Photoreduction of 18O2 and H218O2 with Concomitant Evolution of 16O2 in Intact Spinach Chloroplasts: Evidence for Scavenging of Hydrogen Peroxide by Peroxidase

Illuminated intact spinach chloroplasts decomposed one moleculeof H₂¹⁸O₂ which resulted in the evolution of a half moleculeof ¹⁶O₂, but little ¹⁸O₂. The chloroplasts showed the same rateof photoreduction of ¹⁸C₂ as that of the evolution of ¹⁶O₂ withoutaccumulation of H₂¹⁸O₂. These reactions were suppressed by DCMU,and also by several inhibitors of ascorbate peroxidase and dehydroascorbateand monodehydroascorbate reductases in chloroplasts. These observationsindicate that the hydrogen peroxide produced in chloroplastsis reduced to water by a peroxidase using a photoreductant asthe electron donor. The hydrogen peroxide scavenging systemof chloroplasts was inactivated if hydrogen peroxide was addedin the dark, but not if added during the light. (Received May 4, 1984; Accepted July 10, 1984)     

Light-enhanced carbon dioxide fixation in isolated chloroplasts

Preillumination of leaves of spinach, soybean and maize in theabsence of CO₂ greatly enhanced the capacity for fixing CO₂in an immediately following dark period. Lightenhanced darkCO₂-fixation was further observed in isolated chloroplasts ofspinach and soybean. When isolated chloroplasts were illuminated,CO₂-fixing capacity in the subsequent dark period increasedrapidly at first and later more slowly attaining a stationaryvalue in about 20 min. When the light was turned off at thisstage, the capacity decreased very rapidly becoming zero inabout 10 min. The magnitude of the enhanced dark fixation andits decay in the dark were not influenced by the presence orabsence of atmospheric oxygen. In both leaves and isolated chloroplasts,no significant change in oxygen (21%) occurred in distributionpatterns of radioactivity in products fixed by photosynthetic,or light-enhanced, dark, ¹⁴CO₂-fixation. In preilluminated leaves¹⁴C was incorporated into sucrose in the subsequent dark period,indicating that the photosynthetic carbon reduction cycle isoperating in light-enhanced dark fixation in higher plants. ¹Present address: Noda Institute for Scientific Research, Noda,Chiba Prefecture (Received August 10, 1970; )     

Fatty acid synthesis by spinach chloroplasts I. Property of fatty acid synthesis from acetate

Intact chloroplasts (about 70% Class I chloroplasts) isolatedfrom spinach leaves incorporated 150 nmoles of [1-¹⁴C] acetateinto fatty acids per mg chlorophyll in 1 hr at pH 8.3, 25°Cand 25,000 lux. On electron and phase-contrast microscopiescombined with hypotonic treatment of chloroplasts, this syntheticactivity was shown to be proportional to the percentage of ClassI chloroplasts in the preparation. Light was necessary for thesynthesis, the activity in the complete reaction mixture inthe dark being only 2% of that in the light. The synthetic activityincreased with increasing intensities of light to reach saturationat 6,000 lux. CoA and ATP were most effective as cofactors,HCO₃^–, HPO₄^2–, Mg^2$ and Mn^2$ were less effective.ATP could be replaced by ADP in the presence of Pi, suggestingpossible supply of ATP by photophosphorylation. Omission ofthe NADPH-generation system and NADH did not affect the synthesis,indicating sufficient provision of endogenous NADPH and NADHin intact chloroplasts under light. Addition of DTE did notcause recovery of the synthetic activity of intact chloroplastsin the dark. ¹ Present address: Radioisotope Centre, University of Tokyo,Yayoi, Bunkyo, Tokyo 113, Japan. (Received August 26, 1974; )     

Studies on frost hardiness in Chlorella ellipsoidea III. Changes in O2 uptake and evolution during hardening and after freeze-thawing

