Differential changes in the electron transport properties of thylakoid membranes during aging of attached and detached leaves, and of isolated chloroplasts

Abstract. Aging of chloroplasts both in vivo and in vitro causes a considerable loss in the 2,6-dichlorophenol indophenol (DCPIP)-Hill reaction with water as electron donor. The loss can be reduced by exogenous electron donors like diphenyl carbazide (DPC). suggestive of aging-induced damage of the oxygen evolving system. Aging also brings about a considerable loss in methylviologen (MV) reduction mediated by Photosystem I (PS I) of chloroplasts with an ascorbate-DCPIP couple as the electron donating system.
The loss in the electron transport ability of the plastids is faster during in vitro compared to in vivo aging of the chloroplasts.
Light protects the photo-electron transport ability of chloroplasts during aging of intact leaves in contrast to its action during aging of the isolated organelles.     

EPR characteristics of oxygen-evolving photosytem II particles from Phormidium laminosum

The EPR characteristics of oxygen evolving particles prepared from Phormidium laminosum are described. These particles are enriched in Photosystem II allowing EPR investigation of signals which were previously small or masked by those from Photosystem I in other preparations. EPR signals from a Signal II species and high potential cytochrome beta-559 appear as they are photooxidised at cryogenic temperatures by Photosystem II. The Signal II species is a donor close to the Photosystem II reaction centre and may represent part of the charge accumulation system of water oxidation. An EPR signal from an iron-sulphur centre which may represent an unidentified component of photosynthetic electron transport is also described. The properties of the oxygen evolving particles show that the preparation is superior to chloroplasts or unfractionated alga membranes for the study of Photosystem II with a functional water oxidation system.     

EPR characteristics of oxygen-evoloving Photosytem II particles from Phormidium laminosum

The EPR characteristics of oxygen evolving particles prepared from Phormidium laminosum are described. These particles are enriched in Photosystem II allowing EPR investigation of signals which were previously small or masked by those from Photosystem I in other preparations. EPR signals from a Signal II species and high potential cytochrome b-559 appear as they are photooxidised at cryogenic temperatures by Photosystem II. The Signal II species is a donor close to the Photosystem II reaction centre and may represent part of the charge accumulation system of water oxidation. An EPR signal from an iron-sulphur centre which may represent an unidentified component of photosynthetic electron transport is also described.The properties of the oxygen evolving particles show that the preparation is superior to chloroplasts or unfractionated algal membranes for the study of Photosystem II with a functional water oxidation system.     

Effects of Water Stress on Energy Transduction in Chloroplasts

Water stress inhibited the photosynthetic O2 evolution rate of wheat leaves. It was shown that water stress decreased the electron transport rate, the activities of photophosphorylation and, coupling factor, and, the synthesis of ATP in chloroplasts. PS Ⅱ electron transport was more senstitive to water stress than PS Ⅰ. The reduction in photophosphorylation activity might be the results of reduction in electron transport rate and coupling factor activity, as well as the uncoupling effect of water stress on chloroplasts. The uncoupling effect could be due to the inhibition of light induced proton translocation in chloroplasts.     

Structural and functional stability of isolated intact chloroplasts

The effect of in vitro ageing on the ultrastructure, electron transport, thermoluminescence and flash-induced 515 nm absorbance change of isolated intact (type A) chloroplasts compared with non-intact (types B and C) chloroplasts was studied.When stored in the dark for 18 h at 5°C, the structural characteristics of intact and non-intact chloroplasts were only slightly altered. The most conspicuous difference between the two was in the coupling of the electron transport which was tighter and more stable in intact chloroplasts. Under dark-storage the activity of PS 2* decreased and the -20°C peak of thermoluminescence increased at the expense of the emission at +25°C. These changes were less pronounced in the intact chloroplasts. PS 1 activity and the flash-induced 515 nm absorbance change were not affected by dark-storage.When kept in the light (80 W m^-2 (400–700 nm) for 1 h at 5°C), the thylakoid system of chloroplasts rapidly became disorganized. Although the initial activity of electron transport was much higher in intact chloroplasts, after a short period of light-storage the linear electron transport and the electron transport around PS 2 decreased in both types of preparations to the same low level. These changes were accompanied by an overall decrease of the intensity of thermoluminescence. PS 1 was not inhibited by light-storage, while the flash-induced 515 nm absorbance change was virtually abolished both in preparations of intact and non-intact chloroplasts.The data show that in stored chloroplast preparations intactness cannot be estimated reliably either by the FeCy test or by inspection under the electron microscope. These tests should be cross-checked on the level and coupling of the electron transport.     

