2004
DOI: 10.1074/jbc.m402461200
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Regulation of Photosynthetic Light Harvesting Involves Intrathylakoid Lumen pH Sensing by the PsbS Protein

Abstract: The biochemical, biophysical, and physiological properties of the PsbS protein were studied in relation to mutations of two symmetry-related, lumen-exposed glutamate residues, Glu-122 and Glu-226. These two glutamates are targets for protonation during lumen acidification in excess light. Mutation of PsbS did not affect xanthophyll cycle pigment conversion or pool size. In conditions of excess light, photosynthetic light harvesting is regulated by a feedback de-excitation mechanism termed energy-dependent quen… Show more

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Cited by 511 publications
(440 citation statements)
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“…The control of the rate of the transition into and out of this state by the DES is consistent with the proposed role of the xanthophyll cycle carotenoids as allosteric regulators of qE [9,10]. The data could also be accommodated within a model in which the only role of zeaxanthin is as the direct quencher [8], either bound to PsbS [21], LHCII [22] or to a minor antenna complex [23,24]. However, important new features would need to be invoked: there must be competition between violaxanthin and zeaxanthin for the quenching site; and the rate of binding and release from this site must be rate limiting for qE formation and relaxation respectively.…”
Section: Discussionsupporting
confidence: 75%
“…The control of the rate of the transition into and out of this state by the DES is consistent with the proposed role of the xanthophyll cycle carotenoids as allosteric regulators of qE [9,10]. The data could also be accommodated within a model in which the only role of zeaxanthin is as the direct quencher [8], either bound to PsbS [21], LHCII [22] or to a minor antenna complex [23,24]. However, important new features would need to be invoked: there must be competition between violaxanthin and zeaxanthin for the quenching site; and the rate of binding and release from this site must be rate limiting for qE formation and relaxation respectively.…”
Section: Discussionsupporting
confidence: 75%
“…25,26 Similar results have been reported in pgr5 mutants of rice 37 and Chlamydomonas, 40 but not in mutants devoid of NPQ, such as in the Arabidopsis npq4 plants lacking PsbS protein, 43,45,49 supporting a key and specific role for the PGR5 protein in the Photosynthesis Control mechanism. Clearly, by ensuring the pH-dependent control of PQH 2 oxidation at the level of Cyt b 6 f, PGR5 prevents electrons from flowing freely from PSII to PSI, which would over-reduce the electron carriers on the acceptor side of PSI.…”
Section: Pgr5-dependent Cet and Photosynthesis Controlsupporting
confidence: 72%
“…31,32,34 Thus, CET appears to be important for providing a sufficient proton motive force, which in turn attenuates PSII activity through the induction of the NPQ photoprotective mechanism. 9 That is obtained through the protonation of two glutamic acid residues in the lumenexposed loop of PsbS protein, [43][44][45] which is a component of PSII, and the activation of the Violaxanthin De-Epoxidase (VDE) that converts violaxanthin into zeaxanthin within the xanthophyll cycle. 13,14,46 Secondly, the pgr5 mutants of both Arabidopsis and rice have also been shown to exhibit an elevated proton conductance of the ATP-synthase, 37,47 as well as an increased amount of the ATP synthase b subunit.…”
Section: Pgr5-dependent Cet and Photosynthesis Controlmentioning
confidence: 99%
“…In contrast, the extensive nonphotochemical quenching measured in Arabidopsis was sensitive to addition of nigericin (not shown), indicating that this quenching reflects the occurrence of high-energy state quenching (1,8,9,37). The absence of high-energy state quenching in Chlamydomonas was confirmed by the lack of absorbance changes at 535 nm during illumination (data not shown), a linear indicator for the generation of this type of quenching in plants (38).…”
Section: Light-induced Photochemical and Nonphotochemicalmentioning
confidence: 89%