CO2 reduction by intact chloroplasts under a diminished proton gradient

9-Aminoacridine has been used to monitor the intrathylakoid pH of photo-synthetically competent intact chloroplasts. Values obtained from 9-aminoacridine accumulation in the chloroplasts must be corrected for light-dependent binding of 9-aminoacridine to the thylakoid membranes. During nitrite reduction by intact chloroplasts, the intrathylakoid proton concentration increased. It decreased somewhat during CO₂ reduction. However, low concentrations of uncoupling amines such as NH₃ or cyclohexylamine, which rapidly penetrated the chloroplast envelope and decreased the intrathylakoid proton concentration, failed to reduce, and actually stimulated, rates of CO₂-dependent oxygen evolution even under rate-limiting light. In contrast, low concentrations of carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) or nigericin, which inhibited CO₂ reduction, even appeared to increase the intrathylakoid proton concentration. As indicated by measurements of the 515 nm signal of the chloroplasts, the light-induced membrane potential was not much affected by low concentrations of the uncoupling amines, but was decreased by FCCP and by high concentrations of the amines. Even in the presence of high concentrations of NH₄Cl, ATP/ADP ratios of illuminated chloroplasts remained far above the ratios observed in the dark. In contrast, low concentrations of FCCP were sufficient to reduce ATP/ADP ratios to the dark value even under high intensity illumination. The observations are difficult to explain within the framework of the chemiosmotic hypothesis as presently discussed.     

Control of electron flow in intact chloroplasts by the intrathylakoid pH,not by the phosphorylation potential

In the presence of nitrite or oxaloacetate, intact chloroplasts evolved oxygen at a significant rate for the initial 1 to 2 min of illumination. Subsequently, oxygen evolution was suppressed progressively. The suppressed oxygen evolution was stimulated strikingly by NH₄Cl. The results indicate that coupled electron flow in intact chloroplasts is controlled in the light, and the control is released by NH₄Cl. However, at low concentrations, NH₄Cl was not an effective uncoupler of photophosphorylation in intact chloroplasts. Intrachloroplast ATP levels and ATP/ADP ratios were not significantly influenced by NH₄Cl. In contrast, the quenching of 9-aminoacridine fluorescence, which can be used to indicate the intrathylakoid pH in intact chloroplasts, was reduced drastically even by low concentrations of NH₄Cl. This suggests that the chloroplast phosphorylation potential is not in equilibrium with the proton gradient. In coupled chloroplasts, the intrathylakoid pH was lower in the light with nitrite than with oxaloacetate as electron acceptor. Electron flow was also more effectively controlled in chloroplasts illuminated with nitrite than with oxaloacetate. It is concluded that the intrathylakoid pH, not the phosphorylation potential, is a factor in the control of the rate of electron flow in intact chloroplasts.Abbreviations CCCP carbonylcyanide-m-chlorophenylhydrazone - OAA oxalo-acetate - MES 2-(N-morpholino)-ethanesulfonic acid - HEPES N-2-hyroxyethylpiperazine-N-2-ethanesulfonic acid Postal address     

Synthesis and hydrolysis of ATP by intact chloroplasts under flash illumination and in darkness.

ATP concentrations were measured in isolated intact spinach chloroplasts under various light and dark conditions. The following results were obtained: (1) Even in darkened chloroplasts and in the absence of exogenous substrates, ATP levels in the chloroplast stroma were significant. They decreased on addition of glycerate, phosphoglycerate or dihydroxyacetone phosphate. When dihydroxyacetone phosphate and oxaloacetate were added together, ATP levels increased in darkened chloroplasts owing to substrate level phosphorylation. (2) Under illumination with saturating single turnover flashes, oxygen evolution in the presence of phosphoglycerate, whose reduction requires ATP, was no lower on a unit flash basis at the low flash frequency of 2 Hz than at higher frequencies. Quenching of 9-aminoacridine fluorescence, which indicates the formation of a proton gradient in intact chloroplasts, decreased with decreasing flash frequencies, until there was no significant fluorescence quenching at a flash frequency of about 2 Hz. In contrast to intact chloroplasts, broken chloroplasts did not phosphorylate much ADP at the low flash frequency of 2 Hz. (3) Flashing at extremely low frequencies (0.2 Hz) caused ATP hydrolysis rather than ATP synthesis in intact chloroplasts. At higher flash frequencies, synthesis replaced hydrolysis. Still, even at high frequencies (10 Hz), the first flashes of a series of flashes given after a long dark time always decreased chloroplast ATP levels. From these results, it is concluded that the enzyme, which mediates ATP synthesis in the light, is inactive in darkened intact chloroplasts. Its light activation can be separated from the formation of the high energy condition, which results in ATP synthesis. After its activation, the enzyme catalyzes a reversible reaction.     

