We describe a computer program (Metal Search) that helps design tetrahedrally coordinated metal binding sites in proteins of known structure. The program takes as input the backbone coordinates of a protein and outputs lists of four residues that might form tetrahedral sites if wild-type amino acids were replaced by cysteine or histidine. The program also outputs the side chain dihedral angles of the amino acids and the coordinates of the predicted metal ion. The only function evaluated by Metal Search is the ability of side chains to meet simple geometric criteria for formation of a tetrahedral site, but these criteria are sufficient to produce a manageably small list that can then be evaluated by other means. The program has been used in the introduction of zinc binding sites in the designed four-helix bundle protein alpha 4 and in the B1 domain of streptococcal protein G, and in both cases the tetrahedral coordination of a bound metal ion has been confirmed (Klemba, M., Gardner, K. H., Marino, S., Clarke, N.D., and Regan, L., Nature: Structural Biology 2:368-373, 1995).
Inspired by the Paracelsus Challenge of Rose and Creamer (Proteins 19: 1-3, 1994), we have designed a protein sequence that is 50% identical to an all-helical protein but is intended to fold into a largely beta-sheet structure. Rather than attempt a de novo design, our strategy was to construct a hybrid sequence based on a helical "parent" protein (434 Cro) and a "target" protein with the desired fold (the B1 domain of protein G). The hybrid sequence (Crotein-G) is 50% identical to 434 Cro but is also 62% identical to the B1 domain of protein G. We also created a variant of Crotein-G (ZCrotein-G) that contains a potential His3Cys1 zinc binding site. At low protein concentrations and in the presence of 20% 2,2,2-trifluoroethanol (TFE) (v/v), the circular dichroism spectra of the designed proteins are distinct from that of 434 Cro and similar to that of the B1 domain of protein G. However, the proteins fail to denature in a cooperative manner. Furthermore, aggregation occurs at moderate protein concentrations or in the absence of TFE. Addition of zinc to ZCrotein-G does not promote structure formation. In summary, 434 Cro has been altered to something that may resemble the B1 domain of protein G, but the protein does not adopt a native structure.
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