Effects of Some Chemicals on the Oxygen Evolution and Oxygen Uptake in Isolated Wheat Chloroplasts Irradiated without the Addition of an Oxidant

The oxygen exchange, obtained when isolated chloroplasts of Triticum aestivum, wheat, are irradiated without the addition of a Hill oxidant has been investigated using an oxygen electrode. Ascorbate, catalase, 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone(DBMIB), diethyldithio-carbamate (DEDT), dichlorophenylmethylurea (DCMU), and potassium cyanide were added to the Chloroplasts in order to investigate the oxygen exchange. At least two oxygen uptake reactions, one sensitive to catalase and one catalase-insensitive, appeared upon irradiation. Hydrogen peroxide was the product of the oxygen uptake in the former process, and water was the reductant. The formation of hydrogen peroxide was probably associated with photosystem I. The other oxygen consuming reaction was found to be insensitive to both catalase and potassium cyanide. After the chloroplasts had been treated with DCMU, it was possible to show that the catalase-insensitive oxygen uptake was localized in photosystem I, and that a cyclic electron transport system or some endogenous reductant (-s) acted in the oxygen uptake. Addition of ascorbate or DEDT to the chloroplasts led to an enhanced oxygen uptake in 710 nm light. This was probably due to the effect of these compounds on the superoxide radical ion formed in photosystem I. The stimulated oxygen uptake was only weakly affected by catalase, indicating that hydrogen peroxide was not a product of this oxygen uptake. Addition of DEDT and potassium cyanide inhibited (strongly respectively weakly) the oxygen uptake when photosystem II was functioning. The effect of these compounds was probably due to an inhibition of the electron transport at the plastocyanin. DBMIB inhibited the oxygen uptake reactions and the cooperation between the two photosystems. The cooperation between the photosystems was also studied in DCMU-treated chloroplasts. The reactions in photosystem II, measured as oxygen evolution, were more inhibited than the coupling between the photosystems. The oxygen “gush” appearing upon irradiation in light of 650 nm was not affected by a DBMIB-treatment, showing that the oxygen evolution was due to the reduction of plastoquinone. The reoxidation in the dark of the plastoquinone pool was stimulated by DBMIB and potassium cyanide indicating that an oxygen uptake could be associated with plastoquinone. The sites of interaction of oxygen with the electron transport pathways in chloroplasts, and the different reductants for the oxygen consuming reactions are discussed.     

Photoactivation of the Electron Flow from NADPH to Plastoquinone in Spinach Chloroplasts

Intact chloroplasts from spinach showed a transient increasein Chl fluorescence after saturating illumination with actiniclight and its yield depended on the duration of illuminationand the intensity of the actinic light (AL). The increase waspartially suppressed when antimycin A was added immediatelyafter termination of the AL. The inhibited fluorescence increase,therefore, reflected the electron flow from the reductant(s)that had accumulated during the actinic illumination to theplastoquinone (PQ) pool via ferredoxin and the antimycin A-sensitiveCyt b-559 [Miyake et al. (1995) Plant Cell Physiol. 36: 743].Addition of dihydroxyacetone phosphate (DHAP) to chloroplastscaused the enhancement of the increase in fluorescence afterAL, which was inhibited by antimycin A. Decay of the transientlyraised fluorescence was retarded by 2-heptyl-4-hydroxyquinolineN-oxide and stigmatellin, suggesting that re-oxidation of thereduced PQ pool is coupled with the operation of Q-cycle. Althoughthe activity of the stromal enzyme system that supplies NADPHon addition of DHAP was constant irrespective of light or darkness,the capacity of the intact chloroplasts to show a DHAP-dependentfluorescence increase had a limited lifetime after AL was turnedoff. This result suggests that the antimycin A-sensitive Cytb-559 or ferredoxin-NADP reductase is activated by light anddeactivated in the dark. In ruptured chloroplasts, the additionof NADPH increased the dark fluorescence yield only in the presenceof Fd, which also was inhibited by antimycin A. Thus the photoregulatorymechanism of Cyt b-559 (Fd) in intact chloroplasts appearedto be lost when chloroplasts were ruptured. (Received June 21, 1995; Accepted September 25, 1995)     

