PHOTOSYNTHETIC NITRITE REDUCTION BY DITHIOERYTHRITOL AND THE EFFECT OF NITRITE ON ELECTRON TRANSPORT IN ISOLATED CHLOROPLASTS

Abstract. Photosynthetic reduction of nitrite to ammonia with type C chloroplasts from the heterocont alga Bumilleriopsis filiformis was investigated using 3,6-diaminodurene/ascorbate and 3,6-diaminodurene/dithioerythritol (DAD/DTE) as electron donor couple. Rates approach 6–10 μmol NO^-₂ reduced/mg chlorophyll/h and are steady for up to 30 min. The presence of oxygen or NADP⁺ only slightly diminished the rates of nitrite reduction obtained with DAD/DTE. Illuminated chloroplasts reduce oxygen in the presence of DAD/DTE at 135 μmol/mg chlorophyll/h without acceptor supplied. Photosynthetic oxygen uptake by this system in the presence of ferredoxin and NO^-₂, however, is inhibited to 42% by nitrite reductase with concurrent nitrite reduction. NO^-₃ and NO^-₂ have no effect on photosystem I-mediated NADP⁺ reduction, NO^-₂ (10 m M ) inhibits ferricyanide-mediated oxygen evolution to 72%. Also photosystem II reactions assayed e.g. with silicomolybdate are inhibited significantly by NO^-₂ (1 m M ), but only slightly by NO^-₃. Nitrite reductase is inhibited by p -chloromercuribenzoate ( p CMB), and this inhibition is prevented by DTE. Results suggest that photosynthetic nitrite reduction can cope with low concentrations of either compound, provided relevant thiol groups are protected.     

INHIBITION OF ELECTRON TRANSPORT IN CHLOROPLASTS BY CHAOTROPIC AGENTS AND THE USE OF MANGANESE AS AN ELECTRON DONOR TO PHOTOSYSTEM II*

Abstract— Incubating spinach chloroplasts with various chaotropic agents results in inhibition of photosynthetic electron transport between water and Photosystem II similar to the inhibition caused by washing chloroplasts with a high concentration of Tris buffer. Partial restoration of NADP photoreduction and fluorescence of variable yield is achieved by adding hydroquinone or Mn²⁺, either of which donates electrons to Photosystem II in the inhibited chloroplasts. The inhibitory treatments cause the release of Mn from its bound state in the chloroplast, thus allowing the measurement of the ESR signal of Mn²⁺. The ESR measurement is used to follow the photooxidation of Mn²⁺ as it donates electrons to photosystem II.     

ALTERNATIVE MEASURES OF PHOTOSYSTEM II ELECTRON TRANSFER INHIBITION IN ANTHRAQUINONE-TREATED CHLOROPLASTS

We have previously used chlorophyll fluorescence measurements at Fmax conditions (i.e. with Photosystem II electron acceptor QA reduced) to monitor the action of 9,10-anthraquinones on photosynthetic electron transport in plant chloroplasts. The present investigation employs two additional techniques to characterize the extent of electron transport inhibition induced by the addition of substituted anthraquinones to the suspending medium of spinach chloroplasts. Results are presented for spectrophotometric assays of the rate of electron transfer to an exogenous electron acceptor, 2,6-dichloroindophenol (DCIP) and for electrochemical determinations of the rate of oxygen evolution in anthraquinone-treated chloroplasts. In general, amino-substituted anthraquinones are ineffective inhibitors, maintaining electron transfer rates to DCIP at levels ranging from 50 to 90% of normal rates and yielding rates of O2 evolution averaging at 70% of the rate in untreated chloroplasts. In contrast, hydroxy-substituted anthraquinones efficiently block Photosystem II electron transport, resulting in low rates of DCIP photoreduction ranging from 0 to 20% of normal values and reducing O2 evolution rates to an average of 30% of the rate observed for untreated chloroplasts. Relative rates of DCIP photoreduction for anthraquinone-treated chloroplasts show a strong linear correlation with the reported relative Fmax chlorophyll fluorescence intensities. Relative O2 evolution rates are observed to correlate with the Stern-Volmer fluorescence quenching parameter Ksv. We suggest that slight differences in the extent of inhibitory activity of an anthraquinone as measured by the three techniques are consistent with certain known Photosystem II heterogeneities. The similarities in relative rankings of inhibitory effects for the 9, 10-anthraquinones, however, demonstrate that the three techniques employed (measurements of Fmax chlorophyll fluorescence, DCIP photoreduction rates, and O2 evolution rates) are alternative assays of anthraquinone-induced Photosystem II electron transport inhibition.     

