Effects of copper on photosynthetic electron transport systems in spinach chloroplasts

The effects of copper on photosynthetic electron transfer systemsin isolated spinach chloroplasts were studied. Two differentinhibitions were observed. First, copper markedly inhibitedferredoxin-catalyzed reactions such as NADP⁺ photoreduction.The concentration required for 50% inhibition was about 2 µMof cupric sulfate. However, electron flow from reduced 2,6-dichloroindophenol(DCIP) to methyl viologen was not affected. The dissociationconstant between ferredoxin and ferredoxin-NADP⁺ reductase wasunchanged in the presence of 2.5 µM of cupric sulfate.In enzymic reaction systems, the ferredoxin-dependent electronflow from NADPH to cytochrome c was also strongly inhibitedin the presence of cupric sulfate, while DCIP reduction withNADPH as the electron donor was not affected. Second, DCIP photoreductionwas weakly blocked by copper and the lost activity could notbe recovered by adding 1,5-diphenylcarbazide (DPC). It can be concluded that copper directly interacted with ferredoxincausing inhibition of ferredoxin-dependent reactions. Further,copper caused weak inactivation between the oxidizing side ofthe reaction center of photosystem II and the electron donatingsite of DPC. (Received August 8, 1977; )     

The Photochemical Activity of Chloroplasts and Subchloroplast Particles Isolated from Etiolated Bean Leaves Exposed to Continuous Light

The photochemical activity of chloroplasts and subchloroplastparticles isolated from primary bean leaves between the 4thand 24th hour of illumination of etiolated seedlings is thesubject of this paper. The photosystem I activity (oxygen uptakein the presence of MV, DCIP, ascorbate and DCMU), expressedon a unit chlorophyll basis, decreased approximately 10-foldbetween 4 and 8 h of greening. At the same time the photosystemII activity (DCIP photoreduction in the presence of DPC) wasreduced to a half. The photosystem I activity also decreasedin all hitherto investigated fractions which were isolated fromthe digitonin-treated chloroplasts. However, at the initialphase of greening this decrease was the most significant inthe fraction containing heavy particles. After 24 h of greening DCMU, at concentrations higher than 10^–10M, limited the rate of ferricyanide photoreduction by isolatedchloroplasts, whereas after 6 h of greening this effect wasobservable even in the presence of 10^–12 M DCMU. The resultsobtained demonstrated that under those conditions both photosystemswere active after 4 h of greening and PS I activity developedmore rapidly than that of PS II. It also follows from the presenteddata that the water splitting reactions were delayed in developmentas compared to the other reactions investigated, and that PSII units may limit the electron flow in chloroplasts at earlierstages of leaf greening.     

Formation of singlet molecular oxygen in illuminated chloroplasts. Effects on photoinactivation and lipid peroxidation

The formation of singlet molecular oxygen (¹O₂) in illuminatedchloroplasts and the effects of ¹O₂ on oxidation or destructionof components and functional integrity of chloroplasts werestudied. The rate of photoreduction of 2,6-dichloroindophenol(DCIP) and the extent of the 515-nm absorbance change were decreasedby light irradiation and by xanthine oxidase treatment. Malondialdehyde(MDA) formation, an indicator of lipid peroxidation, was observedin the light-irradiated chloroplast fragments, but not in thexanthine-xanthine oxidase-treated chloroplast fragments. MDAformation was absent under anaerobic conditions. MDA formation was stimulated when electron transfer on the oxidizingside of photosystem II (or I) was inhibited or inactivated bycarbonylcyanide m-chlorophenylhydrazone (CCCP), Tris-treatment,prolonged illumination, etc. MDA formation was also stimulatedby 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU) when electrontransfer between water and the reaction center of photosystemII was intact. CCCPor DCMU-stimulated MDA formation was inhibitedby 1,4-diazabicyclo[2.2.2]octane, a quencher of singlet molecularoxygen (¹O₂). DCMU and electron donors for photosystem II, suchas ascorbate, hydroquinone and semicarbazide, inhibited MDAformation by illumination of the Tris-washed or CCCP-poisonedchloroplast fragments. Reduced DCIP, an electron donor for photosystemI, also inhibited MDA formation in the presence of DCMU. These results lead to the conclusion that MDA formation wasinitiated by ¹O₂ formed in illuminated chloroplasts. Of thethree mechanisms discussed for ¹O₂ generation in illuminatedchloroplasts, the formation by the electron transfer reactionbetween superoxide anion radical and the oxidant formed on theoxidizing side of photosystem II (or I) is mostimportant. (Received March 31, 1975; )     