Monooxygenase activities of dioxygenases. Benzphetamine demethylation and aniline hydroxylation reactions catalyzed by indoleamine 2,3-dioxygenase

Benzphetamine demethylase and aniline hydroxylase activities were determined with various hemoproteins including indoleamine 2,3-dioxygenase in a cytochrome P-450-like reconstituted system containing NADPH, NADPH-cytochrome P-450 reductase, and O2. The highest specific activities, almost comparable to those of liver microsomal cytochrome P-450, were detected with indoleamine 2,3-dioxygenase from the rabbit intestine. The indoleamine 2,3-dioxygenase-catalyzed benzphetamine demethylation reaction was inhibited by catalase but not by superoxide dismutase. Exogenous H2O2 or organic hydroperoxides was able to replace the reducing system and O2. The stoichiometry of H2O2 added to the product formed was essentially unity. These results indicate that the dioxygenase catalyzes the demethylation reaction by the so-called "peroxygenation" mechanism using H2O2 generated in the reconstituted system. On the other hand, the dioxygenase-catalyzed aniline hydroxylation reaction was not only completely inhibited by catalase but also suppressed by superoxide dismutase by about 60%. Although the O2- and H2O2-generating system (e.g. hypoxanthine-xanthine oxidase) was also active as the reducing system, neither exogenous H2O2 nor the generation of O2- in the presence of catalase supported the hydroxylation reaction, indicating that both H2O2 and O2- were essential for the hydroxylation reaction. However, typical scavengers for hydroxyl radical and singlet oxygen were not inhibitory. These results suggest that a unique, as yet unidentified active oxygen species generated by H2O2 and O2- participates in the dioxygenase-mediated aniline hydroxylation reaction.     

Co-operative activation of chloroplast fructose-1,6-bisphosphatase by reductant,pH and substrate

Intact chloroplasts capable of high rates of photosynthesis fail to reduce CO₂ when illuminated in the absence of oxygen. While anaerobiosis limits proton gradient formation leading to ATP deficiency (Ziem-Hanck, U. and Heber, U. (1980) Biochim. Biophys. Acta 591, 266–274), light activation of fructose-1,6-bisphosphatase was also inhibited by anaerobiosis, whereas light activation of NADP-malate dehydrogenase was stimulated by anaerobiosis, indicating that reductant was still available for light activation. The chloroplast pool of NADP was largely reduced during illumination under anaerobiosis and electron transport to oxaloacetate was not inhibited by anaerobic conditions. Significant light activation of fructose-bisphosphatase was observed in anaerobic chloroplasts with 3-phosphoglycerate as substrate, but not with dihydroxyacetone phosphate (3-phosphoglycerate supports electron transport and hence proton gradient formation). In the absence of added substrates, illumination of anaerobic chloroplasts resulted in some light activation of fructose-bisphosphatase when the pH of the medium was increased. Under these conditions, light activation was stimulated by dihydroxyacetone phosphate. Dihydroxyacetone phosphate added together with oxaloacetate allowed light activation of fructose-bisphosphatase in anaerobic chloroplasts, while neither substrate added alone was effective. Formation of a transthylakoid proton gradient can therefore substitute for an alkaline suspension medium by causing an alkaline shift of the stromal pH on illumination. The data are interpreted as indicating that fructose-bisphosphatase, but not NADP-malate dehydrogenase, requires an alkaline pH and the presence of substrate for rapid reductive light activation and they bear on the interpretation of the lag observed in photosynthesis in chloroplasts and leaves on illumination after a prolonged dark period.     

Electron transport pathways in spinach chloroplasts. Reduction of the primary acceptor of photosystem II by reduced nicotinamide adenine dinucleotide phosphate in the dark.

