Photoinhibition and Zeaxanthin Formation in Intact Leaves

Demmig, Barbara; Winter, Klaus; Krüger, Almuth; Czygan, Franz‐Christian

doi:10.1104/pp.84.2.218

Cited by 701 publications

(202 citation statements)

References 15 publications

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“…As expected, enrichment in zeaxanthin caused in the dark adapted sample a decrease in the F v /F m ratio from 0.83 to B0.7 (ref. 30) as well as a high level of NPQ, which took longer than 5 min to fully relax (Fig. 3a).…”

Section: Resultsmentioning

confidence: 99%

Economic photoprotection in photosystem II that retains a complete light-harvesting system with slow energy traps

et al. 2014

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The light-harvesting antenna of higher plant photosystem II has an intrinsic capability for self-defence against intense sunlight. The thermal dissipation of excess energy can be measured as the non-photochemical quenching of chlorophyll fluorescence. It has recently been proposed that the transition between the light-harvesting and self-defensive modes is associated with a reorganization of light-harvesting complexes. Here we show that despite structural changes, the photosystem II cross-section does not decrease. Our study reveals that the efficiency of energy trapping by the non-photochemical quencher(s) is lower than the efficiency of energy capture by the reaction centres. Consequently, the photoprotective mechanism works effectively for closed rather than open centres. This type of defence preserves the exceptional efficiency of electron transport in a broad range of light intensities, simultaneously ensuring high photosynthetic productivity and, under hazardous light conditions, sufficient photoprotection for both the reaction centre and the light-harvesting pigments of the antenna.

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Section: Resultsmentioning

confidence: 99%

Economic photoprotection in photosystem II that retains a complete light-harvesting system with slow energy traps

et al. 2014

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“…These are all associated with photosystem (PS) 1 II and are collectively referred to as nonphotochemical quenching mechanisms (NPQ; 1). However, this term comprises at least three processes: (i) qI, mainly related to photoinhibition, a slowly reversible damage to PSII reaction centers (2,3), although data suggest that a zeaxanthindependent quenching might contribute substantially to this process (4,5), (ii) qT, state transitions, a change in the relative antenna sizes of PSII and PSI, due to the reversible phosphorylation and migration of antenna proteins (LHCII) (6), and (iii) qE, also termed "high-energy state quenching", a form of quenching associated with the development of a low pH in the thylakoid lumen (e.g., ref 7). High-energy state quenching is largely thought to be associated with an increase in thermal dissipation within the light-harvesting apparatus (1,8,9), associated with the generation of a ∆pH (7,10) and with the formation of zeaxanthin via deepoxidation of violaxanthin (11).…”

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confidence: 99%

Nonphotochemical Quenching of Chlorophyll Fluorescence inChlamydomonas reinhardtii

et al. 2006

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Unlike plants, Chlamydomonas reinhardtii shows a restricted ability to develop nonphotochemical quenching upon illumination. Most of this limited quenching is due to state transitions instead of ∆pH-driven high-energy state quenching, qE. The latter could only be observed when the ability of the cells to perform photosynthesis was impaired, either by lowering temperature to ∼0°C or in mutants lacking RubisCO activity. Two main features were identified that account for the low level of qE in Chlamydomonas. On one hand, the electrochemical proton gradient generated upon illumination is apparently not sufficient to promote fluorescence quenching. On the other hand, the capacity to transduce the presence of a ∆pH into a quenching response is also intrinsically decreased in this alga, when compared to plants. The possible mechanism leading to these differences is discussed.The absorption of light in excess of the capacity for photosynthetic electron transport is damaging to photosynthetic organisms (1). That capacity is, however, variable, depending mainly on the efficiency of CO 2 assimilation. For example, decreases in temperature lower the rate with which electrons can be transported within the electron transport chain as well as the capacity of metabolic processes to assimilate the reductant that has been photoproduced. In higher plants, the availability of CO 2 is liable to be limiting under conditions of water stress, due to the closure of stomata. This will again inhibit photosynthetic assimilation. Under such conditions, cells are likely to experience oxidative stress, due to the uncontrolled formation of reactive oxygen species associated with the absorption of light by chlorophyll.Under conditions of excess light, a variety of mechanisms are initiated which protect chloroplasts from damage. In higher plants, a number of processes have been identified, primarily through application of measurements of chlorophyll fluorescence yield. These are all associated with photosystem (PS) 1 II and are collectively referred to as nonphotochemical quenching mechanisms (NPQ; 1). However, this term comprises at least three processes: (i) qI, mainly related to photoinhibition, a slowly reversible damage to PSII reaction centers (2, 3), although data suggest that a zeaxanthindependent quenching might contribute substantially to this process (4, 5), (ii) qT, state transitions, a change in the relative antenna sizes of PSII and PSI, due to the reversible phosphorylation and migration of antenna proteins (LHCII) (6), and (iii) qE, also termed "high-energy state quenching", a form of quenching associated with the development of a low pH in the thylakoid lumen (e.g., ref 7).High-energy state quenching is largely thought to be associated with an increase in thermal dissipation within the light-harvesting apparatus (1,8,9), associated with the generation of a ∆pH (7, 10) and with the formation of zeaxanthin via deepoxidation of violaxanthin (11). However, in vitro at least, this term also encompasses acidic pHinduced proc...

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“…However, ecophysiological research was about to shift this focus to photoprotection involving reversible regulation of light-harvesting efficiency in the antenna and its stabilization by xanthophyll pigment inter-conversions [10]. Interestingly, Jan had also participated in one of the earliest studies of light-dependent changes in the pool of violaxanthin (V) [11].…”

Section: Introductionmentioning

confidence: 99%

From ecophysiology to phenomics: some implications of photoprotection and shade–sun acclimation in situ for dynamics of thylakoids in vitro

Matsubara

Förster

Waterman

et al. 2012

Phil. Trans. R. Soc. B

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Half a century of research into the physiology and biochemistry of sun-shade acclimation in diverse plants has provided reality checks for contemporary understanding of thylakoid membrane dynamics. This paper reviews recent insights into photosynthetic efficiency and photoprotection from studies of two xanthophyll cycles in old shade leaves from the inner canopy of the tropical trees Inga sapindoides and Persea americana (avocado). It then presents new physiological data from avocado on the time frames of the slow coordinated photosynthetic development of sink leaves in sunlight and on the slow renovation of photosynthetic properties in old leaves during sun to shade and shade to sun acclimation. In so doing, it grapples with issues in vivo that seem relevant to our increasingly sophisticated understanding of DpH-dependent, xanthophyll-pigment-stabilized non-photochemical quenching in the antenna of PSII in thylakoid membranes in vitro.

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Photoinhibition and Zeaxanthin Formation in Intact Leaves

Cited by 701 publications

References 15 publications

Economic photoprotection in photosystem II that retains a complete light-harvesting system with slow energy traps

Economic photoprotection in photosystem II that retains a complete light-harvesting system with slow energy traps

Nonphotochemical Quenching of Chlorophyll Fluorescence inChlamydomonas reinhardtii

From ecophysiology to phenomics: some implications of photoprotection and shade–sun acclimation in situ for dynamics of thylakoids in vitro

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