Efficiency of hydrogen photoproduction by chloroplast-bacterial hydrogenase systems

A comparative study of H₂ photoproduction by chloroplasts and solubilized chlorophyll was performed in the presence of hydrogenase preparations of Clostridium butyricum. The photoproduction of H₂ by chloroplasts in the absence of exogenous electron donors, and with irreversibly oxidized dithiothreitol and cysteine, is thought to be limited by a cyclic transport of electrons wherein methylviologen short-circuits the electron transport in photosystem I. The efficiency of H₂ photoproduction by chloroplasts with ascorbate and NADPH is limited by a back reaction between light-reduced methylviologen and the oxidized electron donors. The use of a combination of electron donors (dithiothreitol and ascorbate), providing anaerobiosis without damage to chloroplasts, makes it possible to avoid consumption of reduced methylviologen for the reduction of oxidized electron donors and to exclude the short-circuiting of electron transfer. Under these conditions, photoproduction of H₂ was observed to occur with a rate of 350 to 400 micromoles H₂ per milligram chlorophyll per hour. In this case, the full electron-transferring capability of photosystem I (measured by irreversible photoreduction of methyl red or O₂) is used to produce H₂.     

Inhibition of photosynthetic electron transport by diphenyl ether herbicides

The effects of the diphenyl ether herbicides HOE 29152 (methyl-2[4-(4-trifluoromethoxy) phenoxy] propanoate) and nitrofluorfen (2-chloro-1-[4-nitrophenoxy]-4-[trifluoromethyl]benzene) on photosynthetic electron transport have been examined with pea seedling and spinach chloroplasts. Linear electron transport (water to ferricyanide or methylviologen) is inhibited in treated chloroplasts, but neither photosystem II activity (water to dimethylquinone plus dibromothymoquinone) nor photosystem I activity (diaminodurene to methylviologen) is affected. Cyclic electron flow, cata-lyzed by either phenazine methosulfate or diaminodurene, is resistant to inhibition by nitrofluorfen. In diphenyl ether-treated chloroplasts the half-time for the dark reduction of cytochrome f is increased 5- to 15-fold. These data indicate that the site of inhibition for the diphenyl ethers is between the two photosystems in the plastoquinone-cytochrome f region.     

Comparison of photosynthetic activities of spinach chloroplasts with those of corn mesophyll and corn bundle sheath tissue

Bundle sheath and mesophyll chloroplasts from Zea mays showed comparable rates of O₂ evolution, which amounted to about half of the rate observed in spinach (Spinacia oleracea) chloroplasts.

Ratios of 4.5, 4.6, and 6.2 Mn²⁺ atoms per 400 chlorophylls were observed in mesophyll, bundle sheath, and spinach chloroplasts, respectively. These ratios roughly correspond to the observed O₂ evolution rates.

Rates of electron transport from water to methylviologen (photosystem I and II) in both types of corn chloroplasts were about one-third that in spinach. Compared to spinach, transport rates from reduced diaminodurene to methylviologen (photosystem I) were about one-third and greater than one-half in mesophyll and bundle sheath material, respectively.

In both types of corn chloroplasts, electron flow from photosystem II to P700 was abnormal. This observation, together with the low rates of all activities, suggests that damage occurred during isolation. Such damage may limit the quantitative significance of observations made with these materials (including the following data).

Measurements of flash yields of O₂ evolution or O₂ uptake showed that the size of the photosynthetic unit was the same in photosystems I and II and in all three types of chloroplasts (about 400 chlorophylls per equivalent).

Similarity of the photochemical cross-section of the two photosystems in the three preparations was also found in optical experiments: that is the half-times of the fluorescence rise in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) (photosystem II) and of the photooxidation of P700 (photosystem I).

The ratio of P700 to chlorophyll appeared to be about 2-fold higher in bundle sheath chloroplasts than in the other materials (1/200 versus 1/400).

     

Stimulation of photosynthesis by carbonyl compounds and chelators

A number of carbonyl compounds including bicarbonate, ethylene carbonate, dimethylcarbonate, propylene carbonate, bis-pentamethylene urea, and glycidol, and several chelators were tested for their effect on photosynthetic reactions in isolated spinach chloroplasts. It was found that carbonyl compounds inhibited the DCMU-insensitive silicomolybdate reduction by photosystem II but stimulated the O₂ evolution associated with ferricyanide reduction in presence of DBMIB and the H₂O→methylviologen reaction. Many chelators behaved in the same manner except 1,10-phenanthroline which shows the opposite effect. The carbonyl compounds did not uncouple because they stimulated the proton gradients associated with noncyclic photophosphorylation, whereas some chelators, such as bathocuproine or bathophenanthroline inhibited the proton gradients 100%. Electron transport in presence of ADP and inorganic phosphate showed a stimulation of rates beyond that obtained in presence of an uncoupler. The data are discussed in terms of inhibition of cyclic electron flow around PS II which leads to increased electron transport rates toward PS I.     