OSCILLATIONS OF THE TRIGGERED LUMINESCENCES OF ISOLATED CHLOROPLASTS PREILLUMINATED BY SHORT FLASHES*

Abstract— Four types of triggered luminescence of isolated lettuce chloroplast (HCl-induced, methanol-induced, sodium benzoate-induced and T-jump-induced) were examined after preillumination by a series (from 1 to 10) of short flashes. Oscillations were observed in the luminescence peaks, with a period of four flashes. These oscillations had maxima after the second and the sixth flash, similar to those of delayed light emission. The maxima were shifted forward two flashes by 50 μ M hydroxylamine, as in oxygen evolution, and were abolished by 5 μ M DCMU, as for delayed light. These results may show that the mechanism of triggered luminescence is influenced directly by the oxidation states ( S ₁) on the donor side of photo-system II.     

ELECTRON SPIN ECHO ENVELOPE MODULATION OF THE TRANSIENT EPR SIGNALS OBSERVED IN PHOTOSYNTHETIC ALGAE AND CHLOROPLASTS*

Phase memory decays were obtained from the transient signals sampled within 50 ns of laser excitation by time resolved electron spin echo (ese) spectroscopy in normal protonated, deuterated, deuterated ¹⁵N photosynthetic algae and broken chloroplasts. Previously, it has been shown that application of time resolved ese to study these systems, in particular, gives rise to two kinds of signals (standard and special ese). The standard ese signal at g = 2.0023 and the special ese signal exhibit similar electron spin echo envelope modulation (eseem). The modulation frequency and pattern can be identified with that obtained from stable oxidized P₇₀₀ in the same system. The two lower field resonances of the standard ese signal do not show eseem. The results support the proposed mechanism for formation of special ese and the notion that the standard ese is due to at least two radicals. It is also demonstrated that we can observe eseem of P⁺₇₀₀ under ambient temperature conditions.     

EFFECT OF INACTIVATION OF THE OXYGEN-EVOLVING SYSTEM ON THE THERMOLUMINESCENCE OF ISOLATED CHLOROPLASTS

Abstract— The effect of inactivation of water-splitting enzyme on the thermoluminescence of isolated chloroplasts was investigated. The inhibitory treatments used included Tris-washing, alkaline pH in the presence of the uncoupler gramicidin, incubation with a high concentration of magnesium ions and different chaotropic agents. It was found that inhibition of oxygen evolution resulted in the disappearance of the main thermoluminescence band at +20°C. The A band which appears at — 10°C and has been related to the S₄ state of the water-splitting enzyme (Inoue, 1981) was not considerably affected by the inhibition of oxygen evolution. The results presented here indicate that the participation of the S₄ state of water-splitting enzyme in the generation of the A band should be reinvestigated.     