Chlorella ellipsoidea cells at an intermediate stage in theripening phase of the cell cycle were hardened at 3?C. Oligomycin(OGM) and 3-(3,4-dichiorophenyl)-1,1-dimethylurea (DCMU) addedduring hardening in the light inhibited the development of frosthardiness, suggesting that mitochondria and chloroplasts wereinvolved in the hardening process. The O₂-uptake activity in unhardened cells increased duringhardening in the light while the O²-evolution activity decreased,when these activities were measured at 25?C. The increase inO₂ uptake was suppressed by OGM and DCMU and the decrease inO₂ evolution was stimulated by OGM. While the algal hardinessin the dark was very limited, the addition of glucose duringhardening in the dark caused a remarkable development of frosthardiness. These results suggest that mitochondria and chloroplastsclosely interact at low temperature, and the former plays aprincipal role in the hardening process and the latter servesas substrate-donor in the light. The O₂ evolution in cells which survived freezing was remarkablydecreased by freeze-thawing while the O₂ uptake was hardly affected.The freeze-injured chloroplasts were repaired during the followingincubation. OGM inhibited the repair of freeze-injured chloroplasts.From the results, mitochondria seem to change their membranesinto a structure hardier than chloroplasts, and ATP synthesizedby mitochondria seems to be essential for the repair of freeze-injuredchloroplasts. ¹ Present address: Department of Public Health, Faculty of Medicine,Kyushu University, Maidashi 3-1-1, Higashiku, Fukuoka 812, Japan. (Received November 9, 1977; )     

Reappraisal of the Role of Sodium in the Light-Dependent Active Transport of Pyruvate into Mesophyll Chloroplasts of C4 Plants

The mechanism of light-dependent active transport of pyruvatein C₄ mesophyll chloroplasts has not been clarified, particularlyin Na⁺-type C₄ species, in which the pyruvate uptake into mesophyllchloroplasts is enhanced by illumination or by making a Na⁺gradient (Na⁺-jump) across the envelope in the dark. We re-investigatedhere the effect of Na⁺ on the active transport of pyruvate inmesophyll chloroplasts of Panicum miliaceum, a Na⁺-type C₄ species,by comparing the rate of pyruvate uptake at various externalpHs under four conditions; in the light and dark together with/withoutNa⁺-jump: (1) At neutral pH, the rate of pyruvate uptake inthe dark was enhanced by Na⁺-jump but scarcely by illumination.(2) While the enhancement effect by Na⁺-jump was independentof external pH, that by illumination increased greatly at pHover 7.4, and the effects of light and Na⁺ at the alkaline pHwere synergistic. (3) The light-enhanced pyruvate uptake wasrelated to stromal alkalization induced by illumination. Infact, pyruvate uptake was induced by H⁺-jump in the medium frompH 8.0 to 6.7. (4) Stromal pH was lowered by the addition ofK⁺-pyruvate and more by Na⁺-pyruvate into the medium at pH 7.8in the light. (5) However, the pH and ATP levels in the stromawere not affected by Na⁺-jump. Thus, we discussed possibility that besides pyruvate/Na⁺ cotransportat neutral pH in the medium, pyruvate/H⁺ cotransport enhancedby the presence of Na+ operates in mesophyll chloroplasts ofNa⁺-type C4 species at alkaline medium. ¹Present address: Biological Resources Division, Japan InternationalResearch Center for Agricultural Sciences (JIRCAS), Ministryof Agriculture, Forestry and Fisheries, 2-1 Ohwashi, Tsukuba,305 Japan     

Induction of Light Dependent Pyruvate Transport into Chloroplasts of Mesembryanthemum crystallinum by Salt Stress

