Titration of Photophosphorylation, Oxidative Phosphorylation and Glycolysis in Scenedesmus with Desaspidin: Regulation between Pathways and Sites for Photophosphorylation

Narrow concentration intervals were used, covering 10^?6– 10^?4M desaspidin. The interaction with glycolysis involves three steps, the inhibitor constants (K_i:s) being in turn 2.7 × 10^?5M, 1.3 × 10^?4M, and high. About 18% of total glycolysis is inhibited in each of the two first steps, and 65% left for the third reaction. After compensation for glycolysis, oxidative phosphorylation may show a sudden jump to about 10% inhibition at 1.5 × 10^?5M desaspidin, the possible K_i of the reaction starting here being very high. Correcting for glycolysis, desaspidin affects total Photophosphorylation in two steps, with the K_i values of 7.8 × 10^?5M and 4.6 × 10^?4M respectively. Inhibition in the first step is about 27% of the total photophosphorylation. By applying 10^?6M DCMU[/3-(3, 4-dichlorophenyl)-l, l-dimethy lurea], one can abolish non-cyclic photophosphorylation. Desaspidin then reacts in a single step with a K_i of 1.4 × 10^?4M. At 5 × 10^?5M DCMU, also the pseudocyclic photophosphorylation is abolished. The remaining, true cyclic photophosphorylation has a single K_i of 2.3 × 10^?5M for desaspidin. Under non-cyclic conditions, the true cyclic process contributes about 25% to total Photophosphorylation. Under pseudocyclic conditions, no cyclic photophosphorylation occurs. Under true cyclic conditions, the non-cyclic and pseudocyclic processes are inoperative. This indicates a regulative system, so that either (1) the (non-cyclic + true cyclic), (2) only the pseudocyclic, or (3) only the true cyclic systems can be traced, dependent on the level of DCMU applied. There are two sites for non-cyclic Photophosphorylation, one of them common to the pseudocyclic pathway. Cyclic photophosphorylation has a third site, different from the other two.     

The Effect of Light Intensity on Total Photophosphorylation and the ATP Level in Scenedesmus

The dependence of in vivo photophosphorylation on light intensity was studied in the unicellular green alga Scenedesmus obtusiusculus. By selective use of the inhibitor DCMU, phosphorylation in (I) the complete system, (II) the pseudocyclic system alone, and (III) the true cyclic system alone, were followed. When the total binding of phosphate was studied, all reaction types became light saturated in about the same manner. The effect of DCMU on the level of ATP varied according to light intensity. As for the specific systems of photophosphorylation, the following ATP data were found: (I) In the complete system the level of ATP decreases with light intensity. (II) Under pseudo-cyclic conditions light first increases and then decreases the ATP level. Under the atmospheric conditions used (i.e. CO₂-free nitrogen) this indicates a regulation between photophosphorylation and glycolysis, for which possible explanations are discussed. (III) In the true cyclic conditions light has little effect on the ATP level. The possibility is indicated that there is a structural difference between the non-cyclic (site 1) and the pseudocyclic (site 2) sites of photophosphorylation on the one hand and the true cyclic site (3) on the other.     

Effects of 2,5-Dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB) on Light Induced and Glycolytic Phosphate Uptake in Scenedesmus

