Abstract

Accumulation of different protein-surfactant mixtures affords further knowledge about the structure-property interactions of biomacromolecules. They will help design suitable surfactants, which, in turn, can enhance the utilization of protein-surfactant complexes in biotechnologies, cosmetics, and food industry realms. Owing to their adaptable and remarkably notable properties, we are describing herein the interaction of C <i>_m</i> -E2O-C <i>_m</i> gemini surfactants (<i>m</i> = 12, 14, and 16) with α-CHT by employing various spectroscopic techniques including with molecular docking and density functional theory (DFT) method. Results have revealed complex formation, unfolding, and a static quenching mechanism in the interaction of gemini surfactants with α-CHT. The Stern-Volmer constant (<i>K</i> _SV), quenching constant (<i>k</i> _q), the number of binding sites (<i>n</i>), and binding constant (<i>K</i> _b) were interrogated by utilizing the fluorescence quenching method, UV-vis, synchronous, 3-D, and resonance Rayleigh scattering fluorescence studies. The data perceive the α-CHT-C <i>_m</i> -E2O-C <i>_m</i> complex formation along with conformational alterations induced in α-CHT. The contribution of aromatic residues to a nonpolar environment is illustrated by pyrene fluorescence. Fourier transform infrared spectroscopy and circular dichroism outcomes reveal conformational modifications in the secondary structure of α-CHT with the permutation of gemini surfactants. The computational calculations (molecular docking and DFT) further corroborate the complex formation between α-CHT and C <i>_m</i> -E2O-C <i>_m</i> gemini surfactants and the contribution of electrostatic/hydrophobic interaction forces therein.