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Response of a Designed Metalloprotein to Changes in Metal Ion Coordination, Exogenous Ligands, and Active Site Volume Determined by X-ray Crystallography
journal contribution
posted on 2005-12-14, 00:00 authored by Silvano Geremia, Luigi Di Costanzo, Lucio Randaccio, Donald E. Engel, Angela Lombardi, Flavia Nastri, William F. DeGradoThe de novo protein DF1 is a minimal model for diiron and dimanganese metalloproteins, such
as soluble methane monooxygenase. DF1 is a homodimeric four-helix bundle whose dinuclear center is
formed by two bridging Glu side chains, two chelating Glu side chains, and two monodentate His ligands.
Here, we report the di-Mn(II) and di-Co(II) derivatives of variants of this protein. Together with previously
solved structures, 23 crystallographically independent four-helix bundle structures of DF1 variants have
been determined, which differ in the bound metal ions and size of the active site cavity. For the di-Mn(II)
derivatives, as the size of the cavity increases, the number and polarity of exogenous ligands increases.
This collection of structures was analyzed to determine the relationship between protein conformation and
the geometry of the active site. The primary mode of backbone movement involves a coordinated tilting
and sliding of the first helix in the helix−loop−helix motif. Sliding depends on crystal-packing forces, the
steric bulk of a critical residue that determines the dimensions of the active site access cavity, and the
intermetal distance. Additionally, a torsional motion of the bridging carboxylates modulates the intermetal
distance. This analysis provides a critical evaluation of how conformation, flexibility, and active site
accessibility affect the geometry and ligand-binding properties of a metal center. The geometric parameters
defining the DF structures were compared to natural diiron proteins; DF proteins have a restricted active
site cavity, which may have implications for substrate recognition and chemical stability.