Mechanism of Ubiquinol Oxidation by the <i>bc</i><sub>1</sub> Complex:  Different Domains of the Quinol Binding Pocket and Their Role in the Mechanism and Binding of Inhibitors

Crofts, Antony R.; Barquera, Blanca; Gennis, Robert B.; Kuras, Richard; Guergova-Kuras, Mariana; Berry, Edward A.

doi:10.1021/bi990962m

Cited by 164 publications

(298 citation statements)

References 60 publications

(327 reference statements)

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“…The histidine ligands take up a proton from the substrate, ubiquinol, upon reduction of the [2Fe-2S] cluster and release it to the intermembrane space when oxidized by cytochrome c 1 , as was suggested recently (31). Glu-295 in cytochrome b is important for the release of the second proton, as proposed previously (31)(32)(33). Glu-295 is completely conserved in mitochondrial cytochrome b (34), and the importance of the residue in proton transfer is indicated by mutagenesis studies because alteration of glutamine abolishes ubiquinol oxidation in R. sphaeroides (35).…”

Section: Photosynthetic Growth Behaviors Of the Wild-type Andsupporting

confidence: 56%

Effect of Mutations of Arginine 94 on Proton Pumping, Electron Transfer, and Superoxide Anion Generation in Cytochrome b of the bc1 Complex from Rhodobacter sphaeroides

Zhou

2013

Journal of Biological Chemistry

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Background:The bc 1 complex catalyzes electron transfer from ubiquinol to cytochrome c and translocates protons across the membrane. Results: Substitution of Arg-94 decreased the electron transfer activity and proton pumping capability and increased the superoxide production. Conclusion: Arg-94 is an important amino acid for the proton pumping capability of the bc 1 complex. Significance: The result is significant for understanding the catalytic mechanism of the bc 1 complex.

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Section: Photosynthetic Growth Behaviors Of the Wild-type Andsupporting

confidence: 56%

Effect of Mutations of Arginine 94 on Proton Pumping, Electron Transfer, and Superoxide Anion Generation in Cytochrome b of the bc1 Complex from Rhodobacter sphaeroides

Zhou

2013

Journal of Biological Chemistry

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“…In the native structure the site is vacant. The position of the ISP in our myxothiazole or MOA-stilbenecontaining crystals (23) is the same as in the native structure (7,15,23). A number of features of interest to an understanding of the mechanism of the Q o site should be noted.…”

Section: Positionsmentioning

confidence: 88%

“…We have suggested that the g x ) 1.800 signal reflects the close interaction between quinone bound at the end of the pocket distal from heme b L and the reduced ISP docked at the interface on cytochrome b (15,23). This simple interpretation allows us to use the g x ) 1.800 signal as diagnostic of this interaction and provides a tool to explore the effects of mutation.…”

Section: Mobility and Binding Of The Isp: Complementary Functional Asmentioning

confidence: 93%

“…This rotation facilitates access to the inhibitor, which is also aided by the widening on displacement of the -PEWYloop. Changes deeper in the pocket, including the rotation of Glu-272 into the pocket noted above, are discussed in a separate paper (23). Impaired function upon site-directed mutagenesis of several of these residues has demonstrated their importance to function.…”

Section: Positionsmentioning

confidence: 96%

“…In solid-state systems, equivalent rates are achieved by a fixed intermediate redox carrier (64). Although the main evolutionary advantage of the more flexible arrangement probably pertains to the peculiar mechanism of the bifurcated reaction (22,23), the tethered head mechanism might provide other useful options. By constraining the local diffusional domain, the mechanism avoids the entropic loss of free diffusion and the slower rate of the second-order reaction resulting from dilution in a larger volume.…”

Section: Mobility and Binding Of The Isp: Complementary Functional Asmentioning

confidence: 99%

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Mechanism of Ubiquinol Oxidation by the bc₁ Complex: Role of the Iron Sulfur Protein and Its Mobility

