The improved inhibition of Mn (II)-EGCG on α-glucosidase: Characteristics and interactions properties

•Mn-EGCG were prepared using the lyophilization with C22H14O11Mn2 by MS (m/z 565.4).•Mn-O (623 cm−1)/complex sites (4′, 3′, 5′′ and 4′′-OH) found by FT-IR and 1H-NMR.•Improved thermal stability (30.8%)/α-glucosidase inhibition (91.6%) was obtained.•Increased interaction/binding constants with temp (...

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Published in:Journal of molecular structure 2023-07, Vol.1283, p.135314, Article 135314
Main Authors: Li, Zhenru, Kang, Mengchen, Zhang, Shuangling, Zhang, Suzhi, Dongye, Zixuan, Wang, Li, Chen, Chengwang, Cheng, Xiaofang, Qian, Yaru, Ren, Yuhang
Format: Article
Language:English
Subjects:
Inhibition rate
Interactions
Mn (II)-EGCG
Mn-O bond
Molecular docking
α-glucosidase
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Summary:•Mn-EGCG were prepared using the lyophilization with C22H14O11Mn2 by MS (m/z 565.4).•Mn-O (623 cm−1)/complex sites (4′, 3′, 5′′ and 4′′-OH) found by FT-IR and 1H-NMR.•Improved thermal stability (30.8%)/α-glucosidase inhibition (91.6%) was obtained.•Increased interaction/binding constants with temp (9.52, 9.64, 15.7, × 106 L/mol).•Lower binding energy of Mn-EGCG (−65.50 vs. −41.31) revealed by molecular docking. To improve epigallocatechin gallate (EGCG)’s inhibition on α-glucosidase, Mn (II)-EGCG was prepared and characterized by Fourier transform infrared (FT-IR), mass spectrometry (MS), X-ray diffraction (XRD), nuclear magnetic resonance hydrogen (1H-NMR), and thermogravimetric analysis (TGA). The interactions between Mn-EGCG and α-glucosidase were revealed using fluorescence, isothermal titration calorimetry (ITC), circular dichroism (CD) and molecular docking. FT-IR of Mn-EGCG showed OH participated in the coordination with Mn, a m/z 565.4 peak was found in MS, a new spectral band Mn-O coordination bond was revealed by FT-IR (623 cm−1) and 1H-NMR, Mn replaced H of EGCG at 4′, 3′, 5′′, and 4′′-OH, and the molecular of Mn-EGCG was presumed to be C22H14O11Mn2 [E-4H+2Mn (II)], XRD indicated the broadened and shifted 2θ with crystallinity (79.68%), TGA showed the improved thermal stability of Mn-EGCG (30.8%). Inhibition rate of Mn-EGCG could reach 91.6% with IC50 7.5 mg/L, which was higher than EGCG (70.8%, 14 mg/L). Binding constants of Mn-EGCG were higher than EGCG and increased with temperature, resulting in static quenching of α-glucosidase. ITC and molecular docking showed Mn-EGCG bound to α-glucosidase was dominated by hydrophobic interactions, and three interactions (Alkyl, Pi-Anion, and Metal-Acceptor) appeared. In conclusion, a new functional food component and its inhibition mechanism are described. [Display omitted]
ISSN:0022-2860
1872-8014
DOI:10.1016/j.molstruc.2023.135314