Quantitative Analysis of the Inactivation of Photosynthetic Oxygen Evolution and the Release of Polypeptides and Manganese in the Photosystem II Particles of Spinach Chloroplasts

Photosynthetic oxygen evolution by photosystem II particleswas inactivated by treatment with NaCl, NH₂OH or high pH. Whenthe degree of inactivation was compared with the degree of releasefrom the particles of Mn and three polypeptides having molecularmasses of 33, 24 and 18kdaltons, two types of inactivation werefound: one, brought about with 960 mM NaCl, was related to therelease of the 24 kdalton polypeptide, and the other, broughtabout with 1.5 mM NH₂OH or high pH, seemed to be related tothe release of Mn. ¹Present address: Department of Chemistry, Faculty of Science,Toho University, Miyama 2-2-1, Funabashi 274, Japan. (Received January 31, 1983; Accepted March 28, 1983)     

Restoration by Glycerol of Cholate-Induced Inactivation of Oxygen Evolution in Spinach Chloroplasts

Electron transport in spinach chloroplasts treated with cholateor Tris in the presence and absence of 20% glycerol was measured.Glycerol suppressed the inhibitory action of cholate and Trison the donor side of photosystem II and also restored the Hillactivity previously lowered by cholate. This restoration requiredthe cholate-extract from the chloroplasts. (Received November 17, 1982; Accepted July 25, 1983)     

Ferricyanide Reduction in Photosystem II of Spinach Chloroplasts

Ferricyanide can be reduced in Photosystem II of spinach chloroplasts at 2 separate sites, both of which are sensitive to 3-(3,4-dichlorophenyl)-1,1-dimethylurea, but only one of which is sensitive to dibromothymoquinone. Data presented in this paper emphasize ferricyanide site II of Photosystem II, which is sensitive to thiol inhibition and may reflect a cyclic pathway around Photosystem II. Ferricyanide reduction sites 1 and 2 also differ from each other in fractions isolated from discontinuous sucrose gradients, from fragmented chloroplasts, and upon trypsin treatment. Sucrose density gradient centrifugation shows that ferricyanide reduction site 1 activity at pH 6 decreases from 30 to 50% in various isolated fractions, while the dibromothymoquinone-insensitive activity at pH 8 (site 2) is stimulated from 15 to 35%.     

A Calcium-Selective Site in Photosystem II of Spinach Chloroplasts

After acid-treatment of spinach (Spinacia oleracea) chloroplasts, various partial electron transport reactions are inactivated from 25 to 75%. Divalent cations in concentrations from 10 to 50 millimolar can partially restore electron transport rates. Two cation-specific sites have been found in photosystem II: one on the 3-(3,4-dichlorophenyl)-1, 1-dimethylurea-insensitive silicomolybdate pathway, which responds better to restoration by Mg²⁺ than by Ca²⁺ ions, the other on the forward pathway to photosystem I, located on the 2,5-dimethylbenzoquinone pathway. This site is selectively restored by Ca²⁺ ions. When protonated chloroplasts are treated with N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)aziridine, a carboxyl group modifying reagent, presumed to react with glutamic and aspartic acid residues of proteins, restoration of electron transport at the Ca²⁺-selective site on the 2,5-dimethylbenzoquinone pathway is impaired, while no difference in restoration is seen at the Mg²⁺ site on the 3-(3,4-dichlorophenyl)-1,1-dimethylurea-insensitive silicomolybdate pathway.

Trypsin treatment of chloroplasts modifies the light-harvesting pigment-protein complex, destroys the dibromothymoquinone-insensitive 2,5-dimethyl-benzoquinone reduction, but does not interfere with the partial restoration of activity of this pathway by Ca²⁺ ions, implying that the selective Ca²⁺ effect on photosystem II (selective Ca²⁺ site) is different from its effects as a divalent cation on the light-harvesting pigment-protein complex involved in the excitation energy distribution between the two photosystems.

     

Toxic Effects of Copper on Photosystem II of Spinach Chloroplasts

The room temperature fluorescence induction of chloroplasts was utilized as a probe to locate the site of inhibition on PSII by copper. It was found that, while the initial fluorescence yield was hardly affected, the variable fluorescence yield was lowered without significant change in its kinetics. Addition of DCMU, or abolishing oxygen evolution capability by Tris treatment, did not alter this basic inhibition pattern. Copper was also found to lower the fluorescence yield of chloroplasts treated with linolenic acid which inhibited the secondary electron transport on both oxidizing and reducing sides of PSII. The data indicate that copper adversely affects the primary charge separation at the PSII reaction center. We suggest that the inhibition is due to creation of a lesion close to the reaction center, leading to increased dissipation of incoming excitation energy to heat.     

