Cationic state distribution over the chlorophyll d-containing PD1/PD2 pair in photosystem II

Most of the chlorophyll (Chl) cofactors in photosystem II (PSII) from Acaryochloris marina are Chld, although a few Chla molecules are also present. To evaluate the possibility that Chla may participate in the P_D1/P_D2 Chl pair in PSII from A. marina, the P_D1^?+/P_D2^?+ charge ratio was investigated using the PSII crystal structure analyzed at 1.9-Å resolution, while considering all possibilities for the Chld-containing P_D1/P_D2 pair, i.e., Chld/Chld, Chla/Chld, and Chld/Chla pairs. Chld/Chld and Chla/Chld pairs resulted in a large P_D1^?+ population relative to P_D2^?+, as identified in Chla/Chla homodimer pairs in PSII from other species, e.g., Thermosynechococcus elongatus PSII. However, the Chld/Chla pair possessed a P_D1^?+/P_D2^?+ ratio of approximately 50/50, which is in contrast to previous spectroscopic studies on A. marina PSII. The present results strongly exclude the possibility that the Chld/Chla pair serves as P_D1/P_D2 in A. marina PSII. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.     

Isolation and characterization of oxygen-evolving thylakoid membranes and Photosystem II particles from a marine diatom Chaetoceros gracilis

Thylakoid membranes retaining high oxygen-evolving activity (about 250 μmol O₂/mg Chl/h) were prepared from a marine centric diatom, Chaetoceros gracilis, after disruption of the cells by freeze-thawing. We also succeeded in purification of Photosystem II (PSII) particles by differential centrifugation of the thylakoid membranes after treatment with 1% Triton X-100. The diatom PSII particles showed an oxygen-evolving activity of 850 and 1045 μmol O₂/mg Chl/h in the absence and presence of CaCl₂, respectively. The PSII particles contained fucoxanthin chlorophyll a/c-binding proteins in addition to main intrinsic proteins of CP47, CP43, D2, D1, cytochrome b559, and the antenna size was estimated to be 229 Chl a per 2 molecules of pheophytin. Five extrinsic proteins were stoichiometrically released from the diatom PSII particles by alkaline Tris-treatment. Among these five extrinsic proteins, four proteins were red algal-type extrinsic proteins, namely, PsbO, PsbQ', PsbV and PsbU, whereas the other one was a novel, hypothetical protein. This is the first report on isolation and characterization of diatom PSII particles that are highly active in oxygen evolution and retain the full set of extrinsic proteins including an unknown protein.     

Dynamic metabolism of photosystem II reaction center proteins and pigments

Photosystem II (PSII) reaction center is an intrinsic membrane-protein complex in the chloroplast that catalyzes primary charge separation between P680, a chlorophyll a dimer, and the primary quinone acceptor Q_A. This supramolecular protein complex consists of D1, D2, α and β subunits of cytochrome b₅₅₉, the psbI gene product, and a few low molecular mass proteins. Ligated to this complex are pigments: chlorophyll a, pheophytin a, β-carotenes, and non-heme iron. One of the major outcomes of light-mediated photochemistry is the fact that in the light, D1 protein is rapidly turned over compared to the other proteins of the reaction center; the relative lability of proteins being: D1?D2>Cyt b₅₅₉. D1 degradation in visible light exhibits complex, multiphasic kinetics. D1 degradation can be uncoupled from photosynthetic electron transport, which suggests that degradation may perform some separate function(s) beyond maintaining photosynthetic activity. The presence of a physiologically relevant level of ultraviolet-B (UV-B) radiation in a background of photosynthetically active radiation stimulates D1/D2 heterodimer degradation in a synergistic manner. D1 undergoes several post-translational modifications including N-acetylation, phosphorylation, and palmitoylation. Light-dependent phosphorylation of D1 occurs in all flowering plants but not in the green alga Chlamydomonas or in cyanobacteria, and the same may be true for D2. The roles of these modifications in D1/D2 assembly, turnover, or function are still a matter of conjecture. Nor do we yet know about the fate of the liganded pigments, such as the chlorophyll and carotenoids bound to the reaction center proteins. Environmental extremes that negatively impact photosynthesis seem to involve D1 metabolism. Thus, D1 protein is a major factor of PSII instability, and its replacement after its degradation is a primary component of the PSII repair cycle.     

