Proton pumping in the bc1 complex: A new gating mechanism that prevents short circuits

Crofts, Antony R.; Lhee, Sangmoon; Crofts, Stephanie; Cheng, Jerry; Rose, Stuart W.

doi:10.1016/j.bbabio.2006.02.009

Cited by 95 publications

(158 citation statements)

References 86 publications

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“…Induced curvature profiles are known to exert a segregating force between different types of proteins in the membrane (Frese et al, 2008). stoichiometry is 3:1 (Cartron et al, 2014), consistent with earlier observations (Crofts, 2004;Crofts et al, 2006), corresponding to approximately 4 cytbc 1 dimeric complexes per vesicle. Chromatophore vesicles typically contain 1-2 ATP synthases (Feniouk et al, 2002;Cartron et al, 2014).…”

Section: Supramolecular Organization Of a Chromatophore Vesicle Adaptsupporting

confidence: 87%

“…The primary components of chromatophore vesicles in purple bacteria, as depicted in Figure 1, are, in order of energy utililization (Cogdell et al, 2006,Cartron et al, 2014: (i) light harvesting complex 2 (LH2) (Koepke et al, 1996;Papiz et al, 2003); (ii) light harvesting complex 1 (LH1 Sener et al, 2009]); (iii) RC (Jamieson et al, 2002;Strümpfer and Schulten, 2012a); (iv) cytbc 1 (Crofts, 2004;Crofts et al, 2006); and (v) ATP synthase (Feniouk and Junge, 2009;Hakobyan et al, 2012). RC-LH1 complexes typically form dimeric RC-LH1-PufX complexes facilitated by the polypeptide PufX Sener et al, 2009), although monomeric complexes are also found in membranes from photosynthetically grown cells at a ratio of approximately 10% .…”

Section: Supramolecular Organization Of a Chromatophore Vesicle Adaptmentioning

confidence: 99%

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Overall energy conversion efficiency of a photosynthetic vesicle

Sener

Strümpfer

Singharoy

et al. 2016

eLife

174

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The chromatophore of purple bacteria is an intracellular spherical vesicle that exists in numerous copies in the cell and that efficiently converts sunlight into ATP synthesis, operating typically under low light conditions. Building on an atomic-level structural model of a low-lightadapted chromatophore vesicle from Rhodobacter sphaeroides, we investigate the cooperation between more than a hundred protein complexes in the vesicle. The steady-state ATP production rate as a function of incident light intensity is determined after identifying quinol turnover at the cytochrome bc 1 complex (cytbc 1 ) as rate limiting and assuming that the quinone/quinol pool of about 900 molecules acts in a quasi-stationary state. For an illumination condition equivalent to 1% of full sunlight, the vesicle exhibits an ATP production rate of 82 ATP molecules/s. The energy conversion efficiency of ATP synthesis at illuminations corresponding to 1%-5% of full sunlight is calculated to be 0.12-0.04, respectively. The vesicle stoichiometry, evolutionarily adapted to the low light intensities in the habitat of purple bacteria, is suboptimal for steady-state ATP turnover for the benefit of protection against over-illumination.

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Section: Supramolecular Organization Of a Chromatophore Vesicle Adaptsupporting

confidence: 87%

Section: Supramolecular Organization Of a Chromatophore Vesicle Adaptmentioning

confidence: 99%

Overall energy conversion efficiency of a photosynthetic vesicle

Sener

Strümpfer

Singharoy

et al. 2016

eLife

174

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“…In some models the SQ is thermodynamically stabilized (45), thus lowering its reactivity with O 2 ; in other models it is specifically destabilized (3,36), limiting its reactivity with O 2 by lowering its steady-state concentration. Some models posit that the SQ is shielded from O 2 within the Q o site (3), while access to the site or its reactivity is proposed to be allosterically (46,47) or electrostatically (14,27) gated. Still, other models deny the existence of an SQ intermediate altogether (21).…”

Section: Discussionmentioning

confidence: 99%

“…The key question in cyt bc complexes is how the Q o site minimizes bypass reactions while maintaining high flux through the Q-cycle (14,27,28). The question is profound because the bypass reactions are vastly more thermodynamically favored (21,29).…”

mentioning

confidence: 99%

A semiquinone intermediate generated at the Q _o site of the cytochrome bc ₁ complex: Importance for the Q-cycle and superoxide production

