Preorganization of the catalytic Zn(2+)-binding site in the HNH nuclease motif--A solution study.

The structure of the active site in a metalloenzyme can be a key determinant of its metal ion binding affinity and catalytic activity. In this study, the conformational features of the Zn(2+)-binding HNH motif were investigated by CD-spectroscopy in combination with isothermal microcalorimetric titrations. Various point mutations, including T454A, K458A and W464A, were introduced into the N-terminal loop of the nuclease domain of colicin E7 (NColE7). We show that the folding of the proteins was severely disturbed by the mutation of the tryptophan residue. This points to the importance of W464, being a part of the hydrophobic core located close to the HNH-motif. ITC demonstrated that the Zn(2+)-binding of the mutants including the W464 site became weak, and according to CD-spectroscopic measurements the addition of the metal ion itself cannot fully recover the functional structure. Titrations with Zn(2+)-ion in the presence and absence of the Im7 protein proved that the structural changes in the unfolded mutant included the HNH-motif itself. The metal-binding of the NColE7 mutants could be, however, fully rescued by the complexation of Im7. This suggests that the formation of a preorganized metal-binding site--existing in the wild-type enzyme but not in the W464 mutants--was induced by Im7. The low nuclease activity of all W464A mutants, however, implies that the interactions of this tryptophan residue are required for precise location of the catalytic residues, i.e. for stabilization of the fine-structure and of the tertiary structure. Our results contribute to the understanding of the metal binding site preorganization.

Design of a colicin E7 based chimeric zinc-finger nuclease.

Colicin E7 is a natural bacterial toxin. Its nuclease domain (NColE7) enters the target cell and kills it by digesting the nucleic acids. The HNH-motif as the catalytic centre of NColE7 at the C-terminus requires the positively charged N-terminal loop for the nuclease activity-offering opportunities for allosteric control in a NColE7-based artificial nuclease. Accordingly, four novel zinc finger nucleases were designed by computational methods exploiting the special structural features of NColE7. The constructed models were subjected to MD simulations. The comparison of structural stability and functional aspects showed that these models may function as safely controlled artificial nucleases. This study was complemented by random mutagenesis experiments identifying potentially important residues for NColE7 function outside the catalytic region.