The effects of DBMIB on photophosphorylation and glycolysis in Scenedesmus obtusiusculus Chod. were investigated by measuring the uptake of inorganic phosphate. To analyze the effects of DBMIB on the different energy coupling possibilities in open chain and cyclic photophosphorylation, DBMIB was given to the algae in narrow concentration intervals between 10^?6M to 10^?4M, either alone, or in combination with DCMU (3-(3,4-dichlorophenyl)-1,1-dimethylurea) or desaspidin. DBMIB inhibits non-cyclic as well as cyclic photophosphorylation in Scenedesmus. However, the DCMU resistant photophosphorylation reactions are less sensitive to DBMIB than the open chain photophosphorylating system in non-DCMU treated cells. Low concentrations of DBMIB even released a part of the DCMU inhibition. Experiments with combinations of DBMIB and desaspidin also indicated that cyclic photophosphorylation is less sensitive to DBMIB than non-cyclic. The inhibition of DCMU resistant cyclic phosphorylation by DBMIB, which is a competitive inhibitor of quinones, indicated a participation of plastoquinones in this type of energy coupling as well as in the non-cyclic and DCMU-sensitive processes. The cyclic and the non-cyclic photophosphorylation pathways probably use different parts of the plastoquinone pool. For the purpose of the experiments, it was necessary to produce data for the effect of DBMIB (10^?6–10^?4M) on glycolysis. The highest concentration gave 50% inhibition.     

The Role of Cyclic and Pseudocyclic Photophosphorylation in Photosynthetic 14CO2 Fixation in Hydrodictyon africanum

Experiments are reported in which the effects on photosynthesisof various inhibitors of cyclic photophosphorylation were investigated.These inhibitors, generally had only a small inhibitory effecton photosynthesis, and the inhibition was not increased by conditionswhich inhibit pseudocyclic photophosphorylation. These inhibitorsdo not inhibit the Emerson enhancement effect. From these resultsit was concluded that photosynthesis does not need any ATP otherthan that produced in non-cyclic photophosphorylation. The effectsof these inhibitors on active K influx in light-anaerobic conditionsin the presence or absence of CO₂ suggest that some of the ATPproduced by non-cyclic photophosphorylation can be used to supportactive K influx. The results are discussed in relation to themechanism of the Emerson effect, the stoichiometry of non-cyclicphotophosphorylation, and the ATP requirements for autotrophicgrowth.     

Cyclic and Non-cyclic Photophosphorylation as Energy Sources for Active K Influx in Hydrodictyon africanum

Under anaerobic conditions in the light, active K influx inHydrodictyon africanum is supported by cyclic photophosphorylation.The use of selective inhibitors shows that, in the presenceof CO₂, a considerable portion of the ATP used by the K pumpis supplied by noncyclic photophosphorylation. The rest of theATP in these conditions comes from cyclic photophosphorylation.This is true under light-limiting as well as light-saturatedconditions. If non-cyclic photophosphorylation is inhibited (by removalof carbon dioxide, by the addition of cyanide which interfereswith the carboxylation reaction, or by inhibition of photosystemtwo with DCMU or supplying only far-red light), the K influxat low light intensities is stimulated, and its characteristicsbecome those of a process powered by cyclic photophosphorylationalone. These results are interpreted in terms of a competitionfor ATP between K influx and CO₂ fixation. Implicit in thisexplanation is a requirement for a switch of excitation energyabsorbed by photosystem one from cyclic photophosphorylationto non-cyclic photophosphorylation whenever conditions (presenceof CO₂and photosystem two activity) allow CO₂ fixation to occur. Further evidence for such a switch of excitation energy absorbedby photosystem one was obtained in experiments in which redand far-red light were applied separately and together. It wasfound that CO₂ fixation showed the Emerson enhancement effect,while K influx (in the presence of CO₂) shows a ‘de-enhancement’.This suggests that far-red light alone powers cyclic photophosphorylation;if red light is also present, some of the far-red quanta arediverted to non-cyclic photophosphorylation. The nature of the interaction between cyclic and non-cyclicphotophosphorylation is discussed in relation to these and otherpublished results.     

