Proton and electron transfer in bacterial reaction centers

Okamura, M. Y.; Paddock, Mark L.; Graige, M. S.; Fehér, G.

doi:10.1016/s0005-2728(00)00065-7

Cited by 373 publications

(543 citation statements)

References 84 publications

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“…Many of the membrane-bound protein complexes in the respiratory and photosynthetic systems are known to react with quinone. X-ray crystallographic information clearly confirmed the general functional roles of quinones, for example, at the Q o and Q i sites of mitochondrial complex III [4,8] as well as at the Q A and Q B sites of the bacterial photosynthetic reaction center [23,36]. Various research groups detected proteinbound forms of quinone species by their semiquinone signals using EPR spectroscopy.…”

Section: Introductionmentioning

confidence: 80%

Functional role of Coenzyme Q in the energy coupling of NADH‐CoQ oxidoreductase (Complex I): Stabilization of the semiquinone state with the application of inside‐positive membrane potential to proteoliposomes

Ohnishi

Shinzawa-Ito

et al. 2008

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Coenzyme Q 10 (which is also designated as CoQ 10 , ubiquinone-10, UQ 10 , CoQ, UQ or simply as Q) plays an important role in energy metabolism. For NADH-Q oxidoreductase (complex I), Ohnishi and Salerno proposed a hypothesis that the proton pump is operated by the redox-driven conformational change of a Q-binding protein, and that the bound form of semiquinone (SQ) serves as its gate [FEBS Letters 579 (2005) 45-55]. This was based on the following experimental results: (i) EPR signals of the fast-relaxing SQ anion (designated as ) are observable only in the presence of the proton electrochemical potential ( ); (ii) iron-sulfur cluster N2 and are directly spincoupled; and (iii) their center-to-center distance was calculated as 12Å, but is only 5Å deeper than N2 perpendicularly to the membrane. After the priming reduction of Q to , the proton pump operates only in the steps between the semiquinone anion ( ) and fully reduced quinone (QH 2 ). Thus, by cycling twice for one NADH molecule, the pump transports 4H + per 2e − . This hypothesis predicts the following phenomena: (a) Coupled with the piericidin A sensitive NADH-DBQ or Q 1 reductase reaction, would be established; (b) would enhance the SQ EPR signals; and (c) the dissipation of with the addition of an uncoupler would increase the rate of NADH oxidation and decrease the SQ signals.We reconstituted bovine heart complex I, which was prepared at Yoshikawa's laboratory, into proteoliposomes. Using this system, we succeeded in demonstrating that all of these phenomena actually took place. We believe that these results strongly support our hypothesis.

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Section: Introductionmentioning

confidence: 80%

Functional role of Coenzyme Q in the energy coupling of NADH‐CoQ oxidoreductase (Complex I): Stabilization of the semiquinone state with the application of inside‐positive membrane potential to proteoliposomes

Ohnishi

Shinzawa-Ito

et al. 2008

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“…A better understanding of this phenomenon is sought because it underpins so many fundamental life processes [13][14][15][16][17][18] . One particularly important process involves the delivery of protons to the interior of proteins so that key biochemical reactions can proceed [19][20][21] . In the case of the oxidative phosphorylation complexes, such as cytochrome oxidase, and in the photosynthesis complex, cytochrome b 6 f, vectorial proton pumping is also involved.…”

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confidence: 99%

“…Thus, the experiments presented here, which are the first temperature dependent measurements of tunneling in a biological proton wire and cover a much larger temperature range than previous studies 2,3,5,9 , can help us to better understand this important process. Because the deep tunneling rate is so exquisitely sensitive to tunnel-distance variations, it has the potential to play an important role in controlling transport along protein wires or in enzymatic reactions 5,19,20 .…”

