Regulation of the chloroplast H+-ATPase by light. The involvement of Mg2+ ions

The involvement of Mg2+ ions in the light-dependent regulation of the chloroplast H+-ATPase was studied in both type C and osmotically shocked type A chloroplasts. The following results were obtained. ATPase activity measured under dark, partially uncoupling conditions, following light activation with dithiothreitol and pyocyanine, was markedly enhanced by the presence of Mg2+ in the activation stage. This Mg2+ effect required concentrations in the millimolar range, was rather slow (time range of minutes), reversible, rather unspecific and did not involve changes in the affinity to dithiothreitol. Dark deactivation of the ATPase in the absence of substrate was accelerated by Mg2+. The dark effect of Mg2+ also required millimolar concentrations, but was fast (time range of seconds), highly specific for Mg2+, and did not involve thiol oxidation. The major effect of the absence of Mg2+ from the light-activation stage or of its presence in the dark interval between activation and assay was the induction of an 'abnormal' sensitivity to uncouplers: after these treatments ATP hydrolysis was not stimulated but rather inhibited by NH4Cl or other uncouplers. The pretreatments in the light without Mg2+ or dark with Mg2+ did not affect the membrane proton permeability, nor the proton pumping coupled to ATPase activity. The results are discussed in terms of Mg2+-dependent regulation of the enzyme complex at the level of subunit interaction and its effect on the affinity to protons.     

Evidence for function of the ferredoxin/thioredoxin system in the reductive activation of target enzymes of isolated intact chloroplasts

Results obtained with isolated intact chloroplasts maintained aerobically under light and dark conditions confirm earlier findings with reconstituted enzyme assays and indicate that the ferredoxin/thioredoxin system functions as a light-mediated regulatory thiol chain. The results were obtained by application of a newly devised procedure in which a membrane-permeable thiol labeling reagent, monobromobimane (mBBr), reacts with sulfhydryl groups and renders the derivatized protein fluorescent. The mBBr-labeled protein in question is isolated individually from chloroplasts by immunoprecipitation and its thiol redox status is determined quantitatively by combining sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorescence measurements. The findings indicate that each member of the ferredoxin/thioredoxin system containing a catalytically active thiol group is reduced in isolated intact chloroplasts after a 2-min illumination. The extents of reduction were FTR, 38%; thioredoxin m, 75% (11-kDa form) and 87% (13-kDa form); thioredoxin f, 95%. Reduction of each of these components was negligible both in the dark and when chloroplasts were transferred from light to dark conditions. The target enzyme, NADP-malate dehydrogenase, also underwent net reduction in illuminated intact chloroplasts. Fructose-1,6-bisphosphatase showed increased mBBr labeling under these conditions, but due to interfering gamma globulin proteins it was not possible to determine whether this was a result of net reduction as is known to take place in reconstituted assays. Related experiments demonstrated that mBBr, as well as N-ethylmaleimide, stabilized photoactivated NADP-malate dehydrogenase and fructose-1,6-bisphosphatase so that they remained active in the dark. By contrast, phosphoribulokinase, another thioredoxin-linked enzyme, was immediately deactivated following mBBr addition. These latter results provide new information on the relation between the regulatory and active sites of these enzymes.     

Characteristics of the Mg-ATPase Activity Associated with the Membrane-Bound Maize Coupling Factor

The membrane-bound coupling factor of maize mesophyll thylakoids is a latent ATPase. Mg²⁺-ATPase activity can be induced in the light with either dithiothreitol or low concentrations of trypsin. Maize thylakoids that are activated with light plus trypsin exhibit considerably higher levels of activity in Na₂SO₃-dependent Mg²⁺-ATPase assays compared to thylakoids that are light and dithiothreitol activated (1400 micromoles per milligram of chlorophyll per hour versus 200 micromoles per milligram of chlorophyll per hour). Treatment with light and dithiothreitol or light plus trypsin were also required to demonstrate high levels of octyl glucoside-dependent Mg²⁺-ATPase activity in maize mesophyll thylakoids. Only small differences in octyl glucoside-dependent Mg²⁺-ATPase activity were observed in preparations that were activated in the light with either trypsin or dithiothreitol. Mg²⁺-ATPase activity can also be induced in maize mesophyll chloroplasts by illuminating intact preparations under appropriate conditions. Little or no ATPase activity was observed in the absence of illumination or in the presence of light plus methyl viologen. The active state decayed in the dark with a t_½ of 6 to 7 minutes at room temperature. Based on the effect of the thiol oxidant, o-iodosobenzoate, and the uncoupler, nigericin, on the kinetics of deactivation of ATPase activity in intact maize chloroplasts, it appears that the activation process requires a transmembrane proton gradient and reduction of a key disulfide bridge in the gamma of chloroplast coupling factor one.     