Mode of photosynthesis in Mesembryanthemum crystallinum changesfrom C₃ to Crassulacean acid metabolism (CAM) when the plantswere stressed with high salinity. [¹⁴C]Pyruvate uptake for 30s into intact chloroplasts isolated from leaves of the CAM modeof M. crystallinum was enhanced more than 5-fold in the lightcompared with that in the dark. The stromal concentration ofpyruvate in the light reached to more than 2.5 times of themedium. In contrast, little or no pyruvate uptake occurred inchloroplasts from C₃ leaves in either light or dark condition.The initial uptake rate (10 s incubation at 4°C) into theCAM chloroplasts in the light was about 3-fold higher than therate in the dark. K_m and V_max of the initial uptake in the lightwere 0.54 mM and 8.5 µmol (mg Chl)^–1 h^–1 respectively.These suggest that pyruvate was actively incorporated into theCAM chloroplasts against its concentration gradient across theenvelope in the light. When hydroponically grown M. crystallinumwere stressed by 350 mM NaCl, the capacity of chloroplasts forpyruvate uptake was induced in 6 d corresponding to the inductionof the activities of PEP-carboxylase and NAD(P)⁺-malic enzymesin response to salt stress. (Received October 12, 1995; Accepted January 19, 1996)     

Manganese binding to sodium cyanide-treated chloroplasts: Effects of light and redox-potentials on the binding

Mn²⁺-binding to Mn-depleted chloroplasts by the treatment withcyanide was inhibited by light. Quantitative study indicatesthat only the binding with a high affinity constant was inhibitedby light. This photoinhibition required electron transport activityand disappeared on addition of 2,6-dichlorophenolindophenol.The binding of Mn²⁺ was also inhibited by addition of reductantin the dark. The high affinity binding at various redox potentialsindicates the participation of a two electrons-transfer componenthaving a midpoint potential of 336 mV. Mn²⁺-binding was decreasedon treatment of chloroplasts with proteolytic enzyme in thedark but not in the light. We propose that the high affinitybinding site is concealed in the membrane matrix of chloroplastsat low oxidation-reduction potential. (Received December 14, 1976; )     

Effects of ethanol on the interaction of photosynthetic processes in spinach chloroplasts

The interaction and coupling between photosynthetic processeswere studied in ethanol-treated chloroplasts (in the absenceof ethanol) or in the presence of ethanol. Light-induced H⁺uptake and photophosphorylation were suppressed and electrontransfer was enhanced by ethanol treatment or in the presenceof ethanol (10–25%). Dark recoveries of the H⁺ uptakeand the 515-nm absorbance change were accelerated by ethanol.The half-effective concentrations of ethanol for these processeswere higher in the ethanol-treated chloroplasts than when ethanolwas present in the reaction mixture. The maximum rate of electrontransfer in the ethanol-treated chloroplasts, which was at thesame level as that of the control with an uncoupler, was notaffected by uncouplers. The marked acceleration of recoveryof the 515-nm absorbance change by SCN- or valinomycin plusK⁺ in the untreated chloroplasts was much smaller in the ethanol-treatedchloroplasts or in the presence of ethanol. The ethanol-treatedpreparation had the same characteristics as those of the control,in chlorophyll fluorescence, light-intensity dependence of electrontransfer (compared with the control with an uncoupler), andsensitivity to sucrose osmolarity except for a slight increaseof the packed volume. Under the present conditions, the ethanoltreatment mainly induced an increase of permeability of thylakoidmembranes to ions. In chloroplasts treated with ethanol at various concentrations,the relationships of the uncoupler-stimulated part of electrontransfer with the dark half-recovery time of H⁺ uptake and withphotophosphorylation were linear. Logarithms of the photophosphorylationand the extent of H⁺ uptake had a linear relationship with aslope of about 3. This slope may indicate the stoichiometryof H⁺/ATP. (Received June 17, 1978; )     

Pyruvate Uptake by Mesophyll and Bundle Sheath Chloroplasts of a C4 Plant, Panicum miliaceum L.

