Plasticity of the Quinone-binding Site of the Complex II Homolog Quinol:Fumarate Reductase |
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Authors: | Prashant K Singh Maruf Sarwar Elena Maklashina Violetta Kotlyar Sany Rajagukguk Thomas M Tomasiak Gary Cecchini Tina M Iverson |
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Institution: | From the Departments of ‡Pharmacology and ;‖Biochemistry, Vanderbilt University Medical Center, Nashville, Tennessee 37232.;the §Molecular Biology Division, Veterans Affairs Medical Center, San Francisco, California 94121, and ;the ¶Department of Biochemistry and Biophysics, University of California, San Francisco, California 94158 |
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Abstract: | Respiratory processes often use quinone oxidoreduction to generate a transmembrane proton gradient, making the 2H+/2e− quinone chemistry important for ATP synthesis. There are a variety of quinones used as electron carriers between bioenergetic proteins, and some respiratory proteins can functionally interact with more than one quinone type. In the case of complex II homologs, which couple quinone chemistry to the interconversion of succinate and fumarate, the redox potentials of the biologically available ubiquinone and menaquinone aid in driving the chemical reaction in one direction. In the complex II homolog quinol:fumarate reductase, it has been demonstrated that menaquinol oxidation requires at least one proton shuttle, but many of the remaining mechanistic details of menaquinol oxidation are not fully understood, and little is known about ubiquinone reduction. In the current study, structural and computational studies suggest that the sequential removal of the two menaquinol protons may be accompanied by a rotation of the naphthoquinone ring to optimize the interaction with a second proton shuttling pathway. However, kinetic measurements of site-specific mutations of quinol:fumarate reductase variants show that ubiquinone reduction does not use the same pathway. Computational docking of ubiquinone followed by mutagenesis instead suggested redundant proton shuttles lining the ubiquinone-binding site or from direct transfer from solvent. These data show that the quinone-binding site provides an environment that allows multiple amino acid residues to participate in quinone oxidoreduction. This suggests that the quinone-binding site in complex II is inherently plastic and can robustly interact with different types of quinones. |
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Keywords: | Bioenergetics/Electron Transfer Complex Electron Transfer Redox Respiratory Chain Tricarboxylic Acid (TCA) Cycle Menaquinone Naphthoquinone Ubiquinone |
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