The deactivation process of the proton-ATPase in isolated chloroplasts and whole leaves

Using rapid micromethods for chloroplast isolation and ATPase solubilization from preilluminated leaves, the deactivation of the proton-ATPase after different treatments was compared. The rate of decay of the ‘in vivo’ light-activated membrane-bound Mg²⁺-ATPase was highly dependent on temperature. However, the soluble Ca²⁺-ATPase, extracted from the temperature-inactivated membrane-bound ATPase, was active. Coupling factor 1 with a manifest and stable Ca²⁺-ATPase activity was also solubilized from chloroplasts activated by light in whole leaves and deactivated after chloroplast isolation with gramicidin D. Deactivation of the proton-ATPase in isolated chloroplasts was only associated with the dissipation of the proton gradient. Reaction of the accessible sulfhydryl groups of the membrane-bound proton-ATPase with iodoacetamide prevent inactivation of the enzyme by oxidants. However, the iodoacetamide treatment had not effect on the temperature-dependent decay. The rate of deactivation of the proton-ATPase in whole leaves was similar for both membrane-bound and soluble ATPases. Thus, the oxidation process may play an important role in physiological conditions.     

Effect of dicyclohexylcarbodiimide on the proton conductance of thylakoid membranes in intact chloroplast

The effects of dicyclohexylcarbodiimide, a potent inhibitor of chloroplast ATPase, on the light-induced electric potential changes in intact chloroplasts of Peperomia metallica and of a hornwort Anthoceros sp. were investigated by means of glass microcapillary electrodes. The characteristics of potential changes induced by flashes or continuous light in chloroplasts of both species are similar except for the phase of potential rise in continuous light, which is clearly biphasic in Anthoceros chloroplasts. Dicyclohexylcarbodiimide at concentration 5 · 10⁻⁵ M completely abolishes the transient potential undershoot in the light-off reaction but has little effect on the peak value of the photoelectric response. The membrane conductance in the light and in the dark was tested by measuring the decay kinetics of flash-generated potential in dark-adapted and preilluminated chloroplasts. In the absence of dicyclohexylcarbodiimide, preillumination causes a significant acceleration of the potential decay. The light-induced changes in the decay kinetics of flash-induced responses were abolished in the presence of dicyclohexylcarbodiimide, whereas the rate of potential decay in dark-adapted chloroplasts was not altered by dicyclohexylcarbodiimide. The results are consistent with the notion that dicyclohexylcarbodiimide diminishes H⁺ conductance of energized thylakoid membranes by interacting with the H⁺ channel of ATPase. The occurrence of a lag (approx. 300 ms) on the plot of potential undershoot (diffusion potential) versus illumination time might suggest the increase in H⁺ permeability coefficient of thylakoid membrane during illumination.     

Role of the gamma subunit of chloroplast coupling factor 1 in the light-dependent activation of photophosphorylation and ATPase activity by dithiothreitol

