Photochemical properties of a photosystem I subchloroplast fragment.

Treatment of spinach chloroplast fragments with the detergent lauryl dimethylamine oxide, followed by column chromatography on DEAE-cellulose, leads to the isolation of a Subchloroplast fragment that is enriched in Photosystem I. The spectrum of the lauryl dimethylamine oxide fragments, characterized by maxima at 418, 435, and 671 nm, shows the absence of chlorophyll b. The fragments contain 1 molecule of P700 per 40 chlorophyll molecules but have no cytochromes. The P700 in the fragments is photochemically active at both room temperature and liquid helium temperature. The fragments contain the primary electron acceptor of Photosystem I, as evidenced by the low-temperature photoreduction of a bound iron-sulfur protein. The fragments are able to catalyze noncyclic electron transfer from ascorbate to oxygen but not to the electron acceptor NADP.     

Fluorescence studies on interaction between phospho-LHC II and subchloroplast Photosystem 1 preparations

Chloroplast proteins were phosphorylated under two test conditions: white light irradiance alone and white light irradiance with the addition of glucose and glucose oxidase, used to produce an anaerobic medium. The interaction of phospho-LHC II with Photosystem 1 (PS 1) was studied for two types of PS I preparation. Changes in the chlorophyll a/b ratio and the ratio of 650 and 680 nm band intensities (E650/E680) in fluorescence excitation spectra were used in calculating the phospho-LHC II portion which became associated with PS 1. It is shown that the associated portion of phospho-LHC II varies for each of the PS 1 preparations and phosphorylation procedures. Possible conclusions as regards the transfer of various sets of LHC II subpopulations under different phosphorylation procedures and the differences of interaction with PS 1 are discussed.Abbreviations PS 1 Photosystem 1 - PS 2 Photosystem 2 - LHC II light-harvesting chlorophyll a/b protein complex II - Chl chlorophyll - fluorescence quantum yield - _f life time of fluorescence at =685 nm - F735 fluorescence band with a maximum at 735 nm - F685 fluorescence band with a maximum at 685 nm - E650/E680 ratio of amplitudes in excitation fluorescence spectrum at 650 and 680 nm     

Studies on well coupled Photosystem I-enriched subchloroplast vesicles. Content and redox properties of electron-transfer components

Stable and well coupled Photosystem (PS) I-enriched vesicles, mainly derived from the chloroplast stroma lamellae, have been obtained by mild digitonin treatment of spinach chloroplasts. Optimal conditions for chloroplast solubilization are established at a digitonin/chlorophyll ratio of 1 ($\text{w}\text{w}$) and a chlorophyll concentration of 0.2 mM, resulting in little loss of native components. In particular, plastocyanin is easily released at higher digitonin/chlorophyll ratios. On the basis of chlorophyll content, the vesicles show a 2-fold enrichment in ATPase, chlorophyll-protein Complex I, P-700, plastocyanin and ribulose-1,5-bisphosphate carboxylase as compared to chloroplasts, in line with the increased activities of cyclic photophosphorylation and PS I-associated electron transfer as shown previously (Peters, A.L.J., Dokter, P., Kooij, T. and Kraayenhof, R. (1981) in Photosynthesis I (Akoyunoglou, G., ed.), pp. 691–700, Balaban International Science Services, Philadelphia). The vesicles have a low content of the light-harvesting chlorophyll-protein complex and show no PS II-associated electron transfer. Characterization of cytochromes in PS I-enriched vesicles and chloroplasts at 25°C and 77 K is performed using an analytical method combining potentiometric analysis and spectrum deconvolution. In PS I-enriched vesicles three cytochromes are distinguished: c-554 (E′₀ = 335 mV), b-559_LP (E′₀ = 32 mV) and b-563 (E′₀ = ? 123 mV); no b-559_HP is present (LP, low-potential; HP, high-potential). Comparative data from PS I vesicles and chloroplasts are consistent with an even distribution of the cytochrome b-563- cytochrome c-554 redox complex in the lateral plane of exposed and appressed thylakoid membranes, an exclusive location of plastocyanin in the exposed membranes and a dominant location of plastoquinone in the appressed membranes. The results are discussed in view of the lateral heterogeneity of redox components in chloroplast membranes.     