Cape

Bowman

Kramer

2007

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

155

185

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The cytochrome bc1 and related complexes are essential energyconserving components of mitochondrial and bacterial electron transport chains. They orchestrate a complex sequence of electron and proton transfer reactions resulting in the oxidation of quinol, the reduction of a mobile electron carrier, and the translocation of protons across the membrane to store energy in an electrochemical proton gradient. The enzyme can also catalyze substantial rates of superoxide production, with deleterious physiological consequences. Progress on understanding these processes has been hindered by the lack of observable enzymatic intermediates. We report the first direct detection of a semiquinone radical generated by the Q o site using continuous wave and pulsed EPR spectroscopy. The radical is a ubisemiquinone anion and is sensitive to both specific inhibitors and mutations within the Qo site as well as O2, suggesting that it is the elusive intermediate responsible for superoxide production. Paramagnetic interactions show that the new semiquinone species is buried in the protein, probably in or near the Qo site but not strongly interacting with the 2Fe2S cluster. The semiquinone is substoichiometric, even with conditions optimized for its accumulation, consistent with recently proposed models where the semiquinone is destabilized to limit superoxide production. The discovery of this intermediate provides a critical tool to directly probe the elusive chemistry that takes place within the Qo site.electron transfer ͉ free radical ͉ photosynthesis ͉ reactive oxygen species ͉ respiration T he cytochrome (cyt) bc 1 , b 6 f, and related complexes, collectively termed cyt bc complexes, are essential components of the respiratory and photosynthetic electron transport chains in mitochondria, many bacteria, and chloroplasts (1-3). These complexes oxidize quinol and reduce one-electron redox carriers while generating an electrochemical gradient of protons, termed the proton motive force (pmf ), which drives the synthesis of ATP and other bioenergetic processes. The natural substrate is ubiquinol (UQH 2 ) in the case of the mitochondrial and bacterial cyt bc 1 complexes, and the mobile carrier is cyt c in mitochondria or photosynthetic bacteria. The general mechanistic framework for the cyt bc complexes is the Q-cycle, first proposed by Mitchell (4-6) and modified by many others (e.g., refs. 7-14).In ''standard'' versions of the Q-cycle (2, 9, 15) a unique bifurcated oxidation of QH 2 occurs in the Q o site, located on the positively charged side (p-side) of the membrane. An initial single electron transfer to the ''Rieske'' 2Fe2S cluster produces a free radical semiquinone (SQ) intermediate (the anionic form or the neutral form, depending on the exact sequence of electron and proton transfers). The Rieske 2Fe2S cluster is the first in a series of carriers, termed the ''high potential chain,'' which in mitochondria and certain bacteria includes cyt c 1 followed by a soluble (or mobile) cyt c. Under normal conditions, the SQ intermediate ...

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“…The chemistry of oxygen reduction by cytochrome c oxidase is used to gate proton channels and alter proton affinities resulting in proton pumping, but conformational changes must be subtle compared to either Complex I or the ATP synthase [61]. Complex III has a unique ''Q-cycle'' to move charges across the membrane and a large conformational change of the Rieske Fe-S subunit to assure the two electrons from quinol are bifurcated, i.e., directed to different electron acceptors [62]. The enzymology of each of these systems is distinct from the others and each is a remarkable testament to the different ways that evolution has solved the problem of both generating and utilizing the proton motive force across a biological membrane.…”

Section: The Different Mechanisms Of Coupling To the Proton Electrochmentioning

confidence: 99%

Review and Hypothesis. New insights into the reaction mechanism of transhydrogenase: Swivelling the dIII component may gate the proton channel

et al. 2015

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Edited by Peter BrzezinskiKeywords: Transhydrogenase Membrane-protein structure Nicotinamide nucleotide Proton-pump Proton-gating a b s t r a c tThe membrane protein transhydrogenase in animal mitochondria and bacteria couples reduction of NADP + by NADH to proton translocation. Recent X-ray data on Thermus thermophilus transhydrogenase indicate a significant difference in the orientations of the two dIII components of the enzyme dimer (Leung et al., 2015). The character of the orientation change, and a review of information on the kinetics and thermodynamics of transhydrogenase, indicate that dIII swivelling might assist in the control of proton gating by the redox state of bound NADP + /NADPH during enzyme turnover.

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Proton pumping in the bc1 complex: A new gating mechanism that prevents short circuits

Cited by 95 publications

References 86 publications

Overall energy conversion efficiency of a photosynthetic vesicle

Overall energy conversion efficiency of a photosynthetic vesicle

A semiquinone intermediate generated at the Q _o site of the cytochrome bc ₁ complex: Importance for the Q-cycle and superoxide production

Review and Hypothesis. New insights into the reaction mechanism of transhydrogenase: Swivelling the dIII component may gate the proton channel

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Proton pumping in the bc1 complex: A new gating mechanism that prevents short circuits

Cited by 95 publications

References 86 publications

Overall energy conversion efficiency of a photosynthetic vesicle

Overall energy conversion efficiency of a photosynthetic vesicle

A semiquinone intermediate generated at the Q o site of the cytochrome bc 1 complex: Importance for the Q-cycle and superoxide production

Review and Hypothesis. New insights into the reaction mechanism of transhydrogenase: Swivelling the dIII component may gate the proton channel

Contact Info

Product

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A semiquinone intermediate generated at the Q _o site of the cytochrome bc ₁ complex: Importance for the Q-cycle and superoxide production