In leaves and intact chloroplasts, oxidation and reduction have been shown previously to regulate the ATPase activity of thylakoids. Illumination of spinach chloroplast thylakoids in the presence of dithiothreitol, which activates the ability of thylakoids to catalyze sustained ATP hydrolysis in the dark, causes increased incorporation of N-ethylmaleimide into the gamma subunit of coupling factor 1 (CF1). A disulfide bond in the gamma subunit is reduced during activation. The residues involved in this disulfide bond are the same as those in the disulfide linkage reduced during dithiothreitol activation of soluble CF1. The disulfide and dithiol forms of the gamma subunit may be separated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. N-Ethylmaleimide is preferentially incorporated in the dark into the reduced form of the gamma subunit of CF1 in thylakoids previously exposed to dithiothreitol. Only a subpopulation of the CF1 in thylakoids is susceptible to dithiothreitol reduction and subsequent reaction with N-ethylmaleimide in the dark. Alkylation of the thiol groups exposed by reduction of the disulfide bond protects ATPase activity from inhibition by oxidants. At a given value of the transmembrane pH differential, photophosphorylation rates in dithiothreitol-activated thylakoids can be as much as seven to eight times those of nonactivated controls. N-Ethylmaleimide treatment of activated thylakoids in the dark prevents the loss of the stimulation of ATP synthesis on storage of the thylakoids. Photophosphorylation by intact chloroplasts lysed in assay mixtures is also activated in comparison to that by washed thylakoids. At a low ADP concentration, the rate of photophosphorylation approaches saturation as delta pH increases. These results suggest that the gamma subunit of CF1 plays an important role in regulation of ATP synthesis and hydrolysis.     

Activation and Deactivation of H-ATPase in Intact Chloroplasts

The light activation mechanism of the latent H⁺-ATPase was investigated in intact spinach (Spinacia oleracea, Hybrid 424) chloroplasts. The following observations were made. (a) Photosystem I electron acceptors such as methyl viologen, nitrite, oxaloacetate, etc., inhibit the light activation of the enzyme. (b) The electron transfer inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) fully inhibits the process. (c) Ascorbate plus diaminodurene or dithionite can restore light activation in DCMU-poisoned chloroplasts. (d) The activated state of the enzyme decays rather slowly (within a few minutes) after illumination of the intact chloroplasts. (e) The rate of dark decay is accelerated by oxidants (H₂O₂ or ferricyanide) and slowed down by dithiothreitol.

It is suggested that the physiological mechanism for regulation of the H⁺-ATPase involves oxidation and reduction reactions in a manner which resembles the regulation of the light-activated carbon cycle enzymes.

     

NADP regulates the light activation of NADP-dependent malate dehydrogenase

The chloroplastic NADP-dependent malate-dehydrogenase (EC 1.1.1.82) activity is modulated by light and dark. The enzyme is activated upon illumination of intact or broken chloroplasts or by incubation with dithiothreitol, whereas dark has the opposite effect. The present communication shows an additional regulation of the light modulation: in isolated intact pea chloroplasts, light activation was inhibited in the presence of electron acceptors such as sodium bicarbonate, 3-phosphoglycerate or oxaloacetate, which consume NADPH₂ and produce NADP. With broken chloroplasts, addition of NADP resulted in a pronounced lag phase of NADP-dependent malate dehydrogenase light activation, while NADPH₂ was without any effect. The extent of the lag phase was correlated to the amount of NADP added. When light was replaced by dithiotreitol, the inhibition effect was even more pronounced. It was assumed that NADP inhibits the modulation reaction directly: reduced thioredoxin, a potent mediator of activation by light, or dithiotreitol appear to counteract NADP in a competitive manner. The results indicate a physiological role of NADP in the regulation of chloroplastic NADP-dependent malate dehydrogenase which is capable of removing electrons from the chloroplast, via oxaloacetate reduction and malate export. Thus an NADP concentration sufficient for continuous photosynthetic electron flow may be achieved.     

Role of a disulfide bond in the gamma subunit in activation of the ATPase of chloroplast coupling factor 1

