Removal of Dodecyl Sulfate Ions Bound to Human and Bovine Serum Albumins Using Sodium Cholate.

Abstract

The secondary structures of human serum albumin (HSA) and bovine serum albumin (BSA) were disrupted in the solution of sodium dodecyl sulfate (SDS), while being hardly damaged in the solution of the bile salt, sodium cholate (NaCho). In the present work, the removal of dodecyl sulfate (DS) ions bound to these proteins was attempted by adding various amounts of NaCho. The extent of removal was estimated by the restoration of α-helical structure of each protein disrupted by SDS. Increases and decreases in α-helical structure were examined using the mean residue ellipticity at 222 nm, [θ]222, which was frequently used as a measure of α-helical structure content. The magnitudes of [θ]222 of HSA and BSA, weakened by SDS, were restrengthened upon the addition of NaCho. This indicated that the α-helical structures of HSA and BSA that were disrupted by the binding of DS ions were nearly reformed by the addition of NaCho. The NaCho concentration at which the maximum restoration of [θ]222 of each protein was attained increased nearly linearly with SDS concentration. These results indicated that most of the bound DS ions were removed from the proteins but the removal was incomplete. The removal of DS ions, examined by means of the equilibrium dialysis, was also incomplete. The α-helical structure restoration and the DS ion removal by NaCho were considered to be due to the ability of cholate anions to strip the surfactant ions bound to HSA and BSA. These stripped DS ions appeared to be more likely to form SDS-NaCho mixed micelles in bulk rather than SDS-NaCho mixed aggregates on the proteins.