NikR is a homotetrameric nickel regulatory protein whose binding to free Ni(2+) increases its binding affinity for a gene that codes for a nickel transporter protein. It is comprised of a tetrameric nickel-binding domain, flanked by two dimeric DNA-binding domains. Though X-ray crystallography data for various species (Escherichia coli, Heliobacter pylori, and Pyrococcus horikoshii) of NikR reveal large conformational differences between nickel-bound, DNA-bound, and unbound forms, transitions between them have never been observed. We have run all-atom molecular dynamics simulations of three forms of the Pyrococcus horikoshii species of NikR including two apo-forms and one nickel-bound form. Though all 552 residues of this species occur naturally, quantum-mechanics-based force-field parametrization was required to accurately represent the four nickel-centers in the nickel-bound form. Global conformational analysis of the three 100-ns-long simulations indicates slow conformational kinetics and independent DNA binding domain motion. Correlation and flexibility analysis revealed regions of high structural and dynamical importance. A striking relationship was observed between regions with high levels of structural importance and regions with known biological importance. Mutation of key regions of P. horikoshii and analogous regions in both E. coli and H. pylori are suggested that might inhibit DNA-binding activity while not affecting nickel-binding.
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