Studies on cytochromes in photosynthetic electron transport system I. photoreduction and photo-oxidation of cytochrome b559 by photosystem II in spinach chloroplasts

Light-induced redox-reactions of cytochrome b₅₅₉ in spinachchloroplasts were investigated. Illumination of chloroplastsinduced photoreduction of cytochrorne b₅₅₉ Red light (650 nm)was more effective than far-red light (725 nm), indicating thatthe photoreduction is a photosystem II-mediated reaction. Onaddition of DCMU, the photoreduction was eliminated and a photooxidationof cytochrome b₅₅₉ was observed. The rate of this photooxidationwas faster with photosystem II light than with photo-systemI light. On addition of Mn⁺⁺ the photooxidation was partly suppressed;far-red light became as effective as red light in inducing photooxidationof cytochrome b₅₉₉, in the presence of DCMU and Mn⁺⁺. Ascorbate completely suppressed photooxidation of cytochromeb⁵⁵⁹ In the presence of ascorbate, however, photooxidation wasobserved in the presence of inhibitors or after inhibitory treatmentsof chloroplasts which affected the oxidizing side of systemII. These inhibitors and inhibitory treatments, but not DCMU,decreased the redoxpotential of cytochrome b₅₅₉. Reactivationof Hill reaction in Tris-washed chloroplasts by indophenol-ascorbatetreatment was not accompanied by an abolishment of photooxidationof cytochrome b₅₅₉. A possible mechanism is proposed to account for these reactionsof cytochrome b₅₅₉ in the photosynthetic electron transportin chloroplasts. (Received April 4, 1972; )     

Light-induced chemiluminescence of luminol in spinach chloroplast fragments: Reaction of O2- with electron transfer components

Chemiluminescence of luminol (CLL) was induced by illuminatedspinach chloroplast fragments. CLL was diminished by superoxidedismutase or under anaerobic conditions and increased by anautoxidizable electron acceptor, methyl viologen. The optimumpH for CLL was 10.0-10.5. Ferredoxin and cytochrome c reducing substance (CRS) did notaffect the intensity of CLL, but accelerated the dark decayin the absence of methyl viologen. In the presence of methylviologen, ferredoxin and CRS lowered the intensity and acceleratedthe dark decay. 3-(4-Chlorophenyl)-1,1-dimethylurea diminishedCLL. Carbonylcyanide m-chlorophenylhydrazone accelerated theinitial rate of CLL increase at low concentration and inhibitedit at high concentration. Half-decay time of CLL after the cessationof light was shortened by inhibiting electron transfer on theoxidizing side of photosystem II. We conclude that most of the CLL observed in illuminated chloroplastsis dependent on O₂^–. The results also suggest that O₂^–is reduced by reduced ferredoxin or CRS and oxidized on theoxidizing side of photosystem II. The half life of O₂^–in illuminated chloroplasts was estimated from the half-decaytime of CLL to be a few sec. ¹ Present address: Kyushu Dental College, Department of Biology,Kitakyushu 803, Japan. (Received May 30, 1977; )     

Discrimination and characterization of photosystem I- and photosystem II-induced 515-nm absorbance change in chloroplasts I. Dissipation of electric field and related processes

Distinctive characteristics of the photosystem I-induced 515-nmabsorbance change and the photosystem II-induced change wereanalyzed in spinach chloroplasts in the absence of added salt.Two types of changes were distinguished by 3-(3,4-dichloro-phenyl)-1,1-dimethylurea(DCMU), carbonylcyanide m-chlorophenylhydrazone (CCCP) and illuminationwith red or far-red light. Half-recovery time of the photosystem I-induced absorbance changewas shorter than that of over-all absorbance change and wasinsensitive to a low concentration (<0.50 µM) of CCCP. In the presence of DCMU, the 515-nm absorbance change decayedin parallel with the rapid protonation of reduced 2,6-dichloroindophenol(DCIP) or methyl viologen. This indicates that the photosystemI-induced local field is dissipated in the electron transferfrom photosystem I to an electron acceptor. Thus the mechanismin dissipation of electric field formed by photosystem I isdifferent from that induced by photosystem II where rapid protonationof plastosemiquinone anion may be directly involved in fielddissipation (Yamamoto, Y. and M. Nishimura: Plant & CellPhysiol. 18: 293–301 (1977)). (Received December 9, 1977; )     

Effects of Leaf Chilling on Thylakoid Functions, Measured at Room Temperature, in Cucumis sativus L. and Oryza sativa L.

