Modulation of the activity of mitochondrial aspartate aminotransferase H352C by the redox state of the engineered interdomain disulfide bond.

Molecular modeling suggested that the large and small domain of mitochondrial aspartate aminotransferase might be linked by an engineered disulfide bond that could be expected to interfere with ligand-induced and syncatalytic changes in conformation and thus to assist in the elucidation of their significance for the catalytic mechanism. His-352, which is situated in the small domain close to Cys-166 of the large domain, was replaced with a cysteine residue by oligonucleotide-directed mutagenesis. Aspartate aminotransferase H352C, that had not been exposed to reducing conditions, in part contained a disulfide bond between Cys-166 and Cys-352. Exposure to a reducing agent cleaved the crosslink completely and produced an enzyme derivative with 8% of the activity of the wild type enzyme. Cu2+-mediated autoxidation resulted in complete formation of the disulfide bond and a decrease in enzymic activity to 2%. Independently of the redox state of the disulfide bond, the H352C substitution seems to shift the equilibrium from the open toward the closed conformation of the enzyme. This change in conformation was accompanied by an increase in the binding affinity for both the amino and oxo acid substrate by one order of magnitude. Apparently, 1-2 kcal/mol of the binding energy of the substrates are no longer diverted to shift the conformational equilibrium toward the closed conformation. The kcat/Km values were unchanged or even increased in the reduced form of the mutant enzyme and only slightly decreased in its oxidized form. Both the disulfide-independent decrease in enzymic activity, as observed in reduced aspartate aminotransferase H352C and also in two other mutant enzymes (C166H/H352C and H352Q), and the redox-dependent modulation of activity indicate that unhindered domain movements are essential for full catalytic competence of aspartate aminotransferase.