2013
DOI: 10.1073/pnas.1222248110
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Quinone-dependent proton transfer pathways in the photosynthetic cytochrome b 6 f complex

Abstract: As much as two-thirds of the proton gradient used for transmembrane free energy storage in oxygenic photosynthesis is generated by the cytochrome b 6 f complex. The proton uptake pathway from the electrochemically negative (n) aqueous phase to the n-side quinone binding site of the complex, and a probable route for proton exit to the positive phase resulting from quinol oxidation, are defined in a 2.70-Å crystal structure and in structures with quinone analog inh… Show more

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Cited by 90 publications
(87 citation statements)
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“…The regulation of clock components by metabolites of photosynthesis that change with the light-dark cycle – KaiA and CikA by oxidized quinone [15, 16] and KaiC by the ratio of ATP:ADP [17] – provides a rationale for enrichment of clock protein complexes at a specific membrane location at night. The interaction of KaiA and CikA with quinones, in particular, would require close proximity to the thylakoid, where a quinone-binding site of the photosynthetic cytochrome b6f complex is located close to the membrane-water interface, where protons are transferred to the aqueous phase [45]. Within the thylakoid membrane system two key respiratory electron donors move from an even distribution in high light to discrete patches with an overrepresentation at the poles in low light conditions [30].…”
Section: Discussionmentioning
confidence: 99%
“…The regulation of clock components by metabolites of photosynthesis that change with the light-dark cycle – KaiA and CikA by oxidized quinone [15, 16] and KaiC by the ratio of ATP:ADP [17] – provides a rationale for enrichment of clock protein complexes at a specific membrane location at night. The interaction of KaiA and CikA with quinones, in particular, would require close proximity to the thylakoid, where a quinone-binding site of the photosynthetic cytochrome b6f complex is located close to the membrane-water interface, where protons are transferred to the aqueous phase [45]. Within the thylakoid membrane system two key respiratory electron donors move from an even distribution in high light to discrete patches with an overrepresentation at the poles in low light conditions [30].…”
Section: Discussionmentioning
confidence: 99%
“…These results supported the conclusion (40,42) that the redox state of the Rieske iron-sulfur center governs transcription of mitochondrial and chloroplast DNA, with an oxidized center resulting in RNA synthesis and a reduced center inhibiting it. The Rieske ironsulfur center is a component of cytochrome b-c 1 and b 6 -f complexes, the sites of oxidation of the ubiquinone and plastoquinone pools in the proton-motive Q-cycle (43)(44)(45). Acting as a transcriptional redox sensor, the Rieske protein will respond to imbalance in electron flow into, and out of, the Q-cycle.…”
Section: Experimental Evidence Bearing Directly On Corr Evidence 1: Smentioning
confidence: 99%
“…(Source of the figure: Stirbet and Govindjee (2012), as modified by A. Stirbet and Govindjee (unpublished); it also includes information from Govindjee (2011), Cramer andZhang (2006), Baniulis et al (2008), and Hasan et al (2013). periodic and aperiodic, fluctuations.…”
Section: Ps I Ps I Ps I and Ps Ii Ps Ii Ps Iimentioning
confidence: 99%
“…At 77 K, state 1 (also referred to as state I) and state 2 (also referred to as state II) can be recognized by the characteristic emission spectra: in state 1, one observes higher PS II (F686 and F696) emission bands, and a lower PS I (F730) emission band. For further background on these emission bands, see chapters in Govindjee et al (1986) and Papageorgiou and Govindjee (2004); for LHCII subunits, see Kargul and Barber (2008), Iwai et al (2008Iwai et al ( , 2010a, and Minagawa (2011); for the Cyt b 6 f complex, see Cramer and Zhang (2006), Baniulis et al (2008), Kallas (2012), and Hasan et al (2013); for the PBS, see Allen and Mullineaux (2004).…”
Section: B State Transitionsmentioning
confidence: 99%