Photosynthetic reactions of chloroplasts with unusual structures

Photosynthetic reactions of whole leaves and isolated chloroplasts from various mutants of Nicotiana tabacum have been correlated to the lamellar structure seen in electron micrographs of the chloroplasts. In this way it could be established that a fully active photosystem I can be associated with single unfolded thylakoids. The complete photosynthetic electron transport system including the oxygen evolving apparatus of photosystem II, on the other hand, appears to require a close packing of at least 2 thylakoids. The unusual high capacity for photosynthesis observed earlier for leaves of certain aurea mutants is reflected by a correspondingly high activity of the isolated chloroplasts in the Hill reaction. These chloroplasts contain extended areas where 2 thylakoids touch by forming simple lamellar overlappings instead of the familiar stacks of lamellar discs.     

Rates of vectorial proton transport supported by cyclic electron flow during oxygen reduction by illuminated intact chloroplasts

The light-dependent quenching of 9-aminoacridine fluorescence was used to monitor the state of the transthylakoid proton gradient in illuminated intact chloroplasts in the presence or absence of external electron acceptors. The absence of appreciable light-dependent fluorescence quenching under anaerobic conditions indicated inhibition of coupled electron transport in the absence of external electron acceptors. Oxygen relieved this inhibition. However, when DCMU inhibited excessive reduction of the plastoquinone pool in the absence of oxygen, coupled cyclic electron transport supported the formation of a transthylakoid proton gradient even under anaerobiosis. This proton gradient collapsed in the presence of oxygen. Under aerobic conditions, and when KCN inhibited ribulose bisphosphate carboxylase and ascorbate peroxidase, fluorescence quenching indicated the formation of a transthylakoid proton gradient which was larger with oxygen in the Mehler reaction as electron acceptor than with methylviologen at similar rates of linear electron transport. Apparently, cyclic electron transport occured simultaneously with linear electron transport, when oxygen was available as electron acceptor, but not when methylviologen accepted electrons from Photosystem I. The ratio of cyclic to linear electron transport could be increased by low concentrations of DCMU. This shows that even under aerobic conditions cyclic electron transport is limited in isolated intact chloroplasts by excessive reduction of electron carriers. In fact, P₇₀₀ in the reaction center of Photosystem I remained reduced in illuminated isolated chloroplasts under conditions which resulted in extensive oxidation of P₇₀₀ in leaves. This shows that regulation of Photosystem II activity is less effective in isolated chloroplasts than in leaves. Assuming that a Q-cycle supports a H⁺/e ratio of 3 during slow linear electron transport, vectorial proton transport coupled to Photosystem I-dependent cyclic electron flow could be calculated. The highest calculated rate of Photosystem I-dependent proton transport, which was not yet light-saturated, was 330 mol protons (mg chlorophyll h)^–1 in intact chloroplasts. If H⁺/e is not three but two proton transfer is not 330 but 220 mol (mg Chl H)^–1. Differences in the regulation of cyclic electron transport in isolated chloroplasts and in leaves are discussed.     

PnF3H,a flavanone 3-hydroxylase from the Antarctic moss <Emphasis Type="Italic">Pohlia nutans</Emphasis>, confers tolerance to salt stress and ABA treatment in transgenic <Emphasis Type="Italic">Arabidopsis</Emphasis>

In the condition of prolonged drought stress during the reproductive stage, we addressed the photosynthetic performance in flag leaves of the high-yield hybrid rice (Oryza sativa L.) LYPJ. The chlorophyll a fluorescence transient dynamics analysis indicated a timely and constant responsive pattern involving in both PSI and PSII. For PSII functionality, uncoupling of oxygen evolving complex at the donor side and inhibition of electron transport from Q_A to Q_B at the accepter side were both accounted for the decrease of quantum yield of primary photochemistry at early stage (before 21 days after the onset of drought stress). Likewise, increased size of functional antenna may be primarily responsible for early reaction centers inactivation in drought stressed plants, but transformation to non-Q_A-reducing centers for the later. The consequent redundant excitation energy was predominantly eliminated by the increasing thermal dissipation. Advanced accumulation of drought stress (from 21 to 35 days) showed preferential impact on the donor side of PSII and significant loss of RC/CS₀ was induced during this period. In brief, up-regulation of thermal dissipation and possible cyclic electron transport, as well as down-regulation of activated reaction centers and linear electron transport was crucial for rebalance the energy distribution between the two photosystems from deviant stoichiometry resulting from the uncoupling of oxygen evolving complex.     

