Investigating binding mechanism between coconut globulin and tannic acid mediated by atmospheric cold plasma: Protein structure and stability

Physical methods present promising avenues for inducing covalent modifications of proteins by polyphenols, circumventing the safety and sustainability issues associated with traditional approaches. This study sought to enhance the physicochemical properties of coconut globulin (CG) by facilitating c...

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Bibliographic Details
Published in:Food chemistry 2025-02, Vol.464 (Pt 2), p.141670, Article 141670
Main Authors: Chen, Yang, Chen, Yile, Jiang, Lianzhou, Wang, Jiamei, Zhang, Weimin
Format: Article
Language:English
Subjects:
coconuts
Cocos - chemistry
Covalent cross-linking
crosslinking
denaturation
food chemistry
globulins
Globulins - chemistry
Globulins - metabolism
Hydrophobic and Hydrophilic Interactions
hydrophobicity
nonthermal processing
particle size
Physical stability
Plant protein
Plant Proteins - chemistry
Plant Proteins - metabolism
Plasma Gases - chemistry
Polyphenols
Protein Binding
Protein Stability
protein structure
Solubility
tannins
Tannins - chemistry
temperature
Thermodynamic properties
Viscosity
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Summary:Physical methods present promising avenues for inducing covalent modifications of proteins by polyphenols, circumventing the safety and sustainability issues associated with traditional approaches. This study sought to enhance the physicochemical properties of coconut globulin (CG) by facilitating covalent cross-linking with tannic acid (TA) through atmospheric cold plasma (ACP). The ACP treatment effectively transitioned the interaction between CG and TA from non-covalent to covalent in a voltage-dependent manner at pH 6.0, resulting in structural modifications of CG. The treatment with TA enhanced the spherical structure of CG, with a reduction in particle size from 474 to 384 nm. This size reduction was further amplified by the exposure of charged groups induced by ACP treatment. Consequently, the solubility, surface hydrophobicity, and viscosity of ACP-treated CG-TA increased, leading to an elevated denaturation temperature and enhanced physical stability. These results suggest a viable approach to improving the suboptimal physicochemical properties of plant proteins. [Display omitted] •ACP treatment unfolded the CG structure thereby creating more binding sites for TA.•ACP treatment promoted covalent cross-linking of CG and TA via CN or CS bonds.•Covalent cross-linking improved the stability and emulsifying properties of CG-TA.
ISSN:0308-8146
1873-7072
1873-7072
DOI:10.1016/j.foodchem.2024.141670