The redox state of the NADP system in illuminated chloroplasts

Pyridine nucleotide levels were measured in intact spinach chloroplasts. The NADPH/NADP ratio was close to unity in darkened chloroplasts. On illumination, chloroplast NADP levels decreased rapidly. The decrease was more prominent at low than at high light intensities. In the presence of bicarbonate, NADP subsequently increased to reach a steady-state level. The kinetics of the increase were related in general, but not in detail, to the lag phase of photosynthesis. In the steady state, chloroplast NADP was sometimes, particularly during photosynthesis at high light intensities, less reduced in the light than in the dark. In the dark-light transition, phosphoglycerate reduction is driven by increases in the ratios NADPH/NADP and ATP/ADP. When photosynthesis accelerates after the initial lag phase, the NADPH/NADP ratio decreases and a high ratio of phosphoglycerate to triose phosphate becomes an important factor in driving carbon reduction. Under photosynthetic flux conditions, the redox state of the chloroplast NADP system appeared to be governed largely by the chloroplast ratio of phosphoglycerate to dihydroxyacetone phosphate and by the phosphorylation potential [ATP]/[ADP] [P_i]. The inhibitor of cyclic electron transport, antimycin A, increased reduction of the chloroplast NADP system. Even when reduction was almost complete in the presence of 5 μM antimycin A, photosynthesis was still significant at low light intensities. Electrons appeared to be effectively distributed between the cyclic electron-transport pathway and the noncyclic route to NADP at NADPH/NADP ratios as low as about 1. When bicarbonate was absent, the NADP system remained largely reduced in the light. The energy-transfer inhibitor, Dio-9, and uncouplers and agents which interfered with pH regulation of the Calvin cycle increased reduction of the NADP system while decreasing photosynthesis.     

Inhibitors in the functional dissection of the photosynthetic electron transport system

The significance of inhibitors and artificial electron acceptor and donor systems as experimental tools for studying the photosynthetic system is described by reviewing early classical articles. The historical development in unravelling the role and sequence of electron carriers and energy conserving sites in the electron transport chain is acknowledged. Emphasis is given to inhibitors of the acceptor side of photosystem II and of the plastoquinol oxidation site in the cytochrome b6/f complex. Their role in regulatory processes under redox control is introduced.     

Oxygen exchange associated with electron transport and photophosphorylation in spinach thylakoids

O₂ uptake in spinach thylakoids was composed of ferredoxin-dependent and -independent components. The ferredoxin-independent component was largely 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) insensitive (60%). Light-dependent O₂ uptake was stimulated 7-fold by 70 μM ferredoxin and both uptake and evolution (with O₂ as the only electron acceptor) responded almost linearly to ferredoxin up to 40 μM. NADP⁺ reduction, however, was saturated by less than 20 μM ferredoxin. The affinity of O₂ uptake for for O₂ was highly dependent on ferredoxin concentration, with $\text{K}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{(O}{}_2\text{)}$ of less than 20 μM at 2 μM ferredoxin but greater than 60 μM O₂ with 25 μM ferredoxin. O₂ uptake could be suppressed up to 80% with saturating NADP⁺ and it approximated a competitive inhibitor of O₂ uptake with a K_i of 8–15 μM. Electron transport in these thylakoids supported high rates of photophosphorylation with NADP⁺ (600 μmol ATP/mg Chl per h) or O₂ (280 μmol/mg Chl per h) as electron acceptors, with $\text{ATP}\text{2}\text{e}$ ratios of 1.15–1.55. Variation in $\text{ATP}\text{2}\text{e}$ ratios with ferredoxin concentration and effects of antimycin A indicate that cyclic electron flow may also be occurring in this thylakoid system. Results are discussed with regard to photoreduction of O₂ as a potential source of ATP in vivo.     

