The Influence of pH-Driven Interaction Between Soy Protein Isolate and Soy Isoflavones on the Structural and Functional Properties of Their Complexes.
Jing Yang, Yanling Lu, Yanmei Deng, Jiaojiao Yang, Lei Guo, Fangyu Fan
Abstract
Open AccessSoy protein isolate (SPI)-soy isoflavone (SI) complexes were prepared via a pH-driven method at varying SI concentrations (0-7.0 mg/mL) to study their interactions and to analyze the structural and functional characteristics of the complexes. The findings showed that the SPI-SI complexes' particle size first reduced and then rose with higher SI concentration. Fourier transform infrared spectroscopy revealed a reduction in β-sheet content (35.72%), indicating a limited structural rearrangement toward increased conformational flexibility. Consistently, fluorescence spectroscopy revealed that the fluorescence intensity of SPI diminished with the addition of SI, suggesting hydrogen-bond-mediated interactions. At 3.0 mg/mL SI, the complexes exhibited optimal physicochemical properties, with the most negative zeta potential (-29.78 mV), a solubility increase from 41.90% to 64.70%, and an elevated denaturation temperature from 86.77 °C to 88.79 °C, as well as 1.25-fold higher emulsifying capacity, and 1.86-fold greater emulsion stability; collectively establishing 3.0 mg/mL SI as the concentration where functional advantages are maximized. Overall, these findings demonstrate that pH-induced, non-covalent SPI-SI complexation effectively modulates protein conformation and interfacial properties, providing a green and effective approach for enhancing plant protein functionality in food systems.