Subunit composition of CP43-less photosystem II complexes of Synechocystis sp. PCC 6803: implications for the assembly and repair of photosystem II

Photosystem II (PSII) mutants are useful experimental tools to trap potential intermediates involved in the assembly of the oxygen-evolving PSII complex. Here, we focus on the subunit composition of the RC47 assembly complex that accumulates in a psbC null mutant of the cyanobacterium Synechocystis sp. PCC 6803 unable to make the CP43 apopolypeptide. By using native gel electrophoresis, we showed that RC47 is heterogeneous and mainly found as a monomer of 220 kDa. RC47 complexes co-purify with small Cab-like proteins (ScpC and/or ScpD) and with Psb28 and its homologue Psb28-2. Analysis of isolated His-tagged RC47 indicated the presence of D1, D2, the CP47 apopolypeptide, plus nine of the 13 low-molecular-mass (LMM) subunits found in the PSII holoenzyme, including PsbL, PsbM and PsbT, which lie at the interface between the two momomers in the dimeric holoenzyme. Not detected were the LMM subunits (PsbK, PsbZ, Psb30 and PsbJ) located in the vicinity of CP43 in the holoenzyme. The photochemical activity of isolated RC47-His complexes, including the rate of reduction of P680⁺, was similar to that of PSII complexes lacking the Mn₄CaO₅ cluster. The implications of our results for the assembly and repair of PSII in vivo are discussed.     

Phosphorylation and disassembly of the photosystem II core as an early stage of photoinhibition

The presence of heterogeneity in phosphorylated PSII core populations in grana membranes of spinach (Spinacia oleracea L.) was previously demonstrated (Giardi et al., 1991, Biochem. Biophys. Res. Commun. 176, 1298–1304). The effect of photoinhibitory conditions on the distribution of these phosphorylated PSII core populations in thylakoids and PSII particles has been investigated. The sensitivity of the PSII core to strong illumination depended on the phosphorylation state of D₁ and D₂ proteins as well as on the content of the 9-kDa PsbH phosphoprotein. When D₁ and D₂ proteins are under-phosphorylated, the 9-kDa phosphoprotein is tightly bound to the PSII core; thus, a partial protection from photoinhibition is observed. Of the different PSII core populations isolated from membranes photoinhibited for 10 min, the highly phosphorylated populations lack internal antennae CP43 and CP47; perhaps these migrate out to the non-appressed regions of thylakoids. The degradation of the D₁ protein seems to follow the disassembly of the PSII core.     

D1-S169A substitution of photosystem II reveals a novel S2-state structure

In photosystem II (PSII), photosynthetic water oxidation occurs at the O₂-evolving complex (OEC), a tetramanganese-calcium cluster that cycles through light-induced redox intermediates (S₀–S₄) to produce oxygen from two substrate water molecules. The OEC is surrounded by a hydrogen-bonded network of amino-acid residues that plays a crucial role in proton transfer and substrate water delivery. Previously, we found that D1-S169 was crucial for water oxidation and its mutation to alanine perturbed the hydrogen-bonding network. In this study, we demonstrate that the activation energy for the S₂ to S₁ transition of D1-S169A PSII is higher than wild-type PSII with a ~1.7–2.7× slower rate of charge recombination with Q_A⁻ relative to wild-type PSII. Arrhenius analysis of the decay kinetics shows an E_a of 5.87 ± 1.15 kcal mol⁻¹ for decay back to the S₁ state, compared to 0.80 ± 0.13 kcal mol⁻¹ for the wild-type S₂ state. In addition, we find that ammonia does not affect the S₂-state EPR signal, indicating that ammonia does not bind to the Mn cluster in D1-S169A PSII. Finally, a QM/MM analysis indicates that an additional water molecule binds to the Mn4 ion in place of an oxo ligand O5 in the S₂ state of D1-S169A PSII. The altered S₂ state of D1-S169A PSII provides insight into the S₂➔S₃ state transition.     