The relationship between activation of the latent ATPase activity of isolated chloroplast coupling factor 1 (CF1) and reduction of a disulfide in the gamma subunit has been assessed. The sulfhydryl residues involved in the disulfide bond are distinct from residues normally accessible to maleimide modification during incubation of thylakoids in the dark or the light. Dithiothreitol-induced activation is time dependent, and correlates with reduction of the disulfide. Sulfhydryl residues exposed during activation can be reoxidized to disulfide by incubation with iodosobenzoate , with a concomitant loss of ATPase activity. Activation and deactivation are reversible, but deactivation is prevented by treatment of the reduced enzyme with N-ethylmaleimide. Heat activation does not reduce the disulfide bond unless dithiothreitol is present during activation. Prior heating of CF1, which partially activates the enzyme, renders the disulfide more susceptible to subsequent dithiol reduction. The activity obtained when heat and dithiothreitol are used together is approximately equal to the sum of the partial activations obtained with heat or dithiothreitol alone. Iodosobenzoate has no effect on heat-activated CF1. Enzyme activated by heating in the presence of dithiothreitol can be partially deactivated, consistent with reversal of the activity attributable to the dithiol effect. Fluorescence polarization of anilinonaphthylmaleimide bound to the reduced enzyme indicates that the sulfhydryl residues involved in the disulfide are in a less rigid environment than the other two sulfhydryl residues in the gamma subunit. Polarization of anilinonaphthylmaleimide bound to these sulfhydryls is reduced by heat treatment of CF1. The increased susceptibility of the disulfide to reduction upon heat treatment, and the activation of ATPase activity with or without disulfide bond cleavage are indicative of conformational changes within the gamma subunit that occur during the conversion of CF1 from a latent to an active ATPase. In addition the results are consistent with at least two distinct conformational forms of CF1 that can hydrolyze ATP.     

Sulphydryl groups in photosynthetic energy conservation. I. Light-dependent inhibition of photophosphorylation by the sulphydryl reagent 2-2'dithio bis-(5-nitropyridine).

1. The sulphydryl reagent 2-2'dithio bis-(5-nitropyridine) (DTNP) inhibited photophosphorylation when the chloroplasts were preincubated with the reagent in the light. A maximum inhibition of about 50% was obtained in the presence of pyocyanine and MgCl 2 at 0.3 mumol DTNP per mg chlorophyll and was completed in about 40 s of preillumination. 2. Dithioerythritol, ADP plus Pi (or arsenate) and uncouplers prevented the inhibition when present during the preillumination while phloridzin, Dio-9 and discarine B were ineffective. Low concentrations of ADP or ATP afforded partial protection but other nucleotides had no effect. 3. DTNP inhibited the coupled electron transport rate to the basal level and had no effect on the uncoupled electron transport. The stimulation of proton uptake and inhibition of electron transport by ATP was prevented by DTNP. 4. The trypsin-activated but not the light- and dithioerythritol-triggered ATPase was inhibited by light preincubation of chloroplasts with DTNP. 5. Reversal of DTNP inhibition of photophosphorylation was obtained by a second preillumination in the presence of thiol groups. 6. More DTNP reacted with chloroplasts in the light than in the dark. Two mol of thione were formed in the light per mol of DTNP disappeared. 7. The results suggested that DTNP inhibition is related to the oxidation by DTNP of chloroplast vicinal dithiols probably exposed by a light-induced conformational change.     

Light and thiol activation of maize leaf glycerate kinase : the stimulating effect of reduced thioredoxins and ATP

Glycerate kinase (EC 2.7.1.31) from maize (Zea mays) leaves was shown to be regulated by light/dark transition. The enzyme more than doubled in activity after either the leaves or isolated mesophyll chloroplasts were illuminated with white light for 10 minutes. Rate of inactivation in the dark was faster in leaves than in the isolated chloroplast fraction. The stimulating effect of light could be mimicked in crude preparations by addition of 10 or 50 millimolar dithiothreitol or 100 millimolar 2-mercaptoethanol. The thiol treatment resulted in 8- to 10-fold activation of glycerate kinase, with the highest rates in the range of 27 to 30 micromoles per mg chlorophyll per hour. Activation was not accompanied by any changes in the apparent M_r value of glycerate kinase as determined by gel filtration (M_r = 47,000). In contrast to maize glycerate kinase, the enzyme from spinach was not affected by either light or thiol exposure.

Partially purified maize glycerate kinase was activated up to 3-fold upon incubation with a mixture of spinach thioredoxins m and f and 5 millimolar dithiothreitol. The thioredoxin and dithiothreitol-treated glycerate kinase could be further stimulated by addition of 2.5 millimolar ATP. The results suggest that glycerate kinase from maize leaves is capable of photoactivation by the ferredoxin/thioredoxin system. The synergistic effect of ATP and thioredoxins in activation of the enzyme supports the earlier expressed view that the ferredoxin/thioredoxin system functions jointly with effector metabolites in light-mediated regulation during photosynthesis.

