Interaction between berberine hydrochloride and β-lactoglobulin of two structures by heat treatment

Heat treatment, a method of treating proteins during food processing, can cause conformational and morphological changes. Dairy products contain beta-lactoglobulin (beta-lg), which is usually used at high temperature or pasteurization, and beta-lg can form three-dimensional hydrophilic gel by heat treatment under certain conditions. This study revealed the structural differences between native (n-lg) and heated proteins (h-lg) and compared their binding mechanism with berberine hydrochloride (BH), thereby providing sights into the functional food formulation design. After heat treatment the secondary structure of beta-lg became compact. In addition, the morphology of protein nanoparticles changed from uniform spherical to irregular angular. The interaction mechanism of BH with beta-lg was investigated by multi-spectroscopic methods and computer simulation techniques. The interactions between beta-lg and BH showed a static quenching mechanism with energy transfer under electrostatic and hydrophobic force. Moreover, protein-ligand complexes showed moderate binding capacity with the binding stoichiometric ratio of 1:1. Results were consistent between n-lg-BH and h-lg-BH systems. The differences caused by heat treatment were reflected in the perturbation of the protein structure and the temperature sensitivity of binding affinity. Molecular simulation showed that BH tends to bind on the outside of the barrel and close to Trp19-Arg124 of beta-lg and verified the reliability of the experimental results theoretically. This study showed the importance of heat treatment in food processing and explored the mechanism of heated protein and ligand in the protein-ligand interaction.

Automated summary

Heat treatment causes conformational and morphological changes in proteins. This study examined the differences between native and heated proteins, as well as their binding mechanism with berberine hydrochloride (BH). Results showed that heat treatment resulted in a more compact secondary structure and a change in the morphology of protein nanoparticles. The interaction mechanism between beta-lg and BH was found to involve static quenching with energy transfer under electrostatic and hydrophobic forces, with a binding stoichiometric ratio of 1:1. Mollecular simulation confirmed the experimental results and highlighted the importance of heat treatment in food processing.