AI Article Synopsis
- Understanding how proteins interact with bioactive molecules is vital for drug discovery and design, particularly for determining structure-function relationships.
- Previous studies on β-casein’s interaction with small bioactive molecules lacked clarity on binding pocket locations and amino acids, prompting further investigation through in silico simulations with polyphenols (chrysin, apigenin, and luteolin).
- Molecular docking and dynamics revealed specific amino acids involved in binding, with hydrophobic interactions stabilizing chrysin and apigenin, while polar solvation played a key role in stabilizing luteolin binding to β-casein.
Article Abstract
Revealing the interaction mechanism of proteins with bioactive molecules and the location of their binding pockets is crucial for predicting the structure-function relationship of proteins in drug discovery and design. Despite some published papers on the interaction of β-casein with small bioactive molecules, the ambiguity of the location and constituent amino acids of β-casein binding pockets prompted us to identify them by in silico simulation of its interaction with three polyphenols, chrysin, apigenin, and luteolin. Molecular docking revealed that the primary β-casein binding pocket for chrysin consists of five nonpolar amino acids (Leu73, Phe77, Pro80, Ile89, and Pro196), three polar neutral amino acids (Ser137, Gln138, and Gln197), and two polar charged amino acids (Glu136, and Arg198). For β-casein/apigenin and β-casein/luteolin complexes, Asn83 also contributes to forming the pocket. Molecular dynamics provided more details, such as the relative contribution of determinative amino acids and the role of various forces. For example, we found that Glu210, Glu132, and Glu35 are the most destructive residues in the binding of chrysin, apigenin, and luteolin to β-casein, respectively. Also, we observed that hydrophobic forces mainly stabilize β-casein/chrysin and β-casein/apigenin, and polar solvation (including hydrogen bonds) stabilizes β-casein/luteolin, all by spontaneous processes.
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| http://dx.doi.org/10.1016/j.bbrc.2024.150438 | DOI Listing |
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