Synthesis and hydrolysis of ATP by intact chloroplasts under flash illumination and in darkness

ATP concentrations were measured in isolated intact spinach chloroplasts under various light and dark conditions. The following results were obtained: (1) Even in darkened chloroplasts and in the absence of exogenous substrates, ATP levels in the chloroplast stroma were significant. They decreased on addition of glycerate, phosphoglycerate or dihydroxyacetone phosphate. When dihydroxyacetone phosphate and oxaloacetate were added together, ATP levels increased in darkened chloroplasts owing to substrate level phosphorylation. (2) Under illumination with saturating single turnover flashes, oxygen evolution in the presence of phosphoglycerate, whose reduction requires ATP, was no lower on a unit flash basis at the low flash frequency of 2 Hz than at higher frequencies. Quenching of 9-aminoacridine fluorescence, which indicates the formation of a proton gradient in intact chloroplasts, decreased with decreasing flash frequencies, until there was no significant fluorescence quenching at a flash frequency of about 2 Hz. In contrast to intact chloroplasts, broken chloroplasts did not phosphorylate much ADP at the low flash frequency of 2 Hz. (3) Flashing at extremely low frequencies (0.2 Hz) caused ATP hydrolysis rather than ATP synthesis in intact chloroplasts. At higher flash frequencies, synthesis replaced hydrolysis. Still, even at high frequencies (10 Hz), the first flashes of a series of flashes given after a long dark time always decreased chloroplast ATP levels.From these results, it is concluded that the enzyme, which mediates ATP synthesis in the light, is inactive in darkened intact chloroplasts. Its light activation can be separated from the formation of the high energy condition, which results in ATP synthesis. After its activation, the enzyme catalyzes a reversible reaction.     

Synergistic uncoupling of spinach chloroplasts by combinations of photophosphorylation inhibitors and carbonyl cyanide p-trifluoromethoxyphenylhydrazone.

Combinations of low concentrations of carbonyl cyanide p-trifluoromethoxyphenylhy-drazone (FCCP) with suboptimal concentrations of Dio-9, phloridzin, ajmaline, and dihydrodiscarine B synergistically inhibited cyclic and noncyclic photophosphorylation in spinach chloroplasts but their effects on the light-triggered ATPase were additive rather than synergistic. The effect was reversed by washing and prevented by dithioerythritol and by cistein. Carbonyl cyanide m-chlorophenylhydrazone (CCP) could replace FCCP but uncouplers of other types like atebrin did not substitute for FCCP.Combinations of FCCP with the four inhibitors synergistically uncoupled ferricyanide reduction in the presence of ADP and P_i but not in their absence. The synergistic uncoupling was not observed on the light-dependent pH rise of chloroplast suspensions.Association of FCCP with any of the inhibitors completely abolished the stimulation of proton uptake or the inhibition of electron transport induced by low concentrations of ATP.This synergistic and peculiar uncoupling can not be ascribed to a modification of membrane permeability. One possible explanation is that the effect requires a conformational state of the membrane-bound coupling factor 1 (CF₁) induced by phosphorylating conditions which would facilitate the interaction of inhibitors and FCCP with the membrane.     