Stabilization of Photosystem II (O(2) Evolution) of Spinach Chloroplasts by Radiation-induced Immobilization

Spinach chloroplasts were immobilized with vinyl monomers by radiation-induced polymerization at low temperature and stored in buffer containing bovine serum albumin. The lifetime of O₂ evolution activity in photosystem II was prolonged remarkably in immobilized chloroplasts. Thermostability of immobilized chloroplasts stored in buffer containing bovine serum albumin was far better than that of immobilized chloroplasts in pure buffer and that of intact chloroplasts. When immobilized chloroplasts were stored in buffer including polyethylene glycol, the lifetime of O₂ evolution activity was longer than for those stored in buffer containing bovine serum albumin.     

Biochemical Characterization of Photosystem II Antenna Polypeptides in Grana and Stroma Membranes of Spinach

The photosystem (PS) II antenna system comprises several biochemically and spectroscopically distinct complexes, including light-harvesting complex II (LHCII), chlorophyll-protein complex (CP) 29, CP26, and CP24. LHCII, the most abundant of these, is both structurally and functionally diverse. The photosynthetic apparatus is laterally segregated within the thylakoid membrane into PSI-rich and PSII-rich domains, and the distribution of antenna complexes between these domains has implications for antenna function. We report a detailed analysis of the differences in the polypeptide composition of LHCII, CP29, and CP26 complexes associated with grana and stroma thylakoid fractions from spinach (Spinacia oleracea L.), making use of a very high-resolution denaturing gel system, coupled with immunoblots using monospecific antibodies to identify specific antenna components. We first show that the polypeptide composition of the PSII antenna system is more complex than previously thought. We resolved at least five type I LHCII apoproteins and two to three type II LHCII apoproteins. We also resolved at least two apoproteins each for CP29 and CP26. In state 1-adapted grana and stroma thylakoid membranes, the spectrum of LHCII apoproteins is surprisingly similar. However, in addition to overall quantitative differences, we saw subtle but reproducible qualitative differences in the spectrum of LHCII apoproteins in grana and stroma membrane domains, including two forms of the major type II apoprotein. The implications of these findings for models of PSII antenna function in spinach are discussed.     

Molecular Sizes of the Catalytic Units of Oxygen Evolution and the Reaction Center in Photosystem II of Spinach Thylakoids

Target analysis of the PS II reaction in spinach thylakoidsshowed that the respective molecular masses of the catalyticunits for oxygen evolution and the reaction center are about120 kDa and 250 kDa based on a kinetic separation of the tworeaction rates. The size of the oxygen-evolving enzyme agreedwith that determined for the PS II preparation from a thermophiliccyanobacterium by the same means [Nugent and Atkinson (1984)FEBS Lett. 170: 89]. Single hit-inactivation of oxygen evolutionand the PS II reaction center units indicates that each functionis driven by a structurally assembled unit. (Received August 6, 1984; Accepted December 17, 1984)     

Evidence from Crosslinking for Nearest-Neighbor Relationships among the Three Extrinsic Proteins of Spinach Photosystem II Complexes that are Associated with Oxygen Evolution

Treatment of oxygen-evolving Photosystem II complexes, whichlack light-harvesting chlorophyll a/b proteins, with a seriesof disuccinimidyl esters with different chain lengths yieldeda crosslinked product which consisted of one molecule each ofthe extrinsic 33 kDa and 23 kDa proteins. In addition, crosslinkingbetween the 33 kDa protein and the chlorophyll-carrying 47 kDaprotein and between the 23 kDa and 17 kDa proteins was confirmed.Thus, the three extrinsic proteins are closely associated witheach other to form a complex which is attached to the PS IIreaction center complexes. (Received December 1, 1989; Accepted May 2, 1990)     

Dark Anaerobic Inactivation of Photosynthetic Oxygen Evolution by Chlamydomonas reinhardtii