PHOTOCHEMISTRY OF THE REACTION CENTERS OF SYSTEM II UNDER REPETITIVE FLASH GROUP EXCITATION IN ISOLATED CHLOROPLASTS

Abstract— Absorption changes induced in isolated chloroplasts by excitation with repetitive flash groups have been measured at 690 nm, indicating the photochemical turnover of chlorophyll-a_II (Chl-αn), and at 480 nm and 513 nm respectively, reflecting via electrochromic effect the formation of a transmembrane electric field. The data are compared with measurements of oxygen evolution. In chloroplasts with practically fully intact oxygen evolving capacity it was found: 1. The initial amplitude of the 690 nm absorption change induced by the second flash as a function of the time t_v between the first and second flash of a group increases with a half life of about 35 µs. On the other hand, the average oxygen yield due to the second flash as a function of the time t_v rises with a half life of about 600 µs (and a kinetics in the ms-range of minor extent), confirming the data of Vater et al. (1968). 2. Under far red background illumination, where contributions due to PS I in the µs-range can be excluded, the difference spectrum in the red of the absorption changes induced by the first flash corresponds with that of the absorption changes induced by the second flash fired 200 µ after the first flash. 3. The pattern of the absorption changes at 690 nm induced by repetitive double flash groups at t_v= 200 µs does not markedly change in normal chloroplasts by the presence of DBMIB?. Similar 690 nm absorption changes occur in trypsin treated chloroplasts, independent of the presence of DCMU. 4. The fast regeneration in the µs-range of Chl-a_n is also observed in the third flash of a triple flash group at a time t_v= 200 µs between the flashes of the group. 5. The initial amplitudes of the absorption changes with a decay kinetics slower than 100 µs induced by the second flash at 480 nm and 513 nm, respectively, as a function of the time t, between the first and second flash of a group, are characterized by a recovery half-time of about 600 µs, confirming earlier measurements at 520 nm (Witt and Zickler, 1974). On the basis of these results it is inferred that there does exist a photoreaction of Chl-α_n., with an electron acceptor, referred to as X_a, other than the ‘primary’ plastoquinone acceptor X320, if X320 persists in its reduced state. Under conditions of X320 being in the reduced state, this photochemical reaction was shown to be highly dissipative with respect to charging up the watersplitting enzyme system Y. Furthermore, this Chl-a_n-photoreaction with X_a does not lead to a vectorial transmembrane charge separation, which is stable for more than a few microseconds. Different models for the functional and structural organization of PS II are discussed.     

HERBICIDE MEDIATED UV-RESISTANCE IN CYANOBACTERIA: ON THE ROLE OF PHOTOSYNTHETIC ELECTRON TRANSPORT SYSTEM RATHER THAN REPLICATIVE DNA AS LETHAL TARGET DETERMINING DARK-SURVIVAL OF Anacystis nidulans

Abstract— The role of the replicative state of DNA and of the photosynthetic electron transport system in determining UV-sensitivity of A. nidulans under conditions of non-photoreactivation (by incubating the cells for 24 h in the dark following UV-irradiation) has been investigated. Both the DNA synthesis data and the data on survival levels during cell cycle synchrony forced by light to dark and dark to light transitions showed that the differential UV-sensitivity was not correlated with the replicative state of the DNA as suggested earlier. However, incubation in the light with the herbicides 2/3-4, dichlorophenyl/-l, 1-dimethyl urea (DCMU) and 2-chloro-4-ethylamino-6-isopropylamino-s-triazine (atrazine) which are known to inhibit electron transport by specifically binding to the high turnover B protein of photosynthetic electron transport system II (PSII), enhanced the UV-resistance with kinetics similar to those of a culture transferred from light to dark. We interpret this result as implicative of PSII as the second lethal target in the case of cyanobacteria. The inactivation of electron transport activity of PSII as measured by the fall in DCMU-sensitive fluorescence yield during post-UV dark incubation supports this hypothesis. It is proposed that in wild type cells the survival under conditions of non-photoreactivation following UV-irradiation is essentially determined by the level of dark-repair of damage to PSII and that the 32 kD B protein may have a role in dark-repair of damage to the electron transport system. This hypothesis explains the paradox of negative liquid holding recovery phenomenon under conditions which promote excision-repair of damaged DNA in cyanobacteria.     

THE CONTRIBUTION OF RHODOSPZRZLLUM RUBRUM FERREDOXIN II TO IN VIVO EPR SIGNALS AND ITS ROLE IN ELECTRON TRANSPORT

Evidence is presented that Fd II, an iron-sulfur protein containing 4 irons and 4 acid-labile sulfurs, is responsible for a number of signals previously reported detectable in cells of R. rubrum. When oxidized, Fd II exhibits a g = 2.012 EPR signal which is readily detected in R. rubrum cells. In our hands, Fd II is photochemically reduced to an EPR-silent product contrary to the results of other investigators. However. in the presence of reducing agents. the reduced form is apparently denatured upon freezing. The denatured form exhibits EPR signals similar to some also previously observed in whole cells. Fd II catalyzes the ascorbate-DCPIP linked photoreduction of NAD with R. rubrum chromatophores even in the presence of an inhibitor which suppresses the formation of pH and emf gradients. This result raises the possibility of a role for Fd II in non-cyclic electron transport in R. rubrum.     