The involvement of stromal ATP in maintaining the pH gradient across the chloroplast envelope in the light

The possible involvement of ATP in maintaining the pH gradient across the chloroplast envelope membrane was investigated by simultaneously measuring the stromal ATP concentration and the pH of the stroma and intrathylakoid spaces in intact isolated chloroplasts. Addition of exogenous ATP in the dark increased stromal pH by 0.3–0.4 pH units and increased the pH gradient across the thylakoid membrane by a similar amount. In the dark, dihydroxyacetone phosphate plus oxaloacetate increased stromal ATP to levels equal to those obtained in illuminated chloroplasts, but stromal pH was only increased by 0.1–0.3 pH units compared to an increase of 0.8–1.0 units in the light. The energy-transfer inhibitor, phlorizin, decreased stromal ATP in illuminated chloroplasts almost to dark levels, but did not decrease stromal pH. Inorganic pyrophosphate and an analog of ATP were used to exchange endogenous adenine nucleotides out of chloroplasts, and this also decreased the stromal ATP to dark levels without decreasing stromal pH in the light. Addition of 15–20 μM 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea (DCMU) reduced both the stromal pH and ATP content of illuminated chloroplasts to dark levels but lower concentrations of DCMU preferentially decreased stromal pH. It is concluded that the pH gradient across the chloroplast envelope is unlikely to be maintained by an electrogenic proton pump driven by ATP hydrolysis. Photosynthetic electron transport is required to maintain the pH gradients across both the chloroplast thylakoid and chloroplast envelope membranes.     

The ATP/ADP-antiporter is involved in the uncoupling effect of fatty acids on mitochondria

The ATP/ADP-antiporter inhibitors and the substrate ADP suppress the uncoupling effect induced by low (10-20 microM) concentrations of palmitate in mitochondria from skeletal muscle and liver. The inhibitors and ADP are found to (a) inhibit the palmitate-stimulated respiration in the controlled state and (b) increase the membrane potential lowered by palmitate. The degree of efficiency decreases in the order: carboxyatractylate (CAtr) greater than ADP greater than bongkrekic acid, atractylate. GDP is ineffective, Mg.ADP is of much smaller effect, whereas ATP is effective at much higher concentration than is ADP. Inhibitor concentrations, which maximally suppress the palmitate-stimulated respiration, correspond to those needed for arresting the state 3 respiration. The extent of the CAtr-sensitive stimulation of respiration by palmitate has been found to decrease with an increase in palmitate concentration. Stimulation of the controlled respiration by p-trifluoromethoxycarbonylcyanide phenylhydrozone (FCCP) and gramicidin D at any concentrations of these uncouplers is CAtr-insensitive, whereas that caused by a low concentrations of 2,4-dinitrophenol and dodecyl sulfate is inhibited by CAtr. The above effect of palmitate develops immediately after addition of the fatty acid. It is resistant to EGTA as well as to inhibitors of phospholipase (nupercain) and of lipid peroxidation (ionol). Moreover, palmitate accelerates spontaneous release of the respiratory control, developing in rat liver mitochondria under certain conditions. This effect takes several minutes, being sensitive to EGTA, nupercain and ionol. Like the fast uncoupling, this slow effect is inhibited by ADP but CAtr and atractylate are stimulatory rather than inhibitory. In artificial planar phospholipid membrane, palmitate does not increase the membrane conductance, FCCP increases it strongly and dinitrophenol only slightly. In cytochrome oxidase proteoliposomes, FCCP, gramicidin and dinitrophenol (less effectively) lower, whereas palmitate enhances the cytochrome-oxidase-generated membrane potential. In this system, monensin substitutes for palmitate. It is concluded that the ATP/ADP antiporter is somehow involved in the uncoupling effect caused by low concentrations of palmitate and, partially, of dinitrophenol, whereas uncoupling produced by FCCP and gramicidin is due to their action on the phospholipid part of the mitochondrial membrane. A possible mechanism of this effect is discussed.     