Light-induced de-epoxidation of violaxanthin in lettuce chloroplasts IV. The effects of electron-transport conditions on violaxanthin availability

1. In isolated chloroplasts of Lactuca sativa var. Manoa, the size of the violaxanthin fraction which is available for de-epoxidation is not directly dependent on electron transport but rather related to the reduced level of some electron carrier between the photosystems. This is concluded from the effects of various electrontransport conditions on violaxanthin availability: Under conditions of electron transport through both photosystems, availability was saturated at a lower electron-transport rate with actinic light at 670 than at 700 nm. Under conditions of electron transport through Photosystem I, availability was smaller for linear electron flow from reduced N-methylphenazonium methosulfate via methylviologen to oxygen than for cyclic electron flow mediated by either N-methylphenazonium methosulfate or 2,6-dichlorophenolindophenol; in addition for linear r flow from reduced N-methylphenazonium methosulfate via methylviologen to oxygen, availability increased with decreasing light intensity.2. The postulated carrier whose reduced level is related to availability seems to be some carrier between plastoquinone and the primary acceptor of Photosystem II or plastoquinone itself. This conclusion follows from the fact that availability increased with increasing light intensity under conditions of electron flow through both photosystems and that 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (≤ μM) had no effect on availability, whereas low levels of 3,3-(3′,4′-dichlorophenyl)-1,1-dimethylurea resulted in decreased availability (50% decrease at 1 μM). Furthermore, availability in 3,3-(3′,4′-dichlorophenyl)-1,1-dimethylurea-poisoned chloroplasts was fully restored by 2-methyl-1,4-naphtoquinone (menadione) which mediates cyclic electron flow through plastoquinone.3. Violaxanthin availability was zero in the dark and increased in the light to a maximum of 67% of the total violaxanthin in chloroplasts. It is proposed that this variable violaxanthin availability reflects conformational changes on the internal surface of the thylakoid membrane which result in variable exposure of violaxanthin to the de-epoxidase. The fact that not all of the violaxanthin was available for de-epoxidation may indicate a heterogenous distribution of violaxanthin in the membrane.     

Studies on the Energy-coupling Sites of Photophosphorylation: V. Phosphorylation Efficiencies (P/e(2)) Associated with Aerobic Photooxidation of Artificial Electron Donors

The rate of Hill reaction can be measured accurately as O₂ uptake (the Mehler reaction) if a rapidly autoxidizable electron acceptor (e.g., methylviologen) is used. However, when an artificial electron donor-ascorbate couple (or ascorbate alone) replaces the natural donor, water, the rate of O₂ consumption is no longer a reliable measure of the electron flux, because superoxide radical reactions contribute to O₂ uptake. Such radical reactions, however, can be suppressed by adding enough superoxide dismutase to the reaction mixture. Indeed in all of the photosystem I- and photosystem II-donor reactions tested (except with benzidine which was tested without ascorbate added), the O₂ uptake was inhibited by 30 to 50% by the addition of superoxide dismutase. The rate of phosphorylation was totally unaffected by the enzyme. The reasessment of the phosphorylation efficiencies thus made by the use of superoxide dismutase led us to the following conclusions. The phosphorylation efficiency associated with the transfer of electrons from a donor to methlylviologen (than to O₂) through both photosystems II and I is practically independent of the donor used—catechol, benzidine, p-aminophenol, dicyanohydroquinone, or water. The P/e₂ ratio is 1.0 ± 0.1. Only ascorbate gives a slightly lower value (P/e₂ = 0.9). (NH₂OH-treated, non-water-splitting chloroplasts were used for reactions with these artificial donors.) The phosphorylation efficiency associated with DCMU-insensitive, photosystem I-mediated transfer of electrons from a donor to methylviologen (then to O₂) is again largely independent of the donor used, such as diaminodurene, diaminotoluene, and reduced 2,6-dichlorphenol-indophenol. The P/e₂ ratio is 0.6 ± 0.08.     

