Mutations in the N- and C-terminal tails of potato carboxypeptidase inhibitor influence its oxidative refolding process at the reshuffling stage.

A comparative study of the oxidative refolding for nine selected potato carboxypeptidase inhibitor (PCI) mutants was carried out using the disulfide quenching approach. The mutations were performed at the N- and C-terminal tails of PCI outside its disulfide stabilized central core. The differences between the refolding of wild type and mutant proteins were observed in the second phase of the refolding process, the reshuffling of disulfide bridges, although the first phase, nonspecific packing, was not greatly affected by the mutations. Point mutations at the C-tail or deletion of up to three C-terminal residues of PCI resulted in a lower efficiency of the reshuffling process. In the case of the mutants lacking five N-terminal or four or five C-terminal residues, no "native-like" form was observed after the refolding process. On the other hand, the double mutant G35P/P36G did not attain a native-like form either, although one slightly more stable species was observed after being submitted to refolding. The disulfide pairing of this species is different from that of the wtPCI native form. The differences between the refolding process of wild type and mutant forms are interpreted in the light of the new view of protein folding. The results of the present study support the hypothesis that the refolding of this small disulfide-rich protein, and others, is driven by noncovalent interactions at the reshuffling stage. It is also shown that the interactions established between the N- and C-tail residues and the core of PCI are important for the proper refolding of the protein.

Contribution of C-tail residues of potato carboxypeptidase inhibitor to the binding to carboxypeptidase A A mutagenesis analysis.

The role of each residue of the potato carboxypeptidase inhibitor (PCI) C-terminal tail, in the interaction with carboxypeptidase A (CPA), has been studied by the analysis of two main kinds of site-directed mutants: the point substitution of each C-terminal residue by glycine and the sequential deletions of the C-terminal residues. The mutant PCI-CPA interactions have been characterized by the measurement of their inhibition constant, Ki, in several cases, by their kinetic association and dissociation constants determined by presteady-state analysis, and by computational approaches. The role of Pro36 appears to be mainly the restriction of the mobility of the PCI C-tail. In addition, and unexpectedly, both Gly35 and Pro36 have been found to be important for folding of the protein core. Val38 has the greatest enthalpic contribution to the PCI-CPA interaction. Although Tyr37 has a minor contribution to the binding energy of the whole inhibitor, it has been found to be essential for the interaction with the enzyme following the cleavage of the C-terminal Gly39 by CPA. The energetic contribution of the PCI secondary binding site has been evaluated to be about half of the total free energy of dissociation of the PCI-CPA complex.