Protein environmental effects on iron-sulfur clusters: A set of rules for constructing computational models for inner and outer coordination spheres
The structural properties and reactivity of iron‐sulfur proteins are greatly affected by interactions between the prosthetic groups and the surrounding amino acid residues. Thus, quantum chemical investigations of the structure and properties of protein‐bound iron‐sulfur clusters can be severely lim...
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Veröffentlicht in: | Journal of computational chemistry 2016-07, Vol.37 (18), p.1681-1696 |
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Sprache: | eng |
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Zusammenfassung: | The structural properties and reactivity of iron‐sulfur proteins are greatly affected by interactions between the prosthetic groups and the surrounding amino acid residues. Thus, quantum chemical investigations of the structure and properties of protein‐bound iron‐sulfur clusters can be severely limited by truncation of computational models. The aim of this study was to identify, a priori, significant interactions that must be included in a quantum chemical model. Using the [2Fe‐2S] accessory cluster of the FeFe‐hydrogenase as a demonstrative example with rich electronic structural features, the electrostatic and covalent effects of the surrounding side chains, charged groups, and backbone moieties were systematically mapped through density functional theoretical calculations. Electron affinities, spin density differences, and delocalization indexes from the quantum theory of atoms in molecules were used to evaluate the importance of each interaction. Case studies for hydrogen bonding and charged side‐chain interactions were used to develop selection rules regarding the significance of a given protein environmental effect. A set of general rules is proposed for constructing quantum chemical models for iron‐sulfur active sites that capture all significant interactions from the protein environment. This methodology was applied to our previously used models in galactose oxidase and the 6Fe‐cluster of FeFe‐hydrogenase. © 2016 Wiley Periodicals, Inc.
A set of general rules was developed for constructing computational models that capture covalent and electrostatic interactions from protein environment with significance to the structure of transition‐metal prosthetic group. The rules were developed from detailed analyses of the spin density, Coulomb potential, vertical ionization energies was carried out for a [2Fe‐2S] cluster. Their transferability was evaluated for the H‐cluster of the FeFe‐hydrogenase and the [Cu‐OTyrCys] catalytic centers of the galactose oxidase. |
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ISSN: | 0192-8651 1096-987X |
DOI: | 10.1002/jcc.24384 |