Intact chloroplasts were isolated from mesophyll and bundlesheath protoplasts of a C₄ plant, Panicum miliaceum L., to measurethe uptake of [1-¹⁴C]pyruvate into their sorbitol-impermeablespaces at 4?C by the silicone oil filtering centrifugation method.When incubated in the dark, both chloroplasts showed similarslow kinetics of pyruvate uptake, and the equilibrium internalconcentrations were almost equal to the external levels. Whenincubated in the light, only mesophyll chloroplasts showed remarkableenhancement of the uptake, the internal concentration reaching10–30 times of the external level after 5 min incubation.The initial uptake rate of the mesophyll chloroplasts was enhancedabout ten fold by light and was saturated with increasing pyruvateconcentration; K_m and V_max were 0.2–0.4 mM and 20–40µmol(mg Chl)^–1 h^–1, respectively. The lightenhancement was abolished by DCMU and uncoupling reagents suchas carbonylcyanide-m-chlorophenylhydrazone and nigericin. Theseresults indicate the existence of a light-dependent pyruvatetransport system in the envelope of mesophyll chloroplasts ofP. miliaceum. The uptake activity of mesophyll chloroplastsboth in the light and the dark was inhibited by sulfhydryl reagentssuch as mersalyl and p-chloromercuriphenylsulfonate, but thebundle sheath activity was insensitive to the reagents. Thesefindings are further evidence for the differentiation of mesophylland bundle sheath chloroplasts of a C₄ plant with respect tometabolite transport. (Received July 3, 1986; Accepted October 8, 1986)     

Photosynthetic Characteristics of Chloroplasts Isolated from Euglena gracilis Z Grown Photoautotrophically

Photosynthetically competent chloroplasts were isolated fromcells of Euglena gracilis Z grown photoautotrophically in 1.5%CO₂. The isolated chloroplasts were intact and substantiallyfree from cytosolic, mitochondrial and microbody materials.The effects of some compounds on the activity of photosynthetic¹⁴CO₂ fixation were examined. The optimal pH and sorbitol concentrationwere 8.0 and 0.33 M, respectively. The chloroplasts requireda high level of P, (5 to 20 mM) for the maximal rate of photosynthesis.They were insusceptible to 10 mM of free Mg²⁺. ATP, ADP andAMP at 1 to 5 mM notably stimulated photosynthesis, althoughhigh concentrations of AMP were unfavorable. In the assay mediumdeveloped for this study, the chloroplasts exhibited photosyntheticactivity of 120µmoles-mg^–1 Chl-h^–1 at 30?C. Chloroplasts could also be isolated from cells grown under ordinaryair. The rate of photosynthetic ¹⁴CO₂ fixation at 1 mM NaH^l4CO₃was higher in these chloroplasts than in those isolated fromcells grown in 1.5% CO₂, whereas at 10 mM NaH^l4CO₃, the ratesof the two types of chloroplasts were nearly the same. Theseresults suggest that the CO₂ concentration given during growthof the algal cells affects the affinity for dissolved inorganiccarbon at the chloroplast level. (Received March 30, 1987; Accepted August 17, 1987)     

Acceleration of the Decay of Membrane Potential after Energization of Chloroplasts in Intact Zea mays Leaves

The relationship between dissipation of the flash-induced membranepotential across the thylakoid membrane and the high energystate was studied in Zea mays leaves. The dark decay of theflash-induced 515-nm absorbance change was accelerated by shortpreillumination of the leaf. No acceleration of the decay bypreillumination was observed when leaves were incubated in argonor CO² gas or treated with DCMU. These effects of preilluminationand incubation were reversible. The delayed fluorescence from chlorophyll a was reversibly decreasedby incubating leaves in argon or CO² gas, though the modes ofdepression were somewhat different from each other. In leavesincubated in argon or CO² gas, the phase of slow decrease ofthe intensity of prompt fluorescence during illumination reversiblydisappeared. The results suggested that the dissipation of membrane potentialgenerated by a flash was accelerated after the energizationof chloroplasts in leaves, probably by increased H^– permeabilityof the thylakoid membrane. O2 was important in maintaining (indarkness) and forming (under illumination) the high energy statein chloroplasts in intact leaves. (Received October 1, 1980; Accepted December 15, 1980)     

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; )     

Cytoplasmic Alkalization and Cytoplasmic Streaming Induced by Light and Histidine in Leaf Cells of Egeria densa: in vivo 31P-NMR study