Photosynthetic Electron Transport,Photophosphorylation, and Antioxidants in Two Ecotypes of Reed (Phragmites Communis Trin.) from Different Habitats

We compared chloroplast photochemical properties and activities of some chloroplast-localised enzymes in two ecotypes of Phragmites communis, swamp reed (SR, C₃-like) and dune reed (DR, C₄-like) plants growing in the desert region of north-west China. Electron transport rates of whole electron transport chain and photosystem (PS) 2 were remarkably lower in DR chloroplasts. However, the electron transport rate for PS1 in DR chloroplasts was more than 90 % of the activity similar in the SR chloroplasts. Activities of Mg²⁺-ATPase and cyclic and non-cyclic photophosphorylations were higher in DR chloroplasts than in the SR ones. The activities of chloroplast superoxide dismutase (SOD) and ascorbate peroxidase (APX), both localised at or near the PS1 complex and serving to scavenge active oxygen around PS1, and the content of ascorbic acid, a special substrate of APX in chloroplast, were all higher in DR chloroplasts. Hence reed, a hydrophytic plant, when subjected to intense selection pressure in dune habitat, elevates its cyclic electron flow around PS1. In consequence, it provides extra ATP required by C₄ photosynthesis. Combined high activities of active oxygen scavenging components in DR chloroplasts might improve protection of photosynthetic apparatus, especially PS1, from the damage of reactive oxygen species. This offers new explanation of photosynthetic performance of plant adaptation to long-term natural drought habitat, which is different from those, subjected to the short-term stress treatment or even to the artificial field drought.     

Cold storage of isolated class C chloroplasts: optimal conditions for stabilization of photosynthetic activities

Preservation of photosynthetic activities (photophosphorylation, electron transport, fluorescence induction, 0.3-second delayed light emission) of isolated broken (class C) chloroplasts by low temperature storage was investigated under a wide range of conditions in order to optimize long time activity retention.The more labile functions (photophosphorylation and electron transport) required very low temperatures (below -79 C) and relatively high (above 20%, v/v) concentrations of cryoprotectives for satisfactory stabilization. Fluorescence induction and delayed light emission were less sensitive, especially during the 1st month of storage.Taking into account the effect of cryoprotectives on absolute activities prior to freezing, optimum activity retention was observed with a medium containing ethylene glycol (30%, v/v) and a storage temperature of -100 C or below. In this case, given fast thawing and high chloroplast concentration, practically 100% preservation of all of the photosynthetic activities investigated was obtained for at least 10 months, even with very simple freezing and storage procedures.The same optimal medium at somewhat higher temperatures (-79 C and to a lesser extent at -41 C) caused a dramatic uncoupling effect: photophosphorylation was inhibited in a few hours, while electron transport increased 3- to 5-fold. The enhanced electron transport was stable for almost a month and then declined sharply. This uncoupling effect was specific only to ethylene glycol.     

Inhibition of photosynthesis and respiration by batatasins

Effects of batatasins I, III and V, phenolic growth inhibitors occuring in dormant bulbils of Dioscorea batatas Decne., on photosynthetic reactions of chloroplasts from spinach (Spinacia oleracea L.) and on respiration of mitochondria from potatoes (Solanum tuberosum L.) were investigated. In chloroplasts, the batatasins effectively inhibited CO₂-dependent oxygen evolution and electron flow from water to acceptors such as dichlorophenolindophenol, ferricyanide and methylviologen. Photosystem-I dependent electron transport from ascorbate to oxygen was stimulated. The proton conductivity of thylakoid membranes was increased and phosphorylation was uncoupled from electron transport. Inhibition of electron transport with water as electron donor appeared to precede uncoupling. In mitochondrial, batatasin I did not much inhibit succinate-dependent O₂ uptake in the absence of ADP, but caused strong inhibition in the presence of ADP. Batatasins III and V inhibited oxygen uptake irrespective of the presence or absence of ADP. Inhibition of chloroplast and mitochondrial reactions by batatasins was shown to be reversible.Abbrevations B-I batatasin I, 6-hydroxy-2,4,7-trimethoxyphenanthrene - B-III batatasin III, 3,3-dihydroxy-5-methoxybibenzyl - B-V batatasin V, 2-hydroxy-3,4,5-trimethoxybibenzyl - Chl chlorophyll - MV methylviologen - DCPIP 2,6-dichlorophenol-indophenol - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PVP polyvinylpyrrolidone     