Photosynthetic functions in leaves of cucumber (Cucumis sativusL.) and rice (Oryza sativa L.) were examined before and aftervarious chilling treatments. Cucumber leaves lost the capacityfor the photosynthetic oxygen evolution after chilling at 0°Cin the dark for 48 h. Thyla-koids isolated from such leaveswere not able to reduce dichloroindophenol (DCIP), but the additionof diphenylcarbazide (DPC), an electron donor to PS II, restoredthe ability to reduce DCIP, indicating that the site of damageis in the water-splitting machinery of PS II. In moderate light (500 jumol quanta m^–2s^–1), chillingof cucumber leaves at 5°C for 5 h was sufficient to inducethe complete loss of the capacity for photosynthetic oxygenevolution. Electron transport rates measured in thylakoids wereunaltered, but thylakoids were totally permeable to protons.Since the addition of dicyclohexylcarbodiimide (DCCD) restoredcoupling and the capacity for proton uptake, the primary siteof damage was deduced to be in the ATPase. In rice, both chilling treatments had barely any effect on thylakoidfunctions, although some negative effects was apparent in photosynthesisin leaves. ¹Present address: Department of Botany, Faculty of Science,University of Tokyo, Hongo, Bunkyo-ku, Tokyo, 113 Japan. ²Present address: Department of Botany, Duke University, Durham,NC 27706, U.S.A. (Received January 11, 1989; Accepted June 12, 1989)     

The light-induced oxidation-reduction reaction of cytochrome b-559 in membrane fragments of the blue-green alga Anabaena variabilis

Light-induced oxidation-reduction reactions of cytochrome b-559were investigated with membrane fragments of Anabaena variabilisand supplementarily with Plectonema boryanum. The oxidation-reduction reactions of cytochrome b-559 observedwith membrane fragments were similar in their kinetics to thoseof the cytochrome in aged chloroplasts. The reactions were annihilatedby the addition of Ferro, indicating that the cytochrome ofhigh redox potential (E'_o=+373 mV, pH 6.5) was photoreducedand oxidized. Titration with reducing agents indicated that cytochrome b-559is contained in Anabaena membrane fragments in an amount 1.5times as much as the content of P700 on a molar basis; the contentof the species of high redox potential was estimated to be around70%. Kinetic treatment of the photoreduction indicated that the cytochromewas reduced at some site of the electron transport system betweenthe two photosystems. The photo-oxidation depended on the actionof either photosystem II or I even in the presence of DCMU,indicating that the photooxidation was induced by both photosystems.The oxidation by photosystem I action was inhibited by HgCl₂-treatment,indicating that this reaction is mediated by plastocyanin. EDTA (5?10^-3 M) suppressed the cytochrome photoreduction andenhanced the rapid phase of the photooxidation. The latter effectappeared only when an appropriate dark time (3 min) was insertedafter the cytochrome photoreduction. The phenomenon was interpretedas showing that EDTA modifies the reactivity of the electroncarrier which directly donates electrons to cytochrome b-559.The oxidation, and probably also the reduction of cytochromeb-559, was assumed to be regulated by the oxidation-reductionstate of this carrier. (Received April 26, 1974; )     

Specific inhibition of photosystem II activity in chloroplasts by fumigation of spinach leaves with SO2