Regulation of the cytosolic adenylate ratio as determined by rapid fractionation of mesophyll protoplasts of oat

Adenylate levels in chloroplasts, mitochondria and the cytosol of oat mesophyll protoplasts were determined under light and dark conditions, in the absence and presence of plasmalemma-permeable inhibitors of electron transfer and uncouplers of phosphorylation. This was achieved using a microgradient technique which allowed an integrated homogenization and fractionation of protoplasts within 60 s (Hampp et al. 1982, Plant Physiol. 69, 448–455), under conditions which quench bulk activities of metabolic interconversion in less than 2 s. In illuminated controls, ATP/ADP ratios were found to be 2.1 in chloroplasts, about unity in mitochondria, and 11 in the cytosol; whereas, in the dark, this ratio only showed a large drop in chloroplasts (0.4). None of the compounds used [carbonylcyanide m-chlorophenylhydrazone (CCCP), carbonylcyanide p-trifluoromethoxy-phenylhydrazone (FCCP), antimycin A, dibromothymoquinone (DBMIB), dichlorophenyldi-methylurea (DCMU), or salicylhydroxamic acid (SHAM)] affected the stroma adenylate ratio in the dark. Under illumination, however, the ATP/ADP ratios were partly reduced in the presence of antimycin (inhibitor of cyclic photophosphorylation) and of DCMU (inhibitor of linear electron flow), while in the presence of DBMIB, DCMU+ antimycin (inhibition of both cyclic and linear electron flow), and CCCP (uncoupling) the ratio obtained was the same as that occurring in the dark. In contrast, mitochondrial adenylate levels did not exhibit large variations under the various treatments. The cytosolic ATP/ADP ratio, however, showed dramatic changes: in darkened protoplasts, cytosolic values dropped to 0.2 and 0.1 in the presence of uncouplers and antimycin, respectively, while SHAM did not induce any significant alteration. In the light, a similar pronounced decrease in ATP levels was observed only after the application of uncouplers or inhibitors of both mitochondrial and photosynthetic electron transport, whereas selective inhibition of the latter was largely ineffective in reducing the cytosolic ATP/ADP ratio. Thus, the results show that the antimycin-sensitive electron transport is, potentially, equally active in light and darkness. In addition, they indicate that antimycin-insensitive electron transport in mitochondria (alternative pathway) does not significantly contribute to the cytosolic energy state.Abbreviations CCCP carbonylcyanide m-chlorophenylhydrazone - DBMIB dibromothymoquinone (2,5-dibromo-3-methyl-6-isopropy-p-benzoquinone) - DCMU dichlorophenyldimethylurea - FCCP carbonylcyanide-p-trifluoromethoxy-phenylhydrazone - SHAM sancylhydroxamic acid     

Measurement of chloroplast internal protons with 9-aminoacridine. Probe binding, dark proton gradient, and salt effects

A defined ratio, gamma, of the total proton uptake to the concentration change of free internal H+ is observed for illuminated envelope-free chloroplasts (Haraux, F. and de Kouchkovsky, Y. (1979) Biochim. Biophys. Acta, 546, 455-471). Proton uptake is measured by the external pH shift, free internal H+ by 9-aminoacridine fluorescence quenching. Extension of this work leads to the following conclusions, which, in the case of 9-aminoacridine behaviour, should apply to any kind of diffusible protonizable delta pH probe: 1. The gamma constancy is preserved when the internal volume (Vi) is modulated by chlorophyll and osmolarity changes: thus, 9-aminoacridine behaves as expected from the delta pH distribution of an amine of high pK; previous doubts on this point are attributed to the lack of control of the external proton uptake. 2. With variable 9-aminoacridine concentration, however, some variation of gamma confirms the existence of slight light-induced probe-membrane interactions. 3. According to the diffuse layer theory, salts decrease the negative potential at the 'plane of closest approach' of the thylakoids, thereby releasing the excess 9-aminoacridine in this diffuse layer, which increases its fluorescence. Although of equal valency, NH4+ is more potent than K+, suggesting competition between amines for specific anionic binding sites. 4. Two categories of membrane modifications are induced by salts: in addition to the above-mentioned electrical effect, mono- and divalent cations at high concentration increase the chloroplast proton binding capacity. La3+ is only able to release the excess dye in the diffuse layer and leaves gamma unchanged. Therefore the probe-membrane interactions should have limited importance for steady-state delta pH measurement. 5. A Donnan-type dark pH difference, which could seriously bias these delta pH estimates, is found experimentally to be less than 2 (no significant gamma change when Vi varies) and even theoretically less than 1 (on the basis of the concentration of the non-diffusible internal protonizable groups). Similarly, the predictable errors of Vi and its possible light-induced variations must have a small effect on delta pH under present experimental conditions.     