Phenylmereuric Acetate and Phosphate Control of Light-Dependent Shrinkage and Reactions in Chloroplasts

An investigation of the action of phenylmereuric acetate (PMA) and phosphate on light-induced shrinkage (measured by light scattering and Coulter Counter techniques) and on photosynthetic reactions in spinach chloroplasts led to the following conclusions:

• 1) PMA stimulated light-induced shrinkage (under conditions of cyclic and non-cyclic electron flow) at concentrations which completely inhibited cyclic and non-cyclic photophosphorylation and nicotinamide adenine dinucleotide phosphate (NADP) reduction, though ferricyanide reduction was activated. Although PMA inhibited NADP reduction (probably because this sulfhydryl reagent interfered with the ferredoxin-NADP rednetase) it ean also be considered an uncoiipler (when ferricyanide is the electron acceptor).
• 2) Phosphate maximized light-induced shrinkage (under conditions of cyclic and non cyclic electron flow) at concentrations which did not affect ferricyanide reduction but caused a 40 to 50 per cent inhibition of NADP reduction.
• 3) The pattern of the light scattering response to these two compounds was quite different. In the presence of PMA, the forward (light on) and hack (light off) reactions went to completion rapidly. In the presence of phosphate, the back reaction was rapid but, in the light-induced reaction, three phases were discernible.
• 4) Compared with uncouplers such as NH₄Cl, carbonyl cyanide m-chlorophenyl-hydrazone, pentachlorophenol, and dicoumarol, all of which inhibited both photophosphorylation and conformational changes in chloroplasts, PMA (like quinacrine) had a specific action since it inhibited photophosphorylation while shrinkage was stimulated.
• 5) It appeared that PMA acted at a site beyond the formation of high energy inter-mediates and that, in the absence of photophosphorylation, more energy was diverted to mechanical work (shrinkage). It would seem that, in a cyclic electron flow system, in which ATP synthesis is blocked at a late step (e.g. by PMA), shrinkage may be an indirect method for measuring electron flow.

     

Rates and properties of endogenous cyclic photophosphorylation of isolated intact chloroplasts measured by CO2 fixation in the presence of dihydroxyacetone phosphate.

1. Dihydroxyacetone phosphate in concentrations greater than or equal to 2.5 mM completely inhibits CO2-dependent O2 evolution in isolated intact spinach chloroplasts. This inhibition is reversed by the addition of equimolar concentrations of Pi, but not by addition of 3-phosphoglycerate. In the absence of Pi, 3-phosphoglycerate and dihydroxyacetone phosphate, only about 20% of the 14C-labelled intermediates are found in the supernatant, whereas in the presence of each of these substances the percentage of labelled intermediates in the supernatant is increased up to 70-95%. Based on these results the mechanism of the inhibition of O2 evolution by dihydroxyacetone phosphate is discussed with respect to the function of the known phosphate translocator in the envelope of intact chloroplasts. 2. Although O2 evolution is completely suppressed by dihydroxyacetone phosphate, CO2 fixation takes place in air with rates of up to 65 mu mol-mg1 chlorophyll-h1. As non-cyclic electron transport apparently does not occur under these conditions, these rates must be due to endogenous pseudocyclic and/or cyclic photophosphorylation. 3. Under anaerobic conditions, the rates of CO2 fixation in presence of dihydroxyacetone phosphate are low (2.5-7 mumol-mg1 chlorophyll-h1), but they are strongly stimulated by addition of dichlorophenyl-dimethylurea (e.g. 2-10(-7) M) reaching values of up to 60 mumol-mg1 chlorophyll-h1. As under these conditions the ATP necessary for CO2 fixation can be formed by an endogenous cyclic photophosphorylation, the capacity of this process seems to be relatively high, so it might contribute significantly to the energy supply of the chloroplast. As dichlorophenyl-dimethylurea stimulates CO2 fixation in presence of dihydroxyacetone phosphate under anaerobic but not under aerobic conditions, it is concluded t-at only under anaerobic conditions an "overreduction" of the cyclic electron transport system takes place, which is removed by dichlorophenyl-dimethylurea in suitable concentrations. At concentrations above 5-10(-7) M dichlorophenyl-dimethylurea inhibits dihydroxyacetone phosphate-dependent CO2 fixation under anaerobic as well as under aerobic conditions in a similar way as normal CO2 fixation. Therefore, we assume that a properly poised redox state of the electron transport chain is necessary for an optimal occurrence of endogenous cyclic photophosphorylation. 4. The inhibition of dichlorophenyl-dimethylurea-stimulated CO2 fixation in presence of dihydroxyacetone phoshate by dibromothymoquinone under anaerobic conditions indicated that plastoquinone is an indispensible component of the endogenous cyclic electron pathway.     