Rapid proton release accompanying photosynthetic electron transport in intact cells of Rhodopseudomonas capsulata

The release of protons from intact cells of Rhodopseudomonas capsulata after either 4μs flashes or during brief periods of continuous illumination has been measured with the indicator, cresol red. The half-time for H⁺-release after a flash was 35 ms and the extent, 1H⁺ per 134 bacteriochlorophyll. Myxothiazol completely inhibited the flash-induced H⁺-release and antimycin A reduced it by 37%. The proton-releasing reaction is discussed with reference to the protonmotive Q-cycle. During continuous illumination the rapid phase of H⁺ release is followed by a lag and then by another period of acidification, suggesting that other protolytic reactions may be in operation.     

Conditions limiting the use of ionophore A23187 as a probe of divalent cation involvement in biological reactions. Evidence from the slow fluorescence quenching of Type A spinach chloroplasts

The conditions under which ionophore A23187 can be used as a probe of Mg²⁺ involvement in the reactions of intact (Type A) spinach chloroplasts have been investigated by monitoring ionophore-induced reversal of slow fluorescence quenching. The following observations were made: (1) A23187-dependent reversal of quenching is a strong function of pH. This is consistent with competition between protons and divalent cations for the carboxylic acid moiety of the ionophore. (2) In the presence of exogenous Mg²⁺, quenching reversal by A23187 is significantly slowed. It is suggested that formation of the dimeric A23187 · Mg²⁺ complex delays action of the ionophore at the thylakoid membrane by slowing equilibration of the ionophore among chloroplast membrane phases. (3) In the absence of Mg²⁺, significant interaction of A23187 with certain monovalent cations — Li⁺ and Na⁺, but not K⁺ — is observed. Evaluations of the interaction of ionophore A23187 with specific biological systems and inferences of divalent cation involvement, or lack thereof, must take these limitations into account.     

Regulation of the photosynthetic electron transport chain

The regulation of electron transport between photosystems II and I was investigated in the plant Silene dioica L. by means of measurement of the kinetics of reduction of P₇₀₀ following a light-to-dark transition. It was found that, in this species, the rate constant for P₇₀₀ reduction is sensitive to light intensity and to the availability of CO₂. The results indicated that at 25 °C the rate of electron transport is down-regulated by approximately 40–50% relative to the maximum rate achievable in saturating CO₂ and that this down-regulation can be explained by regulation of the electron transport chain itself. Measurements of the temperature sensitivity of this rate constant indicated that there is a switch in the rate-limiting step that controls electron transport at around 20 °C: at higher temperatures, CO₂ availability is limiting; at lower temperatures some other process regulates electron transport, possibly a diffusion step within the electron transport chain itself. Regulation of electron transport also occurred in response to drought stress and sucrose feeding. Measurements of non-photochemical quenching of chlorophyll fluorescence did not support the idea that electron transport is regulated by the pH gradient across the thylakoid membrane, and the possibility is discussed that the redox potential of a stromal component may regulate electron transport. Received: 4 March 1999 / Accepted: 25 May 1999     

The interaction of nitrite with photosynthetic electron transport under anaerobic conditions

Chlorella cells were examined in a modulated oxygen polarograph under aerobic and anaerobic conditions. At light intensities below about 600 ergs · cm^?2 · s^?1 of 650 nm light, the oxygen yield and phase lag are lower under anaerobic conditions. Addition of 25 mM sodium nitrite increases both these parameters to values close to those found in the presence of oxygen. It is proposed that nitrite is reduced by Photosystem I thus diverting electrons from the cyclic electron transport pathway. The intersystem electron transport chain becomes more oxidized and this suppresses a backflow of electrons to the oxidizing side of Photosystem II, hence increasing the oxygen yield and the phase lag. The removal of oxygen from the bathing medium also alters the response of dark adapted _Chlorella to a series of saturating light flashes. In terms of the Kok model of Photosystem II (Kok, B., Forbush, B. and McGloin, M. (1970) Photochem. Photobiol. 11, 457–475) there is a large increase in the parameter α. Addition of nitrite reverses this change and virtually restores the response seen in the presence of oxygen. The deactivation of the S₂ state is greatly speeded up in the absence of oxygen but the addition of nitrite again reverses this.     