Inhibition of violaxanthin deepoxidation by ultraviolet-B radiation in isolated chloroplasts and intact leaves

The effect of pretreatment with ultraviolet-B (UV-B) light (280-320 nanometers) on the enzymatic conversion of the diepoxyxanthophyll violaxanthin to the epoxy-free zeaxanthin occurring in thylakoid membranes was investigated. When isolated chloroplasts of pea (Pisum sativum) were exposed to UV-B, a biologically effective fluence of 7000 joules per square meter caused about 50% inhibition of the activity of the violaxanthin deepoxidase, measured as the first order rate constant of the absorbance change at 505 nanometers. The dose requirement for the inhibition of the deepoxidase in intact leaves, however, was about 2 orders of magnitude higher. The inhibition of the rate constant was observed for both the dark deepoxidation at pH 5, and for the light-driven deepoxidation induced by the lumen acidification due to electron transport from H₂O to methylviologen or due to a photosystem I partial reaction with duroquinol as the electron donor. The availability of violaxanthin was not directly affected by UV-B radiation, as shown for UV-B-treated chloroplasts by the final extent of the 505 nanometer change measured in the dark at pH 5 or by the partial photosystem I reaction. A significant decrease in the violaxanthin availability was observed when lumen acidification was caused by electron transport from H₂O to methylviologen. That effect was probably caused by the wellknown UV-B inhibition of photosystem II with a subsequent decreased ability to reduce the plastoquinone pool, the redox state of which is believed to regulate the final amount of converted violaxanthin.     

Functional size of photosynthetic electron transport chain determined by radiation inactivation

Radiation inactivation technique was employed to determine the functional size of photosynthetic electron transport chain of spinach chloroplasts. The functional size for photosystem I+II (H₂O to methylviologen) was 623 ± 37 kilodaltons; for photosystem II (H₂O to dimethylquinone/ferricyanide), 174 ± 11 kilodaltons; and for photosystem I (reduced diaminodurene to methylviologen), 190 ± 11 kilodaltons. The difference between 364 ± 22 (the sum of 174 ± 11 and 190 ± 11) kilodaltons and 623 ± 37 kilodaltons is partially explained to be due to the presence of two molecules of cytochrome b₆/f complex of 280 kilodaltons. The molecular mass for other partial reactions of photosynthetic electron flow, also measured by radiation inactivation, is reported. The molecular mass obtained by this technique is compared with that determined by other conventional biochemical methods. A working hypothesis for the composition, stoichiometry, and organization of polypeptides for photosynthetic electron transport chain is proposed.     

Light-induced absorbance changes due to Photosystems 1 and 2 in spinach chloroplasts at −50 °C

Absorbance changes in the region 500–565 nm and at 702 nm, brought about by excitation of Photosystems 1 and 2, respectively, were measured in spinach chloroplasts at ?50 °C. Either dark-adapted chloroplasts were used or chloroplasts preilluminated with a number of short saturating flashes just before cooling.Both photosystems were found to cause a light-induced increase of absorbance at 518 nm (due to “P518”). The System 1-induced change was not affected by preillumination. It decayed within 1 s in the dark and showed similar kinetics as P700. Experiments in the presence of external electron acceptors (methylviologen or Fe(CN)₆^3?) suggested that P518 was not affected by the redox state of the primary electron acceptor of System 1. The absorbance increase at 518 nm due to System 2 decayed in the dark with a half-time of several min. The kinetics were similar to those of C-550, the presumed indicator of the primary electron acceptor of System 2. After two flashes preillumination the changes due to P518 and C-550 were reduced by about 40%, and a relatively slow, System 2-induced oxidation of cytochrome b₅₅₉ occurred which proceeded at a similar rate as the increase in yield of chlorophyll a fluorescence. The results indicate that at ?50°C two different photoreactions of System 2 occur. One consists of a photoreduction of the primary electron acceptor associated with C-550, accompanied by the oxidation of an unknown electron donor; the other is less efficient and results in the photooxidation of cytochrome b₅₅₉.     

