Inorganic pyrophosphatase and photosynthesis by isolated chloroplasts. I. Characterisation of chloroplast pyrophosphatase and its relation to the response to exogenous pyrophosphate

1. 1. A soluble, alkaline, Mg²⁺-dependent inorganic pyrophosphatase (EC 3.6.1.1) has been isolated from the stroma of intact spinach and pea chloroplasts and purified some 100-fold. The enzyme has a high specificity for inorganic pyrophosphate and Mg²⁺, and exhibits maximal activity at pH 8.2–8.6. The enzyme shows allosteric characteristics with Mg²⁺ as activator and optimal rates are obtained with a ratio of Mg²⁺ to PP_i of approximately 4 to 1. The enzyme is inhibited by anionic PP_i and by its own reaction product, orthophosphate.

2. 2. If Mg²⁺ is excluded from the medium in which isolated chloroplasts are assayed, active photosynthetic oxygen evolution can still be observed. The addition of P_i, but not PP_i, will then offset a phosphate deficiency. If external Mg²⁺ is present PP_i will also offset a phosphate deficiency and in these circumstances the rapidity and nature of the response is related to the external pyrophosphatase activity.

3. 3. Evidence is presented that the chloroplast envelope is relatively impermeable to PP_i and that the response to added PP_i is due to external hydrolysis followed by entry of P_i to the chloroplast. These results have significance concerning proposed mechanisms for control of photosynthesis.

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.     

Photosynthesis by isolated chloroplasts. Reversal of orthophosphate inhibition by Calvin-cycle intermediates

1. The orthophosphate inhibition of photosynthesis by isolated spinach chloroplasts can be reversed by 3-phosphoglycerate, dihydroxyacetone phosphate, glyceraldehyde 3-phosphate, fructose 6-phosphate and fructose 1,6-diphosphate. 2. Metabolically related compounds such as ribulose 1,5-diphosphate, glucose 6-phosphate, 6-phosphogluconate and phosphoenolpyruvate are ineffective. 3. The kinetics of reversal are characteristic of the intermediate used, but, in each instance, the onset of oxygen evolution is accompanied by a carbon dioxide fixation and except with 3-phosphoglycerate the stoicheiometry is close to unity. 4. The nature of orthophosphate inhibition and its reversal is discussed in relation to metabolic control of photosynthesis.     

Photophosphorylation as a function of illumination time. II. Effects of permeant buffers

(1) The amounts of orthophosphate, bicarbonate and tris(hydroxymethyl)-aminomethane found inside the thylakoid are almost exactly the amounts predicted by assuming that the buffers equilibrate across the membrane. Since imidazole and pyridine delay the development of post-illumination ATP formation while increasing the maximum amount of ATP formed, it follows that such relatively permeant buffers must also enter the inner aqueous space of the thylakoid.(2) Photophosphorylation begins abruptly at full steady-state efficiency and full steady-state rate as soon as the illumination time exceeds about 5 ms when permeant ions are absent or as soon as the time exceeds about 50 ms if valinomycin and KCl are present. In either case, permeant buffers have little or no effect on the time of illumination required to initiate phosphorylation. A concentration of bicarbonate which would delay acidification of the bulk of the inner aqueous phase for at least 350 ms has no effect at all on the time of initiation of phosphorylation. In somewhat swollen chloroplasts, the combined buffering by the tris(hydroxymethyl)aminomethane and orthophosphate inside would delay acidification of the inside by 1500 ms but, even in the presence of valinomycin and KCl, the total delay in the initiation of phosphorylation is then only 65 ms. Similar discrpancies occur with all of the other buffers mentioned.(3) Since these discrepancies between internal acidification and phosphorylation are found in the presence of saturating amounts of valinomycin and KCl, it seems that photophosphorylation can occur when there are no proton concentration gradients and no electrical potential differences across the membranes which separate the medium from the greater part of the internal aqueous phase.(4) We suggest that the protons produced by electron transport may be used directly for phosophorylation without ever entering the bulk of the inner aqueous phase of the lamellar system. If so, phosphorylation could proceed long before the internal pH reflected the proton activity gradients within the membrane.     