Photochemical and spectral properties of photosystem-2 subchloroplast fragments, highly purified from photosystem-1 mixtures]

A rather simple method of isolation of photosystem 2 fragments, which are highly purified from Photosystem 1 admixture, has been developed on the basis of combined action of detergents and differential centrifugation. The isolated fragments are characterized by insignificant content of P700 (one molecule per 10500 molecules of chlorophyll) and by high ratio of band values at 685 and 735 nm in the low temperature emission spectrum of fluorescence (F685/F735=5.9). The data on photochemical activity and ability for photoinduced changes in fluorescence prove that the activity of Photosystem 2 is retained both at the level of reaction centre operation and at that of water photooxidation with oxygen evolution.     

Natural Variants of Photosystem II Subunit D1 Tune Photochemical Fitness to Solar Intensity

Photosystem II (PSII) is composed of six core polypeptides that make up the minimal unit capable of performing the primary photochemistry of light-driven charge separation and water oxidation in all oxygenic phototrophs. The D1 subunit of this complex contains most of the ligating amino acid residues for the Mn₄CaO₅ core of the water-oxidizing complex (WOC). Most cyanobacteria have 3–5 copies of the psbA gene coding for at least two isoforms of D1, whereas algae and plants have only one isoform. Synechococcus elongatus PCC 7942 contains two D1 isoforms; D1:1 is expressed under low light conditions, and D1:2 is up-regulated in high light or stress conditions. Using a heterologous psbA expression system in the green alga Chlamydomonas reinhardtii, we have measured growth rate, WOC cycle efficiency, and O₂ yield as a function of D1:1, D1:2, or the native algal D1 isoform. D1:1-PSII cells outcompete D1:2-PSII cells and accumulate more biomass in light-limiting conditions. However, D1:2-PSII cells easily outcompete D1:1-PSII cells at high light intensities. The native C. reinhardtii-PSII WOC cycles less efficiently at all light intensities and produces less O₂ than either cyanobacterial D1 isoform. D1:2-PSII makes more O₂ per saturating flash than D1:1-PSII, but it exhibits lower WOC cycling efficiency at low light intensities due to a 40% faster charge recombination rate in the S₃ state. These functional advantages of D1:1-PSII and D1:2-PSII at low and high light regimes, respectively, can be explained by differences in predicted redox potentials of PSII electron acceptors that control kinetic performance.     

Optical and EPR characterizations of oxygen-evolving Photosystem II subchloroplast fragments isolated from the thermophilic blue-green alga Phormidium laminosum

An oxygen-evolving, Photosystem II particle was isolated from the thermophilic, blue-green alga, Phormidium laminosum, according to the procedure of Stewart and Bendall (Stewart, A.C. and Bendall, D. (1979) FEBS Lett. 107, 308–312). Our particle has an oxygen-evolution activity of 1500–1600 μmol O₂/mg chlorophyll per h. The oxygen-evolution activity has a pH optimum at 5–6, and is abolished at pH 9. Maximum oxygen evolution occurs at approx. 47°C in whole cells, but at 29°C in the particles. The activity decreases to 50% when the cells are heated for 30 min at 55°C; with the particles, 50% inactivation occurred at 47°C for the same heating time of 30 min. Flash excitation of the particle at 100 K produced absorbance changes whose difference spectrum in the ultraviolet-to-near infrared region shows photochemical charge separation and recombination of P-680⁺ and Q⁻ in the dark with of 1.75 ms. An EPR spectrum for the P-680⁺ free radical, with g 2.0027 and ΔH_pp = 8 G, was constructed from flash-induced EPR changes under conditions identical to those used for obtaining P-680 absorbance changes. The actinic light-induced variable fluorescence yield is 5-fold that induced by the weak probing beam alone. Addition of dithionite to the particle brings the fluorescence to the same maximum level. Under the reducing condition, strong actinic light caused the fluorescence to decrease. This observation is consistent with the notion that variable fluorescence yield in Photosystem II originates, as in green-plant chloroplasts, from recombination luminescence, the attenuation of which corresponds to photoaccumulation of reduced pheophytin under these conditions. Broad segments (300 nm) of the difference spectrum for pheophytin photoreduction were recorded by an intensified photodiode array in conjunction with a phosphoroscopic photometer. Kinetic spectrophotometric assays together with chemical analysis showed a rather clean and simple stoichiometry in these particles, namely, 1 P-680:1 Ph:1 Q:4 Mn:44 Chl. Initial investigation failed to reveal the doublet EPR spectrum previously observed for Ph⁻·Q⁻ Fe in spinach subchloroplast particles (Klimov, V.V., Dolan, E. and Ke, B. (1980). FEBS Lett. 118, 97–100). A hyperfine EPR spectrum consisting of 16–20 lines and presumably associated with the manganese clusters in the oxygen-evolving protein has been confirmed in these particles. Tris washing but not washing with EDTA eliminates this signal. Active oxygen-evolving particles also yield the II_vf signal with a of approx. 800 μs. Upon Tris washing, the II_f signal appears which decays in 23.5 ms.     