Influence of photoinhibition on electron transport and photophosphorylation of isolated chloroplasts

The effects of a photoinhibition treatment (PIT) on electron transport and photophosphorylation reactions were measured in chloroplasts isolated from triazine-resistant and susceptible Chenopodium album plants grown under high and low irradiance. Electron transport dependent on photosystem I (PSI) alone was much less affected by PIT than that dependent on both photosystem II (PSII) and PSI. There was a smaller difference in susceptibility to PIT between the photophosphorylation activitity dependent on PSI alone and that dependent on both PSII and PSI. Because in all cases photophosphorylation activity decreased faster upon PIT than the rate of electron transport, we conclude that photoinhibition causes a gradual uncoupling of electron transport with phosphorylation. Since the extent of the light-induced proton gradient across the thylakoid membrane decreased upon PIT, it is suggested that photoinhibiton causes a proton leakiness of the membrane. We have found no significant differences to PIT of the various reactions measured in chloroplasts isolated from triazine-resistant and susceptible plants. We have also not observed any significant differences to PIT of the photophosphorylation reactions in chloroplasts of plants grown under low irradiance, compared with those grown under high irradiance. However, the electron transport reactions in chloroplasts from plants grown under low irradiance appeared to be somewhat less sensitive to PIT than those grown under high irradiance.     

Fatty acid content and the functional state of pea chloroplasts under altered gravity

The results of the study of the fatty acid content and the functional state of chloroplasts isolated from leaves of pea plants grown during 7 and 14 days in the stationary conditions and under clinorotation (2 rpm) are presented. An increase in the unsaturated fatty acid content occurred after 7-day clinorotation while it insignificantly decreased after more prolonged 14-day clinorotation. A study of the functional state of chloroplasts (the rate of electron transport in photosystems II [PSII] and in photosystem I [PSI] and in the whole photosynthetic electron transport chain) showed its decrease under both terms of clinorotation in comparison with control ones. In addition, 14-day clinorotation caused more significant lowering of the electron transport rate, particularly in PSI. Changes in both the fatty acid content and the electron transport rate are discussed in relation to the activation of lipid peroxidation and the increased production of activated oxygen species in chloroplasts under clinorotation.     

Inhibition and uncoupling of photophosphorylation in isolated chloroplasts by organotin, organomercury and diphenyleneiodonium compounds

1. Trialkyltin, triphenyltin and diphenyleneiodonium compounds inhibited ADP-stimulated O(2) evolution by isolated pea chloroplasts in the presence of phosphate or arsenate. Tributyltin and triphenyltin were the most effective inhibitors, which suggests a highly hydrophobic site of action. Phenylmercuric acetate was a poor inhibitor of photophosphorylation, which suggests that thiol groups are not involved. 2. Triethyltin was a potent uncoupler of photophosphorylation by isolated chloroplasts in media containing Cl(-), but had little uncoupling activity when Cl(-) was replaced by NO(3) (-) or SO(4) (2-), which are inactive in the anion-hydroxide exchange. It is suggested that uncoupling by triethyltin is a result of the Cl(-)-OH(-) exchange together with a natural uniport of Cl(-). Tributyltin, triphenyltin and phenylmercuric acetate had low uncoupling activity, probably because in these compounds the uncoupling activity is partially masked by inhibitory effects. 3. At high concentrations the organotin compounds caused inhibition of electron transport uncoupled by carbonyl cyanide m-chlorophenylhydrazone or NH(4)Cl. At these high concentrations the organotin compounds may be producing a detergent-like disorganization of the membrane structure. In contrast, diphenyleneiodonium sulphate inhibited uncoupled electron transport at low concentrations; however, this inhibition is less than the inhibition of photophosphorylation, which suggests that the compound also inhibits the phosphorylation reactions as well as electron transport. 4. The effects of these compounds on basal electron transport were complex and depended on the pH of the reaction media. However, they can be explained on the basis of three actions: inhibition of the phosphorylation reactions, uncoupling and direct inhibition of electron transport. 5. The inhibition of cyclic photophosphorylation in the presence of phenazine methosulphate by diphenyleneiodonium sulphate shows that it inhibits in the region of photosystem 1.     

Trypsin inhibition of electron transport

1. 1. A relaxation spectrophotometer was employed to measure the effects of trypsin treatment on electron transport in both cyclic and non-cyclic chloroplast reactions. The parameters measured were electron flow rate through P700 (flux) and the time constant for dark reduction of P700.