Light-Induced Phosphate Binding in Relation to Photophosphorylation and Levels of ATP, ADP and AMP in the Green Alga Scenedesmus

Synchronous cultures of Scenedesmus obtusiusculus Chod. were starved for phosphorus for 48 h. Such cells develop an efficient mechanism for phosphate binding which is very sensitive to metabolic inhibitions. Phosphate binding, fluctuations in the ATP pool during dark-light-dark transitions, and steady state levels of ATP, ADP and AMP were studied. The experiments were carried out in a CO₂-free N₂ atmosphere. DCMU, phloridzin and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB) were used as inhibitors of photophosphorylation. Light-induced phosphate uptake was inhibited to various extents by all the inhibitions. The dark-light-dark transition experiments show that neither the light-induced increment in ATP nor the decrease at darkening are affected by DCMU, but DBMIB and phloridzin inhibit both processes. DCMU seems to affect the regulation of the ATP pool size. The steady state levels of the adenylate pools were almost the same in the light as in the dark, and they were also little sensitive to the inhibitors. In unpoisoned cells in the light the steady state ATP/ADP ratio was 1.7 and the energy charge was 0.66. The rates of phosphate binding are not correlated to any of the adenylate parameters studied. This is probably due to the diverse effects of the inhibitors on light-stimulated production of reducing equivalents, photophosphorylation and transfer of energy from the chloroplast to the cytoplasm.     

Differential effects of desaspidin on photosynthetic phosphorylation

Sensitivity to low concentrations of desaspidin (5 x 10(-7)m) sharply distinguishes the photophosphorylations associated with the photooxidation of water from all other types of photophosphorylation by isolated chloroplasts.Contrary to recent reports in the literature, the effects of desapidin were not altered by changes in the redox conditions as influenced by the concentration of ascorbate and by the presence or absence of oxygen. Desaspidin consistently inhibited all types of cyclic photophosphorylation and the photophosphorylation coupled with the reduction of NADP by ascorbate-dichlorophenol indophenol. The same concentration of desaspidin gave little or no inhibition of photophosphorylation that are coupled with the photooxidation of water.     

Rates and properties of endogenous cyclic photophosphorylation of isolated intact chloroplasts measured by CO2 fixation in the presence of dihydroxyacetone phosphate