Programmed cell death in plants under anaerobic conditions: Effect of Ag+

We investigated epidermal peels from the leaves of pea (Pisum sativum L.) consisting of a monolayer of the cells of two types: stomatal guard cells (GC) with chloroplasts and mitochondria and basic epidermal cells (EC) containing only mitochondria. As inducers of programmed cell death, we used KCN destroying the nuclei in GC and EC and chitosan that destroys nuclei only in EC. AgNO₃ (10 μM) stimulated the destruction of nuclei in GC and EC induced by CN^? and suppressed chitosan-induced destruction of nuclei in EC. The destruction of nuclei in GC induced by CN^? occurred under aerobic conditions and was prevented under anaerobiosis. The destruction of nuclei in GC induced by (CN^? + Ag⁺) occurred both under aerobic and anaerobic conditions and was not suppressed by antioxidants. Among the tested cations of metals (Ag+, Hg²⁺, Fe²⁺, Fe³⁺, Cu²⁺, and Mn²⁺), Ag⁺ turned out to be the most efficient in respect to the stimulation of cyanide-induced destruction of nuclei in GC. Half-maximum concentrations of Ag⁺ and Hg²⁺ were equal to 4–5 μM. In epidermal peels treated with chitosan, GC were permeable to propidium iodide; however, the nuclei in GC (in contrast to EC) were not destructed in the presence of chitosan. It was concluded that Ag⁺, acting as an electron acceptor during photosynthetic electron transfer in the chloroplasts from pea leaves, impeded the O₂ evolution by the chloroplasts treated with ferricyanide or silicomolybdate as electron acceptors, impeded the consumption of O₂ in the course of electron transfer from the (ascorbate + N,N,N′,N′-tetramethyl-p-phenylenediamine) to methylviologen and suppressed the production of reactive oxygen species (ROS) in GC and EC.     

The effect of quinolines on electron transport and proton gradients associated with photophosphorylation in spinach chloroplasts

The effect of several different quinolines and related compounds was investigated on electron transport and proton translocation associated with photophosphorylation in spinach chloroplasts. It was found that many quinolines, regardless of their chelating ability, strongly inhibited dimethylbenzoquinone reduction by photosystem II (PS II) or the ascorbate + diaminodurene (DAD) → methylviologen (MV) pathway in photosystem I (PS I). Ascorbate + N,N,N¹,N¹-tetramethyl-p-phenylene diamine (TMPD) oxidation by PS I could also be inhibited by some quinolines and related compounds. Three modes of action presumably explain the effects observed: (1) chelation of non-heme irons found in PS II between the plastoquinone pool and cytochrome f, (2) non-specific lipid effect on chloroplast membranes by quinoline-like nitrogen bases and (3) sulfhydryl effects on chloroplast proteins by mercaptoquinoline type substances. The inhibition of proton gradients associated with cyclic and non-cyclic photophosphorylation resulted from removal of protons by the quinolines.     

Photophosphorylation in isolated maize bundle sheath chloroplasts and cells

Isolated maize bundle sheath chloroplasts showed substantial rates of noncyclic photophosphorylation. A typical rate of phosphorylation coupled to whole-chain electron transport (methylviologen or ferricyanide as acceptor) was 60 μmol per hour per milligram chlorophyll) with a coupling efficiency (P/e₂) of 0.6. Partial electron transport reactions driven by photosystem I or II supported phosphorylation with P/e₂ values of 0.2 to 0.3. Thus, two sites of phosphorylation seem to be associated with the photosynthetic chain in much the same way as in spinach chloroplasts.     

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     

Studies on the Energy-coupling Sites of Photophosphorylation: II. Treatment of Chloroplasts with NH(2)OH Plus Ethylenediaminetetraacetate to Inhibit Water Oxidation while Maintaining Energy-coupling Efficiencies

Artificial electron donors to photosystem II provide an important means for characterizing the newly discovered site of energy coupling near photosystem II. However, water oxidation must be completely abolished, without harming the phosphorylation mechanism, for these donor reactions and the associated phosphorylation to withstand rigorous quantitative analysis. In this paper we have demonstrated that treatment of chloroplasts with hydroxylamine plus EDTA at pH 7.5 in the presence of Mg²⁺ followed by washing to remove the amine is a highly reliable technique for this purpose. The decline of the Hill reaction and the coupled phosphorylation during the treatment were carefully followed. No change in the efficiency of phosphorylation (P/e₂ 1.0-1.1) was observed until the reactions became immeasurable. Photosystem I-dependent reactions, such as the transfer of electrons from diaminodurene or reduced 2,6-dichlorophenolindophenol to methylviologen, and the associated phosphorylation were totally unaffected. It is clear that the hydroxylamine treatment is highly specific, with no adverse effect on the mechanism of phosphorylation itself. Benzidine photooxidation via both photosystems II and I in hydroxylamine-treated chloroplasts (electron acceptor, methylviologen; assayed as O₂ uptake) supports phosphorylation with the same efficiency as that observed for the normal Hill reaction (P/e₂ = 1.1). An apparent P/e₂ ratio of 0.6 was computed for the photooxidation of ascorbate.     