Seasonal changes in photosystem II organisation and pigment composition in Pinus sylvestris

Conifers of the boreal zone encounter considerable combined stress of low temperature and high light during winter, when photosynthetic consumption of excitation energy is blocked. In the evergreen Pinus sylvestris L. these stresses coincided with major seasonal changes in photosystem II (PSII) organisation and pigment composition. The earliest changes occurred in September, before any freezing stress, with initial losses of chlorophyll, the D1-protein of the PSII reaction centre and of PSII light-harvesting-complex (LHC II) proteins. In October there was a transient increase in F₀, resulting from detachment of the light-harvesting antennae as reaction centres lost D1. The D1-protein content eventually decreased to 90%, reaching a minimum by December, but PSII photochemical efficiency [variable fluorescence (F_v)/maximum fluorescence (F_m)] did not reach the winter minimum until mid-February. The carotenoid composition varied seasonally with a twofold increase in lutein and the carotenoids of the xanthophyll cycle during winter, while the epoxidation state of the xanthophylls decreased from 0.9 to 0.1 from October to January. The loss of chlorophyll was complete by October and during winter much of the remaining chlorophyll was reorganised in aggregates of specific polypeptide composition, which apparently efficiently quench excitation energy through non-radiative dissipation. The timing of the autumn and winter changes indicated that xanthophyll de-epoxidation correlates with winter quenching of chlorophyll fluorescence while the drop in photochemical efficiency relates more to loss of D1-protein. In April and May recovery of the photochemistry of PSII, protein synthesis, pigment rearrangements and zeaxanthin epoxidation occurred concomitantly. Indoor recovery of photosynthesis in winter-stressed branches under favourable conditions was completed within 3 d, with rapid increases in F₀, the epoxidation state of the xanthophylls and in light-harvesting polypeptides, followed by recovery of D1-protein content and F_v/F_m, all without net increase in chlorophyll. The fall and winter reorganisation allow Pinus sylvestris to maintain a large stock of chlorophyll in a quenched, photoprotected state, allowing rapid recovery of photosynthesis in spring.Abbreviations Elips early light-induced proteins - EPS epoxidation state - F₀ instantaneous fluorescence - F_m maximum fluorescence - F_v variable fluorescence - LHC II light-harvesting complex of PSII - LiDS lithium dodecyl sulfate This research was supported by the Swedish Natural Science Research Council. We wish to thank Dr. Adrian Clarke¹ (Department of Plant Physiology, University of Umeå, Sweden) for advice on electrophoresis, valuable discussion and providing antibodies. Dr. Stefan Jansson¹ and Dr. Torill Hundal (Department for Biochemistry, University of Stockholm, Sweden) provided antibodies. Jan Karlsson¹ helped with the HPLC, Dr. Marianna Krol gave advice on green gels and Dr. Vaughan Hurry (Cooperative Research Centre for Plant Sciences, Australian National University, Canberra, Australia) provided valuable discussion.     

Quantification of bound bicarbonate in photosystem II

In this study, we presented a new approach for quantification of bicarbonate (HCO₃^?) molecules bound to PSII. Our method, which is based on a combination of membrane-inlet mass spectrometry (MIMS) and ¹⁸O-labelling, excludes the possibility of “non-accounted” HCO₃^? by avoiding (1) the employment of formate for removal of HCO₃^? from PSII, and (2) the extremely low concentrations of HCO₃^?/CO₂ during online MIMS measurements. By equilibration of PSII sample to ambient CO₂ concentration of dissolved CO₂/HCO₃^?, the method ensures that all physiological binding sites are saturated before analysis. With this approach, we determined that in spinach PSII membrane fragments 1.1 ± 0.1 HCO₃^? are bound per PSII reaction center, while none was bound to isolated PsbO protein. Our present results confirmed that PSII binds one HCO₃^? molecule as ligand to the non-heme iron of PSII, while unbound HCO₃^? optimizes the water-splitting reactions by acting as a mobile proton shuttle.     

Photoinhibition and light-dependent turnover of the D1 reaction-centre polypeptide of photosystem II are enhanced by mineral-stress conditions