1. Dihydroxyacetone phosphate in concentrations ? 2.5 mM completely inhibits CO₂-dependent O₂ evolution in isolated intact spinach chloroplasts. This inhibition is reversed by the addition of equimolar concentrations of P_i, but not by addition of 3-phosphoglycerate. In the absence of P_i, 3-phosphoglycerate and dihydroxyacetone phosphate, only about 20% of the ¹⁴C-labelled intermediates are found in the supernatant, whereas in the presence of each of these substances the percentage of labelled intermediates in the supernatant is increased up to 70–95%. Based on these results the mechanism of the inhibition of O₂ evolution by dihydroxyacetone phosphate is discussed with respect to the function of the known phosphate translocator in the envelope of intact chloroplasts.2. Although O₂ evolution is completely suppressed by dihydroxyacetone phosphate, CO₂ fixation takes place in air with rates of up to 65μ mol · mg^?1 chlorophyll · h^?1. As non-cyclic electron transport apparently does not occur under these conditions, these rates must be due to endogenous pseudocyclic and/or cyclic photophosphorylation.3. Under anaerobic conditions, the rates of CO₂ fixation in presence of dihydroxyacetone phosphate are low (2.5–7 μmol · mg^?1 chlorophyll · h^?1), but they are strongly stimulated by addition of dichlorophenyl-dimethylurea (e.g. 2 · 10^?7 M) reaching values of up to 60 μmol · mg^?1 chlorophyll · h^?1. As under these conditions the ATP necessary for CO₂ fixation can be formed by an endogenous cyclic photophosphorylation, the capacity of this process seems to be relatively high, so it might contribute significantly to the energy supply of the chloroplast. As dichlorophenyl-dimethylurea stimulates CO₂ fixation in presence of dihydroxyacetone phosphate under anaerobic but not under aerobic conditions, it is concluded that only under anaerobic conditions an “overreduction” of the cyclic electron transport system takes place, which is removed by dichlorophenyl-dimethylurea in suitable concentrations. At concentrations above 5 · 10^?7 M dichlorophenyl-dimethylurea inhibits dihydroxyacetone phosphate-dependent CO₂ fixation under anaerobic as well as under aerobic conditions in a similar way as normal CO₂ fixation. Therefore, we assume that a properly poised redox state of the electron transport chain is necessary for an optimal occurrence of endogenous cyclic photophosphorylation.4. The inhibition of dichlorophenyl-dimethylurea-stimulated CO₂ fixation in presence of dihydroxyacetone phosphate by dibromothymoquinone under anaerobic conditions indicates that plastoquinone is an indispensible component of the endogenous cyclic electron pathway.     

Photophosphorylation in Scenedesmus in vivo: O2 evolution, ATP pools and transients, and phosphate binding during photoreduction of NO3−, NO2− and CO2

The relation between light-induced electron transport with NO₃^?, NO₂^? or CO₂ as acceptors, ATP pools and transients in dark-light-dark transitions, and phosphate uptake was examined in phosphorus-starved cells of Scenedesmus obtusiusculus Chod. Net O₂ evolution at saturating light was around 6 μmol × (mg chlorophyll × h)^?1 in the absence of any acceptor, but reached average rates of 21, 65 and 145 μmol × (mg chlorophyll × h)^?1 upon additions of 5 mM KNO₃, KNO₂ and KHCO₃, respectively. The apparent rate of photophosphorylation in transition experiments was only a few percent of the rate calculated from CO₂-dependent O₂ evolution. Blocking non-cyclic electron transport with DCMU inhibited phosphate assimilation, but acceleration of non-cyclic electron flow by addition of NO₃^? or NO₂^? did not stimulate phosphate assimilation as compared to the situation without an acceptor. A functional non-cyclic system might primarily be needed for an efficient shuttle transfer of ATP from the chloroplast to the cytoplasm. An inhibition of the non-cyclic system due to lack of reducible substrates accelerates the cyclic system and thus indicates a regulation mechanism between the two systems.     

The stoichiometry (ATP/2e− ratio) of non-cyclic photophosphorylation in isolated spinach chloroplasts

1. The stoichiometry of non-cyclic photophosphorylation and electron transport in isolated chloroplasts has been re-investigated. Variations in the isolation and assay techniques were studied in detail in order to obtain optimum conditions necessary for reproducibly higher ADP/O (equivalent to ATP/2e^?) and photosynthetic control ratios.2. Studies which we carried out on the possible contribution of cyclic phosphorylation to non-cyclic phosphorylation suggested that not more than 10% of the total phosphorylation found could be due to cyclic phosphorylation.3. Photosynthetic control, and the uncoupling of electron transport in the presence of NH₄Cl, were demonstrated using oxidised diaminodurene as the electron acceptor. A halving of the ADP/O ratio was found, suggesting that electrons were being accepted between two sites of energy conservation, one of which is associated with Photosystem I and the other associated with Photosystem II.4. ATP was shown to inhibit State 2 and State 3 of electron transport, but not State 4 electron transport or the overall ADP/O ratio, thus confirming its activity as an energy transfer inhibitor. It is suggested that part of the non-phosphorylating electron transport rate (State 2) which is not inhibited by ATP is incapable of being coupled to subsequent phosphorylation triggered by the addition of ADP (State 3). If the ATP-insensitive State 2 electron transport is deducted from the State 3 electron transport when calculating the ADP/O ratio, a value of 2.0 is obtained.5. The experiments reported demonstrate that there are two sites of energy conservation in the non-cyclic electron transfer pathway: one associated with Photosystem II and the other with Photosystem I. Thus, non-cyclic photophosphorylation can probably produce sufficient ATP and NADPH “in vivo” to allow CO₂ fixation to proceed.     