The phytotoxic effects of sulfur dioxide (SO₂) were investigatedby fumigating spinach plants with SO₂. Inhibition of 2,6-dichloroindophenol(DCIP) photoreduction was observed in spinach chloroplasts isolatedfrom fumigated leaves. NADP and DCIP photoreductions were inhibitedto a similar extent by fumigation with 2.0 ppm SO₂ but electronflow from reduced DCIP to NADP was not affected. When electronflow from H₂O to NADP was inhibited by 36%, a 39% inhibitionof non-cyclic photophosphorylation was observed. However, phenazinemethosulfate(PMS)-catalyzed cyclic photophosphorylation wasas active as in the control chloroplasts. Moreover, in the presenceof PMS, no significant suppression was observed in the extentof light-induced H⁺ uptake or in the rate of H⁺ efflux in chloroplasts.From these results, it can be concluded that SO₂ inhibits theelectron flow driven by photosystem II when plants have beenfumigated with SO₂. In spinach leaves fumigated with SO₂, the rate of photosyntheticO₂ evolution was reduced under light-limited conditions, whilethe rate of respiratory O₂ uptake changed slightly. (Received February 8, 1979; )     

Light-induced changes in chlorophyll a fluorescence and cytochrome f in intact spinach chloroplasts: The site of light-dependent regulation of electron transport

Dark-adapted intact spinach chloroplasts exhibited two peaks,P and M₁, at the early phase of fluorescence induction and atransient reduction of cytochrome f shortly after its initialphotooxidation and in parallel to the appearance of P. Analysisof the peak P and the transient reduction of cytochrome f indicatedthat electron transport in intact spinach chloroplasts was regulatedby light: electron transport was inactivated at the reducingside of photosystem I in the dark-adapted chloroplasts but rapidlyreactivated by illumination. The fluorescence peak M₁ was correlatedto the proton gradient formed across the thylakoid membrane. Effects on P and transient reduction of cytochromef of NO₂^–,3-phosphoglycerate (PGA) and oxalacetate (OAA), which can penetrateinto intact chloroplasts and accept electrons at different sitesafter photosystem I, were studied to determine the site of thelight regulation. NC₂^–, which receives electrons fromreduced ferredoxin, markedly diminished both P and the transientreduction of cytochrome.f, whereas PGA and OAA, the reductionsof which are NADP-dependent, failed to affect the two transients.The ineffectiveness of PGA and OAA could not be attributed tothe dark inactivation of glyceraldehyde-3-phosphate and malicdehydrogenases, because dark-adapted chloroplasts still retainedsufficiently high levels of the enzyme activities. The resultsindicate that electron transport in intact spinach chloroplastsis regulated by light after ferredoxin but before NADP, i.e.,at the reducing terminal of the electron transport chain. (Received May 29, 1980; )     

Light-induced Changes of the Electrical Potential in Chloroplasts Associated with the Activity of Photosystem I and Photosystem II

The electric potential changes induced by flashing and continuouslight were measured with microcapillary electrodes in isolatedwhole chloroplasts of Peperomia inetallica. In continuous lightthe chloroplast electrical potential rose in two phases. Theinitial rapid phase coincided in extent with the flash-inducedpotential and was insensitive to the electron transfer inhibitorDBMIB. The subsequent phase was relatively slow (20–30ms) and was inhibited by DBMIB. Electron acceptors of photosystemII (p-phenylendiamine, p-benzoquinone) added to DBMIB-treatedchloroplasts produced a suppression of the flash-induced responseand a considerable increase in the steady level of the potentialin the light. The electrical potential associated with the activityof photosystem II rose in continuous light much more slowlythan that associated with the activity of photosystem I aloneor the activities of both photosystems. Illumination of chloroplastswith successive flashes at a repetition rate 5 Hz in the presenceof oxaloacetate, a terminal acceptor of photosystem I, was accompaniedwith a gradual decline of the flash-induced potential. The specificrole of two photosystems in the light-induced H⁺ transport andthe electrogenesis across the chloroplast thylakoid membranesis discussed.     