Pyridine nucleotides and H2 as electron donors to the respiratory and photosynthetic electron-transfer chains and to nitrogenase in Anabaena heterocysts

The pathways through which NADPH, NADH and H₂ provide electrons to nitrogenase were examined in anaerobically isolated heterocysts. Electron donation in freeze-thawed heterocysts and in heterocyst fractions was studied by measuring O₂ uptake, acetylene reduction and reduction of horse heart cytochrome c. In freeze-thawed heterocysts and membrane fractions, NADH and H₂ supported cyanide-sensitive, respiratory O₂ uptake and light-enhanced, cyanide-insensitive uptake of O₂ resulting from electron donation to O₂ at the reducing side of Photosystem I. Membrane fractions also catalyzed NADH-dependent reduction of cytochrome c. In freeze-thawed heterocysts and soluble fractions from heterocysts, NADPH donated electrons in dark reactions to O₂ or cytochrome c through a pathway involving ferredoxin:NADP reductase; these reactions were only slightly influenced by cyanide or illumination. In freeze-thawed heterocysts provided with an ATP-generating system, NADH or H₂ supported slow acetylene reduction in the dark through uncoupler-sensitive reverse electron flow. Upon illumination, enhanced rates of acetylene reduction requiring the participation of Photosystem I were observed with NADH and H₂ as electron donors. Rapid NADPH-dependent acetylene reduction occurred in the dark and this activity was not influenced by illumination or uncoupler. A scheme summarizing electron-transfer pathways between soluble and membrane components is presented.     

The role of ubiquinone in linking nitrate reductase and cytochrome o to the respiratory chain of Paracoccus denitrificans

Three alternatives of the mode of branching in the ubiquinone-cytochrome b region of the anaerobic respiratory chain of Paracoccus denitrificans were experimentally tested. It was found that the view that the constitutive cytochrome b-560 or b-566 serves as an electron donor for the nitrate reductase is incompatible with the proposed scheme of the cyclic electron flow in the bc₁ segment. By means of the extraction procedure, the extent of reduction of ubiquinone was determined in cells utilizing oxygen and nitrate in the presence of antimycin. It was found that the redox response of ubiquinone was consistent with what had been predicted by the pool model of Kröger and Klingenberg, extended for more than one terminal acceptor. Our results are in support of the assumption that in cells of P. denitrificans ubiquinol (QH₂) has a function of an electron donor both for nitrate reductase and cytochrome o.     

Respiratory control over photosynthetic electron transport in chloroplasts of higher-plant cells: evidence for chlororespiration

Flash-induced primary charge separation, detected as electrochromic absorbance change, the operation of the cytochrome b/f complex and the redox state of the plastoquinone pool were measured in leaves, protoplasts and open-cell preparations of tobacco (Nicotiana tabacum L.), and in isolated intact chloroplasts of peas (Pisum sativum L.). Addition of 0.5–5 mM KCN to these samples resulted in a large increase in the slow electrochromic rise originating from the electrogenic activity of the cytochrome b/f complex. The enhancement was also demonstrated by monitoring the absorbance transients of cytochrome f and b ₆ between 540 and 572 nm. In isolated, intact chloroplasts with an inhibited photosystem (PS) II, low concentrations of dithionite or ascorbate rendered turnover of only 60% of the PSI reaction centers, KCN being required to reactivate the remainder. Silent PSI reaction centers which could be reactivated by KCN were shown to occur in protoplasts both in the absence and presence of a PSII inhibitor. Contrasting spectroscopic data obtained for chloroplasts before and after isolation indicated the existence of a continuous supply of reducing equivalents from the cytosol.Our data indicate that: (i) A respiratory electron-transport pathway involving a cyanide-sensitive component is located in chloroplasts and competes with photosynthetic electron transport for reducing equivalents from the plastoquinone pool. This chlororespiratory pathway appears to be similar to that found in photosynthetic prokaryotes and green algae. (ii) There is an influx of reducing equivalents from the cytosol to the plastoquinone pool. These may be indicative of a complex respiratory control of photosynthetic electron transport in higher-plant cells.Abbreviations and symbols A₅₁₅ flash-induced electrochromic absorbance change at 515 nm - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PS photosystem - SHAM salicylhydroxamic acid     