Temperature-dependent changes in Photosystem II heterogeneity support a cycle of Photosystem II during photoinhibition

High light treatments were given to attached leaves of pumpkin (Cucurbita pepo L.) at room temperature and at 1°C where the diffusion- and enzyme-dependent repair processes of Photosystem II are at a minimum. After treatments, electron transfer activities and fluorescence induction were measured from thylakoids isolated from the treated leaves. When the photoinhibition treatment was given at 1°C, the Photosystem II electron transfer assays that were designed to require electron transfer to the plastoquinone pool showed greater inhibition than electron transfer from H₂O to paraphenyl-benzoquinone, which measures all PS II centers. When the light treatment was given at room temperature, electron transfer from H₂O to paraphenyl-benzoquinone was inhibited more than whole-chain electron transfer. Variable fluorescence measured in the presence of ferricyanide decreased only during room-temperature treatments. These results suggest that reaction centers of one pool of Photosystem II, non-Q_B-PS II, replace photoinhibited reaction centers at room temperature, while no replacement occurs at 1°C. A simulation of photoinhibition at 1°C supports this conclusion.Abbreviations BSA bovine serum albumin - Chl chlorophyll - DCMU 3-(3,4,-dichlorophenyl)-1,1,-dimethylurea - DCPIP dichlorophenol-indophenol (2,6-dichloro-4((4-hydroxyphenyl)imino)-2,5-cyclohexadien-1-one) - DPC diphenyl carbazide (2,2-diphenylcarbonic dihydrazide) - FeCN ferricyanide (hexacyanoferrate(III)) - _app apparent quantum yield of photosynthetic oxygen evolution - MV methyl viologen (1,1-dimethyl-4,4-bipyridinium dichloride) - PPBQ phenyl-p-benzoquinone - PPFD photosynthetic photon flux density - PQ pool plastoquinone - Q_B secondary quinone acceptor of PS II - RT room temperature - WC whole chain electron transfer     

C-550 in photosystem II subchloroplast particles

The photoreactions mediated by Photosystem II at low temperatures were examined in subchloroplast particles enriched in Photosystem II to determine if the Photosystem II activity was independent of C-550 in such particle preparations. Two types of Photosystem II particle preparations were tested, one enriched in chlorophyll b and the other purified further to eliminate the chlorophyll b. The Photosystem II-mediated photoreactions at low temperature were the same in both of the Photosystem II particle preparations as they were in normal chloroplasts. C-550 acted as if it were the primary electron acceptor of Photosystem II in all of the experiments performed.     

The quantum yield of reaction center photooxidation in subchloroplast fragments enriched with Photosystem I

Suspensions of light particles sedimented at 16500×g from pea subchloroplast preparations were investigated. The exciting light readily caused the photooxidation of P₇₀₀ in a fraction of active particles. The effective energy transfer has been shown to occur between individual P₇₀₀. The quantum yield of P₇₀₀ photooxidation was estimated by means of the relative method to be ?0.75.     