Addition of NADPH to osmotically lysed spinach chloroplasts results in a reduction of the primary acceptor (Q) of photosystem II. This reduction of Q reaches a maximum of 50% in chloroplasts maintained under weak illumination and requires added ferredoxin and Mg2+. The reaction is inhibited by (I) an antibody to ferredoxin-NADP+ reductases (EC 1.6.7.1), (ii) treatment of chloroplasts with N-ethylmaleimide in the presence of NADPH, (iii) disulfodisalicylidenepropanediamine, (iv) antimycin, and (v) acceptors of non-cyclic electron transport. Uncouplers of phosphorylation do not affect NADPH-driven reduction of Q. It is proposed that electron flow from NADPH to Q may occur in the dark by a pathway utilising portions of the normal cyclic and non-cyclic electron carrier sequences. The possible in vivo role for such a pathway in redox poising of cyclic electron transport and hence in controlling the ATP/NADPH supply ratio is discussed.     

NADP regulates the light activation of NADP-dependent malate dehydrogenase

The chloroplastic NADP-dependent malate-dehydrogenase (EC 1.1.1.82) activity is modulated by light and dark. The enzyme is activated upon illumination of intact or broken chloroplasts or by incubation with dithiothreitol, whereas dark has the opposite effect. The present communication shows an additional regulation of the light modulation: in isolated intact pea chloroplasts, light activation was inhibited in the presence of electron acceptors such as sodium bicarbonate, 3-phosphoglycerate or oxaloacetate, which consume NADPH₂ and produce NADP. With broken chloroplasts, addition of NADP resulted in a pronounced lag phase of NADP-dependent malate dehydrogenase light activation, while NADPH₂ was without any effect. The extent of the lag phase was correlated to the amount of NADP added. When light was replaced by dithiotreitol, the inhibition effect was even more pronounced. It was assumed that NADP inhibits the modulation reaction directly: reduced thioredoxin, a potent mediator of activation by light, or dithiotreitol appear to counteract NADP in a competitive manner. The results indicate a physiological role of NADP in the regulation of chloroplastic NADP-dependent malate dehydrogenase which is capable of removing electrons from the chloroplast, via oxaloacetate reduction and malate export. Thus an NADP concentration sufficient for continuous photosynthetic electron flow may be achieved.     

Mechanism of aromatic hydroxylation. Properties of a model for pyridine nucleotide-dependent flavoprotein hydroxylases

A model (NADH-phenazine methosulfate-O₂) formally similar to pyridine nucleotide-dependent flavoprotein hydroxylases catalyzed the hydroxylation of several aromatic compounds. The hydroxylation was maximal at acid pH and was inhibited by ovine Superoxide dismutase, suggesting that perhydroxyl radicals might be intermediates in this process. The stoichiometry of the reaction indicated that a univalent reduction of oxygen was occurring. The correlation between the concentration of semiquinone and hydroxylation, and the inhibition of hydroxylation by ethanol which inhibited semiquinone oxidation, suggested the involvement of phenazine methosulfate-semiquinone. Activation of hydroxylation by Fe³⁺ and Cu²⁺ supported the contention that univalently reduced species of oxygen was involved in hydroxylation. Catalase was without effect on the hydroxylation by the model, ruling out H₂O₂ as an intermediate. A reaction sequence, involving a two-electron reduction of phenazine methosulfate to reduced phenazine methosulfate followed by disproportionation with phenazine methosulfate to generate the semiquinone, was proposed. The semiquinone could donate an electron to O₂ to generate O₂ which could be subsequently protonated to form the perhydroxyl radical.     

The tiron free radical as a sensitive indicator of chloroplastic photoautoxidation.

