Miho Yoshioka scite author profile

Photosystem II is vulnerable to various abiotic stresses such as strong visible light and heat. Under both stresses, the damage seems to be triggered by reactive oxygen species, and the most critical damage occurs in the reaction center-binding D1 protein. Recent progress has been made in identifying the protease involved in the degradation of the photo- or heat-damaged D1 protein, the ATP-dependent metalloprotease FtsH. Another important result has been the discovery that the damaged D1 protein aggregates with nearby polypeptides such as the D2 protein and the antenna chlorophyll-binding protein CP43. The degradation and aggregation of the D1 protein occur simultaneously, but the relationship between the two is not known. We suggest that phosphorylation and dephosphorylation of the D1 protein, as well as the binding of the extrinsic PsbO protein to Photosystem II, play regulatory roles in directing the damaged D1 protein to the two alternative pathways.

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Quality control of Photosystem II: Cleavage and aggregation of heat-damaged D1 protein in spinach thylakoids

Komayama

Khatoon

Takenaka

et al. 2007

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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Moderate heat stress (40 degrees C, 30 min) on spinach thylakoids induced cleavage of the D1 protein, producing an N-terminal 23-kDa fragment, a C-terminal 9-kDa fragment, and aggregation of the D1 protein. A homologue of Arabidopsis FtsH2 protease, which is responsible for degradation of the damaged D1 protein, was abundant in the stroma thylakoids. Two processes occurred in the thylakoids in response to heat stress: dephosphorylation of the D1 protein in the stroma thylakoids, and aggregation of the phosphorylated D1 protein in the grana. Heat stress also induced the release of the extrinsic PsbO, P and Q proteins from Photosystem II, which affected D1 degradation and aggregation significantly. The cleavage and aggregation of the D1 protein appear to be two alternative processes influenced by protein phosphorylation/dephosphorylation, distribution of FtsH, and intactness of the thylakoids.

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Quality Control of Photosystem II

Yoshioka

Uchida

Mori

et al. 2006

Journal of Biological Chemistry

119

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When spinach thylakoids were subjected to moderate heat stress (40°C for 30 min), oxygen evolution was inhibited, and cleavage of the reaction center-binding protein D1 of photosystem II took place, producing 23-kDa N-terminal fragments. The D1 cleavage was greatly facilitated by the addition of 0.15 mM ZnCl 2 and 1 mM ATP and was completely inhibited by 1 mM EDTA, indicating the participation of an ATP-dependent metalloprotease(s) in the D1 cleavage. Herbicides 3-(3,4-dichlorophenyl)-1,1-dimethyl urea, bromoxynil, and ioxynil, all of which bind to the Q B site, inhibited the D1 cleavage, suggesting that the DE-loop of the D1 protein is the heat-sensitive cleavage site. We solubilized the protease by treating the thylakoids with 2 M KSCN and detected a protease activity in the supernatant by gelatin activity gel electrophoresis in the 70 -80-kDa region. The antibodies against tobacco FtsH and Arabidopsis FtsH2 reacted with a 70 -80-kDa band of the KSCN-solubilized fraction, which suggests the presence of FtsH in the fraction. In accordance with this finding, we identified the homolog to Arabidopsis FtsH8 in the 70 -80-kDa region by matrix-assisted laser desorption ionization time-of-flight mass analysis of the thylakoids. The KSCN-solubilized fraction was successively reconstituted with thylakoids to show heat-induced cleavage of the D1 protein and production of the D1 fragment. These results strongly suggest that an FtsH protease(s) is involved in the primary cleavage of the D1 protein under moderate heat stress. Photosystem II (PS II)2 is prone to various environmental stresses, the most prominent being strong visible light. Under light stress conditions, the reaction center-binding D1 protein of PS II is damaged and is promptly replaced by a newly synthesized D1 protein (1-4). This process is referred to as photoinhibition and repair of PS II, and a lot of effort has been made to elucidate the details of the process. Two basic mechanisms have been shown to operate in the photoinhibitory steps (3, 4). In the acceptor side mechanism of photoinhibition, over-reduction of the acceptor side of PS II by excessive light induces charge recombination between the oxidized primary electron donor P680 ϩ and the reduced primary electron acceptor Pheo Ϫ , leading to the formation of triplet state P680. The triplet state P680 subsequently reacts with molecular oxygen to form a highly reactive singlet oxygen, which is very destructive to the D1 protein. The site of damage in the D1 protein is the stroma-exposed DE-loop of the D1 protein. In the donor side mechanism of photoinhibition, the D1 protein is damaged by endogenous cationic radicals such as P680 ϩ and chlorophyll ϩ generated by illumination of PS II that has an impaired oxygen-evolving system. In this case, electron donation from water to the reaction center is inefficient, and photodamage to the D1 protein takes place at the lumen-exposed AB-loop.The photodamaged D1 protein is degraded by proteolytic enzymes and removed from PS II (5). In the acceptor side photoinh...