Studies on P-700 photo-oxidation and reduction in Photosystem I subchloroplast particles

The photochemical oxidation and reduction of P-700 were studied in digitonin- and in sodium dodecyl sulphate (SDS)-Photosystem I (PS I) particles in the presence of ascorbate. In digitonin-PS I particles, reduction of P-700⁺ occurs by the bound iron-sulphur protein (P-430) and by ascorbate. The relative contribution of these back reactions depends on the length of the exposure to light and on the temperature and pH of the reaction medium. Experiments performed under anaerobic conditions demonstrate that some endogenous component may serve as the electron acceptor of P-430^?. The rate of the latter reaction is also dependent upon the temperature and pH of the sample. At pH 9 and lower temperatures the rate of this reaction is so much reduced that the reduction of P-700⁺ by ascorbate, which increases rapidly at high pH, can be observed even during illumination. The effects of secondary electron acceptors and of the presence of SDS on the absorption changes due to P-700 are also reported. Low concentrations of SDS are shown to retard the back reaction of P-700⁺ with P-430^?. Studies with SDS-PS I particles (CP_I) confirm the absence of the iron-sulphur centres in this preparation. Three larger P-700-chlorophylla-protein complexes prepared by mild electrophoresis in the presence of SDS plus Triton X-100, however, still contain P-430.     

Photosystem II.

Electron crystallography of photosystem II has revealed the location of important subunits and photoactive pigment molecules within this large membrane protein complex. It has also demonstrated a close evolutionary link among all types of photosynthetic reaction centres.     

Membrane-surface electric properties of Triton-fractionated spinach subchloroplast fragments

Surface charge density of subchloroplast fragments fractionated from spinach by Triton X-100 treatment was estimated from cation-induced quenching of chlorophyll fluorescence, with the premise that the fluorescence yield is dependent on the surface electric potential of the preparations. Application of the Gouy-Chapman theory of diffuse double layer to the subchloroplast preparations, or treating the surface of the preparations under electric charge regulation conditions yielded a result suggesting the Photosystem II reaction-center preparation (TSF-IIa) to be more negatively charged than the Photosystem I reaction-center preparation (TSF-I). Isoelectric points of the subchloroplast fragments were determined by measuring 90° light scattering and more directly by gel isoelectric focusing. Isoelectric points of TSF-I and -IIa were estimated to be 4.8 and 4.0 from light-scattering experiments, and 4.5 and 4.1 from gel electrophoresis, respectively. The TSF-II preparation that contains both a light-harvesting complex and the reaction-center (core) complex showed a small cation-induced quenching of chlorophyll fluorescence. This fluorescence quenching may be ascribed mostly to the regulation of energy transfer in the preparation (Yamamoto, Y. and Ke, B. (1980) Biochim. Biophys. Acta 592, 296–302). Furthermore, the TSF-II preparation showed a broad and indefinite peak in light scattering in the pH range 3–8, suggesting that the complex probably carries a small amount of charge in this pH range. The physiological role of the membrane surface charge of the subchloroplast preparations in membrane structure and cation regulated processes in chloroplast is discussed.     

Influence of protein phosphorylation on the electron-transport properties of Photosystem II