Reaction of cytochrome c in the electron-transport chain of Paracoccus denitrificans

The reaction of the cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1) of Paracoccus denitrificans cytoplasmic membranes with the endogenous cytochrome c of the membranes was studied, as well as its interaction with added exogenous cytochrome c from P. denitrificans or bovine heart. The polarographic method was employed, using N,N,N′,N′-tetramethyl-p-phenylenediamine plus ascorbate to reduce the cytochrome c. We found that overall electron transport can proceed maximally while the cytochrome c remains membrane bound; NADH or succinoxidase activities were not inhibited by the addition of substances which bind the P. denitrificans cytochrome c strongly. In contrast to our observations with the spectrophotometric method (Smith, L., Davies, H.C. and Nava, M.E. (1976) Biochemistry 15, 5827–5831), in the polarographic assays the membrane-bound oxidase reacts with about equal rapidity with exogenous bovine and P. denitrificans cytochromes c. The reaction of the oxidase with the endogenous cytochrome c proceeds at high rates and preferentially to that with exogenous cytochrome c; the reaction with the latter, but not the former is inhibited by positively charged poly(l-lysine). The cytochrome c and the oxidase appear to be very closely associated on the membrane.     

Action of cyanide on the photosynthetic water-splitting process

KCN inhibits O₂ evolution from inside-out chloroplast thylakoid vesicles suspended in a low chloride-containing medium. Evidence is presented to suggest that the inhibition is due to CN^? and that this anion blocks electron flow close to the water-splitting process by interacting with a photo-oxidised species.     

Sulfhydryl reagents inhibit electron transport in Photosystem II of spinach chloroplasts

A 120 min incubation period with sulfhydryl reagents, such as p-chloromercuribenzoic acid, shows greater than 50% loss of electron-transport activity in Photosystem (PS) II of spinach chloroplasts. Since p-chloromercuriphenylsulfonic acid, a nonpenetrating sulfhydryl reagent, and 4,4′-dithiopyridine, a bifunctional sulfhydryl reagent, show greater inhibition of 3-(3,4-dichlorophenyl)-1,1-dimethylurea-insensitive silicomolybdate reduction than of dibromothymoquinone-insensitive indophenol reduction, it is postulated that two different sulfhydryl reagent-sensitive sites are involved in the PS II electron-transport chain of spinach chloroplasts.     

Key-word system of indexing

The effects of uncouplers of photophosphorylation on the P-S₁ transient of the fluorescence induction in darkadapted intact chloroplasts of Bryopsis maxima were studied to examine the mechanism of light-dependent regulatory changes in electron transport. (1) Carbonyl cyanide m-chlorophenylhydrazone (CCCP) and nigericin slowed down the fluorescence quenching from P to S₁, whereas the transient was significantly accelerated by the addition of NH₄Cl and methylamine. (2) The P-S₁ decline was slowed down at low pH of the suspending medium, suggesting sensitivity of the transient to the stroma pH. The inhibitory effect of nigericin was markedly enhanced at low pH and at low KCl concentrations, whereas the ionophore stimulated the transient at high pH and at high KCl concentrations. Similar results were obtained on the combined addition of CCCP and valinomycin. (3) Nigericin and the CCCP-valinomycin couple altered the internal pH of intact chloroplast through the H⁺-K⁺ exchange across the outer limiting membrane. The fluorescence decline was rapid at alkaline internal pH but was suppressed with lowering internal pH below 8.0 (4) A similar internal pH dependence of the transient was obtained when the internal pH was changed by the addition of NH₄Cl and acetate. (5) It is proposed that the photoactivation of electron transport is regulated by the stroma pH. The progress of the photoactivation is slow at acidic or neutral pH but is significantly accelerated by light-induced alkalinization near the light-regulation site of electron transport located on the outer surface of the thylakoid membrane.     