2. 2. In the reduction of methyl viologen by the ascorbate-2,6-dichlorophenol-indophenol (DCIP) donor couple, there was no effect of trypsin on P700 flux or on the time constant for dark reduction of P700. In the phenazine methosulfate (PMS) cyclic system, trypsin had either a slightly stimulatory or slightly inhibitory effect on the P700 flux, depending on the presence or absence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU): either effect being marginal compared to trypsin effects on Photosystem II.With both ferricyanide and methyl viologen reduction from water, trypsin treament gave a first order decline in P700 flux: which matched the trypsin-induced decline in electron transport with the water to DCIP system, measured by dye reduction. This implies that Photosystem II is inhibited. The inhibition of Photosystem II was up to 90% with a 6–10-min trypsin treatment. This result is consistent with the concept of Photosystem I (P700) being in series with Photosystem II in the electron transfer sequence.

3. 3. Cyclic phosphorylation was severely inhibited (85%) by trypsin treatment which had a somewhat stimulatory effect on P700 flux, indicating uncoupling. Non-cyclic phosphorylation was uncoupled as well as electron flow being inhibited since the P/2e ratio decreased more rapidly as a function of trypsin incubation time than inhibition of electron flow. The two effects, uncoupling and non-cyclic electron flow inhibition, are separate actions of trypsin. It is probably that the uncoupling action of trypsin is due to attack on the coupling factor protein, known to be exposed on the outer surface of thylakoids.

4. 4. Trypsin treatment caused an increase in the rate constant, k_d, for the dark H⁺ efflux, resulting in a decreased steady state level of proton accumulation. The increased proton efflux and the inhibition of phosphorylation are consistent with an uncoupling effect on trypsin.

5. 5. Trypsin treatment did not reduce the manganese content of chloroplasts: as reported by others, Tris washing did remove about 30% of the chloroplast manganese.

6. 6. Electron micrographs of both negatively stained and thin-sectioned preparations showed that, under these conditions, trypsin does not cause a general breakdown of chloroplast lamellae. Inhibition by trypsin must therefore result from attacks on a few specific sites.

7. 7. Both System II inhibition and uncoupling occur rapidly when trypsin treatment is carried out in dilute buffer, a condition which leads to thylakoid unstacking, but both are prevented by the presence of 0.3 M sucrose and 0.1 M KCl, a condition that helps maintain stacked thylakoids. Evidently vulnerability to trypsin requires separation of thylakoids.

8. 8. Since trypsin does not appear to disrupt thylakoids nor prevent their normal aggregation in high sucrose-salt medium and since the trypsin molecule is probably impermeable, it is probable that the site(s) of trypsin attack in System II are exposed on the outer thylakoid surface.

Use of uncoupling acridine dyes as stoichiometric energy probes in chloroplasts

In a suspension of spinach chloroplasts the fluorescence of atebrin and other uncoupling acridine dyes is quenched upon energization which is associated with a proportional binding of the dyes to the organelles. There is a stoichiometric relation between the amount of dye bound and the actual steady state level of energy. When the concentration of atebrin is increased in energized chloroplasts the fluorescence is completely quenched until a certain concentration is attained above which the response sharply declines. Such titrations with atebrin were carried out under conditions of partial electron transport governed by photosystems I and II, in the presence of 3-(3,4-dichlorophenyl)-1, 1-dimethylurea and cyanide, respectively, and of complete electron transport governed by the two photo-systems. The sum of the saturating amounts of atebrin obtained in these partial electron flow systems equals that obtained in the complete system. This lends strong support to the view that two sites of energy conservation are coupled to the linear photosynthetic electron transport.     

Oxygen Evolution and Oxygen Uptake by Isolated Chloroplasts of Wheat Irradiated with Monochromatic Light, without the Addition of an Oxidant