     

Shikimate kinase from spinach chloroplasts : purification, characterization, and regulatory function in aromatic amino Acid biosynthesis

Shikimate kinase was purified to near homogenity from spinach Spinacia oleracea L. chloroplasts and found to consist of a single 31 kilodalton polypeptide. The purified enzyme was unstable, but could be stabilized by a variety of added proteins, including oxidized and reduced thioredoxins. Whereas the isolated enzyme was stimulated by mono- and dithiol reagents, the enzyme in intact chloroplasts was unaffected by added thiols and showed only minor response to dark/light transitions. These results indicate that the previously reported stimulation of shikimate kinase activity by reduced thioredoxins is due to enzyme stabilization rather than to activation. In the current study, the purified enzyme was inhibited by added ADP and showed a strong response to energy charge. When intact chloroplasts were incubated in the dark in presence of shikimate, phosphoenolpyruvate and a source of ATP (dihydroxyacetone phosphate or ATP itself under appropriate conditions), aromatic amino acids were formed: phenylalanine and tyrosine. The data indicate that energy charge plays a role in regulating shikimate kinase, thereby controlling the shikimate pathway. An unidentified enzyme of the latter part of the pathway, leading from shikimate-3-phosphate to phenylalanine, appears to be activated by light.     

Evidence for a light dependent increase of phosphoglucomutase activity in isolated, intact spinach chloroplasts

Phosphoglucomutase (PGM) activity was measured in spinach (Spinacia oleracea L.) chloroplasts. Initial enzyme activity in a chloroplast lysate was 5 to 10% of total activity measured with 1 micromolar glucose 1,6-bisphosphate (Glc 1,6-P₂) in the assay. Initial PGM activity increased 2- to 3-fold when chloroplasts were illuminated for 10 minutes prior to enzyme measurement and then decreased slowly in the dark. Measurements of total enzyme activity were unchanged by prior light treatment. Initial PGM activity from light treated chloroplasts was sufficient to account for in vivo rates of starch synthesis. Changes in PGM activity were affected by stromal pH and orthophosphate concentration. Photosynthetic inhibitors, dl-glyceraldehyde, glycolaldehyde, and glyoxylate, decreased and 3-phosphoglyceric acid increased light induced changes of PGM activity. Dark preincubation of chloroplasts with 10 millimolar dithiothreitol had no effect upon initial PGM activity, suggesting that light effects did not involve a sulfhydryl mechanism. Hexose monophosphate levels increased in illuminated chloroplasts. Activation of PGM in a chloroplast lysate by Glc 1,6-P₂ was maximal between pH 7.5 and 8.5. Stromal concentrations of Glc 1,6-P₂ were between 20 and 30 micromolar for both light and dark incubated chloroplasts and these levels should saturate PGM activity. Light dependent alterations of enzyme activity may be due to changes of phosphorylated PGM levels in the stroma or are the result of changes in residual activity by the dephosphorylated form of the enzyme. The above results indicate that PGM activity in spinach chloroplasts may be regulated by light, stromal pH, and Glc 1,6-P₂ concentration.     

Correlation between the activity of membrane-bound ATPase and the decay rate of flash-induced 515-nm absorbance change in chloroplasts in intact leaves,assayed by means of rapid isolation of chloroplasts