When intact cells of Chlamydomonas reinhardtii were anaerobicallyincubated in the dark, rapid inactivation of oxygen evolutionwith benzoquinone as the Hill oxidant occurred. Measurementsof electron transport using thylakoids isolated after anaerobictreatment showed that the inactivation occurred at, or before,the secondary electron acceptor of PS II, whereas PS I activitywas largely unaffected. In addition, after anaerobic treatmentfluorescence transients measured with no addition or with dibromomethylisopropylbenzoquinonepresent were virtually the same as those obtained with DCMUpresent. When 10 mM NaHCO₃ was added to inactivated cells, partof the oxygen evolution capacity was restored rapidly. However,almost complete recovery (within 20 to 25 min) required theaddition of oxygen as well. This recovery was not light-dependentand was faster in the presence of 1 mM KCN. We suggest thatthe in activation of benzoquinone-dependent oxygen evolutionwas due to both bicarbonate depletion and reduction of the plastoquinonepool. ¹Present address: Institute of Molecular Biophysics, FloridaState University, Tallahassee, Florida 32306, U.S.A. (Received January 17, 1984; Accepted February 25, 1984)     

Action of Mercury on the Photosynthetic Apparatus of Spinach Chloroplasts

In chloroplasts of Spinacea oleracea L., Hg2+ ions interact with some sites in the photosynthetic electron transport chain: (l) with the intermediates Z+/D+ situated in the D1 and D2 proteins and with the manganese cluster in the oxygen evolving complex which are located on the donor side of photosystem (PS) 2, (2) with the chlorophyll a dimer in the core of PS1 (P700). P700 is oxidized in the dark by HgCl2. The Hg2+ ions form organometallic complexes with amino acids contained in chloroplast proteins.     

Effect of Anions on Photosystem 1-Mediated Electron Transport in Spinach Chloroplasts

The effect of various anions on photosystem I (PSI)-mediatedelectron transport was studied in control and heat-treated chloroplasts.Results show that heat treatment exposes not only some of thereduced dichlorophenolindophenol binding sites, but also certainanion binding sites. Moreover, the site of action of anionsis at two places in the electron transport chain: one site isbetween the DCMU binding site and the HgCl₂, binding site (onplastocyanin) and the other is on the P700 itself. Key words: Anions, chloroplasts, electron transport, heat-treatment, photosystem I, spinach     

Defining the Far-Red Limit of Photosystem II in Spinach

The far-red limit of photosystem II (PSII) photochemistry was studied in PSII-enriched membranes and PSII core preparations from spinach (Spinacia oleracea) after application of laser flashes between 730 and 820 nm. Light up to 800 nm was found to drive PSII activity in both acceptor side reduction and oxidation of the water-oxidizing CaMn₄ cluster. Far-red illumination induced enhancement of, and slowed down decay kinetics of, variable fluorescence. Both effects reflect reduction of the acceptor side of PSII. The effects on the donor side of PSII were monitored using electron paramagnetic resonance spectroscopy. Signals from the S₂-, S₃-, and S₀-states could be detected after one, two, and three far-red flashes, respectively, indicating that PSII underwent conventional S-state transitions. Full PSII turnover was demonstrated by far-red flash-induced oxygen release, with oxygen appearing on the third flash. In addition, both the pheophytin anion and the Tyr Z radical were formed by far-red flashes. The efficiency of this far-red photochemistry in PSII decreases with increasing wavelength. The upper limit for detectable photochemistry in PSII on a single flash was determined to be 780 nm. In photoaccumulation experiments, photochemistry was detectable up to 800 nm. Implications for the energetics and energy levels of the charge separated states in PSII are discussed in light of the presented results.     

Promotion of Energy Transfer and Oxygen Evolution in Spinach Photosystem II by Nano-anatase TiO<Subscript>2</Subscript>

Being a proven photocatalyst, nano-anatase is capable of undergoing electron transfer reactions under light. In previous studies we had proven that nano-anatase improved photosynthesis and greatly promoted spinach growth. The mechanisms by which nano-anatase promotes energy transfer and the conversion efficiency of the process are still not clearly understood. In the present paper, we report the results obtained with the photosystem II (PSII) isolated from spinach and treated by nano-anatase TiO₂ and studied the effect of nano-anatase TiO₂ on energy transfer in PSII by spectroscopy and on oxygen evolution. The results showed that nano-anatase TiO₂ treatment at a suitable concentration could significantly change PSII microenvironment and increase absorbance for visible light, improve energy transfer among amino acids within PSII protein complex, and accelerate energy transport from tyrosine residue to chlorophyll a. The photochemical activity of PSII (fluorescence quantum yield) and its oxygen-evolving rate were enhanced by nano-anatase TiO₂. This is viewed as evidence that nano-anatase TiO₂ can promote energy transfer and oxygen evolution in PSII of spinach.     