Carboxyatractylate inhibits the uncoupling effect of free fatty acids

The ATP/ADP-antiporter inhibitors and ADP decrease the palmitate-induced stimulation of the mitochondrial respiration in the controlled state. The degree of inhibition decreases in the order: carboxyatractylate greater than bongkrekic acid, palmitoyl-CoA, ADP greater than atractylate. GDP is ineffective. The inhibiting concentration of carboxyatractylate coincides with this arresting the state 3 respiration. Carboxyatractylate inhibition decreases when the palmitate concentration increases. Stimulation of controlled respiration by FCCP or gramicidin D at any concentration of these uncouplers is carboxyatractylate-resistant, whereas that by low concentrations of DNP is partially suppressed by carboxyatractylate. These data together with observations that palmitate does not increase H+ conductance in bilayer phospholipid membranes and in cytochrome oxidase-asolectin proteoliposomes indicate that the ATP/ADP-antiporter is somehow involved in the uncoupling by low concentrations of fatty acids (or DNP), whereas that by FCCP and gramicidin D is due to their effect on the phospholipid bilayer. It is suggested that the antiporter facilitates translocation of palmitate anion across the mitochondrial membrane.     

Analysis of light-induced proton uptake in isolated chloroplasts

1. 1. A simple kinetic analysis of light-induced proton uptake into chloroplasts is presented. It is derived from a model of the reaction in which the incoming proton is obligatorily bound by an intra-chloroplast component, and allows quantitative analysis of the effect into parameters of light and dark rate constants and the availability of the chloroplast component.

2. 2. The effect of the following agents on the derived parameters has been measured: electron and energy transfer inhibitors, uncouplers, NaCl concentration, light intensity and pH.

3. 3. A maximal ratio of 4 protons taken up per electron transported has been observed, using ferricyanide as an electron acceptor.

4. 4. A stimulation of light-induced proton uptake by phosphate or arsenate, ADP and Mg has been observed. It was not sensitive to concentrations of Dio-9, which eliminated ATP synthesis.

5. 5. The results are seen as inconsistent with the chemiosmotic theory of energy coupling as presently presented. It is suggested that they may be interpreted in terms of a model in which the function of the proton pump is to enable co-transport into the chloroplasts of the negatively charged complex of phosphate, ADP and Mg.

Inhibition of stomatal opening in sunflower leaves by carbon monoxide,and reversal of inhibition by light

When leaves of Helianthus annuus, whose stomates had been opened in the dark in the absence of CO₂, were exposed to 25% carbon monoxide (CO), stomatal conductivity for water vapor decreased from about 0.4 to 0.2 cm·s^-1. The CO effect on stomatal aperture required a CO/O₂ ratio of about 25. As this ratio was decreased the stomata opened, indicating that inhibitio of cytochrome-c oxidase by CO is competitive in respect to O₂. Photosynthetically active red light was unable to reverse CO-induced stomatal closure even at high irradiances, when CO₂ was absent. When it was present, stomatal opening was occasionally, but not consistently observed. Carbon monoxide did not inhibit photosynthetic carbon reduction in leaves of Helianthus.In contrast to red light, very weak blue light (405 nm) increased the stomatal aperture in the presence of CO. It also increased leaf ATP/ADP ratios which had been decreased in the presence of CO. The blue-light effect was not related to photosynthesis. Neither could it be explained by photodissociation of the cytochrome a ₃-CO complex which has an absorption maximum at 430 nm. The data indicate that ATP derived from mitochondrial oxidative phosphorylation provides energy for stomatal opening in sunflower leaves in the dark as well as in the light. Indirect transfer of ATP from chloroplasts to the cytosol via the triose phosphate/phosphoglycerate exchange which is mediated by the phosphate translocator of the chloroplast envelope can support stomatal opening only if metabolite concentrations are high enough for efficient shuttle transfer of ATP. Blue light causes stomatal opening in the presence of CO by stimulating ATP synthesis.     