Regulation of proton-to-electron stoichiometry in photosynthetic electron transport: physiological function in photoprotection

The primary stable products of photosynthetic electron flow are NADPH and ATP. Stoichiometry of their production depends on the ratio of protons pumped across the thylakoid membrane to electrons passed through the electron transport pathway (H⁺/e⁻ ratio). Flexible requirements of the ATP/NADPH ratio by various assimilatory reactions in chloroplasts must be fulfilled by the H⁺/e⁻ ratio during the electron flow. In addition to the well-known role of ΔpH during ATP synthesis, ΔpH also functions as a trigger of the down-regulation of photosystem II (PSII) photochemistry. Excessive light energy is safely dissipated as heat by this regulatory process to suppress the generation of toxic reactive oxygen species. Thus, regulation of the H⁺/e⁻ ratio may function in the photoprotection, as well as in the regulation of the ATP/NADPH production ratio. It has long been the consensus that the H⁺/e⁻ ratio can be controlled by regulating the proton-transporting Q-cycle in the cytochrome b ₆ f complex and by the cyclic electron flow around photosystem I (PSI). Despite the possible physiological importance and the long history of interest, the molecular identity of Q-cycle regulation and the cyclic electron flow around PSI have been remained unclear. The recent improvements in research tools, including the genetic approach using chlorophyll fluorescence imaging and establishment of the chloroplast transformation technique, are providing new insights into classical topics. In this review, we focus on regulation of the H⁺/e⁻ ratio especially from the view of photosynthetic regulation. Received: August 2, 2001 / Accepted: October 1, 2001     

Electron transfer between the two photosystems. I. Flash excitation under oxidizing conditions

The redox changes of cytochrome b-563 (cytochrome b), cytochrome f, plastocyanin and P-700 were measured on dark-adapted chloroplasts after illumination by a series of flashes in oxidizing conditions (0.1 mM ferricyanide). In these conditions, the plastoquinone pool is fully oxidized and the only available plastoquinol are those formed by Photosystem (PS) II reaction. According to the two-electron gate mechanism proposed by Bouges-Bocquet (Bouges-Bocquet, B. (1973) Biochim. Biophys. Acta 314, 250–256), plastoquinol is mainly formed after the second and the fourth flashes. After the second flash, the reoxidation of plastoquinol occurs by a concerted reaction which reduces most of the cytochrome b present and a fraction of PS I donors. Most of these electrons are stored on P-700, which implies a large equilibrium constant between the secondary PS I donors and P-700. One electron is stored on cytochrome b during a time ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈ 1}\text{s}$) much longer than the dark interval between flashes. After the fourth flash, a new plastoquinol molecule is formed, which induces the reduction of PS I donors with no corresponding further reduction of cytochrome b. The number of electrons transferred after the fourth flash is larger than that transferred after the second flash although the rate of transfer is lower. To interpret these data, we assume that the plastoquinol formed after the fourth flash is reoxidized by a second concerted reaction: one electron is directly transferred to PS I donors while the other cooperates with the electron stored on cytochrome b to reduce a plastoquinone molecule localized on a site close to the outer face of the membrane. This newly formed plastoquinol crosses the membrane and transfers a second electron to PS I donors. This interpretation resembles a model proposed by Velthuys (Velthuys, B.R. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 2765?2769) and which belongs to the modified Q-cycle class of models.     