Photophosphorylation as a function of illumination time. I. Effects of permeant cations and permeant anions

(1) Very brief periods of illumination do not initiate photophosphorylation in isolated chloroplast lamellae. The time of illumination required before any phosphorylation can be detected is inversely proportional to the light intensity. At very high intensities, phosphorylation is initiated after illumination for about 4 ms.(2) There is no similar delay in the initiation of electron transport. The rate of electron transport is very high at first but declines at about the time the capacity for ATP synthesis develops. When the chloroplasts are uncoupled with gramicidin the high initial rate persists.(3) Various ions which permeate the thylakoid membrane (K⁺ or Rb⁺ in the presence of valinomycin, SCN^?, I^?, or ClO₄^?) markedly increase the time of illumination required to initiate phosphorylation. Potassium ions in the presence of valinomycin increase the delay to a maximum of about 50 ms whereas thiocyanate ions increase the delay to a maximum of about 25 ms. The effects of K⁺ with valinomycin and the effect of SCN^? are not additive. Permeant ions and combinations of permeant ions have little or no effect on phosphorylation during continuous illumination.(4) The reason for the threshold in the light requirement and the reason for the effect of permeant ions thereon are both obscure. However, it could be argued that the energy for phosphorylation initially resides in an electric potential gradient which is abolished by migration of ions in the field, leaving a more slowly developing proton concentration gradient as the main driving force for phosphorylation during continuous illumination. If so, the threshold in the presence of permeant ions should depend on internal hydrogen ion buffering.     

Inhibition of photosynthesis by oxygen in isolated spinach chloroplasts

The inhibition of photosynthetic CO₂ fixation by O₂, commonly referred to as the Warburg effect, was examined in isolated intact spinach (Spinacia oleracea) chloroplasts. The major characteristics of this effect in isolated chloroplasts are rapid reversibility when O₂ is replaced by N₂, an increased inhibition by O₂ at low concentrations of CO₂ and a decreased effect of O₂ with increased concentrations of CO₂.     

Photoswelling and light-inactivation of isolated chloroplasts II. Functional and structural changes in isolated chloroplasts under the influence of lysolecithin

Lysolecithin was added to spinach chloroplasts in suspension,and its effect as a detergent on structure and electron transportactivities was examined. At low concentrations of lysolecithin,the activities of FeCN photoreduction and O₂-linked DCPIPH₂photo-oxidation were stimulated but the photoreduction of NADPwas not enhanced and decreased with an increase in concentration.Absorption bands over the whole visible region were intensifiedwithout any shifts. At high concentrations, the activities ofFeCN photoreduction and O₂-linked DCPIPH₂ photo-oxidation decreasedfrom a maximum to 10–50% of the control activity, andNADP photoreduction was completely inhibited. Absorption bandswere further intensified and the red band was slightly shifted.Results indicate that lysolecithin treatment is useful in chloroplastbiochemistry. Lysolecithin formation and the deterioration ofchloroplasts during light-aging is also discussed. (Received August 15, 1974; )     

Inhibition of photosynthesis in isolated spinach chloroplasts by inorganic phosphate or inorganic pyrophosphatase in the presence of pyrophosphate and magnesium ions

Inhibition of photosynthesis in isolated spinach chloroplasts by P_i is decreased by the presence of PP_i and increased with increasing Mg²⁺ concentration. Previously reported regulation of this photosynthesis by protein factors from spinach leaves appears to be due mostly to pyrophosphate phosphohydrolase (EC 3.6.1.1) activity which converts PP_i to P_i and to the effects of PP_i and Mg²⁺ on this pyrophosphatase activity.     

Permeability characteristics of erythrocyte ghosts prepared under isoionic conditions by a glycol-induced osmotic lysis