Inhibition of the Chloroplast Photochemical Reactions by Treatment of Wheat Seedlings with Low Concentrations of Cadmium: Analysis of Electron Transport Activities and Changes in Fluorescence Yield

The effect of treatment of wheat plants with Cd²⁺ ions on thephotochemical activity of the primary leaves was examined. Threeday-old etiolated seedlings were treated with Cd²⁺ ions for24 h in dark, and after this treatment the plants were grownin the light until the primary leaves were fully developed.Cd²⁺ ions (30–120 µM) induced a significant decreasein activities of both photosystem II and photosystem I. Theextent of the decrease in PS II activity was much greater thanthat in the PS I activity. Analysis of changes in the fluorescenceyield of chlorophyll also indicated that Cd²⁺ ions drasticallyaffect the photochemistry of photosystem II. Cd²⁺ ions induceddecrease in the rates of photoreduction of 2,6-dichlorophenolindophenol even in the presence of the exogenous electron donor,hydroxylamine, both in Tris-treated and untreated chloroplasts.This result suggests that the site of inhibition is near thesite of donation of electrons by hydroxylamine. Treatment withCd²⁺ ions impairs the electron transport system on the reducingside of PS II. The decrease in the fluorescence yield of Chi is less than that in the evolution of O₂ mediated by oxidizedphenylenediamine. This difference may be a result of inhibitionon the reducing side of PS II. In addition to inhibition onthe reducing side, Cd²⁺ ions may affect the oxidizing side ofPS II. A comparative study of the rates of evolution of O₂ withp-benzoquinone and dichloro-p-benzoquinone as electron acceptorswas performed since the halogenated benzoquinones have beenshown to accept electrons from both active and inactive centersof photosystem II while some of the benzoquinones accept electronsonly from active centers. The results suggest that Cd²⁺ ionsinduced a marginal increase in the number of inactive reactioncenters in PS II. Analysis of light-saturation-kinetics of theevolution of O₂ catalysed by PS II indicates a reduction inthe size of the antennae as well as in the concentration ofthe active (-type) reaction centers of PS II. Thus, the Cd²⁺-inducedeffects on the photochemistry of PS II involve changes on thereducing side of PS II as well as possible changes in the sizesof the populations of active and inactive centers. Thus, short-termexposure to Cd²⁺ ions during establishment of seedlings hasa severely detrimental effect on photochemical activities inchloroplasts. (Received October 17, 1990; Accepted July 3, 1991)     

Inhibition of Photosystem II in the Green Alga Ankistrodesmus falcatus by Copper

Copper strongly inhibited 2,6-dichloroindophenol (DCIP) photoreduction in the broken cells of the green alga Ankistrodesmus falcatus (C303), and the activity lost could not be restored by adding 1,5-diphenylearbazide (DPC). Inactivation of the DCIP Hill reaction reached 45% after incubation with 10 μM cupric sulfate for 20 min. In the same time, copper (13 μg/mg chlorophyll) was bound to the broken cells. Addition of 10 mM KCl reduced copper binding by about 53%. Fluorescence intensity at room temperature decreased upon addition of cupric sulfate and was partially restored by adding 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), These results suggest that copper inactivates electron transport between the oxidizing side of the reaction center of photosystem II and the electron-donating site of DPC. Further, the effect of light intensity shows that copper mostly affected the reaction rate of the dark step and had less inhibitory effect on the quantum efficiency of the primary reaction of electron transport in photosystem II.     

Sites of electron donation by alkylhydroquinones in the electron transport chain of spinach chloroplasts

Alkyl derivatives of p-hydroquinones were examined as electrondonors for the electron transport chain in spinach chloroplasts.Hydrophobic hydroquinones with long side chains donate relativelymore electrons to photosystem 1, while hydrophilic hydroquinoneand methylhydroquinone donate electrons specifically to photosystem2. ¹On leave; Research Laboratories, Fuji Photo Film Co., Ltd.,Asaka, Saitama. (Received March 2, 1973; )     

Requirements for the light-stimulated degradation of stromal proteins in isolated pea (Pisum sativum L.) chloroplasts

Chloroplasts from 17-d-old pea leaves (Pisum sativum L.) wereisolated to elucidate the requirements for the light-induceddegradation of stromal proteins. The influence of electron transportthrough the thylakoids and the influence of ATP on protein degradationwere investigated. When chloroplasts were incubated in the light(45 µmol m^–2s^–1), glutamine synthetase, thelarge subunit of ribulose-1,5-bisphosphate carboxylase and glutamatesynthase were degraded, whereas phosphoribulokinase, ferredoxin-NADP⁺reductase and the 33 kDa protein of photosystem II remainedmore stable. Major protein degradation was not observed over240 mm in darkness. The electron transport inhibitor dichlorophenyldimethylureareduced protein degradation in the light over several hours,whereas dibromothymoquinone was less effective. Inhibiting theproduction of ATP with tentoxin or by destroying the     