The function of photosystem II (PSII) and the turnover of its D1 reaction-center protein were studied in spinach (Spinacia oleracea L.) plants set under mineral stress. The mineral deficiencies were induced either by supplying the plants with an acidic nutrient solution or by strongly reducing the supply of magnesium alone or together with sulfur. After exposure for 8–10 weeks to the different media, the plants were characterized by a loss of chlorophyll and an increase in starch content, indicating a disturbance in the allocation of assimilates. Depending on the severity of the mineral deficiencies the plants lost their ability to adapt even to moderate iradiances of 400 mol photons·m^–2·s^–1 and became photoinhibited, as indicated by the decrease in F_v/F_m (the ratio of yield of variable fluorescence to yield of maximal fluorescence when all reaction centers are closed). The loss of PSII function was induced by changes on the acceptor side of PSII. Fast fluorescence decay showed a loss of PSII centers with bound Q_B, the secondary quinone acceptor of PSII, and a fast reoxidation kinetic of q _a ^- , the primary quinone acceptor of PSII, in the photoinactivated plants. No appreciable change could be observed in the amount of PSII centers with unbound Q_B and in Q_B-nonreducing PSII centers. Immunological studies showed that the contents of the D1 and D2 proteins of the PSII reaction center and of the 33-kDa protein of the water-splitting complex were diminished in the photoinhibited plants, and the occurrance of a new polypetide of 14 kDa that reacted with an antibody against the C-termius of the D1 protein. As shown by pulse-labelling experiments with [¹⁴C]leucine both degradation and synthesis of the D1 protein were enhanced in the mineral-deficient plants when compared to non-deficient plants. A stimulation of D1-protein turnover was also observed in pH 3-grown plants, which were not inhibited at growth-light conditions. Obviously, stimulation of D1-protein turnover prevented photoinhibition in these plants. However, in the Mg- and Mg/S-deficient plants even a further stimulation of D1-protein turnover could not counteract the increased rate of photoinactivation.Abbreviations amp_(f,m,s) amplitude of the fast, (medium and slow) exponential component of fluorescence decay - F_m yield of maximum fluorescenc when all reaction centers are closed - F_o yield of intrinsic fluorescence at open PSII reaction centers in the dark - F_v yield of variable fluorescence, (difference between F_m and F_o) - LHC light-harvesting complex - PFD photon flux density - Q_A primary quinone acceptor of PSII - Q_B secondary quinone acceptor of PSII Dedicated to Professor Dr. Dres. hc. Achim Trebst on the occasion of his 65th birthdayThis work was supported by grants from the BMFT and the Ministerium für Umwelt, Raumordnung and Landwirtschaft, Nordrhein-Westfalen. The authors thank H. Wietoska and M. Bronzel for skilful technical assistance.     

Peroxynitrite inhibits electron transport on the acceptor side of higher plant photosystem II

Peroxynitrite is a strong oxidant that has been proposed to form in chloroplasts. The interaction between peroxynitrite and photosystem II (PSII) has been investigated to determine whether this oxidant could be a hazard for PSII. Peroxynitrite is shown to inhibit oxygen evolution in PSII membranes in a dose-dependent manner. Analyses by PAM fluorimetry and EPR spectroscopy have demonstrated that the inhibition target of peroxynitrite is on the PSII acceptor side. In the presence of the herbicide DCMU, the chlorophyll (Chl) a fluorescence induction curve is inhibited by peroxynitrite, but the slow phase of the Chl a fluorescence decay does not change. EPR studies demonstrate that the Signal II_slow and Signal II_fast of peroxynitrite-treated Tris-washed PSII membranes are induced at room temperature, implying that the redox active tyrosines Y_Z and Y_D of PSII are not significantly nitrated. A featureless EPR signal with a g value of approximately 2.0043 ± 0.0003 and a line width of 10 ± 1 G is induced under continuous illumination in the presence of peroxynitrite. This new EPR signal corresponds with the semireduced plastoquinone Q_A in the absence of magnetic interaction with the non-heme Fe²⁺. We conclude that peroxynitrite impairs PSII electron transport in the Q_AFe²⁺ niche.     

Impact of PsbTc on forward and back electron flow, assembly, and phosphorylation patterns of photosystem II in tobacco

Photosystem II (PSII) of oxygen-evolving cyanobacteria, algae, and land plants mediates electron transfer from the Mn₄Ca cluster to the plastoquinone pool. It is a dimeric supramolecular complex comprising more than 30 subunits per monomer, of which 16 are bitopic or peripheral, low-molecular-weight components. Directed inactivation of the plastid gene encoding the low-molecular-weight peptide PsbTc in tobacco (Nicotiana tabacum) does not prevent photoautotrophic growth. Mutant plants appear normal green, and levels of PSII proteins are not affected. Yet, PSII-dependent electron transport, stability of PSII dimers, and assembly of PSII light-harvesting complexes (LHCII) are significantly impaired. PSII light sensitivity is moderately increased and recovery from photoinhibition is delayed, leading to faster D1 degradation in ΔpsbTc under high light. Thermoluminescence emission measurements revealed alterations of midpoint potentials of primary/secondary electron-accepting plastoquinone of PSII interaction. Only traces of CP43 and no D1/D2 proteins are phosphorylated, presumably due to structural changes of PSII in ΔpsbTc. In striking contrast to the wild type, LHCII in the mutant is phosphorylated in darkness, consistent with its association with PSI, indicating an increased pool of reduced plastoquinone in the dark. Finally, our data suggest that the secondary electron-accepting plastoquinone of PSII site, the properties of which are altered in ΔpsbTc, is required for oxidation of reduced plastoquinone in darkness in an oxygen-dependent manner. These data present novel aspects of plastoquinone redox regulation, chlororespiration, and redox control of LHCII phosphorylation.     