Physiological ligands ADP and Pi modulate the degree of intrinsic coupling in the ATP synthase of the photosynthetic bacterium Rhodobacter capsulatus

The proton-pumping and the ATP hydrolysis activities of the ATP synthase of Rhodobacter capsulatus have been compared as a function of the ADP and P(i) concentrations. The proton pumping was measured either with the transmembrane pH difference probe, 9-amino-6-chloro-2-methoxyacridine, or with the transmembrane electric potential difference probe, bis(3-propyl-5-oxoisoxazol-4-yl)pentamethine oxonol, obtaining consistent results. The comparison indicates that an intrinsic uncoupling of ATP synthase is induced when the concentration of either ligand is decreased. The half-maximal effect was found in the submicromolar range for ADP and at about 70 microM for P(i). It is proposed that a switch from a partially uncoupled state of ATP synthase to the coupled state is induced by the simultaneous binding of ADP and P(i).     

Photosynthetic control, “energy-dependent” quenching of chlorophyll fluorescence and photophosphorylation under influence of tertiary amines

The effects of the tertiary amines tetracaine, brucine and dibucaine on photophosphorylation and control of photosynthetic electron transport in isolated chloroplasts of Spinacia oleracea were investigated. Tertiary amines inhibited photophosphorylation while the related electron transport decreased to the rates, observed under non-phosphorylating conditions. Light induced quenching of 9-aminoacridine fluorescence and uptake of ¹⁴C-labelled methylamine in the thylakoid lumen declined in parallel with photophosphorylation, indicating a decline of the transthylakoid proton gradient. In the presence of ionophoric uncouplers such as nigericin, no effect of tertiary amines on electron transport was seen in a range of concentration where photophosphorylation was inhibited. Under the influence of the tertiary amines tested, pH-dependent feed-back control of photosystem II, as indicated by energy-dependent quenching of chlorophyll fluorescence, was unaffected or even increased in a range of concentration where 9-aminoacridine fluorescence quenching and photophosphorylation were inhibited. The data are discussed with respect to a possible involvement of localized proton flow pathways in energy coupling and feed-back control of electron transport.Abbreviations 9-AA 9-aminoacridine - J _e flux of photosynthetic electron transport - PC photosynthetic control - pH₁ H⁺ concentration in the thylakoid lumen - pmf proton motive force - _P potential quantum yield of photochemistry of photosystem II (with open reaction centers) - Q _A primary quinone-type electron acceptor of photosystem II - q _Q photochemical quenching of chlorophyll fluorescence - q _E energy-dependent quenching of chlorophyll fluorescence - q _AA light-induced quenching of 9-amino-acridine fluorescence     

Energetic and regulatory role of proton potential in chloroplasts

The review focuses on the energetic and regulatory role of proton potential in the activity of chloroplasts, the light energy-converting organelles of plant cells. Mechanisms of generation of the transmembrane difference of electrochemical potentials of hydrogen ions in the chloroplast thylakoid membranes are considered. Methods for measuring the intrathylakoid pH in chloroplasts are described. It is shown that under conditions of phosphorylation in chloroplasts, the pH of the intrathylakoid space decreases moderately (pH_in ⩾ 6.0–6.2, at the stroma pH_out ∼ 7.8–8.0), with a corresponding concentration component of equal to ΔpH ⩽ 1.6–2.0. On analyzing the energy and structural features of ATP synthase of chloroplasts, we conclude that the energy stored as the concentration component of the proton potential ΔpH is sufficient to sustain ATP synthesis. The mechanisms of pH-dependent regulation of electron transport in chloroplasts (photosynthetic control of electron transport, enhancement of non-photochemical quenching of chlorophyll excitation in the light-harvesting antenna, light-induced activation of the Calvin-Benson cycle reactions, activation of ATP synthase) are considered briefly.     

Anion and amine uptake and uncoupling in submitochondrial particles.