The Effect of Cadmium on Photosystem II in Spinach Chloroplasts

Cadmium ions, as an environmental pollution factor, significantly inhibited the photosynthesis especially, photosystem Ⅱ activity in isolated spinach chloroplasts. The presence of 5 mmol/l Cd2+ inhibited the O2-evolution to 53%. Cd2+ reduced the activity of photoreduction of DCIP and the variable fluorescence of chloroplasts and PSⅡ preparation. The inhibited DCIP photoreduction activity could only be restored slightly by the addition of an artificial electron donor of PSII, DPC, and the inhibited variable fluorescence could not be obviously recovered by the addition of NH2OH, another artificial electron donor of PSⅡ. It is considered that, besides the oxidizing side of PSI1, Cd2+ could also inhibit directly the PSⅡ reaction center. The inhibitory effect of Cd2+ on the whole chain electron transport (H2O→MV) was more serious than on O2-evolution (H2O→DCMU). It is suggested that the oxidizing side of PSⅡ is not the only site for Cd2+ action. There may be another site inhibited by Cd2+ in the electron transport chain between PSⅠ and PSⅡ.     

Rates of Photosynthesis in Characean Cells: I. PHOTOSYNTHETIC 14CO2 FIXATION BY NITELLA TRANSLUCENS

A study has been made of photosynthetic ¹⁴CO₂ fixation by isolated‘mature’ internodes of Nitella translucens. Experimentalconditions were similar to those used in studies of the ionicrelations of these cells. Maximum rates of photosynthesis were33–40µµmoles CO₂, fixed per cm² of surfacearea per second (equivalent to 12–15 /xmoles fixed permg chlorophyll per hour). ^l4CO₂ fixation was inhibited to thedark level by 3(3,4,dichlorophenyl)-1, 1-dimethylurea (at 0-6µM or 10µM) and by the uncoupler carbonyl cyanide-m-chlorophenylhydrazone(SµM). The presence of imidazole or ammonium sulphate(both of which uncouple ATP production in vitro) did not resultin an inhibition of 14CO2 fixation. These results are discussedin relation to published work on solute uptake by Nitella translucens.During photosynthesis there was rapid movement of ¹⁴C-labelledorganic compounds out of the chloroplasts. ¹⁴C-labelled sucrose,ammo-acids, and sugar phosphates were found in samples of vacuolarsap.     

Disproportionation of 1,5-diphenylcarbazone. A new reaction catalysed by Photosystem I

1. 1,5-Diphenylcarbazide (DPC) was shown to compete with water as an electron donor to photosystem II in untreated chloroplasts.     

Alteration in the acceptor side of photosystem II of chloroplast by high light

The effect of high light on the acceptor side of photosystem II of chloroplasts and core particles of spinach was studied. BothV _max and apparentK _m for DCIP were altered in photoinhibited photosystem II core particles. The double reciprocal plot analysis as a function of actinic light showed increased slope in chloroplasts photoinhibited in the presence of DCMU. Exposure of chloroplasts to high light in the presence of DCMU did not protect the chloroplast against high light induced decrease in F_m, level. Further the high light stress induced decrease inF _m level was not restored by the addition of DCMU. These results suggest that the high light stress induced damage to chloroplast involves alteration in the binding site forQ _B on the DI protein on the acceptor side of photosystem II     

Inhibition of photosynthetic electron transfer by amphotericin B

The polyene antibiotic amphotericin B inhibits photosynthetic electron transfer by Class II maize mesophyll chloroplasts, from water to FeCN, DCIP and diquat but not to plastocyanin. Photosystem 1 activity is also inhibited by amphotericin B, but ferredoxin-NADP reductase activity is not affected. The activity of all the photosynthetic electron transfer systems inhibited by amphotericin B can be restored by the addition of carrier amounts of plastocyanin. The results suggest that amphotericin B inhibits photosynthetic electron transfer by acting only at the plastocyanin site in the chain, and that the primary site of reduction of FeCN and DCIP from water by Class II chloroplasts lies on the reducing side of photosystem 1.