Wheat chloroplasts photochemically reduced molecular oxygen, as a Hill oxidant in the Mehler reaction, to superoxide anion which then oxidized added 1,2-dihydroxybenzene-3,5-disulfonate to its semiquinone, a comparatively stable free radical at pH 7. The last mentioned reaction was rapid in aqueous solution, but the rate of formation of 1,2-dihydroxybenzene-3,5-disulfonate semiquinone by the chloroplast system was calculated as T1 of 0.6 s. The Mehler reaction, or more specifically the univalent reduction of oxygen by Photosystem I, was rate-limiting so that the 1,2-dihydroxybenzene-3,5-disulfonate seniquinone was a useful spin probe for superoxide anion production at room temperature. The ESR signal of 1,2-dihydroxybenzene-3,5-disulfonate semiquinone was proportional to its steady state concentration and decayed in the dark with a T1/2 of 5-6 s. This oxygen-dependent signal was enhanced by mediation of chloroplastic oxygen reduction through methyl viologen. The superoxide anion scavengers ascorbate and L-epinephrine competitively obscured 1,2-dihydroxybenzene-3,5-disulfonate semiquinone formation, butadded superoxide dismutase was not as effective in this role. Partial inhibition by superoxide dismutase was achieved only by preincubation of Photosystem I enriched particles with ten times the endogenous concentration of superoxide dismutase. This and the persistence of a small amount of a 1,2-dihydroxybenzene-3,5-disulfonate (Tiron) oxidizing species in the dark supports the concept of Tiron accessibility but not the superoxide dismutase accessibility of superoxide anion bound in its formative enzyme complex. Benzoquinone and naphthoquinone disulfonate also reacted with superoxide anion, and supported both the Hill reaction and the Mehler reaction as final oxidants of both water and superoxide anion.     

Photosynthetic apparatus of chilling-sensitive plants. XI. Reversibility by light of cold- and dark-induced inactivation of cyanide-sensitive superoxide dismutase activity in tomato leaf chloroplasts

(1) The inactivation of cyanide-sensitive, copper- and zinc-containing superoxide dismutase activity in chloroplasts following cold and dark storage of both detached leaves and growing tomato plants is accompanied by a decrease in copper and zinc content in both chloroplast preparations and butanol extracts of the enzyme. In contrast, this treatment of chloroplast preparations affects neither superoxide dismutase activity nor copper and zinc content. (2) Copper- and zinc-containing superoxide dismutase is not reactivated following the 2–3 h illumination of cold- and dark-stored detached leaves. However, prolonged illumination of growing seedlings results in the restoration of both the enzyme activity and copper and zinc content in chloroplasts. (3) The data suggest that the dissociation of copper, and probably of zinc, from the enzyme during cold and dark treatment of either detached leaves or growing plants and reincorporation of the metals following the illumination of intact plants are responsible for the reversible inactivation of chloroplast cyanide-sensitive superoxide dismutase of chilling-sensitive plants.     

pH dependent changes in the reactivity of the primary electron acceptor of System II in spinach chloroplasts to external oxidant and reductant

Changes in the rates of dark oxidation and reduction of the primary electron acceptor of System II by added oxidant and reductant were investigated by measuring the induction of chlorophyll fluorescence under moderate actinic light in 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea-inhibited chloroplasts at pH values between 3.6 and 9.5. It was found that:

1. (1) The rate of dark oxidation of photoreduced primary acceptor was very slow at all the pH values tested without added electron acceptor.

2. (2) The rate was accelerated by the addition of ferricyanide in the whole pH range. It was dependent approximately on the 0.8th power of the ferricyanide concentration.

3. (3) The rate constant for the oxidation of the primary acceptor by ferricyanide was pH-dependent and became high at low pH. The value at pH 3.6 was more than 100 times that at pH 7.8.

4. (4) The pH-dependent change in the rate constant was almost reversible when the chloroplasts were suspended at the original pH after a large pH change (acid treatment).

5. (5) An addition of carbonylcyanide m-chlorophenylhydrazone or heavy metal chelators had little effect on the rate of dark oxidation of the primary acceptor by ferricyanide.

6. (6) The dark reduction of the primary acceptor by sodium dithionite also became faster at low pH.

From these results it is concluded that at low pH the primary acceptor of System II becomes accessible to the added hydrophilic reagents even in the presence of 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea.     