Inhibition of photo-induced electron transport and related reactions in isolated chloroplasts by phenol

Phenol inhibits the Hill reaction with several Hill oxidants and the accompanying non-cyclic phosphorylation. It inhibits also pseudocyclic and cyclic phosphorylation. Partial reactions which are dependent on cyclic electron flow are inhibited too, but electron flow from ascorbate via dichlorophenolindophenol to TPN is not. The activity of various benzene and phenol derivatives was compared. It is concluded that the inhibition is a result of interfering with an electron carrier which participates in cyclic and non-cyclic electron flow.     

叶绿体atpE基因表达产物的生化特性

在细菌中表达的叶绿体ａｔｐＥ基因产物ε亚基蛋白对不同方式激活的叶绿体ＡＴ－Ｐａｓｅ均有抑制作用,而其抗血清则促进ＡＴ－Ｐａｓｅ活力。Ｅ．ｃｏｌｉ中表达的ε亚基蛋白在光合磷酸化反应中对循环和非循环光合磷酸化都有促进作用,其抗血清对循环光合磷酸化有抑制作用,而对非循环光合磷酸化则起促进作用。     

Light-stimulated Absorption of Nitrate by Wolffia arrhiza

The mechanism of the light-stimulated absorption of nitrate by Wolffia arrhiza was studied. The nitrate-absorption mechanism in ammonium-grown plants is stimulated by the presence of nitrate. In a manner similar to the absorption of many other ions, the absorption of nitrate follows a typical biphasic pattern in relation to external nitrate concentration. Mechanism 1 is effective at nitrate concentrations up to 0.5 to 0.75 mM and mechanism 2 becomes operative at higher nitrate levels. Light stimulates the absorption of nitrate independently of the effect of light on the reduction of nitrate. The effects of uncouplers, inhibitors, and light of wavelengths of 700 nm or longer indicate that nitrate absorption by Wolffia cells is reduced when non-cyclic electron transport is blocked. It is postulated that under this condition, ATP in the chloroplast (produced by cyclic photophosphorylation) may be less readily transported across the chloroplast envelope than when non-cyclic electron transport is proceeding.     

The relationship of cyclic and non-cyclic electron flow patterns with reduced indophenols to photophosphorylation

Optimal cyclic photophosphorylation with reduced indophenols under anaerobic conditions was shown to require a critical redox balance. Over-reduction inhibited this phosphorylation; addition of oxidizing agents like ferricyanide, air, ferredoxin or ferredoxin plus triphosphopyridine nucleotide relieved the inhibition.

When ascorbate and indophenol served as the electron donor couple for TPN⁺ reduction, only the amount of TPNH formed was dependent on the concentration of TPN⁺. The phosphorylation observed in this system was dependent only on the concentration of indophenol, and on the ability of reduced indophenol to mediate cyclic photophosphorylation. The cyclic electron flow with reduced indophenol was shown to operate simultaneously with the non-cyclic electron flow to TPN⁺. It was concluded that there was no phosphorylation site in the non-cyclic electron flow between ascorbate-indophenol and TPN⁺ and that the phosphorylation observed in this case was due only to cyclic photophosphorylation with the reduced indophenols.

