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Unveiling kaempferol glycosides as the key antiglycative components in butterfly pea (Clitoria ternatea) flower

Jun Wu, Jun Jie Gong, Qiaochun Chen, Wen Hao, Jiayi He, Mingfu Wang, Qian Zhou

2024Current Research in Food Science8 citationsDOIOpen Access PDF

Abstract

Edible flowers have been used in dietary practices since ancient times. In recent years, they have garnered increasingly more attentions for their potentials in the prevention and amelioration of pathological conditions. The present study employed in vitro BSA models to evaluate the antiglycative effect of some edible flowers. Results showed that butterfly pea flower (BFPF) exhibited the highest potential in preventing advanced glycation end products (AGEs) formation, which had an inhibition rate of 92.11% at 1 g/mL, 56.99% at 0.1 g/mL, and 9.94% at 0.01 g/mL, respectively. Moreover, the antiglycative components in BFPF were identified as four flavonol glycosides through chromatographic and spectral analyses, which were manghaslin (quercetin 3-2″-rhamnosylrutinoside, QCT-Rh), clitorin (kaempferol 3–2″-rhamnosylrutinoside, KFR-Rh), rutin (quercetin 3-rutinoside), and kaempferol 3-neohesperidoside (KFR-Ne). Notably, KFR-Rh and KFR-Ne were presented in higher concentrations in BFPF (764.31 mg/kg and 1135.10 mg/kg dry matter) and significantly contributed to the antiglycative activity (IC 50 = 182.17 μM and IC 50 = 131.03 μM). Molecular docking (MD) and nuclear magnetic resonance (NMR) analyses revealed that KFR-Rh and KFR-Ne formed hydrogen bonds and hydrophobic interactions with BSA, while KFR-Ne demonstrating a stronger interaction than KFR-Rh. Collectively, our findings highlight the beneficial effects of BFPF with clearly identified active components, which might further promote its application in functional food and medical industry. • Butterfly pea flower exhibits remarkable antiglycative activity. • Flavonol glycosides are identified as the major contributors. • Kaempferol glycosides content surpass quercetin glycosides significantly. • Hydrogen bond and hydrophobic interaction mediate flavonol glycoside-BSA interaction.

Topics & Concepts

Clitoria ternateaButterflyKaempferolKey (lock)BotanyBiologyFlavonoidMedicineEcologyAntioxidantPathologyAlternative medicineBiochemistryMedicinal Plant ResearchMoringa oleifera research and applicationsEthnobotanical and Medicinal Plants Studies