Rotational streaming of the cytoplasm including chloroplastswas induced by L-histidine, as well as by light, on the anticlinalface of leaf cells of Egeria densa. In the case of treatmentwith L-histidine some of the chloroplasts remained stationaryon the periclinal face of cells after rotational cytoplasmicstreaming was initiated. However, these chloroplasts were easilydislodged and translocated to the centrifugal end of the histidine-treatedcells by application of a centrifugal force that barely affectedthe location of chloroplasts in cells incubated in the darkwithout L-histidine. This result indicates that the anchoringof chloroplasts was weakened by L-histidine. Thus only the releaseof chloroplasts from anchoring was not enough for initiationof their streaming. The cytoplasmic pH (pH_c) and vacuolar pH(pH_v) were noninvasively monitored by in vivo ³¹P-nuclear magneticresonance (NMR) spectroscopy. Compared with the dark controlvalue, both illumination and treatment with L-histidine increasedthe pH_c by 0.3 units. In contrast, pH_v changed only a littlewith both illumination and treatment with L-histidine. Releaseof chloroplasts from anchoring and initiation of cytoplasmicstreaming are discussed in relation to the increase in pH_c inducedby both light and L-histidine. ⁴ Present address: Department of Cell Biology, National Instituteof Agrobiological Resources, Kannondai, Tsukuba, Ibaraki, 305Japan ⁵ Present address: Marine Biotechnology Institute Co., Ltd.,Head Office, 2-35-10 Hongo, Bunkyo-ku, Tokyo, 113 Japan (Received July 16, 1990; Accepted December 20, 1990)     

Vieillissement de l'appareil photosynth?tique II. Effet synergique de la lumi?re et du vieillissement in vitro sur les activit?es photochimiques de chloroplastes isol?s d'?pinard

The consequences of chloroplast ageing in vitro were furtherinvestigated, especially on the photochemical activities ofthese organelles. Ageing of chloroplasts in dark was accompanied by decreasesin activities for photohydrolysis and cyclic and non-cyclicsyntheses of ATP, photoreduction of NADP⁺ and O₂ evolution;but there was no decrease in ferricyanide photoreduction. Therates of decrease in these activities were comparable to therate of increase in chloroplast volume. Complete inhibitionswere reached when maximum chloroplast swelling had occurred,i.e. after 5 to 6 hr of incubation at 20?C in a Tris-NaCl (pH8) medium. Ageing in the light resulted in much accelerateddecreases in activities tested; the loss of capacity for light-inducedshrinkage was also accelerated by the light during ageing. Thus,light acts synergetically towards the ageing process. Moreover,light and, to a less extent, dark ageing, resulted in an uncouplingof chloroplast photophosphorylation and associated electronflow measured by ferricyanide photoreduction. The part of theelectron flow which is induced by coupling (+ ADP, Pi, MgCl₂,pH 8) or by uncoupling (+ NH₄C1, pH 7) was found to be verysensitive to light ageing. The NADP⁺ photoreduction loss wasrestored by addition of the ascorbate-DCPIP electron donor system,suggesting that ageing interferes with the integrity of photosystemII. In many respects, these effects of ageing are comparable withthe action of detergents and fatty acids on the structure andphotochemical activities of chloroplasts, especially in thatthey attack the energy transducing mechanism in chloroplasts. (Received May 24, 1969; )     

Ageing of chloroplasts in vitro II. Changes in absorption spectra and the DCPIP Hill reaction