In the light of these results, a working hypothesis with two different sites for cyclic and non-cyclic photophosphorylation is suggested.     

Chloroplastic activity in response to gibberellic acid treatment of dwarf and normal cultivars of pea (Pisum sativum L.)

Levels of ferricyanide reduction, cyclic and non-cyclic photophosphorylation were measured in chloroplasts of two cultivars of pea and a comparison of their P/2e⁺ ratios were made. No differences were observed in cyclic photophosphorylation or ferricyanide reduction but non-cyclic photophosphorylation was lower in chloroplasts from the dwarf than the normal cultivar. Thus the P/2e⁺ ratio of the dwarf was lower than the normal. Dwarf seedlings treated with gibberellic acid (GA₃) had similar rates of cyclic photophosphorylation as the untreated dwarf but non-cyclic photophosphorylation was lower as was ferricyanide reduction. This resulted in P/2e⁺ ratios that were higher in chloroplasts from the GA₃ treated dwarf seedlings than the untreated, and were the same as the untreated normal. Addition of GA₃ directly to the chloroplasts did not alter the activity in any way. Hence gibberellins do not directly affect changes in chloroplastic activity but may conceivably be involved in a feed-back control system.     

On an Inhibitor of Ferredoxin Catalyzed Cyclic Photophosphorylation in Thylakoid Membranes*

Dibromo- and diiodo-naphthoquinones are shown to be inhibitors of the cytochrome b₆/f complex in isolated thylakoid membranes from spinach chloroplasts. Dibromo-naphthoquinone inhibits ferredoxin catalyzed cyclic photophosphorylation at 0.1 μM concentrations, but non cyclic e-flow only at 10 μM. It does not inhibit cyclic systems with artifical cofactors, nor non-cyclic electron flow from duroquinol through photosystem I via the cytochrome b₆/f complex. Dibromo-naphthoquinone does however, lower the stoichiometry for ATP formation in the duroquinol donor system. This inhibitory pattern is quite different from that of DBMIB, but very similar to that of antimycin. This antimycin-like behaviour of these inhibitors is interpreted to indicate a) the existence of a Q_c site in the cytochrome b₆/f complex and its obligate function in ferredoxin catalyzed cyclic electron flow and b) a non-essential role of the Q_c site in non-cyclic electron flow, but which — when operative — pumps an extra proton across the thylakoid membrane increasing the ATP yield.     

ATP pools and transients in the blue-green alga,Anabaena cylindrica

Anabaena cylindrica grown in steady state continuous culture has an extractable ATP pool, measured on the basis of the luciferin-luciferase assay of 165±35 nmoles ATP mg chla ^-1. This pool is maintained by a dynamic balance between the rate of ATP synthesis and the rate of ATP utilization. Phosphorylating mechanisms which can maintain the pool in the short term are total photophosphorylation, cyclic photophosphorylation and oxidative phosphorylation. The alga can maintain its ATP pool by switching rapidly from one of these phosphorylating mechanisms to another depending on the environmental conditions. At each switch-over there is a transient drop in the ATP pool for a few seconds. On switching to conditions where only substrate level phosphorylation operates, the ATP pool falls immediately, but takes several hours to recover. The apparent rates of ATP synthesis by total photophosphorylation and by cyclic photophosphorylation are both much higher (210±30 and 250±13 moles ATP mg chla ^-1 h^-1 respectively) than the apparent rate of ATP synthesis by oxidative phosphorylation (22±3 moles ATP mg chla ^-1 h^-1). In long term experiments the ATP pool is maintained when total photophosphorylation is operating. It cannot be maintained in the long term by cyclic photophosphorylation alone in the absence of photosystem II activity or endogenous carbon compounds, or by oxidative phosphorylation in the absence of endogenous carbon compounds. Measurements of ATP, ADP and AMP show that the total pool of adenylates is similar in the light and in the dark in the short term. There is only limited production of ATP under dark anaerobic conditions when glycolysis and substrate phosphorylation can operate which suggests that these processes are of limited significance in providing ATP in Anabaena cylindrica.Abbreviations ADP adenosine 5-diphosphate - AMP adenosine 5-monophosphate - ATP adenosine 5-triphosphate - CCCP carbonyl cyanide m-chlorophenyl hydrazone - DCMU 3-(3,4-dichlorophenyl)1,1-dimethyl urea - HEPES N-2-hydroxyethylpiperazine-N-2-ethane sulfonic acid - PEP phosphoenolpyruvate     