SUPPRESSION OF LIPID PHOTOPEROXIDATION BY QUERCETIN AND ITS GLYCOSIDES IN SPINACH CHLOROPLASTS

Abstract— Quercetin, quercitrin and rutin suppressed lipid photoperoxidation in spinach chloroplasts in the presence of 100 μ M carbonylcyanide m -chlorophenylhydrazone (CCCP) or 100 μ M methyl viologen (MV). Fifty percent inhibition of lipid peroxidation by quercetin was observed between 30 and 50 μ M . Concentrations of quercetin and rutin higher than 100 μ M were required to obtain 50% inhibition. Ouercitrin was more effective than rutin in the suppression of lipid photoperoxidation.
Photooxidation of the flavonols by chloroplasts in the presence of MV was suppressed by superoxide dismutase (SOD) more than 90%, and the rates of the oxidation decreased in order of quercetin, quer citrin and rutin suggesting that the reactivity of the flavonols with O₂-decreased in that order. The photooxidation of the flavonols by CCCP-poisoned chloroplasts was partially suppressed by SOD. Radicals generated in the course of lauroyl peroxide degradation also oxidized the flavonols and the oxidation was insensitive to SOD. In these experiments, oxidation rate of quercetin was faster than those of its glycosides. The results obtained suggest that flavonols can function as antioxidants in chloroplasts by scavenging both O₂-and the radicals formed during lipid peroxidation.     

PICOSECOND TRANSIENT BEHAVIOR OF REACTION-CENTER PARTICLES OF PHOTOSYSTEM I ISOLATED FROM SPINACH CHLOROPLASTS. ENERGY AND ELECTRON TRANSFER UPON SINGLE AND MULTIPLE PHOTON EXCITATION

Abstract— Both [15-¹³C] and [14-¹³C] all-trans-retinals were synthesized. Bacteriorhodopsin containing [14-¹³C]retinal as a chromophore, when solubilized with octyl-β-D-glucoside, showed characteristic resonances at 125 and 118 ppm from tetramethyl silane. The former was assigned to the signal from free retinal and the latter from protonated Sehiff base. When the bacteriorhodopsin was denatured in sodium dodecyl sulfate, the signal at 118 ppm disappeared, while the signal at 125 ppm rather increased.
In the case of bacteriorhodopsin containing [15-¹³C]retinal, when solubilized with Triton X-100, a characteristic resonance at 169 ppm was distinguishable as a shoulder peak superimposed on the broad signal of carbonyl carbons and it was assigned to the signal from the protonated Sehiff base. The other signal observed at 191 ppm was from free retinal.
These results suggested that the Sehiff base of bacteriorhodopsin is protonated in the dark.     

NEW PHOTOSYSTEM I ELECTRON ACCEPTORS: IMPROVEMENT OF HYDROGEN PHOTOPRODUCTION BY CHLOROPLASTS *

Abstract Four novel electron carriers (two zwitterionic bipyridyls, dicarboxyl colbalticinium and sodium metatungstate), which are negatively charged in their reduced form, have been tested as photo-system I acceptors and as mediators of H₂ evolution. Measurements of O₂ uptake, anaerobic photoreduction rates and stationary concentrations of reduced species under continuous illumination indicate that Coulombic interactions control the electron transfer between the photosynthetic membrane and the mediators. Both rates of forward transfer and back reaction (electron cycling) seem to depend on the charge of the electron carrier. The low concentration of anionic species in the diffuse layer associated with the membrane could explain our results. Hydrogen evolution rates obtained with these four mediators used as electron relays between the photosynthetic membrane and colloidal platinum catalyst are higher than with methylviologen. This improvement of the conversion efficiency parallels the high steady state accumulation of reduced carriers favoured by their negative charge. It is also shown that these synthetic mediators, except metatungstate, are able to evolve hydrogen with an hydrogenase isolated from Desulfovibrio desulfuricans.     