(1) The relationship between activation of the membrane-bound ATPase and the stimulation of dissipation of the flash-induced membrane potential by preillumination was studied in intact spinach leaves by measuring the ATPase activity of rapidly isolated chloroplasts and the decay of the flash-induced 515-nm absorbance change (ΔA₅₁₅) in intact leaves. (2) The decay of ΔA₅₁₅ was accelerated by preillumination. The ΔA₅₁₅ decay in leaves treated with N,N′-dicyclohexylcarbodiimide (DCCD) became slower and was not accelerated by preillumination. However, treatment with DCCD did not lower the intensity of delayed fluorescence. (3) Membrane-bound ATPase of chloroplasts which were rapidly isolated from the preilluminated leaves (90 s preparation time) showed a higher activity (over 200 μmol P_i/mg chlorophyll per h in the case of 2-min preillumination) than that of chloroplasts isolated from dark-adapted leaves. (4) The acceleration of ΔA₅₁₅ decay and the activation of ATPase showed similar dependences on illumination time in intact leaves. 3-(3′,4′-Dichlorophenyl)-1,1-dimethylurea, carbonyl cyanide p-chlorophenylhydrazone and DCCD inhibited the activation of ATPase and the acceleration of the ΔA₅₁₅ decay by preillumination. (5) The ATPase activity of chloroplasts isolated from illuminated leaves showed a single exponential decay (‘dark inactivation in vitro’). The ATPase activity induced by illuminating the leaves became lower as the dark interval between illumination and the isolation of chloroplasts was increased (‘dark inactivation in vivo’). The time course of the decay of activity had a lag and showed a sigmoidal curve when plotted semilogarithmically. The decay had an apparent half-time of 25 min. (6) The recovery of the accelerated ΔA₅₁₅ decay in preilluminated leaves to the original slow rate showed a sigmoidal decay similar to that of the activity of ATPase in intact leaves with a half-time of about 23 min in the dark. (7) It was concluded that the decay rate of ΔA₅₁₅ reflected the chloroplast ATPase activity in intact leaves and that the ion conductance of thylakoid membrane was mainly determined by the H⁺ flux through the ATPase, the activity of which was increased after the formation of the high-energy state.     

Ribulose 1,5-bisphosphate and activation of the carboxylase in the chloroplast

Ribulose 1,5-bisphosphate in the chloroplast has been suggested to regulate the activity of the ribulose bisphosphate carboxylase/oxygenase. To generate high levels of ribulose bisphosphate, isolated and intact spinach chloroplasts were illuminated in the absence of CO₂. Under these conditions, chloroplasts generate internally up to 300 nanomoles ribulose 1,5-bisphosphate per milligram chlorophyll if O₂ is also absent. This is equivalent to 12 millimolar ribulose bisphosphate, while the enzyme, ribulose bisphosphate carboxylase, offers up to 3.0 millimolar binding sites for the bisphosphate in the chloroplast stroma. During illumination, the ribulose bisphosphate carboxylase is deactivated, due mostly to the absence of CO₂ required for activation. The rate of deactivation of the ribulose bisphosphate carboxylase was not affected by the chloroplast ribulose bisphosphate levels. Upon addition of CO₂, the carboxylase in the chloroplast was completely reactivated. Of interest, addition of 3-phosphoglycerate stopped deactivation of the carboxylase in the chloroplast while ribulose bisphosphate accumulated. With intact chloroplasts in light, no correlation between deactivation of the carboxylase and ribulose bisphosphate levels could be shown.     

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.     

Pyruvate,orthophosphate dikinase in leaves and chloroplasts of C(3) plants undergoes light-/dark-induced reversible phosphorylation

Pyruvate,orthophosphate (Pi) dikinase (PPDK) is best recognized as a chloroplastic C(4) cycle enzyme. As one of the key regulatory foci for controlling flux through this photosynthetic pathway, it is strictly and reversibly regulated by light. This light/dark modulation is mediated by reversible phosphorylation of a conserved threonine residue in the active-site domain by the PPDK regulatory protein (RP), a bifunctional protein kinase/phosphatase. PPDK is also present in C(3) plants, although it has no known photosynthetic function. Nevertheless, in this report we show that C(3) PPDK in leaves of several angiosperms and in isolated intact spinach (Spinacia oleracea) chloroplasts undergoes light-/dark-induced changes in phosphorylation state in a manner similar to C(4) dikinase. In addition, the kinetics of this process closely resemble the reversible C(4) process, with light-induced dephosphorylation occurring rapidly (< or =15 min) and dark-induced phosphorylation occurring much more slowly (> or =30-60 min). In intact spinach chloroplasts, light-induced dephosphorylation of C(3) PPDK was shown to be dependent on exogenous Pi and photosystem II activity but independent of electron transfer from photosystem I. These in organello results implicate a role for stromal pools of Pi and adenylates in regulating the reversible phosphorylation of C(3)-PPDK. Last, we used an in vitro RP assay to directly demonstrate ADP-dependent PPDK phosphorylation in desalted leaf extracts of the C(3) plants Vicia faba and rice (Oryza sativa). We conclude that an RP-like activity mediates the light/dark modulation of PPDK phosphorylation state in C(3) leaves and chloroplasts and likely represents the ancestral isoform of this unusual and key C(4) pathway regulatory "converter" enzyme.     