Electron transport pathways in spinach chloroplasts. Reduction of the primary acceptor of Photosystem II by reduced nicotinamide adenine dinucleotide phosphate in the dark

Addition of NADPH to osmotically lysed spinach chloroplasts results in a reduction of the primary acceptor (Q) of Photosystem II. This reduction of Q reaches a maximum of 50% in chloroplasts maintained under weak illumination and requires added ferredoxin and Mg²⁺. The reaction is inhibited by (i) an antibody to ferredoxin-NADP⁺ reductase (EC 1.6.7.1), (ii) treatment of chloroplasts with N-ethylmaleimide in the presence of NADPH, (iii) disulfodisalicylidenepropanediamine, (iv) antimycin, and (v) acceptors of non-cyclic electron transport. Uncouplers of phosphorylation do not affect NADPH-driven reduction of Q.It is proposed that electron flow from NADPH to Q may occur in the dark by a pathway utilising portions of the normal cyclic and non-cyclic electron carrier sequences. The possible in vivo role for such a pathway in redox poising of cyclic electron transport and hence in controlling the ATP/NADPH supply ratio is discussed.     

Hemin-mediated para-hydroxylation of aniline: A potential model for oxygen activation and insertion reactions of mixed function oxidases

The activation of molecular oxygen by alkaline hemin (ferriprotoporphyrin IX) has been studied. In the presence of reductant nicotineamide adenine dinucleotide (NADH) or nicotineamide adenine dinucleotide phosphate (NADPH) and organic substrate, aniline, hemin activates oxygen to the hydroperoxide anion (HO₂^?) and subsequently mediates insertion of active oxygen into the benzene ring of the substrate to form p-aminophenol, with a high degree of regiospecificity. Oxygen activation does not occur in the absence of aniline. Stoichiometry of the reaction indicates that two electrons are required per molecule of oxygen activated or atom of oxygen inserted into the substrate aromatic ring system. Direct measurements of H₂O₂ and of the pK_a for maximum rate of p-aminophenol formation (11.7 ± 0.1) indicate participation of the hydroperoxide anion as the active oxygen species in the rate-determining step of the insertion reaction. Powerful scavengers of the hydroxyl radical (OH′) have little effect on the formation of H₂O₂ or p-aminophenol by the system. Superoxide dismutase (10^?7 mol dm^?3) inhibited both p-aminophenol and H₂O₂ formation, when added to the system immediately prior to initiation of the reaction. Studies involving N-phenylhydroxylamine indicate that aromatic ring hydroxylation is occurring directly and not by rearrangement of an N-hydroxylated intermediate. Implications of hemin-mediated hydroxylation reactions for those of enzymatic mixed function oxidase activity are discussed.     

The action of o-dihydric phenols in the hydroxylation of p-coumaric acid by a phenolase from leaves of spinach beet (Beta vulgaris L.)

1. Under defined conditions, the hydroxylation of p-coumaric acid catalysed by a phenolase from leaves of spinach beet (Beta vulgaris L.) was observed to develop its maximum rate only after a lag period. 2. By decreasing the reaction rate with lower enzyme concentrations or by increasing it with higher concentrations of reductants, the length of the lag period was inversely related to the maximum rate subsequently developed. 3. Low concentrations of caffeic acid or other o-dihydric phenols abolished this lag period. With caffeic acid, the rate of hydroxylation was independent of the reductant employed. 4. Hydroxylation was inhibited by diethyldithiocarbamate, but with low inhibitor concentrations hydroxylation recovered after a lag period. This lag could again be abolished by the addition of high concentrations of caffeic acid or other o-dihydric phenols. 5. Catechol oxidase activity showed no lag period, and did not recover from diethyldithiocarbamate inhibition. 6. The purified enzyme contained 0.17-0.33% copper; preparations with the highest specific activity were found to have the highest copper content. 7. The results are interpreted to suggest that the oxidation of o-dihydric phenols converts the enzymic copper into a species catalytically active in hydroxylation. This may represent the primary function for the catechol oxidase activity of the phenolase complex. The electron donors are concerned mainly, but not entirely, in the reduction of o-quinones produced in this reaction.     

On the mechanism and stoichiometry of the oxidation of hydrazine by illuminated chloroplasts

Hydrazine can support a rapid oxygen uptake in illuminated chloroplasts. The oxygen uptake rate is inhibited by 3-(3,4-dichlorophenyl)-1, 1-dimethylurea but is only slightly increased by added methyl viologen, and little H₂O₂ is produced. The pH optimum for hydrazine-dependent oxygen uptake is much higher than that of the Hill reaction. Addition of Mn (II) increases the rate of oxygen uptake in the light and causes the reaction to continue in the dark, the dark rate being dependent on the duration of the preceding light period. Flash yield experiments show that at least six electrons are transferred from hydrazine per flash compared to one electron per flash when water is the electron donor.     