LIMITING REACTIONS IN HYDROGEN PHOTOPRODUCTION BY CHLOROPLASTS AND HYDROGENASE

Abstract— Hydrogen was photoproduced from water in a system containing isolated chloroplasts, hy-drogenase, a coupling electron carrier (ferredoxin or methyl viologen), and an oxygen scavenger. The rate and extent of hydrogen production anaerobically was much less than the rate of aerobic electron-carrier reduction by chloroplasts and was not limited by hydrogenase. The limiting reaction in the coupled system was the extent of reduction of methyl viologen anaerobically rather than its oxidation by oxygen produced during the course of the reaction. Inhibition of photosystem II by 3-(3,4dichlorophenyl)-1,1-dimethylurea and addition of a photosystem 1 electron donor did not lead to photoproduction of hydrogen or photoreduction of methyl viologen. Extensive photosystem I hydrogen evolution was obtained when thiols were also present. Platinum asbestos or palladium asbestos replaced hydrogenase in a system coupled to chloroplasts.     

THE OXIDATION OF ASCORBATE BY ELECTRON AFFINIC DRUGS AND CARCINOGENS

Abstract— The nitrobenzenes, the carcinogens 4-nitropyridine- N -oxide and 4-nitro-quinoline- N -oxide as well as the nitrofurans, also known to be carcinogenic, have been found to enhance the reaction of ascorbate with oxygen. The reaction results in the oxidation of ascorbate, the production of dehydroascorbate, superoxide radical, peroxide and water. The drugs are not reduced to stable intermediates during the oxidation but are recycled to their original state. The oxygen consumption is partially inhibited by either superoxide dismutase or catalase. If both superoxide dismutase and catalase are included in the reaction mixture, total oxygen consumption was equal to the amount expected for oxidation of ascorbate to dehydroascorbate and reduction of oxygen to water. The oxygen consumption was inhibited by ferricytochrome c. Semiquinones, nitro and hydroxylamine radicals, produced by electron transfer from ascorbate, reduce ferricytochrome c. These oxygen reactive radicals are responsible for the stimulation of oxygen utilization and ascorbate oxidation. In addition we have found that Ehrlich cells, containing catalase and superoxide dismutase, inhibit the drug catalyzed oxidation of ascorbate. The presence of cyanide, known to inhibit catalase and superoxide dismutase, abolished the cell effect for most of the drugs tested.     

SENSITIVITY OF THE ELECTRON TRANSPORT CHAIN OF PIGMENTED AND NON-PIGMENTED SARCINA MEMBRANES TO PHOTODYNAMIC ACTION

Abstract— With malate as substrate, the respiratory system of Sarcina lutea is subject to photodynamic action when toluidine blue is added as a photosensitiser. Both whole cells and isolated cell membranes show similar photoinactivation. Cell and membrane suspensions of a carotenoid-containing strain are significantly less sensitive than those from a non-pigmented mutant prepared from the pigmented strain. Addition of histidine also provides photoprotection. Attempts to locate the site of photoinactivation within the respiratory system lead to the conclusion that several sites are affected. Short periods of illumination do not result in permanent damage since activity is recovered in these suspensions when incubated in the dark subsequent to illumination. The significance of these results and the possible mechanisms involved are discussed.     