Cyclic electron transport in chloroplasts. The Q-cycle and the site of action of antimycin

Cyclic electron transport systems have been set up in broken chloroplasts, with photochemically reduced ferredoxin or 9,10-anthraquinone-2-sulphonate as cofactor. In good agreement with the literature, only the ferredoxin-catalyzed pathway was found to be inhibited by antimycin; but both pathways were found to have a slow electrogenic reaction, both were inhibited by the cytochrome b-563 oxidation inhibitor 2-heptyl-4-hydroxyquinoline N-oxide (the inhibition being strongest at limiting light intensity), and the two pathways had the same proton/electron stoichiometry at limiting light intensity. It is concluded that a Q-cycle can occur in cyclic electron transport with either cofactor; and therefore that the site of action of antimycin in chloroplasts is not within the Q-cycle, as it is believed to be in mitochondria and bacteria. Instead, a ferredoxin-quinone reductase is proposed as the site of action of antimycin in the ferredoxin-catalyzed cyclic pathway. It is also concluded that the data presented here are consistent with the suggestion that the Q-cycle in photosynthetic electron transport is a facultative one, its degree of engagement depending on competition between the Rieske centre and cytochrome b-563 for reducing equivalents from plastosemiquinone.     

Characterization of the photosynthetic electron transport chain in normal and photobleachedAnabaena cylindrica by flash spectroscopy

Electron transport of normal and photobleachedAnabaena cylindrica was studied using spectral and kinetic analyses of absorbance transients induced by single turnover flashes. Between 500 and 600 nm two positive bands (540 and 566 nm) and two negative bands (515 and 554 nm) were found. Absorbance changes at 515 and 540 nm were partly characterized. None of these absorbance changes represent an electrochromic shift. Absorbance changes at 554 and 566 nm correspond to the oxidation of cytochromef and the reduction of cytochromeb ₅₆₃, respectively. We found a very slight 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU) sensitivity of cytochromef in normal cells, while DCMU was completely ineffective for cytochromef reduction in photobleached cells. The absorbance change of cytochromeb ₅₆₃ increased, while the absorbance change of cytochromef was smaller than in normal cells. The increased O₂ evolution in photobleached cells and the negligible electron transport via cytochromef suggest the participation of other electron acceptor(s) in the electron-transport chain of photobleachedAnabaena cylindrica.     

Silicotungstate lowers dramatically the quantum yield of chlorophyll fluorescence in situ without affecting the rate of electron transport

Electron-transport and fluorescence properties of chloroplasts in the presence of silicotungstate are studied by O₂-evolution and fluorescence-quenching techniques. Results show that silicotungstate lowers the fluorescence quantum yield of closed units, without affecting electron-transport activities of open units. Open and closed units are units with oxidized and reduced primary electron acceptor (Q), respectively.     

Oxidation and reduction of plastoquinone by photosynthetic and respiratory electron transport in a cyanobacterium Synechococcus sp.

The I-D dip, an early transient of the fluorescence induction, was examined as a means to monitor redox changes of plastoquinone in cells of a cyanobacterium, Synechococcus sp. That the occurrence of the dip depends upon the reduced state of the plastoquinone pool was indicated by observations that 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone and 3-(3,4-dichlorophenyl)-1,1-dimethylurea did not affect the initial rise to I but abolished the subsequent decline from I to D and that illumination of the cells with light 1, prior to fluorescence measurements, eliminated the transient. The I-D dip was prominent in freshly harvested cells containing abundant endogenous substrates, disappeared slowly as the cells were starved by aeration but reappeared on addition of fructose to the starved cells in the dark. The dip that had been induced by a brief illumination of the starved cells with light 2 was rapidly diminished in the dark and KCN inhibited the dark decay of the transient. The results indicate that plastoquinone is reduced with endogenous as well as exogenous substrates and oxidized by a KCN-sensitive oxidase in the dark, thus providing strong support for the view that plastoquinone of photosynthetic electron transport also functions in respiration. In addition, the occurrence of a cyclic pathway of electrons from Photosystem I to plastoquinone, possibly via ferredoxin or NADP, was suggested. Several lines of evidence indicate that, under a strong light 2, Photosystem I-dependent oxidation of plastoquinone predominates over Photosystem II-dependent reduction of the quinone in the cyanobacterium which contains Photosystem I more abundantly than Photosystem II.