference NMR analysis revealed the proximity of protons of functional moieties in SRJ23 to K-RasG12V, suggesting positive binding. SRJ23 binds strongly and interacts stably with K-RasG12V to exhibit its inhibitory activity.
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ISSN:1756-8919
1756-8927
DOI:10.4155/fmc-2020-0104