1. Unlike chloroplasts, submitochondrial particles are not uncoupled by nigericin + KCl or NH4Cl. Also the uncoupling effect of lipophilic anions is largely independent of the addition of weak bases. 2. Low concentrations of permeant anions cause a shift of the steady-state energy level rather than a cycle of energy utilization. The degree of inhibition of ATP synthesis by tetraphenylboron is larger than required for the uptake of the anion. 3. Lipophilic anions such as bromthymolblue, bromcresolpurple, and 8-anilino-1-napthalene sulphonate cause a pH-independent, 50% uncoupling in submitochondrial particles at concentrations of 3, 30 and 30 muM, respectively. The passive interaction of bromthymolblue and bromcresolpurple appears as a pH-dependent distribution between two pHases. ATP causes a pH-independent slight shift in the anion distribution, with negligible anion accumulation. 4. Addition of amines to energized submitochondrial particles results in two types of effects; uptake of amines and uncoupling. While in chloroplasts amine uptake and uncoupling are closely associated, this is not the case in submitochondrial particles. The uncoupling effect is observed only with lipophilic and not with hydrophilic amines, and the degree of uncoupling increases with the lipophilicity of the amines. The amine uptake, on the other hand, is accompanied by negligible uncoupling. 5. While the uptake of amines is dependent on the presence of non-permeant anions, such as Cl-, the uncoupling effect is independent of Cl-. Furthermore the amine uncoupling is markedly enhanced by lipophilic anions. 6. The view is discussed that the uncoupling effect of lipophilic anions and lipophilic amines in submitochondrial particles is due to a catalytic energy dissipation rather than to a stoichiometry energy utilization. The molecular mechanism of uncoupling presumably involves a cycling of charges after a perturbation of the membrane structure.     

Regulation of photosynthesis in isolated spinach chloroplasts during orthophosphate limitation

The stromal concentration of orthophosphate in intact spinach chloroplasts (prepared in the absence of orthophosphate or pyrophosphate but supplied with both in the reaction medium) fell from a value of approx. 20 mM in the dark to a steady-state concentration of approx. 8 mM in the light. Chloroplasts illuminated in the absence of orthophosphate or pyrophosphate showed a similar trend. However, in this situation the stromal inorganic phosphate (P_i) concentration rapidly decreased from approx. 10 mM in the dark to a constant steady-state concentration of between 1.5 and 2.5 mM in the light. This P_i concentration was not further diminished (even though CO₂-dependent O₂ evolution had ceased) and was therefore considered to be stromal orthophosphate not freely available to metabolism. In the P_i-deficient chloroplasts the rate of photosynthesis declined rapidly after 1–2 min in the light such that CO₂-dependent O₂ evolution ceased with 5 min of the onset of illumination. The decline in O₂ evolution was accompanied by an increase in the transthylakoid ΔpH (as measured by 9-aminoacridine fluorescence quenching) and in the high-energy state, non-photochemical component of chlorophyll fluorescence quenching (q_E). Measurements of stromal metabolite concentrations showed that the ATP/ADP ratio was decreased in the P_i-deficient chloroplasts relative to chloroplasts illuminated in the presence of P_i. The stromal concentration of glycerate 3-phosphate was comparable in the P_i-deficient chloroplasts and those to which P_i had been supplied. Chloroplasts which were illuminated in P_i-free media showed a large accumulation of ribulose-1,5-bisphosphate relative to those supplied with P_i, suggesting inhibition of ribulose-1,5-bisphosphate carboxylase under these conditions. When P_i was added to chloroplasts illuminated in the absence of P_i, both non-photochemical quenching (q_E), photochemical quenching (q_Q) and ΔpH increased. This suggests that electron transport was not limited by inability to discharge transthylakoid ΔpH. These observation are consistent with the hypothesis that P_i limitation results in decreased ATP production by the thylakoid ATP synthase. The data presented here show that there are multiple sites of flux control exerted by low stromal P_i in the chloroplast. At least three factors contribute to the inhibition of photosynthesis under phosphate limitation: (1) there appears to be a direct effect of P_i on the energy-transducing system; (2) there is direct inhibition of the Calvin cycle decreasing the ability of the pathway to act as a sink for ATP and NADPH; and (3) feedback inhibition of primary processes occurs either via ΔpH or the redox state of electron carriers. However, ΔpH does not appear to be a limiting factor, but rather an inability to regenerate NADP as electron acceptor is suggested. The addition of DCMU to chloroplasts during illumination in the absence of P_i for periods of up to 10 min showed that there was very little loss of variable fluorescence despite a 60% reduction in the capacity for O₂ evolution. This would suggest that photoinhibitory damage to Photosystem II was not the major cause of the inhibition of photosynthesis observed with low P_i.     

