Structural adaptations in the bovine serum albumin protein in archetypal deep eutectic solvent reline and its aqueous mixtures

The global concern over the environmental impact and challenges associated with the use of conventional solvents in biotransformation processes have pushed the search for alternative solvents. Recently, deep eutectic solvents (DESs) have appeared as a promising replacement with better biocompatibility and have been postulated to hold great potential in protein engineering and crystallization processes. In this context, herein, we have investigated the effect of reline (a choline chloride : urea mixture in 1 : 2 proportion) DES in its pure and hydrated forms on the structural stability and conformation of the bovine serum albumin (BSA) protein using all-atom molecular dynamics simulations. We observe a substantial overall expansion of the BSA structure with a simultaneous increment in the solvent accessible surface area, signifying the influence of reline on the BSA tertiary structure. These induced structural perturbations are quite pronounced in reline-water mixtures. Concomitantly, a notable reline concentration-dependent disruption of the BSA secondary structure through the melting of α-helices, mainly driven by H-bonding interactions, is observed. In the presence of pure reline, significant rigidity in the protein backbone is also observed. Thus, despite the expansion, the BSA tertiary structure in pure reline is found to be most close to the native protein structure and remains in a partially folded state at all the studied reline concentrations. In pure reline, BSA-urea hydrogen bonding is more prevalent than BSA-[Ch]+. We also observe that in aqueous reline systems, the BSA-water hydrogen bonds are mostly compensated by BSA-urea hydrogen bonds. The aqueous re-equilibration of these partially denatured protein conformations showed a significant recovery of secondary and tertiary structures, where the recovery is most profound for the BSA conformation extracted from pure reline.