Changes in polyamine content, arginine and ornithine decarboxylases and transglutaminase activities during light/dark phases (of initial differentiation) in maize calluses and their chloroplasts

Maize calluses and their isolated chloroplasts were analysed to study the changes in polyamine content, arginine and ornithine decarboxylases and transglutaminase activities during light/dark phases of the first day after subculture in maintenance medium (containing 2,4-D) and differentiation medium (without 2,4-D). Free polyamine content changed significantly in both differentiating calluses and chloroplasts showing a maximum during light phase and also increasing after mid-dark phase. Acid-insoluble polyamines showed a similar trend. In whole cells from the callus cultured in maintenance medium, the changes were not significant, except for free putrescine which increased in the dark phase. In chloroplasts of both types of calluses, the trend was similar. Arginine decarboxylase activity in vitro assayed in optimal conditions was not affected by hormone deprivation either in whole cells from the callus or in chloroplasts. The formation of putrescine by arginine decarboxylase activity gradually increased in the light until 9–12 h after subculture, whereas at the onset of the dark phase, a significant decrease was observed. Ornithine decarboxylase activity in vitro always showed slight changes, except in growing callus where putrescine synthesis increased abruptly at 8 h and decreased thereafter. Transglutaminase was immunodetected in whole cells from the callus and in isolated chloroplasts by western blot. In the entire cells, protein substrates were found which were not present in isolated chloroplast. Transglutaminase activity was light sensitive and also affected by hormone deprivation. This enzyme was more active in differentiation than in maintenance medium, in both callus and chloroplasts, in light and dark phases. These data indicate that, the parameters studied here are not only light affected but also regulated by a daily rhythm.     

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.     

Environmental and metaboliccontrol of LHCII protein phosphorylation: revealing the mechanismsfor dual regulation of the LHCII kinase

Light‐harvesting complex II (LHCII) protein phosphorylation inplant chloroplasts is under complex regulation. Combination of the invivo monitoring of LHCII protein phosphorylation (by immunoblotting)with the in vitro[γ‐³²P]ATPphosphorylation assays revealed that the basic activation/deactivationmodel of the LHCII kinase, regulated by reversible occupation/releaseof plastoquinol at the plastoquinol oxidation (Q_o) siteof the cytochrome b₆f (cyt b₆f) complex, isconsistent with, but not sufficient to explain the data obtainedwith isolated chloroplasts, leaf discs or intact leaves. Not onlythe light conditions but also the metabolic state of the entireplant, particularly the sugar metabolism, exerted a control overLHCII protein phosphorylation. Feeding of leaves with glucose (alsowith glutathione) activated the LHCII kinase in darkness. On the otherhand, independently of the basic activation/deactivationmechanism of the kinase, a strong inhibition of LHCII protein phosphorylationoccurred in vivo at increasing irradiances and even at lowlight conditions, depending on the metabolic state of the plant.Both the experiments with intact chloroplasts and the reconstitutionexperiments with isolated thylakoids to mimic LHCII kinase inhibition,disclosed that the kinase in its activated state (plastoquinol at theQ_o site of cyt b₆f complex) is protected againstinhibition by thiol reductants. However, directly upon deactivationof the kinase (release of plastoquinol from the Q_o site) itbecomes a target for inhibition by thiol reductants. Thus the twointerdependent regulatory systems of the LHCII kinase, the constantlyoccurring activation and deactivation on the one hand and the inhibitionby thiol reductants on the other, are strongly dependent on theconcentration of reducing equivalents in the chloroplast stroma.A scheme demonstrating the interconversion of activated, deactivated andinhibited states of the LHCII kinase in the chloroplast environmentof intact leaves is presented.