Oxygen requirement of photosynthetic CO2 assimilation

In the absence of electron acceptors and of oxygen a proton gradient was supported across thylakoid membranes of intact spinach chloroplasts by far-red illumination. It was decreased by red light. Inhibition by red light indicates effective control of cyclic electron flow by Photosystem II. Inhibition was released by oxygen which supported a large proton gradient. Oxygen appeared to act as electron acceptor simultaneously preventing over-reduction of electron carriers of the cyclic electron transport pathway. It thus has an important regulatory function in electron transport. Under anaerobic conditions, the inhibition of electron transport caused by red illumination could also be released and a large proton gradient could be established by oxaloacetate, nitrite and 3-phosphoglycerate, but not by bicarbonate. In the absence of oxygen, ATP levels remained low in chloroplasts illuminated with red light even when bicarbonate was present. They increased when electron acceptors were added which could release the over-reduction of the electron transport chain. Inhibition of electron transport in the presence of bicarbonate was relieved and CO2-fixation was initiated by oxygen concentrations as low as about 10 microM. Once CO2 fixation was initiated, very low oxygen levels were sufficient to sustain it. The results support the assumption that pseudocyclic electron transport is necessary to poise the electron transport chain so that a proper balance of linear and cyclic electron transport is established to supply ATP for CO2 reduction.     

Modification of flow-force relationships by external ATP in yeast mitochondria

The purpose of this work is to measure protonmotive force and cytochrome reduction level under different respiratory steady states in isolated yeast mitochondria. The rate of respiration was varied by using three sets of conditions: (a) different external phosphate concentrations with a fixed concentration of ADP (ATP synthesis) and (b) different concentrations of carbonylcyanide m-chlorophenylhydrazone in the presence of oligomycin and carboxyatractylate (uncoupling) either in the absence or (c) in the presence of external ATP. ADP plus phosphate stimulates respiration more than uncoupler at the same protonmotive force value. However, the relationships between respiratory rate and protonmotive force were similar when stimulation was induced either by ADP + Pi or by carbonylcyanide m-chlorophenylhydrazone in the presence of ATP. At the same respiratory rate, cytochrome a + a3 is more reduced by uncoupler than by ADP + Pi additions. However, the relationships between respiratory rate and reduction level of cytochrome-c oxidase are similar both under ATP synthesis and with uncoupling conditions in the presence of external ATP. Control of respiration exerted by cytochrome-c oxidase, and support the view the condition mentioned above. This control was low when the respiratory rate was varied by the ATP synthesis rate; it increased as a function of the respiratory rate with uncoupler in the absence of ATP. ATP decreased this control under uncoupling conditions. These results suggest a regulatory effect of external ATP on cytochrome-c oxidase, and support the view that the relationships between respiratory rate and protonmotive force, on the one hand, and respiratory rate and the reduction level of cytochrome-c oxidase, on the other, depend respectively on the kinetic regulations of the system.     

Effects of Water Stress on Energy Transduction in Chloroplasts

Water stress inhibited the photosynthetic O2 evolution rate of wheat leaves. It was shown that water stress decreased the electron transport rate, the activities of photophosphorylation and, coupling factor, and, the synthesis of ATP in chloroplasts. PS Ⅱ electron transport was more senstitive to water stress than PS Ⅰ. The reduction in photophosphorylation activity might be the results of reduction in electron transport rate and coupling factor activity, as well as the uncoupling effect of water stress on chloroplasts. The uncoupling effect could be due to the inhibition of light induced proton translocation in chloroplasts.