The active sites of thiol-protein oxidoreductases consist of the characteristic Cys-X-X-Cys motif, and the redox potentials of these enzymes reflect the propensity of the bis(cysteinyl) sequence portion for disulfide loop formation. Thereby, as is known from comparing the three-dimensional (3D) structures of thioredoxin and glutaredoxin in the reduced and oxidized state, reduction of the disulfide bond is accompanied by minimal perturbation of the backbone folding of the active sites. In order to estimate the sequence-dependent intrinsic free energy of formation of the active-site disulfide loops in oxidoreductases, synthetic fragments corresponding to the sequences 31-38, 10-17, 134-141, and 34-41 of thioredoxin, glutaredoxin, thioredoxin reductase, and protein disulfide isomerase (PDI), respectively, were analyzed for their tendency to form 14-membered rings. For this purpose thiol/disulfide exchange experiments, with glutathione as reference redox pair, were performed on the bis(cysteinyl) octapeptides. As the free energy of ring closure of linear peptides consists mainly of the free energy of formation of the disulfide loop with a defined geometry from a statistical ensemble of conformations of the bis(cysteinyl) peptides, the observed differences in the equilibrium constants, although relatively small (within a factor 10), suggest that sequence-dependent information for loop formation is retained in the excised active-site fragments. These inherent redox potentials are, however, significantly affected and/or amplified in the native proteins by the conformational restraints imposed by the "structural domains" on the "functional domains".