Photochemical dimerization of ferulic Acid by chloroplasts from sorghum

Sorghum (Sorghum bicolor) chloroplasts, lamellar fragments, and Triton X-100 solubilized preparations catalyze a blue and red light-sensitized oxidation of ferulic acid to its beta-beta-linked dimer and its hydrolysis product, the acid dimer. Exogenous superoxide dismutase had no effect, and catalase and 1 to 10 mm KCN inhibited this photooxidative dimerization only in detergent-treated chloroplasts. It is postulated that the final oxidant is H(2)O(2), formed by light-induced photosystem I electron transport, followed by an unidentified peroxidatic activity. The reaction differs, however, from that catalyzed by horseradish peroxidase in the presence of H(2)O(2).     

Photosynthetic apparatus of chilling-sensitive plants. X. Relationship between superoxide dismutase activity and photoperoxidation of chloroplast lipids

(1) The rate of photoperoxidation of chloroplast lipids, as measured by malondialdehyde formation following the illumination of either leaves or chloroplast preparations, is found to be approx. 2-fold higher in chloroplasts from both cold- and dark-stored as well as stored and illuminated tomato leaves than in those from fresh leaves. (2) Enhanced lipid photoperoxidation can also be observed in chloroplasts from fresh leaves treated with cyanide as well as in superoxide dismutase-depleted chloroplasts following washing with Tris or Hepes. (3) Cyanide-sensitive superoxide dismutase activity is not detected in chloroplasts isolated from cold- and dark-stored leaves. Their illumination does not reactivate the enzyme activity. (4) On the basis of these observations, it is concluded that inactivation of chloroplast cyanide-sensitive superoxide dismutase due to cold and dark treatment of leaves, rather than diminished electron transport, is responsible for accelerated chloroplast lipid photoperoxidation.     

Biosynthesis of Sulfoquinovosyldiacylglycerol in Higher Plants: The Incorporation of SO(4) by Intact Chloroplasts in Darkness

Intact spinach chloroplasts incorporated ³⁵SO₄²⁻ into sulfoquinovosyldiacylglycerol in the dark at rates equivalent to those previously reported for illuminated chloroplasts provided that either ATP itself or an ATP-generating system was added. No additional reductant was necessary for SQDG synthesis by chloroplasts. The optimal concentration of ATP was between 2 and 3 millimolar. Rates of synthesis up to 2.6 nanomoles per milligram chlorophyll per hour were observed. UTP, GTP, and CTP could not substitute for ATP. Incubation of UTP with ATP (1:1) stimulated synthesis of sulfoquinovosyldiacylglycerol. No additional stimulation of the reaction was observed upon addition of other nucleoside triphosphates with ATP. For the generation of ATP in the chloroplast, addition of dihydroxyacetone phosphate alone did not promote synthesis of sulfoquinovosyldiacylglycerol, but in combination with inorganic phosphate and oxaloacetate, rates of synthesis up to 3.2 nanomoles per milligram chlorophyll per hour were observed. Dark synthesis was optimal in the presence of 2 millimolar dihydroxyacetone phosphate, 2 millimolar oxaloacetate, and 1 millimolar KH₂PO₄.     