Heterogeneity in chloroplast photosystem II

Photosystem-two (PSII) in the chloroplasts of higher plants and green algae is not homogeneous. A review of PSII heterogeneity is presented and a model is proposed which is consistent with much of the data presented in the literature. It is proposed that the non-quinone electron acceptor of PSII is preferentially associated with the sub-population of PSII known as PSIIß.Abbreviations and symbols ATP Adenosine triphosphate - Chl Chlorophyll - C₅₅₀ Absorbance bandshift at 550 nm; proportional to [Q_A ^-] - D, D Components involved ir electron donation to P680 - pH Transthylakoid proton gradient - Transthylakoid electrical gradient - DCMU 3-(3,4-Dichlorophenyl)-1,1-dimethylurea referred to as diuron - E _h Oxidation-reduction potential - E _m Cxidation-reduction midpoint potential - EPR Electron paramagnetic resonance - Fm Fluorescence yield when all traps are closed - Fo Fluorescence yield when all traps are open - Fv Variable fluorescence equal to Fm-Fo - Fi Initial fluorescence yield, (usually equivalent to Fo in dark-adapted thylakoids) - Hepes 2-hydroxyethylpiperazine-N-2-ethane sulphonic acid - LHCP Light-harvesting chlorophyll a/b binding protein - PQ Plastoquinone - PSII Photosystem II - P680 Reaction centre chlorophyll of PSII - P₅₁₈ Absorbance bandshift at 518 nm, reflects asymmetric charge distribution across the thylakoid membrane - Q_A, _QH , Q₁ Primary stable plastoquinone electron acceptor of PSII; a quencher of fluorescence - Q _B , B, R Plastoquinone associated with the Q _B -protein, the two-electron gate - Q _D , Q₂, X _a Non-quinone electron acceptor of PSII - X₃₂₀ Absorbance bandshift at 320 nm; semiquinone anion indicator     

Photoinhibition of photosystem II under environmental stress

Inhibition of the activity of photosystem II (PSII) under strong light is referred to as photoinhibition. This phenomenon is due to an imbalance between the rate of photodamage to PSII and the rate of the repair of damaged PSII. In the “classical” scheme for the mechanism of photoinhibition, strong light induces the production of reactive oxygen species (ROS), which directly inactivate the photochemical reaction center of PSII. By contrast, in a new scheme, we propose that photodamage is initiated by the direct effect of light on the oxygen-evolving complex and that ROS inhibit the repair of photodamaged PSII by suppressing primarily the synthesis of proteins de novo. The activity of PSII is restricted by a variety of environmental stresses. The effects of environmental stress on damage to and repair of PSII can be examined separately and it appears that environmental stresses, with the exception of strong light, act primarily by inhibiting the repair of PSII. Studies have demonstrated that repair-inhibitory stresses include CO₂ limitation, moderate heat, high concentrations of NaCl, and low temperature, each of which suppresses the synthesis of proteins de novo, which is required for the repair of PSII. We postulate that most types of environmental stress inhibit the fixation of CO₂ with the resultant generation of ROS, which, in turn, inhibit protein synthesis.     

Using site-directed mutagenesis to probe the role of the D2 carotenoid in the secondary electron-transfer pathway of photosystem II