A detailed study has been made of the permeability characteristics of human erythrocyte ghosts prepared under isoionic conditions by a glycol-induced lysis (Billah, M.M., Finean, J.B., Coleman, R. and Michell, R.H. (1976) Biochim. Biophys. Acta 433, 45–54). Impermeability to large molecules such as dextran (average molecular weight 70 000) was restored immediately and spontaneously after each of the 5–7 lyses that were required to remove all of the haemoglobin. Permeabilities to smaller molecules such as MgATP^2?, [³H]inositol and [¹⁴C]choline were initially high but could be greatly reduced by incubation at 37°C for an hour. The extent of such resealing decreased as the number of lyses to which the ghosts had been subjected increased. Both removal of haemoglobin and permeabilities to small molecules were affected significantly by pH, Ca²⁺ concentrations and divalent cation chelators. Maximum resealing was achieved in ghosts prepared in the basic ionic medium (130 mM KCl, 10 mM NaCl, 2 mM MgCl₂, 10 mM $\text{N-2-}\text{hydroxyethylpiperazine}\text{-N′-2-}\text{ethanesulphonic}$ acid (HEPES)) at pH 7.0 (0°C) and with a calcium level around 10^?5 M. Acidic pH facilitated the removal of haemoglobin whilst the presence of divalent cation chelators slowed down its release. Retention of K⁺ by ghosts loaded with K⁺ during the first lysis and subsequently incubated at 37° C was substantial but little K⁺ could be retained within the haemoglobin-free ghosts. Permeability of the ghosts to K⁺ after one lysis was affected by temperature, pH, Ca²⁺ concentrations and by the presence of divalent cation chelators.     

The mechanism of the oxidation of ascorbate and Mn by chloroplasts: The role of the radical superoxide

1. 1. The mechanism of the photooxidation of ascorbate and of Mn²⁺ by isolated chloroplasts was reinvestigated.

2. 2. Our results suggest that ascorbate or Mn²⁺ oxidation is the result of the Photosystem I-mediated production of the radical superoxide, and that neither ascorbate nor Mn²⁺ compete with water as electron donors to Photosystem II nor affect the rate of electron transport through the two photosystems: The radical superoxide is formed as a result of the autooxidation of the reduced forms of low potential electron acceptors, such as methylviologen, diquat, napthaquinone, or ferredoxin.

3. 3. In the absence of ascorbate or Mn²⁺ the superoxide formed dismutases either spontaneously or enzymatically producing O₂ and H₂O₂. In the presence of ascorbate or Mn²⁺, however, the superoxide is reduced to H₂O₂ with no formation of O₂. Consequently, in the absence of reducing compounds, in the reaction H₂O to low potential acceptor one O₂ (net) is taken up per four electrons transported where as in the presence of ascorbate, Mn²⁺ or other suitable reductants up to three molecules O₂ can be taken up per four electrons transported.

4. 4. This interpretation is supported by the following observations: (a) in a chloroplast-free model system containing NADPH and ferredoxin-NADP reductase, methylviologen can be reduced to a free radical which is autooxidizable in the presence of O₂; the addition of ascorbate or Mn²⁺ to this system results in a two fold stimulation of O₂ uptake, with no stimulation of NADPH oxidation. The stimulation of O₂ uptake is inhibited by the enzyme superoxide dismutase; (b) the stimulation of light-dependent O₂ uptake in the system H₂O → methylviologen in chloroplasts is likewise inhibited by the enzyme superoxide dismutase.

5. 5. In Class II chloroplasts in the system H₂O → NADP upon the addition of ascorbate or Mn²⁺ an apparent inhibition of O₂ evolution is observed. This is explained by the interaction of these reductants with the superoxide formed by the autooxidation of ferredoxin, a reaction which proceeds simultaneously with the photoreduction of NADP. Such an effect usually does not occur in Class I chloroplasts in which the enzyme superoxide dismutase is presumably more active than in Class II chloroplasts.

6. 6. It is proposed that since in the Photosystem I-mediated reaction from reduced 2,4-dichlorophenolindophenol to such low potential electron acceptor as methylviologen, superoxide is formed and results in the oxidation of the ascorbate present in the system, the ratio ATP/2e in this system (when the rate of electron flow is based on the rate of O₂ uptake) should be revised in the upward direction.

Phosphorylation in isolated chloroplasts coupled to dichlorophenyldimethylurea-insensitive silicomolybdate reduction