et al. 1999

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Native structures of ubihydroquinone:cytochrome c oxidoreductase (bc 1 complex) from different sources, and structures with inhibitors in place, show a 16-22 Å displacement of the [2Fe-2S] cluster and the position of the C-terminal extrinsic domain of the iron sulfur protein. None of the structures shows a static configuration that would allow catalysis of all partial reactions of quinol oxidation. We have suggested that the different conformations reflect a movement of the subunit necessary for catalysis. The displacement from an interface with cytochrome c 1 in native crystals to an interface with cytochrome b is induced by stigmatellin or 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT) and involves ligand formation between His-161 of the [2Fe-2S] binding cluster and the inhibitor. The movement is a rotational displacement, so that the same conserved docking surface on the iron sulfur protein interacts with cytochrome c 1 and with cytochrome b. The mobile extrinsic domain retains essentially the same tertiary structure, and the anchoring N-terminal tail remains in the same position. The movement occurs through an extension of a helical segment in the short linking span. We report details of the protein structure for the two main configurations in the chicken heart mitochondrial complex and discuss insights into mechanism provided by the structures and by mutant strains in which the docking at the cytochrome b interface is impaired. The movement of the iron sulfur protein represents a novel mechanism of electron transfer, in which a tethered mobile head allows electron transfer through a distance without the entropic loss from free diffusion.The ubihydroquinone:cytochrome c oxidoreductase (bc 1 complex) 1 (E.C. 1.10.2.2) and the related b 6 f complex of oxygenic photosynthesis are central components of the major electron-transfer chains that carry the energy flux of the biosphere. The bc 1 complex of the mitochondrial respiratory chain transfers electrons from ubihydroquinone (quinol) to cytochrome (cyt) c in the aqueous phase and catalyzes the coupled transfer of protons across the membrane. Our understanding of the function of these enzymes at the atomic level has been greatly aided by structures recently solved by X-ray crystallography. These include cyt f (the equivalent of cyt c 1 in the b 6 f complex) from chloroplasts (1, 2) and the Rieske iron sulfur protein (ISP) from the beef heart mitochondrial complex (3) and chloroplasts (4), all crystallized as water-soluble fragments generated by proteolysis or mutagenesis. A partial structure of the beef heart mitochondrial complex at ∼2.9 Å resolution has been published by Xia and colleagues (5, 6). However, the crystals were disordered in the region of the ISP and cytochrome c 1 , and this precluded a detailed consideration of the mechanistic role of these subunits. More complete structures for the complexes from chicken, rabbit, and beef heart mitochondria have been provided by Zhang et al. ‡ University of Illinois. § University of California. ...

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Antimalarials

Smithson¹,

Guiguemde²,

Guy³

2010

Burger's Medicinal Chemistry and Drug Discovery

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While the treatment of malaria has until recently relied upon a small number of therapeutic agents with a few mechanisms of action, the past decade has seen a huge growth in the number of targets being addressed and new agents being pushed to the clinic. This chapter briefly reviews existing agents and close homologs in development and then carefully explores new targets and new chemotypes being developed.

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Mechanism of Ubiquinol Oxidation by the bc₁ Complex: Different Domains of the Quinol Binding Pocket and Their Role in the Mechanism and Binding of Inhibitors

Cited by 164 publications

References 60 publications

Effect of Mutations of Arginine 94 on Proton Pumping, Electron Transfer, and Superoxide Anion Generation in Cytochrome b of the bc1 Complex from Rhodobacter sphaeroides

Effect of Mutations of Arginine 94 on Proton Pumping, Electron Transfer, and Superoxide Anion Generation in Cytochrome b of the bc1 Complex from Rhodobacter sphaeroides

Mechanism of Ubiquinol Oxidation by the bc₁ Complex: Role of the Iron Sulfur Protein and Its Mobility

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Mechanism of Ubiquinol Oxidation by the bc1 Complex: Different Domains of the Quinol Binding Pocket and Their Role in the Mechanism and Binding of Inhibitors

Cited by 164 publications

References 60 publications

Effect of Mutations of Arginine 94 on Proton Pumping, Electron Transfer, and Superoxide Anion Generation in Cytochrome b of the bc1 Complex from Rhodobacter sphaeroides

Effect of Mutations of Arginine 94 on Proton Pumping, Electron Transfer, and Superoxide Anion Generation in Cytochrome b of the bc1 Complex from Rhodobacter sphaeroides

Mechanism of Ubiquinol Oxidation by the bc1 Complex: Role of the Iron Sulfur Protein and Its Mobility

Antimalarials

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Mechanism of Ubiquinol Oxidation by the bc₁ Complex: Different Domains of the Quinol Binding Pocket and Their Role in the Mechanism and Binding of Inhibitors

Mechanism of Ubiquinol Oxidation by the bc₁ Complex: Role of the Iron Sulfur Protein and Its Mobility