Association of the Chloroplastic Respiratory and Photosynthetic Electron Transport Chains of Chlamydomonas reinhardii with Photoreduction and the Oxyhydrogen Reaction

The hydrogenase-dependent processes, photoreduction and the dark oxyhydrogen reaction, both of which can support CO₂ assimilation, were compared with aerobic photosynthesis and respiration for their sensitivity to electron transport inhibitors in cells and intact chloroplasts of Chlamydomonas reinhardii 11-32/6. Photoreduction but not photosynthesis was inhibited in chloroplasts and the oxyhydrogen reaction detected only in cells was inhibited up to 75 and 90%, respectively, by 150 micromolar rotenone, indicating the involvement of a NAD(P)H-plastoquinone oxidoreductase in the hydrogen utilizing pathways. The oxyhydrogen reaction coupled to CO₂ fixation was inhibited more than 95% by 10 micromolar 2,5 - dibromo - 3 - methyl - 6 - isopropyl - p - benzoquinone (DBMIB), a concentration which did not affect respiratory activity. In cells, both photoreduction and the oxyhydrogen reaction exhibited a similar sensitivity to salicylhydroxamic acid (SHAM) showing approximately 90% inhibition by 7 millimolar concentration. Photosynthesis was inhibited only 30% by the same concentration of SHAM. Antimycin A (18 micromolar, 10 micrograms per milliliter) inhibited both photoreduction (80%) and the oxyhydrogen reaction (92%) in cells with the oxyhydrogen reaction being approximately 10 times more sensitive to lower concentrations of the inhibitor. Antimycin A at 18 micromolar concentration did not inhibit photosynthetic CO₂ fixation unless the cells were adapted to an atmosphere of N₂ and the reaction conducted anaerobically. Photosynthesis, photoreduction, and the oxyhydrogen reaction coupled to CO₂ fixation were all inhibited greater than 90% by 10 micromolar carbonylcyanide-p-trifluoromethoxyphenylhydrazone. ATP added to chloroplasts adapted to an atmosphere of H₂ could support CO₂ uptake in the dark. These results are interpreted as evidence that photoreduction and the oxyhydrogen reaction involve some common components of thylakoidal electron transport pathways in Chlamydomonas including NAD(P)H-plastoquinone oxidoreductase and the plastoquinone pool. An O₂-consuming thylakoidal or mitochondrial reaction is an additional component of the oxyhydrogen reaction.     

Capacities of pea chloroplasts to catalyse the oxidative pentose phosphate pathway and glycolysis

The aim of this work was to measure the capacities of pea (Pisum sativum) shoot chloroplasts to catalyse the oxidative pentose phosphate pathway and glycolysis. Of the total activities in the unfractionated homogenates, appreciable proportions of those of glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, and phosphofructokinase, and smaller but significant proportions of those of phosphopyruvate hydratase and pyruvate kinase were recovered in crude preparations of chloroplasts, and co-purified with intact chloroplasts on sucrose gradients. The activities in the chloroplasts showed considerable latency that was closely correlated with chloroplast integrity. Phosphoglyceromutase activity in the above preparations of chloroplasts did not exceed that expected from cytoplasmic contamination. The mass-action ratio for phosphoglyceromutase in illuminated isolated chloroplasts differed markedly from the enzyme's equilibrium constant. Isolated chloroplasts converted 2-phosphoglycerate to pyruvate. The enzyme activities of the chloroplasts were compared with the rates of respiration and starch breakdown in pea leaves in the dark. It is concluded that in the dark chloroplasts could metabolize all the products of starch breakdown and catalyse much of the respiration of pea shoots via the oxidative pentose phosphate pathway and/or glycolysis as far as 3-phosphoglycerate. It is suggested that pea shoot chloroplasts lack phosphoglyceromutase but contain some phosphopyruvate hydratase and pyruvate kinase.     

Inhibition of Photosystem II by uncouplers at alkaline pH and its reversal by artificial electron donors

When chloroplasts are aged for 5 min at pH 9.6, or are exposed to uncouplers at pH 8.5–9.0, electron flow from water to Hill acceptors is inhibited. Both treatments induce rapid millisecond dark decay of delayed light emission. 3-(3,4-Dichlorophenyl)-1,1-dimethylurea-sensitive electron transport through Photosystem II can be regenerated in both types of inhibited chloroplasts by the artificial electron donor, 1,5-diphenylcarbohydrazide. Neither treatment inhibits electron flow through Photosystem I. Uncouplers at alkaline pH, when added in the light, are less effective in producing the inhibition than when added in the dark. These results are interpreted as indicating inhibition of the oxygen-evolving apparatus by alkaline intrathylakoid pH.