1. The electron transport in isolated chloroplasts with silicomolybdate as electron acceptor has been reinvestigated. The silicomolybdate reduction has been directly measured as ΔA₇₅₀ or indirectly as O₂ evolution (in the presence or absence of ferricyanide).2. Silicomolybdate-dependent O₂ evolution is inhibited to a similar extent by 3-(3,4-dichlorophenyl) 1, 1-dimethylurea (DCMU) or dibromothymoquinone (DBMIB), indicating the existence of two different sites of silicomolybdate reduction: one before the DCMU block (i.e. at Photosystem II) and one after the DBMIB block (i.e. at Photosystem I).3. Silicomolybdate-dependent O₂ evolution is coupled to ATP synthesis with an $\text{ATP}\text{2}\text{e}{}^{\mathrm{?}}$ ratio of 1.0 to 1.1. The presence of ferricyanide inhibits this ATP synthesis ($\text{ATP}\text{2}\text{e}{}^{\mathrm{?}}$ ratio then is about 0.3).4. Silicomolybdate-dependent O₂ evolution is also coupled to ATP-synthesis in the presence of DCMU with an $\text{ATP}\text{2}\text{e}{}^{\mathrm{?}}$ ratio of 0.6–0.8 characteristic of Site II; in this case the electron transport itself is not affected by uncouplers or energy-transfer inbihitors.5. The data are interpreted as a further demonstration that the water-splitting reaction is responsible for the conservation of energy at Photosystem II.     

The ATP/2e ratio during photosynthesis in intact spinach chloroplasts.

Addition of ribose-5-phosphate to intact spinach chloroplasts in the absence of added P_i resulted in a conversion of part of the Benson-Calvin cycle into a linear sequence so that triose phosphate accumulated during CO₂ fixation stoichiometrically with the O₂ evolved (triose phosphate / O₂ ratio was 2.0). The fortunate consequence of this effect is that the $\text{ATP}\text{2e}$ ratio may be calculated from the 3-phosphoglycerate and triose phosphate accumulated and the O₂ evolved. In this way the $\text{ATP}\text{2e}$ ratio was shown to be 2.0, with cyclic or pseudocyclic phosphorylation contributing less than 9% to the total phosphorylation.     

Photosynthesis by isolated protoplasts, protoplast extracts, and chloroplasts of wheat: influence of orthophosphate, pyrophosphate, and adenylates

Protoplasts, protoplast extracts (intact chloroplasts plus extrachloroplastic material), and chloroplasts isolated from protoplasts of wheat (Triticum aestivum) have rates of photosynthesis as measured by light-dependent O₂ evolution of about 100 to 150 micromoles of O₂ per milligram of chlorophyll per hour at 20 C and saturating bicarbonate. The assay conditions sufficient for this activity were 0.4 molar sorbitol, 50 millimolar N-2-hydroxyethylpiperazine-N′-2-ethanesulfonic acid KOH (pH 7.6), and 10 millimolar NaHCO₃ with protoplast, plus a requirement of 1 to 10 millimolar ethylenediaminetetraacetate (EDTA) and 0.2 to 0.5 millimolar inorganic orthophosphate (Pi) with protoplast extracts and chloroplasts. Protoplast extracts evolved approximately 6 micromoles of O₂ per milligram of chlorophyll before photosynthesis became largely dependent on exogenous Pi while photosynthesis by chloroplasts had a much stronger dependence on exogenous Pi from the outset.

Photosynthesis by chloroplasts from 6-day-old wheat plants under optimum levels of Pi was similar to that with the addition of 5 millimolar inorganic pyrophosphate (PPi) plus 0.2 millimolar adenosine-5′-diphosphate (ADP). Either PPi or ADP added separately inhibited photosynthesis. When chloroplasts were incubated in the dark for 2 to 6 minutes, photosynthesis was strongly inhibited by 5 millimolar PPi and this inhibiting was relieved by including adenosine-5′-triphosphate (ATP) or ADP (0.2 to 0.6 millimolar). Chloroplasts from 9-day-old wheat leaves were slightly less sensitive to inhibition by PPi and showed little or no inhibition by ADP.

Chloroplasts isolated from protoplasts and assayed with 0.3 millimolar Pi added before illumination have an induction time from less than 1 minute up to 16 minutes depending on the time of the assay after isolation and the components of the medium. In order to obtain maximum rates of photosynthesis and minimum induction time, NaHCO₃ and chelating agents, EDTA or PPi (+ATP), are required in the chloroplast isolation, resuspension and assay medium. With these inclusions in the isolation and resuspension medium the induction time decreased rapidly during the first 20 to 30 minutes storage of chloroplasts on ice. Requirements for isolating intact and photosynthetically functional chloroplasts from wheat protoplasts are discussed.