Many of the core proteins in Photosystem II (PS II) undergo reversible phosphorylation. It is known that protein phosphorylation controls the repair cycle of Photosystem II. However, it is not known how protein phosphorylation affects the partial electron transport reactions in PS II. Here we have applied variable fluorescence measurements and EPR spectroscopy to probe the status of the quinone acceptors, the Mn cluster and other electron transfer components in PS II with controlled levels of protein phosphorylation. Protein phosphorylation was induced in vivo by varying illumination regimes. The phosphorylation level of the D1 protein varied from 10 to 58% in PS II membranes isolated from pre-illuminated spinach leaves. The oxygen evolution and Q_A ⁻ to Q_B(Q_B ⁻) electron transfer measured by flash-induced fluorescence decay remained similar in all samples studied. Similar measurements in the presence of DCMU, which reports on the status of the donor side in PS II, also indicated that the integrity of the oxygen-evolving complex was preserved in PS II with different levels of D1 protein phosphorylation. With EPR spectroscopy we examined individual redox cofactors in PS II. Both the maximal amplitude of the charge separation reaction (measured as photo-accumulated pheophytin⁻) and the EPR signal from the Q_A ⁻ Fe²⁺ complex were unaffected by the phosphorylation of the D1 protein, indicating that the acceptor side of PS II was not modified. Also the shape of the S₂ state multiline signal was similar, suggesting that the structure of the Mn-cluster in Photosystem II did not change. However, the amplitude of the S₂ multiline signal was reduced by 35% in PS II, where 58% of the D1 protein was phosphorylated, as compared to the S₂ multiline in PS II, where only 10% of the D1 protein was phosphorylated. In addition, the fraction of low potential Cyt b ₅₅₉ was twice as high in phosphorylated PS II. Implications from these findings, were precise quantification of D1 protein phosphorylation is, for the first time, combined with high-resolution biophysical measurements, are discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Purification and properties of an oxygen-evolving Photosystem II reaction-center complex from spinach

A chlorophyll-protein complex, capable of photochemical water oxidation and consisting of only one extrinsic protein of 33 kDa in addition to six intrinsic proteins of the Photosystem II reaction center, has been isolated from spinach thylakoids by digitonin extraction, performed at pH 6.0, followed by chromatographic separations using DEAE-Toyopearl 650S as described briefly (Tang, X.S. and Satoh, K. (1985) FEBS Lett. 179, 60–64). The protein complex contained approx. 3–4 manganese atoms, 2 mol plastoquinone-9 and 2 mol low-potential forms of cytochrome b-559 heme per mol of the photoactive primary acceptor, Q_A. The oxygen evolution of the complex was highly stimulated by the presence of CaCl₂ and stabilized by glycerol; the typical rate of 400–500 μmol O₂ per mg Chl per h was attained with 2,5-dichlorobenzoquinone and potassium ferricyanide as electron acceptors in the presence of 50 mM CaCl₂. The protein complex exhibited a dark-stable EPR Signal II; the microwave power saturation profile of the signal was almost identical with that of oxygen-evolving membrane preparations. The multiline EPR signal ascribable to Kok's S₂-state was elicited in this protein complex by illumination at 200 K, as in membrane preparations. These results indicate that the basic machinery of photosynthetic water oxidation is preserved in an almost intact state in the isolated chlorophyll-protein complex.     

Functional Analyses of the Plant Photosystem I-Light-Harvesting Complex II Supercomplex Reveal That Light-Harvesting Complex II Loosely Bound to Photosystem II Is a Very Efficient Antenna for Photosystem I in State II

State transitions are an important photosynthetic short-term response that allows energy distribution balancing between photosystems I (PSI) and II (PSII). In plants when PSII is preferentially excited compared with PSI (State II), part of the major light-harvesting complex LHCII migrates to PSI to form a PSI-LHCII supercomplex. So far, little is known about this complex, mainly due to purification problems. Here, a stable PSI-LHCII supercomplex is purified from Arabidopsis thaliana and maize (Zea mays) plants. It is demonstrated that LHCIIs loosely bound to PSII in State I are the trimers mainly involved in state transitions and become strongly bound to PSI in State II. Specific Lhcb1-3 isoforms are differently represented in the mobile LHCII compared with S and M trimers. Fluorescence analyses indicate that excitation energy migration from mobile LHCII to PSI is rapid and efficient, and the quantum yield of photochemical conversion of PSI-LHCII is substantially unaffected with respect to PSI, despite a sizable increase of the antenna size. An updated PSI-LHCII structural model suggests that the low-energy chlorophylls 611 and 612 in LHCII interact with the chlorophyll 11145 at the interface of PSI. In contrast with the common opinion, we suggest that the mobile pool of LHCII may be considered an intimate part of the PSI antenna system that is displaced to PSII in State I.