Changes in absorption characteristics and in Hill activity werestudied during ageing of isolated chloroplasts in the dark andlight. Ageing of chloroplasts brings about significant reductionin the peak absorption in the blue and red bands and resultsin a blue shift in the red band. Incubation of chloroplastsin the dark prevented the early appearance of a light-inducedblue shift at pH 7 and pH 8 but not at pH 6 of the storage media.Addition of BSA or DTT to chloroplast suspensions of pH 6 andpH 7 significantly delayed the blue shift both in the lightand dark, but the chemicals had no effect at pH 8. Ageing-induced loss in DCPIP reduction is restored considerablyby the addition of exogenous electron donors such as DPC orMn²⁺, which suggests loss of the oxygen evolution system. Mn²⁺loses its ability to donate electrons for DCPIP photoreductionduring ageing faster than DPC. This indicates that there aretwo sites between water and the PS II reaction centre for theentry of electrons from these two donors and that ageing causessequential loss of these sites. The loss in DPC supported DCPIP photoreduction coincides, intime, with the ageing-induced blue shift of the red absorptionband and thus suggests structure and function relations of theplastid membrane. (Received October 30, 1978; )     

Swelling of spinach chloroplasts induced by HCHO and KMnO4, an effect partially hidden by the wide size range of chloroplasts

Both KMnO₄ and HCHO in concentrations used for fixation forelectron microscopy induce pronounced swelling of spinach chloroplasts.However, since electron microscopy samples small numbers, itis possible to overlook the swelling effect because the sizerange of the swollen chloroplasts can overlap the extremelywide range of chloroplasts in living mesophyll cells. HCHO fixesspinach chloroplasts only after 16 hr incubation, as verifiedby failure of the chloroplaststo swell when subsequently washedwith water. However, the HCHO treatment fails to prevent aninitial swelling and KMnO₄ further swells chloroplasts pre-fixedwith HCHO. Spinach chloroplasts in vivo measured in face area27.7 0.06 µ² mean value, 23.8 µ² mode value, range6.2 to 102.9 µ², and their distribution is skewed so thatthe coefficient of skewness is 0.15. Chloroplasts isolated directlyinto phosphate buffered 4% HCHO after 24 hrs measured in facearea 58.2 µ² mean value, 46.5 µ² mode value, range22 to 121 µ², and the coefficient of skewness increasedto 0.24. When such chloroplasts were additionally treated withphosphate buffered 2.8 % KMnO₄ the spinach chloroplasts measuredin facearea 96.4 1.40 µ² mean value, 86.1 µ² modevalue, range22 to 203 µ², and the coefficient of skewnessunchanged at 0.24. Volumes of spinach chloroplasts isolatedin NaCl as reported in the literature approach the volumes ofchloroplasts swollen by HCHO and KMnO₄. Some problems concerningsampling difficulties because of wide size ranges and skeweddistributions are discussed. ¹ Present address: Department of Agriculture, Bangkhen ExperimentStation, Bangkok, Thailand. ² Present address: Department of Biology, Wright State University,Dayton, Ohio 45431 U.S.A.     

Light Activation of Pyruvate, Orthophosphate Dikinase in Maize Mesophyll Chloroplasts: A Role for Adenylate Energy Charge

Pyruvate, orthophosphate dikinase (EC 2.7.9.1 [EC] ) was activatedin the light and inactivated following a dark treatment in intactmaize mesophyll chloroplasts. Addition of catalase (100–250units/ml) to the assay medium was necessary to obtain good activationand to keep the enzyme in an active state during illumination.Arsenate and carbonyl cyanide m-chlorophenyl-hydrazone, uncouplersof photophosphorylation, inhibited the activation. Pyruvate,which has been proposed to have a critical role in supportingthe light activation of pyruvate, orthophosphate dikinase, actuallyinhibited the activation. The pyruvate level in the chloroplastsuspension decreased when the enzyme was light-activated. Measurementsof adenylates and pyruvate in the chloroplasts indicated thatthe energy state of the chloroplasts was more important forthe light activation than was the level of pyruvate. ¹Present address: Department of Biochemistry, Faculty of Science,Saitama University, 255, Shimo-Okubo, Urawa, 338 Japan ²Present address: National Institute of Agrobiological Resources,Yatabe, Tsukuba, Ibaraki, 305 Japan (Received May 2, 1989; Accepted October 2, 1989)     

Photoproduction and Detoxification of Hydroxyl radicals in Chloroplasts and Leaves and Relation to Photoinactivation of Photosystems I and II