Coupling Ratios H+/e=3 versus H+/e=2 in Chloroplasts and Quantum Requirements of Net Oxygen Exchange during the Reduction of Nitrite, Ferricyanide or Methylviologen

Using intact and osmotically ruptured chloroplasts, ratios ofcoupling between deposition of protons in the intrathylakoidspace and light-dependent transport of electrons from waterto an external acceptor were determined. The data indicate couplingbetween proton and electron transport at a ratio of H⁺/e=3 withmethylviologen as electron acceptor in thylakoids and with nitriteas electron acceptor in intact chloroplasts. With ferricyanideas electron acceptor in thylakoids, values close to H⁺/e=2 wereobserved. Evidence is discussed that H⁺/e=3 is a fixed valuein intact chloroplasts at levels of thylakoid energization sufficientfor supporting effective carbon assimilation. In the presence of methylviologen and ascorbate, the minimumquantum requirement of oxygen uptake by thylakoids was about2.7 quanta of 675 nm light per O₂ indicating an e/O₂ ratio of1.33. In the absence of ascorbate, and with KCN present in additionto methylviologen, e/O₂ ratios up to 4 were observed. The minimumquantum requirement of oxygen evolution by thylakoids in thepresence of ferricyanide and by intact chloroplasts in the presenceof nitrite was about 8 quanta/O₂. (Received May 1, 1995; Accepted October 2, 1995)     

Site-specific inhibition of photophosphorylation in isolated spinach chloroplasts by HgCl2. II. Evidence for three sites of energy conservation associated with non-cyclic electron transport

Energy transfer inhibition by HgCl₂ has been demonstrated to be selective for certain System I partial reactions. On the basis of different HgCl₂ effects on the System I reactions, reduced 2,6-dichlorophenolindophenol → methylviologen, diaminodurene → methylviologen and N-phenazine methosulfate cyclic, two sites of energy conservation associated with System I are proposed. Furthermore, these sites are in parallel with each other, in series with the site closely associated with Photosystem II and are shared between non-cyclic and cyclic electron transport.     

The site of phosphorylation associated with Photosystem I

1. 1. Small particles prepared from spinach chloroplasts after treatment with digitonin, exhibited Photosystem I reactions, including phosphorylation, at rates as high as those in chloroplasts, whereas electron flow from water to NADP⁺ or ferricyanide through Photosystem II was completely lost. Mediators of cyclic electron flow, such as pyocyanine, or N-methylphenazonium methosulfate in red light, had to be reduced to support photophosphorylation.Diaminodurene at high concentrations catalyzed cyclic phosphorylation under anaerobic conditions without addition of a reductant. In fact, addition of ascorbate gave rise to a marked inhibition which was released by addition of a suitable electron acceptor such as methylviologen.

2. 2. Under aerobic conditions a low O₂ uptake, observed in the presence of diaminodurene, was stimulated several-fold upon addition of methylviologen and was stimulated again several-fold on further addition of ascorbate. The rate of phosphorylation, however, remained the same. The low P/2e ratio obtained under these conditions was not decreased at lower light intensities.

3. 3. These findings suggest a phosphorylation site associated with cyclic electron flow through Photosystem I without participation of the electron carriers of Photosystem II. A non-cyclic electron flow to O₂ can be induced in this system by addition of methylviologen which effectively competes with the electron acceptors of cyclic flow. This non-cyclic electron flow still involves the same phosphorylation site. A scheme for electron transport and for the location of phosphorylation sites in chloroplasts is proposed.

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.     

Evidence for alpha-Tocopherol Function in the Electron Transport Chain of Chloroplasts

The effect of three different stable radicals-2,2-diphenyl-1-picrylhydrazyl, 1,3,5-triphenyl-verdazyl, and galvinoxyl-was studied in photosystem II of spinach (Spinacia oleracea) chloroplasts. Inhibition by the three was noted on dimethylbenzoquinone reduction in presence of 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB) and on silicomolybdate reduction in presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) in photosystem II and on the H₂O → methylviologen reaction encompassing both photosystems. Inhibition of all photosystem II reactions except silicomolybdate reduction could be partially restored by α-tocopherol or by 9-ethoxy-α-tocopherone but not by other quinones or radical chasers. On this basis, a functional role for α-tocopherol in the electron transport chain of spinach chloroplasts between the DCMU and DBMIB inhibition sites is postulated.     

Mechanism of photoactivation of electron transport in intact bryopsis chloroplasts

The mechanism of photoactivation of photosystem I electron transport was studied in intact Bryopsis corticulans chloroplasts. The evidence from chemical and photochemical studies suggests that photoactivation is a consequence of a reduction of an electron transport component, presumably ferredoxin-NADP⁺ reductase. O₂ does not act as a mediator of the process but rather acts as an electron acceptor after photoactivation has occurred. We suggest that the initial function of the chloroplasts in a transition from dark to light is to initiate pseudocyclic electron flow.