Secondary electron transfer in photosystem II (PSII), which occurs when water oxidation is inhibited, involves redox-active carotenoids (Car), as well as chlorophylls (Chl), and cytochrome b ₅₅₉ (Cyt b ₅₅₉), and is believed to play a role in photoprotection. Car_D2 may be the initial point of secondary electron transfer because it is the closest cofactor to both P₆₈₀, the initial oxidant, and to Cyt b ₅₅₉, the terminal secondary electron donor within PSII. In order to characterize the role of Car_D2 and to determine the effects of perturbing Car_D2 on both the electron-transfer events and on the identity of the redox-active cofactors, it is necessary to vary the properties of Car_D2 selectively without affecting the ten other Car per PSII. To this end, site-directed mutations around the binding pocket of Car_D2 (D2-G47W, D2-G47F, and D2-T50F) have been generated in Synechocystis sp. PCC 6803. Characterization by near-IR and EPR spectroscopy provides the first experimental evidence that Car_D2 is one of the redox-active carotenoids in PSII. There is a specific perturbation of the Car^?+ near-IR spectrum in all three mutated PSII samples, allowing the assignment of the spectral signature of Car _D2 ^?+ ; Car _D2 ^?+ exhibits a near-IR peak at 980 nm and is the predominant secondary donor oxidized in a charge separation at low temperature in ferricyanide-treated wild-type PSII. The yield of secondary donor radicals is substantially decreased in PSII complexes isolated from each mutant. In addition, the kinetics of radical formation are altered in the mutated PSII samples. These results are consistent with oxidation of Car_D2 being the initial step in secondary electron transfer. Furthermore, normal light levels during mutant cell growth perturb the shape of the Chl^?+ near-IR absorption peak and generate a dark-stable radical observable in the EPR spectra, indicating a higher susceptibility to photodamage further linking the secondary electron-transfer pathway to photoprotection.     

Function of two β-carotenes near the D1 and D2 proteins in photosystem II dimers

The antenna proteins in photosystem II (PSII) not only promote energy transfer to the photosynthetic reaction center (RC) but provide also an efficient cation sink to re-reduce chlorophyll a if the electron transfer (ET) from the Mn-cluster is inhibited. Using the newest PSII dimer crystal structure (3.0 Å resolution), in which 11 β-carotene molecules (Car) and 14 lipids are visible in the PSII monomer, we calculated the redox potentials (E_m) of one-electron oxidation for all Car (E_m(Car)) by solving the Poisson-Boltzmann equation. In each PSII monomer, the D1 protein harbors a previously unlocated Car (Car_D1) in van der Waals contact with the chlorin ring of Chl_Z(D1). Each Car_D1 in the PSII dimer complex is located in the interface between the D1 and CP47 subunits, together with another four Car of the other PSII monomer and several lipid molecules. The proximity of Car bridging between Car_D1 and plastoquinone/Q_A may imply a direct charge recombination of Car⁺Q_A⁻. The calculated E_m(Car_D1) and E_m(Chl_Z(D1)) are, respectively, 83 and 126 mV higher than E_m(Car_D2) and E_m(Chl_Z(D2)), which could explain why Car_D2⁺ and Chl_Z(D2)⁺ are observed rather than the corresponding Car_D1⁺ and Chl_Z(D1)⁺.     

Reactive oxygen species derived from impaired quality control of photosystem II are irrelevant to plasma-membrane NADPH oxidases