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Quality control of Photosystem II: Where and how does the degradation of the D1 protein by FtsH proteases start under light stress? – Facts and hypotheses

Yoshioka

Yamamoto

2011

Journal of Photochemistry and Photobiology B: Biology

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Quality Control of Photosystem II

Khatoon

Inagawa

Pospı́šil

et al. 2009

Journal of Biological Chemistry

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Photosystem II is vulnerable to light damage. The reaction center-binding D1 protein is impaired during excessive illumination and is degraded and removed from photosystem II. Using isolated spinach thylakoids, we investigated the relationship between light-induced unstacking of thylakoids and damage to the D1 protein. Under light stress, thylakoids were expected to become unstacked so that the photodamaged photosystem II complexes in the grana and the proteases could move on the thylakoids for repair. Excessive light induced irreversible unstacking of thylakoids. By comparing the effects of light stress on stacked and unstacked thylakoids, photoinhibition of photosystem II was found to be more prominent in stacked thylakoids than in unstacked thylakoids. In accordance with this finding, EPR spin trapping measurements demonstrated higher production of hydroxyl radicals in stacked thylakoids than in unstacked thylakoids. We propose that unstacking of thylakoids has a crucial role in avoiding further damage to the D1 protein and facilitating degradation of the photodamaged D1 protein under light stress.In the chloroplasts of higher plants and green algae, thylakoid membranes are closely associated and stack to form grana. Under electron microscopy, cylindrical grana consisting of 10 -20 layers of thylakoids have been observed. They have a diameter of 300 -600 nm and are interconnected by lamellae of several hundred nm in length (1, 2). The structure of grana in the chloroplasts of higher plants is well known, but the precise role of grana is incompletely understood. Their possible functions in primary photochemical reactions and subsequent events have been discussed extensively (3-9). Photosystem I (PSI) 3 and II (PSII) complexes are segregated from each other in thylakoids, showing lateral heterogeneity in their distribution. The PSII complex is a multisubunit pigment-protein complex responsible for the photochemical oxidation of water and reduction of plastoquinone (8, 10 -13). It comprises Ͼ25 protein subunits and other low molecular weight cofactors, including chlorophylls, carotenoids, plastoquinones, and manganeses. In the chloroplasts of higher plants, PSII complexes and the associated light-harvesting antenna complex LHCII are not present throughout the thylakoid membranes but are abundant in the grana (2, 14). A densely packed array of PSII complexes in the grana was visualized by electron microscopy (8, 15). Grana formation is more prominent in shade leaves (or shade plants) than in sun leaves (or sun plants), so it has been suggested that enrichment of the PSII⅐LHCII complex in grana is a strategy of plants to collect excitation energy by PSII under weak light (16). The grana structure probably provides an organized environment for PSII. PSI and ATP synthase are located exclusively in the stroma-exposed thylakoids, including the stroma thylakoids, grana end membranes, and grana margins, because these complexes protrude into the stroma. Cytochrome b 6 /f complexes without this protrusion are present unif...

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Miho Yoshioka

Quality control of photosystem II: impact of light and heat stresses

Quality control of Photosystem II: Cleavage and aggregation of heat-damaged D1 protein in spinach thylakoids

Quality Control of Photosystem II

Quality control of Photosystem II: Where and how does the degradation of the D1 protein by FtsH proteases start under light stress? – Facts and hypotheses

Quality Control of Photosystem II

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