VECTORIAL ELECTRON TRANSPORT ACROSS LIPID VESICLE MEMBRANES DRIVE BY TWO PHOTOREACTIONS. II. PHOTOCHEMICAL REGENERATION OF REDUCED CYTOCHROME c BY FLAVIN TRIPLET STATE AND ETHYLENEDIAMINETETRAACETIC ACID IN THE INNER COMPARTMENT AND REDUCTION OF FERREDOXIN BY CHLOROPHYLL TRIPLET STATE IN THE OUTER COMPARTMENT

We have attempted to mimic natural photosynthesis with regard to the photogeneration of a powerful reductant, using a negatively charged lipid bilayer vesicle system incorporating two photoreactions sensitized by a flavin analog (flavin mononucleotide [FMN]) and chlorophyll (chl) in their respective triplet states. Ethylenediamine-tetraacetic acid (EDTA) in the inner aqueous compartment was used as a sacrificial electron donor to the FMN triplet, and ferredoxin in the outer aqueous compartment served as the final electron acceptor (mediated via triplet electron transfer chain in this multicomponent system to be elucidated. By itself, EDTA does not function as an effective donor to membran-bound oxidized chl (chl^+.), which is formed by electron transfer from triplet chl to the viologen follwed by transbilayer electron migration. This is a consequence of electrostatic repulsive interactions with the negatively charged membrane. This limitation is avoided when FMN is used as a photomediator between EDTA and chl^+.. The overall reaction is dramatically increased in rate by enclosing cytochrom c together with EDTA and FMN in the inner compartment. The rate constant of the key step in the reaction, i.e. elctron transfer from reduced cytochrome c, generated via photoreduction by the FMN/EDTA system, to chl^+. is increased 20-fold over that obtained with cytochrome c alone as the elctron donor. One of the important constraints that limited the net electron transfer across the bilayer to 50% of the added cytochrome, i.e. inhibition by oxidized cytochrome c formed in the inner compartment, is avoided by the inclusion of the second photoreaction in this system, thus allowing photoreduction of all of the added ferredoxin to be achieved. This system provides a model for a photochemical energy storage process that utilizes two photorections operating in series resulting in electron flow across a lipid bilayer membrane.     

LIGHT SCATTERING SPECTROPHOTOMETRY FROM ISOLATED CONTROL AND TRIAZOLE-TREATED CHLOROPLASTS

Light scattering relaxation spectrophotometry has proven to be a useful technique to monitor rapid cytophysical changes in chloroplast suspensions brought about by flash illumination. This paper compares the Mg-ATP dependent light scattering behaviour of cholorplasts isolated from control and triazole-treated wheat seedlings. Our results suggest that triazole-treatment enhances Mg-ATP dependent activity. This same enhancement in control chloroplasts can be brought about by introducing potassium ion in the presence of valinomycin. Therefore, the potassium ion might account for part of the stress resistance conferred by triazole treatment.     

PHOTOXIDATION OF ASCORBATE TO OXALATE AND THREONATE MEDIATED BY CHLOROPLASTS IN FAR RED LIGHT

Abstract— Chloroplasts illuminated with light absorbed predominantly by Photosystem I can mediate the photoxidation of ascorbic acid to threonic and oxalic acids. Two micromoles of oxygen are consumed for each micromole of ascorbic acid added. The kinetics of this endogenous chloroplast system closely resemble the kinetics of an artificial flavin-manganese-catalase system in which flavin is the photosensitizing dye.     

INFLUENCE OF LIGHT ON THE EPR-DETECTABLE, ELECTRON TRANSPORT COMPONENTS IN WHOLE CELL RHODOSPIRILLUM RUBRUM

Abstract —The influence of light upon the electron paramagnetic resonance (EPR)-active components of R. rubrum , both in whole cells and in subcellular particle preparations, is presented. In the whole cells, 16 EPR signals can be detected, 11 of which are influenced by illumination of the bacteria. Four of these are also affected by illumination at 77 K. The effects of K₃Fe(CN)₆, Na₂S₂O₄ and heating upon the signals observed in the whole cells are also presented. The whole cells contain several photoinfluenced, EPR-active components that are missing in the subcellular particle preparations. The kinetics of most of the signals in the whole cells are complex, whereas in the subcellular particles the kinetics are generally monotonic. For comparison, some of the EPR signals detected in whole-cell Chromatium D are also presented. The signals observed in these two strains of bacteria differ considerably. A discussion of the possible identities of the R. rubrum signals and speculation as to the role of some of them in the photosynthetic electron transport system are also included.