The oxygen exchange obtained when isolated chloroplasts of wheat are irradiated, without the addition of a Hill oxidant, has been investigated. Depending on the wavelength, two types of oxygen exchange are obtained. In light absorbed by both photosystems an oxygen gush appears directly upon irradiation. This oxygen evolving reaction is soon replaced by an oxygen uptake which is present until the end of the irradiation period. In light absorbed mainly in photosystem I, no oxygen gush can be observed, instead an oxygen uptake appears directly upon irradiation. An oxygen evolving process can also be observed in irradiations performed with photo-system I light, but this process appears after 10–15 seconds of irradiation. The influence of various external factors on the oxygen gush and the oxygen uptake, e.g. different wavelengths, light intensity, length of the dark periods between irradiations, was studied. The results show that the oxygen evolving reaction appearing upon irradiation with light absorbed by photosystem II and I, reflect the reduction of an oxidant, probably plasto-quinone, in the electron transport chain between the two photosystems. The reoxidation of this oxidant can be brought about after irradiating with light absorbed in photosystem I, or by prolonging the dark period between irradiations, or through some unknown process connected to photosystem II. The oxygen uptake which consists of two components, one appearing directly upon irradiation and the other one appearing after about 10 seconds of irradiation, confirms earlier observations that oxygen can be reduced in photosystem I. The electrons for the oxygen uptake appearing directly upon irradiation, are obtained from the reduced intermediates in the electron transport chain between the two photosystems. The electrons for the other oxygen uptake process are obtained from a reductant in the chloroplasts with access to the carrier chain between the photosystems. Whether the two oxygen uptake reactions reflect two sites of interaction of oxygen with the electron transport chain or only one site is discussed.     

Inhibition of photosynthetic reactions by light

Illumination of isolated intact chloroplasts of Spinacia oleracea L. for 10 min with 850 W m^-2 red light in the absence of substrate levels of bicarbonate caused severe inhibition of subsequently measured photosynthetic activities. The capacity of CO₂-dependent O₂ evolution and of non-cyclic electron transport were impaired to similar degrees. This photoinactivation was prevented by addition of bicarbonate which allowed normal carbon metabolism to proceed during preillumination. Photoinhibition of electron transport was observed likewise upon illumination of intact or broken chloroplasts when efficient electron acceptors were absent. Addition of uncouplers did not influence the extent of inhibition. Studies of partial electron-transport reactions indicated that the activity of both photosystems was affected by light. In addition, the water-oxidation system or its connection to photosystem II seemed to be impaired. Preillumination did not cause uncoupling of photophosphorylation. Chlorophyll-fluorescence data obtained at room temperature and at 77 K are consistent with the view that photosystem-II reaction centers were altered. Addition of superoxide dismutase (EC 1.15.1.1), catalase (EC 1.11.1.6) or 1,4-diazabicyclo(2,2,2)octane to isolated thylakoids prior to preillumination substantially diminished photoinhibition. This result shows that reactive oxygen species were involved in the damage. It is concluded that bright light, which normally does not damage the photosynthetic apparatus, may exert the described destructive effects under conditions that restrict metabolic turnover of photosynthetic energy.Abbreviations Chl chlorophyll - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PSI photosystem I - PSII photosystem II     

Nano-Anatase Relieves the Inhibition of Electron Transport Caused by Linolenic Acid in Chloroplasts of Spinach

Linolenic acid is an inhibitor of electron transport in chloroplasts of higher plants. It has obvious effects on the structure and function of chloroplasts. In the present paper, we investigated the nano-anatase relieving the inhibition of photoreduction activity and oxygen evolution caused by linolenic acid in spinach chloroplasts. The results showed that linolenic acid in various concentrations could obviously reduce the whole chain electron transport and the photoreduction activity of two photosystems, especially on the oxidative reside and reduce reside of photosystem II (PS II). After adding nano-anatase to chloroplasts treated by linolenic acid, the whole chain electron transport rate, the photoreduction activity of two photosystems, and the oxygen evolution rate were increased significantly, indicating that nano-anatase could obviously decrease the inhibition of linolenic acid on the electron transport, photoreduction activity, and oxygen evolution of spinach chloroplasts.     

Inhibition of oxygen evolution in chloroplasts by ferricyanide

Preincubation of chloroplasts from pea leaves (Pisum sativum L. cv. Kelvedon) with 0.5 millimolar ferricyanide in the dark, caused a parallel inhibition of the rate of rise of the variable fluorescence and the rate of electron transport. Both reactions were inhibited to a similar extent by varying the time of preincubation, the concentration of ferricyanide during preincubation, and by raising the concentration of salts in the preincubation medium. Ferricyanide treatment of Tris-washed chloroplasts did not inhibit electron transport from the Photosystem II (PSII) electron donor 1,5-diphenylcarbazide to methylviologen. The inhibition of the variable fluorescence rise and of NADP reduction (caused by ferricyanide pretreatment) was bypassed by addition of the PSII electron donor couple hydroquinone/ascorbate. It was concluded that preincubation of chloroplasts with ferricyanide in the dark inhibited electron transport between water and PSII.