Protein stability function relations: native β‐lactoglobulin sulphhydryl–disulphide exchange with PDS

Intermolecular sulphhydryl–disulphide exchange with β‐lactoglobulin dimer occurs when this dissociates to form monomers exposing two SH groups. This notion is re‐evaluated in the light of recent structural data suggesting that the degree of SH group exposure in β‐lactoglobulin is unaffected by dissociation. β‐Lactoglobulin was treated with 2,2′‐dipyridyl disulphide (PDS). The rate of sulphhydryl–disulphide exchange was measured at sub‐denaturation temperatures of 25–60 ° C. Parallel studies were conducted by reacting PDS with reduced glutathione (GSH). The SH group of GSH was up to 31 000 times more reactive than β‐lactoglobulin. At pH 7 the reaction activation enthalpy (Δ H # ) and entropy (Δ S # ) was 26 kJ mol −1 and −100 J mol −1  K −1 respectively for GSH. For β‐lactoglobulin, Δ H # was 157.2 kJ mol −1 and Δ S # was 254 J mol −1  K −1 . At pH 2.6, Δ H # was 14.4 kJ mol −1 and Δ S # was −213 J mol −1  K −1 for GSH. The corresponding results for β‐lactoglobulin were 20.3 kJ mol −1 and −147 J mol −1  K −1 . These and other thermodynamic results are discussed in terms of the effects of β‐lactoglobulin conformational structure and stability on SH group reactivity. For native β‐lactoglobulin at neutral pH, intermolecular sulphhydryl–disulphide exchange appears to involve the dissociated monomer. SH group activation probably arises from the lower structural stability of the monomer relative to the dimer. At pH 2.6 the mechanism of SH–disulphide exchange does not require protein dissociation and probably involves breathing motions or localised changes in protein structure. © 2000 Society of Chemical Industry