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confidence: 99%

Wide-dynamic-range kinetic investigations of deep proton tunnelling in proteins

et al. 2016

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Abstract:Directional proton transport along "wires" that feed biochemical reactions in proteins is poorly understood. Amino acid residues with high pK a are seldom considered as active transport elements in such wires because of their large classical barrier for proton dissociation. Here we use the light-triggered proton wire of the green fluorescent protein (GFP) to study its ground electronic state proton transport kinetics, revealing a large temperature-dependent kinetic isotope effect. We show that "deep" proton tunneling between hydrogen-bonded oxygen atoms having a typical donor-acceptor distance of 2.7-2.8 Ǻ fully accounts for the rates at all temperatures, including the unexpectedly large value (2.5 10 9 s -1 ) found at room temperature. The rate limiting step in GFP is assigned to tunneling of the ionization-resistant serine hydroxyl proton. This suggests how high pK a residues within a proton wire can act as a "tunnel-diode" to kinetically trap protons and control the direction of proton flow.

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“…The coupled ET͞PT reactions involving Q A/B in bRC proceed in two phases, as shown by the following reaction schemes (reviewed in refs. 1 The PT to Glu-L212 near Q B is a prerequisite for the first ET event belonging to kinetic phase 1 (Eq. 1b).…”

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confidence: 99%

Induced conformational changes upon Cd ²⁺ binding at photosynthetic reaction centers

Ishikita

Knapp

2005

Proc. Natl. Acad. Sci. U.S.A.

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Cd 2؉ binding at the bacterial photosynthetic reaction center (bRC) from Rhodobacter sphaeroides is known to inhibit proton transfer (PT) from bulk solvent to the secondary quinone Q B. To elucidate this mechanism, we calculated the pK a for residues along the water channels connecting Q B with the stromal side based on the crystal structures of WT-bRC and Cd 2؉ -bound bRC. Upon Cd 2؉ binding, we observed the release of two protons from His-H126͞128 at the Cd 2؉ binding site and significant pKa shifts for residues along the PT pathways. Remarkably, Asp-L213 near Q B, which is proposed to play a significant role in PT, resulted in a decrease in pK a upon Cd 2؉ binding. The direct electrostatic influence of the Cd 2؉ -positive charge on these pK a shifts was small. Instead, conformational changes of amino acid side chains induced electrostatically by Cd 2؉ binding were the main mechanism for these pKa shifts. The longrange electrostatic influence over Ϸ12 Å between Cd 2؉ and Asp-L213 is likely to originate from a set of Cd 2؉ -induced successive reorientations of side chains (Asp-H124, His-H126, His-H128, Asp-H170, Glu-H173, Asp-M17, and Asp-L210), which propagate along the PT pathways as a ''domino'' effect.Cd͞Zn binding effect ͉ photosystem ͉ proton uptake ͉ revertant mutants ͉ secondary quinone

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Proton and electron transfer in bacterial reaction centers

Cited by 373 publications

References 84 publications

Functional role of Coenzyme Q in the energy coupling of NADH‐CoQ oxidoreductase (Complex I): Stabilization of the semiquinone state with the application of inside‐positive membrane potential to proteoliposomes

Functional role of Coenzyme Q in the energy coupling of NADH‐CoQ oxidoreductase (Complex I): Stabilization of the semiquinone state with the application of inside‐positive membrane potential to proteoliposomes

Wide-dynamic-range kinetic investigations of deep proton tunnelling in proteins

Induced conformational changes upon Cd ²⁺ binding at photosynthetic reaction centers

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Proton and electron transfer in bacterial reaction centers

Cited by 373 publications

References 84 publications

Functional role of Coenzyme Q in the energy coupling of NADH‐CoQ oxidoreductase (Complex I): Stabilization of the semiquinone state with the application of inside‐positive membrane potential to proteoliposomes

Functional role of Coenzyme Q in the energy coupling of NADH‐CoQ oxidoreductase (Complex I): Stabilization of the semiquinone state with the application of inside‐positive membrane potential to proteoliposomes

Wide-dynamic-range kinetic investigations of deep proton tunnelling in proteins

Induced conformational changes upon Cd 2+ binding at photosynthetic reaction centers

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Induced conformational changes upon Cd ²⁺ binding at photosynthetic reaction centers