Protein quality control plays an important role in the photosynthetic apparatus because its components receive excess light energy and are susceptible to photooxidative damage. In chloroplasts, photodamage is targeted to the D1 protein of Photosystem II (PSII). The coordinated PSII repair cycle (PSII disassembly, D1 degradation and synthesis, and PSII reassembly) is necessary to mitigate photoinhibition. A thylakoid protease FtsH, which is formed predominantly as a heteromeric complex with two isoforms of FtsH2 and FtsH5 in Arabidopsis, is the major protease involved in PSII repair. A mutant lacking FtsH2 (termed var2) shows compromised D1 degradation. Furthermore, var2 accumulates high levels of chloroplastic reactive oxygen species (cpROS), reflecting photooxidative stress without functional PSII repair. To examine if the cpROS produced in var2 are connected to a ROS signaling pathway mediated by plasma membrane NADPH oxidase (encoded by AtRbohD or AtRbohF), we generated mutants in which either Rboh gene was inactivated under var2 background. Lack of NADPH oxidases had little or no impact on cpROS accumulation. It seems unlikely that cpROS in var2 activate plasma membrane NADPH oxidases to enhance ROS production and the signaling pathway. Mutants that are defective in PSII repair might be valuable for investigating cpROS and their physiological roles.Key words: reactive oxygen species (ROS), photosystem II repair cycle, chloroplast, FtsH, NADPH oxidase, D1 protein, protein turnoverPhotosynthetic apparatus components receive excess light energy that can ultimately engender photoinhibition.^1,2 Chloroplasts are therefore equipped with molecular systems to minimize accumulation of photodamaged proteins.³ Photosystem II, a large pigment-protein complex located in the thylakoid membrane, transfers electrons to plastoquinone and drives oxidation of water molecules using light energy.^4,5 Because PSII is an initial and rate-limiting step of electron flow, photosynthetic organisms have evolved a unique mechanism of protein quality control (PSII repair cycle), in which the damage is centralized into the reaction center D1 protein, and in which PSII is recycled efficiently.^6,7 Several lines of evidence from genetic and biochemical studies indicate that a prokaryotic ATP-dependent metalloprotease FtsH plays a critical role in D1 turnover of the PSII repair.^8–12In chloroplasts, FtsH forms a heteromeric complex with two major isoforms.^13,14 Mutants lacking either major isoform (var2 lacking FtsH2 or var1 lacking FtsH5) show leaf variegation forming white sectors that contain cells with aberrant plastids.^8,9,11,15 The variegated phenotype implies that FtsH is involved not only in D1 degradation but also in thylakoid development.^16,17 We conducted in vivo D1 degradation assays using “non-variegated” var1 and var2 mutants (owing to a trans-acting suppressor mutation fug1).^18,19 Results showed that both D1 degradation and PSII electron transport rates were impaired in these non-variegated lines.¹⁹ Collectively, our results corroborate the important role of chloroplast FtsH in the PSII repair cycle. We also infer that the variegation phenotype in var mutants is separable from the defect in the PSII repair.Two important observations concomitant with impaired D1 degradation were made in our recent study.¹⁹ One is the accumulation of PSII partial complexes in var2. Two-dimensional blue-native SDS-PAGE analysis demonstrated that thylakoid-membrane fractions from var2 chloroplasts contained fewer PSII supercomplexes (representing functional PSII) and more partial PSII complexes (representing disassembled intermediates in the PSII repair cycle). These results indicate, although indirectly, that the impaired D1 degradation affects the disassembly/ reassembly step of the PSII repair cycle. The other important observation is the accumulation of reactive oxygen species (ROS), such as superoxide radical (O₂⁻) and hydrogen peroxide (H₂O₂) in var2. Results of NBT staining indicated that O₂⁻ is specially localized in chloroplasts of var2 green sectors in a light-dependent manner. No NBT staining was detected in wild type under identical conditions. Similarly, DAB staining indicated that H₂O₂ is detectable in var2 green sectors. High ROS in var2 therefore demonstrates that chloroplasts suffer from photooxidative stress without a functional PSII repair system. Where these ROS are generated within chloroplasts remains unclear. We raise one possibility: that PSII partial complexes in var2 contribute to ROS production because they potentially accumulate excitation energy that might not be used for water oxidation.A considerable amount of chloroplastic O₂⁻ in var2 might be converted rapidly to H₂O₂, which can then be exported to cytosol or to other organelles for detoxification. Simultaneously, H₂O₂ in cytosol might act as a signaling molecule and consequently affect responses to environmental stress.²⁰ We raised one possibility: cpROS in var2 are influenced by an apoplastic oxidative burst that is mediated by plasma membrane-bound NADPH oxidases and which further activates downstream signaling cascades. For example, cpROS produced in guard cells of ozonetreated Arabidopsis were shown to activate certain NAPDH oxidases through the action of heterotrimeric G protein signaling. ²¹ Although Gα subunit activated by cpROS is primarily involved in oxidative bursts, Gβγ complexes appear to act on further production of cpROS.²¹ These observations led us to examine whether high cpROS in var2 are regulated by NADPH oxidases.Ten genes for NADPH oxidases (AtRbohA to AtRbohJ) are reported in Arabidopsis.²² Among these, AtRbohD and AtRbohF are expressed in mesophylls and are involved in cpROS signaling in guard cells.^22–24 To investigate the effect of these NADPH oxidases on cpROS accumulation in var2, we generated double mutants (var2/atrbohD and var2/atrbohF). The degrees of leaf variegation were similar in var2 and the double mutants. Single atrbohD and atrbohF mutants did not accumulate detectable ROS (not shown). We observed strong signals in var2/ atrbohD and var2/atrbohF double mutants both in NBT and DAB stains (Fig. 1). Overall, results showed no significant difference in the accumulation of cpROS between var2 and the double mutants. Furthermore, results of our microarray analyses demonstrated that expression levels of AtRbohD and AtrbohF are similar between var2 green sectors and wild type (unpublished data). Taken together, these results suggest that no apparent NADPH oxidase activities in plasma membranes contribute to cpROS detected in var2.Open in a separate windowFigure 1ROS accumulation in var2 and var2/atrboh mutants. (A) In situ detection of superoxide by staining with NBT (blue, bottom panels) in four-week-old wild type (Columbia), var2, var2/atrbohD, var2/atrbohF leaves. Bar = 1 mm. (B) In situ detection of hydrogen peroxide by DA B staining (dark brown, bottom panels) in four-week-old wild type (Columbia), var2, var2/rbohD, var2/rbohF leaves. Bar = 1 mm.Actually, ROS transiently generated by apoplastic NADPH oxidases are known to regulate a cell-death signaling pathway such as a hypersensitive response against pathogen infection.²⁵ Based on results of our current genetic and microarray analyses, we reason that, in var2, constitutive cpROS do not activate the ROS-mediated signaling pathway. Nevertheless, involvement of cpROS in signaling cascades has been suggested in other experimental systems. The mutants described in this report might be valuable for use in future studies.     