Electron transport and photophosphorylation by Photosystem I in vivo in plants and cyanobacteria

Recently, a number of techniques, some of them relatively new and many often used in combination, have given a clearer picture of the dynamic role of electron transport in Photosystem I of photosynthesis and of coupled cyclic photophosphorylation. For example, the photoacoustic technique has detected cyclic electron transport in vivo in all the major algal groups and in leaves of higher plants. Spectroscopic measurements of the Photosystem I reaction center and of the changes in light scattering associated with thylakoid membrane energization also indicate that cyclic photophosphorylation occurs in living plants and cyanobacteria, particularly under stressful conditions.In cyanobacteria, the path of cyclic electron transport has recently been proposed to include an NAD(P)H dehydrogenase, a complex that may also participate in respiratory electron transport. Photosynthesis and respiration may share common electron carriers in eukaryotes also. Chlororespiration, the uptake of O₂ in the dark by chloroplasts, is inhibited by excitation of Photosystem I, which diverts electrons away from the chlororespiratory chain into the photosynthetic electron transport chain. Chlororespiration in N-starved Chlamydomonas increases ten fold over that of the control, perhaps because carbohydrates and NAD(P)H are oxidized and ATP produced by this process.The regulation of energy distribution to the photosystems and of cyclic and non-cyclic phosphorylation via state 1 to state 2 transitions may involve the cytochrome b ₆-f complex. An increased demand for ATP lowers the transthylakoid pH gradient, activates the b ₆-f complex, stimulates phosphorylation of the light-harvesting chlorophyll-protein complex of Photosystem II and decreases energy input to Photosystem II upon induction of state 2. The resulting increase in the absorption by Photosystem I favors cyclic electron flow and ATP production over linear electron flow to NADP and poises the system by slowing down the flow of electrons originating in Photosystem II.Cyclic electron transport may function to prevent photoinhibition to the photosynthetic apparatus as well as to provide ATP. Thus, under high light intensities where CO₂ can limit photosynthesis, especially when stomates are closed as a result of water stress, the proton gradient established by coupled cyclic electron transport can prevent over-reduction of the electron transport system by increasing thermal de-excitation in Photosystem II (Weis and Berry 1987). Increased cyclic photophosphorylation may also serve to drive ion uptake in nutrient-deprived cells or ion export in salt-stressed cells.There is evidence in some plants for a specialization of Photosystem I. For example, in the red alga Porphyra about one third of the total Photosystem I units are engaged in linear electron transfer from Photosystem II and the remaining two thirds of the Photosystem I units are specialized for cyclic electron flow. Other organisms show evidence of similar specialization.Improved understanding of the biological role of cyclic photophosphorylation will depend on experiments made on living cells and measurements of cyclic photophosphorylation in vivo.Abbreviations CCCP carbonylcyanide m-chlorophenylhydrazone - cyt cytochrome - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DCCD dicyclohexylcarbodiimide - DCHC dicyclohexyl-18-crown-6 - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - FCCP carbonylcyanide 4-(trifluoromethoxy) phenylhydrazone - LHC light harvesting chlorophyll - LHCP II light harvesting chlorophyll protein of Photosystem II - PQ plastoquinone - PS I, II Photosystem I, II - SHAM salicyl hydroxamic acid - TBT Tri-n-butyltin CIW/DPB Publication No. 1146