The light-dependent production of hydroxyl radicals (HO{dot})by thylakoids, chloroplasts and leaves of Spinacia oleraceawas investigated using dimethylsulfoxide as HO{dot} trappingagent. Maximum rates of HO{dot} production by thylakoids asindicated by the formation of methane sulfinic acid were observedunder aerobic conditions in the absence of added electron acceptors.They were higher than 2 µmol (mg Chl h)^–1. Saturationof HO{dot} production occurred at the low photon flux densityof 100 µmol m^–2 s^–1. Trapping of HO{dot} bydimethylsulfoxide suppressed, but did not eliminate light-dependentinactivation of PSI and II suggesting that HO{dot} formationcontributed to the photosensitivity of isolated thylakoids.DCMU inhibited HO{dot} formation. Importantly, methylviologendecreased HO{dot} formation in the absence, but stimulated itin the presence of Fe³⁺. In intact chloroplasts, HO{dot} formation became appreciableonly after KCN had been added to inhibit effective H₂O₂ scavengingby ascorbate peroxidase. It was stimulated by ferrisulfate,but not by ferricyanide which does not penetrate the chloroplastenvelope. Infiltrated spinach leaves behaved similar in principleto intact chloroplasts in regard to HO{dot} formation but HO{dot}production was very slow if detectable at all by the formationof methylsulfinic acid indicating effective radical detoxification. HO{dot} formation is interpreted to be the result of a Fenton-typereaction which produces HO{dot} in chloroplasts from H₂O₂ andreduced ferredoxin, when O₂ is electron acceptor in the Mehlerreaction and radical detoxification reactions are inhibited. (Received November 13, 1996; Accepted April 23, 1996)     

Inactivation of Ascorbate Peroxidase in Spinach Chloroplasts on Dark Addition of Hydrogen Peroxide: Its Protection by Ascorbate

Dark addition of hydrogen peroxide to intact spinach chloroplastsresulted in the inactivation of ascorbate peroxidase accompaniedby a decrease in ascorbate contents. This was also the casein reconstituted chloroplasts containing ascorbate, NADP⁺, NAD⁺and ferredoxin. The addition of hydrogen peroxide during light,however, showed little effect on ascorbate contents and ascorbateperoxidase activity in either the intact or reconstituted chloroplasts.In contrast to ascorbate peroxidase, the enzymes participatingin the regeneration of ascorbate in chloroplasts (monodehydroascorbatereductase, dehydroascorbate reductase and glutathione reductase)were not affected by the dark addition of hydrogen peroxide.Ascorbate contents increased again by illumination of the chloroplastsafter the dark addition of hydrogen peroxide. These resultsshow that the inactivation of the hydrogen peroxide scavengingsystem on dark addition of hydrogen peroxide [Anderson et al.(1983) Biochim. Biophys. Acta 724: 69, Asada and Badger (1984)Plant & Cell Physiol. 25: 1169] is caused by the loss ofascorbate peroxidase activity. Ascorbate peroxidase activitywas rapidly lost in ascorbate-depleted medium, and protectedby its electron donors, ascorbate, isoascorbate, guaiacol andpyrogallol, but not by GSH, NAD(P)H and ferredoxin. (Received June 14, 1984; Accepted August 15, 1984)     

Studies of pesticides effects on Chlorella metabolism II. Effect of DCMU on galactolipid metabolism

DCMU (N'-(3,4-dichlorophenyl)-N, N-dimethylurea) was testedfor effects on the metabolism of galactolipids in Chlorellaand chloroplasts isolated from higher plants. In Chlorella,DCMU affected galactolipid synthesis in the light more thanthat of other lipids, but it showed no effect on lipid synthesisin the dark. DCMU did not affect the turnover of galactolipidsin the light. In vitro studies using ¹⁴C-acetate or ¹⁴C-UDP-galactoseas a precursor showed that DCMU had no effect on the synthesisof gross lipid or galactolipids in chloroplasts isolated fromhigher plants. The significance of these observations are discussed. (Received September 21, 1974; )