Assembly of D1/D2 complexes of photosystem II: Binding of pigments and a network of auxiliary proteins

Photosystem II (PSII) is the multi-subunit light-driven oxidoreductase that drives photosynthetic electron transport using electrons extracted from water. To investigate the initial steps of PSII assembly, we used strains of the cyanobacterium Synechocystis sp. PCC 6803 arrested at early stages of PSII biogenesis and expressing affinity-tagged PSII subunits to isolate PSII reaction center assembly (RCII) complexes and their precursor D1 and D2 modules (D1_mod and D2_mod). RCII preparations isolated using either a His-tagged D2 or a FLAG-tagged PsbI subunit contained the previously described RCIIa and RCII* complexes that differ with respect to the presence of the Ycf39 assembly factor and high light-inducible proteins (Hlips) and a larger complex consisting of RCIIa bound to monomeric PSI. All RCII complexes contained the PSII subunits D1, D2, PsbI, PsbE, and PsbF and the assembly factors rubredoxin A and Ycf48, but we also detected PsbN, Slr1470, and the Slr0575 proteins, which all have plant homologs. The RCII preparations also contained prohibitins/stomatins (Phbs) of unknown function and FtsH protease subunits. RCII complexes were active in light-induced primary charge separation and bound chlorophylls (Chls), pheophytins, beta-carotenes, and heme. The isolated D1_mod consisted of D1/PsbI/Ycf48 with some Ycf39 and Phb3, while D2_mod contained D2/cytochrome b₅₅₉ with co-purifying PsbY, Phb1, Phb3, FtsH2/FtsH3, CyanoP, and Slr1470. As stably bound, Chl was detected in D1_mod but not D2_mod, formation of RCII appears to be important for stable binding of most of the Chls and both pheophytins. We suggest that Chl can be delivered to RCII from either monomeric Photosystem I or Ycf39/Hlips complexes.

Analysis of isolated assembly complexes provides new insights into the early stages of photosystem II biogenesis.     

Hydrogencarbonate is not a tightly bound constituent of the water-oxidizing complex in photosystem II

Since the end of the 1950s hydrogencarbonate (‘bicarbonate’) is discussed as a possible cofactor of photosynthetic water-splitting, and in a recent X-ray crystallography model of photosystem II (PSII) it was displayed as a ligand of the Mn₄O_xCa cluster. Employing membrane-inlet mass spectrometry (MIMS) and isotope labelling we confirm the release of less than one (≈ 0.3) HCO₃⁻ per PSII upon addition of formate. The same amount of HCO₃⁻ release is observed upon formate addition to Mn-depleted PSII samples. This suggests that formate does not replace HCO₃⁻ from the donor side, but only from the non-heme iron at the acceptor side of PSII. The absence of a firmly bound HCO₃⁻ is corroborated by showing that a reductive destruction of the Mn₄O_xCa cluster inside the MIMS cell by NH₂OH addition does not lead to any CO₂/HCO₃⁻ release. We note that even after an essentially complete HCO₃⁻/CO₂ removal from the sample medium by extensive degassing in the MIMS cell the PSII samples retain ≥ 75% of their initial flash-induced O₂-evolving capacity. We therefore conclude that HCO₃⁻ has only ‘indirect’ effects on water-splitting in PSII, possibly by being part of a proton relay network and/or by participating in assembly and stabilization of the water-oxidizing complex.