Abstract
A challenging objective of de novo metalloprotein design is to control of the outer coordination spheres of an active site to fine tune metal properties. The well-defined three stranded coiled coils, TRI and CoilSer peptides, are used to address this question. Substitution of Cys for Leu yields a thiophilic site within the core. Metals such as Hg(II) , Pb(II) , and As(III) result in trigonal planar or trigonal pyramidal geometries; however, spectroscopic studies have shown that Cd(II) forms three-, four- or five-coordinate Cd(II) S(3) (OH(2) )(x) (in which x=0-2) when the outer coordination spheres are perturbed. Unfortunately, there has been little crystallographic examination of these proteins to explain the observations. Here, the high-resolution X-ray structures of apo- and mercurated proteins are compared to explain the modifications that lead to metal coordination number and geometry variation. It reveals that Ala substitution for Leu opens a cavity above the Cys site allowing for water excess, facilitating Cd(II) S(3) (OH(2) ). Replacement of Cys by Pen restricts thiol rotation, causing a shift in the metal-binding plane, which displaces water, forming Cd(II) S(3) . Residue d-Leu, above the Cys site, reorients the side chain towards the Cys layer, diminishing the space for water accommodation yielding Cd(II) S(3) , whereas d-Leu below opens more space, allowing for equal Cd(II) S(3) (OH(2) ) and Cd(II) S(3) (OH(2) )(2) . These studies provide insights into how to control desired metal geometries in metalloproteins by using coded and non-coded amino acids.