In silico modelling of apo-lactoferrin under simulated gastric conditions: Structural dynamics, binding with β-lactoglobulin and α-lactalbumin, and functional implications

Abstract

This study employs computational techniques to investigate whether the inclusion of β-lactoglobulin and α-lactalbumin can enhance the molecular stability of apo-lactoferrin in conditions of gastric pH. Atomistic molecular dynamics simulations reveal that acidic pH results in weakened interactions between lactoferrin and the other proteins compared to those under neutral pH. Nevertheless, protein-protein dissociation free energy calculations using the umbrella sampling calculations confirm that some contacts are maintained between apo-lactoferrin and the other whey proteins, specifically the β-lactoglobulin units. This is manifested as a broad energy minimum at the intermediate inter-molecular distance of the inter-protein free energy profiles; thereby, demonstrating the formation of a nano-scale flocculant, followed by a potential gel, composed of protein particles. Practically, this property could be exploited to entrap further bioactive components within the protein matrix for novel engineered food materials. Furthermore, it was found that the anti-bacterial peptide regions of apo-lactoferrin are unaffected by the acidic pH, indicating the potential capability of apo-lactoferrin to act against harmful bacteria. Overall, this work unveils an understanding at a molecular level regarding the structural changes of the aforementioned proteins that maybe beneficial for future advancement of nutraceuticals.