Effects of Proteolysis on the Photochemical Activity and Polypeptide Composition of the Photosystem II Core Complex Isolated from Spinach Chloroplasts

The photosystem II core complex (TSF-IIa) is composed of polypeptides of molecular weight 54-, 47-, 42-, and 30 kilodaltons (kD) and cytochrome b-559. After treatment with trypsin or α-chymotrypsin for 20 hours, the TSF-IIa particles still retained their photochemical activity and the light-induced cytochrome b-559 signal, although all of the polypeptides of the complexes, except the 30 kD unit were extensively degraded. Proteolytic treatment decreased the apparent molecular weight of the complex from 250,000 to 100,000 daltons as determined by gel filtration, and also decreased the protein to chlorophyll ratio by 40%. Chlorophyll a appeared to be associated with the 47- and 42 kD polypeptides. Proteolysis of the complex produced a single chlorophyll a band with a slightly higher electrophoretic mobility. This band was not equivalent to the 30 kD polypeptide. Proteolysis also reduced the sensitivity of the TSF-IIa particles to 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea (DCMU), but did not completely abolish it.     

Glycinebetaine Stabilizes Photosystem 1 and Photosystem 2 Electron Transport in Spinach Thylakoid Membranes Against Heat Inactivation

Glycinebetaine, a compatible osmolyte of halotolerant plants and bacteria, partially protected photosystem (PS) 1 and PS2 electron transport reactions against thermal inactivation but with different efficiencies. In its presence, the temperature for half-maximal inactivation (t_1/2) was generally shifted downward by 3–12 °C. Glycinebetaine stabilized photoinduced oxygen evolving reactions of PS2 by protecting the tetranuclear Mn cluster and the extrinsic proteins of this complex. A weaker, although noticeable, stabilizing effect was observed in photoinduced PS2 electron transport reactions that did not originate in the oxygen-evolving complex (OEC). This weaker protection by glycinebetaine was probably exerted on the PS2 reaction centre. Glycinebetaine protected also photoinduced electron transport across PS1 against thermal inactivation. The protective effect was exerted on plastocyanin, the mobile protein in the lumen that carries electrons from the integral cytochrome b ₆ f complex to the PS1 complex. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effects of CaCl2-washing on EPR Signals of Cytochrome b559 in Photosystem II Preparation from Spinach Chloroplasts

Washing of PS II preparation by 1 M CaCl₂ inactivates oxygenevolution without loss of bound manganese [Ono and Inoue (1983)FEBS Lett. 164: 255]. Most of the high-potential Cyt b₅₅₀, whichamounts to about a half of the total Cyt b₅₅₉ in untreated preparation,was converted to its low-potential form by CaCl₂-washing. Theeffect was similar to that of Tris-washing. The peak positionof the g_s band of the EPR spectrum of the CaCl₂-washed preparation(g=2.95) was the same as that of the low potential form of untreatedpreparation but was slightly different from that of the Tris-washedor heat-treated preparation (g=2.98). ¹ Present address: Department of Biology, Faculty of Science,Tokyo Metropolitan University, Fukazawa 2-1-1, Setagaya, Tokyo158, Japan. (Received November 14, 1984; Accepted January 30, 1985)     

Inhibition of Photosystem II in Isolated Chloroplasts by Lead

Inhibition of photosynthetic electron transport in isolated chloroplasts by lead salts has been demonstrated. Photosystem I activity, as measured by electron transfer from dichlorophenol indophenol to methylviologen, was not reduced by such treatment. However, photosystem II was inhibited by lead salts when electron flow was measured from water to methylviologen and Hill reaction or by chlorophyll fluorescence. Fluorescence induction curves indicated the primary site of inhibition was on the oxidizing side of photosystem II. That this site was between the primary electron donor of photosystem II and the site of water oxidation could be demonstrated by hydroxylamine restoration of normal fluorescence following lead inhibition.     

Sulfite Inhibition of Photosystem II in Illuminated Spinach Leaves

PS II activity (dichlorophenolindophenol photoreduction) inchloroplasts isolated from sulfite-treated spinach leaves inlight was inhibited but not in darkness. Sulfite treatment decreasedthe variable part of fluorescence induction and the fluorescenceintensities of emissions at 685 and 694 nm at 77K, but it hadno effect when sulfite was administered together with DCMU.These results indicate that sulfite inactivates the PS II reactioncenter when electron transport takes place. (Received August 5, 1983; Accepted November 25, 1983)