     

The effect of dihydroxyacetone phosphate and 3-phosphoglycerate on O2 evolution and on the levels of ATP,ADP and Pi in isolated intact chloroplasts

Addition of dihydroxyacetone phosphate (2.5 mM) or 3-phosphoglycerate (2.5 mM) to a suspension of isolated intact chloroplasts, which contains P_i only in low concentrations (0.2 mM) leads to a competitive inhibition of P_i uptake in the light. In consequence, the ATP/ADP ratio is strongly decreased. The rate of O₂ evolution is also reduced under these conditions, but the degree of inhibition is much higher after addition of dihydroxyacetone phosphate than after addition of 3-phosphoglycerate. Therefore, besides the competitive inhibition of P_i uptake, additional effects of dihydroxyacetone phosphate and 3-phosphoglycerate on O₂ evolution and CO₂ fixation of isolated intact chloroplasts must occur, which are discussed.     

The role of monovalent cations for photosynthesis of isolated intact chloroplasts

The role of monovalent cations in the photosynthesis of isolated intact spinach chloroplasts was investigated. When intact chloroplasts were assayed in a medium containing only low concentrations of mono- and divalent cations (about 3 mval l^-1), CO₂-fixation was strongly inhibited although the intactness of chloroplasts remained unchanged. Addition of K⁺, Rb⁺, or Na⁺ (50–100 mM) fully restored photosynthesis. Both the degree of inhibition and restoration varied with the plant material and the storage time of the chloroplasts in low-salt medium. In most experiments the various monovalent cations showed a different effectiveness in restoring photosynthesis of low-salt chloroplasts (K⁺>Rb⁺>Na⁺). Of the divalent cations tested, Mg²⁺ also restored photosynthesis, but to a lesser extent than the monovalent cations.In contrast to CO₂-fixation, reduction of 3-phosphoglycerate was not ihibited under low-salt conditions. In the dark, CO₂-fixation of lysed chloroplasts supplied with ATP, NADPH, and 3-phosphoglycerate strictly required the presence of Mg²⁺ but was independent of monovalent cations. This finding excludes a direct inactivation of Calvin cycle enzymes as a possible basis for the inhibition of photosynthesis under low-salt conditions.Light-induced alkalization of the stroma and an increase in the concentration of freely exchangeable Mg²⁺ in the stroma, which can be observed in normal chloroplasts, did not occur under low-salt conditions but were strongly enhanced after addition of monovalent cations (50–100 mM) or Mg²⁺ (20–50 mM).The relevance of a light-triggered K⁺/H⁺ exchange at the chloroplast envelope is discussed with regard to the light-induced increase in the pH and the Mg²⁺ concentration in the stroma, which are thought to be obligatory for light activation of Calvincycle enzymes.     

Energy-dependent accumulation of iron by isolated rat liver mitochondria V. Effect on factors controlling respiration and oxidative phosphorylation

1. Depending on the metabolic state, the addition of iron(III)-sucrose induces an inhibition or a stimulation of the respiration rate when added to isolated rat liver mitochondria.2. Under conditions identical to those used in the accumulation studies (Romslo, I. and Flatmark, T. (1973) Biochim. Biophys. Acta 305, 29?40), the ferric complex induces a decrease in the oxygen uptake concomitant to an oxidation of cytochromes c (+c₁) and a (+a₃). These results suggest that ferric iron is reduced to ferrous iron by the respiratory chain prior to or simultaneously with its energy-dependent accumulation.3. On the other hand, the addition of iron(III)-sucrose induces a stimulation of respiration in State 4 and State 3 provided Mg²⁺ is present in the suspending medium. In contrast to Ca²⁺, iron stimulates State 4 respiration in a cyclic process only within narrow concentration limits; at concentrations of iron above 100 μM the respiration remains in the activated state until anaerobiosis. The stimulation of State 4 respiration is more pronounced with succinate than with NAD-linked substrates, a difference which partly may be attributed to a stimulation of the succinate dehydrogenase complex.4. The stimulation of respiration by iron is approx. 3 times higher in State 3 than in State 4 and this difference can be attributed to a stimulation of the adenine nucleotide exchange reaction in State 3 with a concomitant increase in the rate of oxidative phosphorylation, although the $\text{P}\text{O}$ ratio is slightly diminished.