Characterization of dicarboxylate stimulation of ammonia, glutamine, and 2-oxoglutarate-dependent o(2) evolution in isolated pea chloroplasts

Intact isolated chloroplasts from pea (Pisum sativum) leaves carried out light-dependent (NH₃, 2-oxoglutarate) and (glutamine, 2-oxoglutarate)-dependent O₂ evolution at rates of 3.3 ± 0.7 (n = 7) and 6.0 ± 0.4 (n = 5) micromoles per milligram chlorophyll per hour, respectively. Malate stimulated the rate of (NH₃, 2-oxoglutarate)-dependent O₂ evolution 2.1 ± 0.5 (n = 7)-fold in the absence of glutamine, and 3.3 ± 0.4 (n = 11)-fold in the presence of glutamine. Malate also stimulated (glutamine, 2-oxoglutarate)-dependent O₂ evolution in the presence of high concentrations of glutamine. The affinity (K_1/2) of (NH₃, glutamine, 2-oxoglutarate)-dependent O₂ evolution for 2-oxoglutarate was estimated at 200 to 250 micromolar in the absence of malate and 50 to 80 micromolar when malate (0.5 millimolar) was present. In contrast to malate and various other dicarboxylates, aspartate, glutarate, and glutamate did not stimulate (NH₃, glutamine, 2-oxoglutarate)-dependent O₂ evolution in isolated pea chloroplasts. Using both in vitro assays and reconstituted chloroplast systems, malate was shown to have no effect on the activities of either glutamine synthetase or glutamate synthase.

The concentration of malate required for maximal stimulation of O₂ evolution was dependent on the concentration of 2-oxoglutarate present. However, the small extent of the competition between malate and 2-oxoglutarate for uptake was not consistent with that predicted by the current `single carrier' model proposed for the uptake of dicarboxylates into chloroplasts.

     

Polarographic study of oxaloacetate reduction by isolated pea chloroplasts

Suspensions of pea chloroplasts, prepared by differential centrifugation, catalyzed oxaloacetate-dependent O(2) evolution (mean rate of 29 determinations 10.9 micromoles per milligram of chlorophyll per hour, sd 3.2) with the concomitant production of malate. At optimum concentrations of oxaloacetate, both reactions were light-dependent, inhibited by 3-(3,4- dichlorophenyl)-1, 1-dimethylurea and oxalate, and enhanced 2.5- to 4-fold by 10 millimolar NH(4)Cl. At concentrations of oxaloacetate (<50 micromolar), 10 millimolar NH(4)Cl was inhibitory. The ratio of O(2) evolved to malate produced was 0.39 to 0.58. The ratio of O(2) evolved to oxaloacetate supplied was commensurate with the theoretical value of 0.5.Chloroplast suspensions contained both NAD- and NADP-malate dehydrogenase activities. It was concluded from oxalate inhibition studies and the promotion of oxaloacetate-dependent O(2) evolution by shocked chloroplasts by NADPH (but not NADH) that the reaction was mediated via the NADP enzyme.     

A Two-Translocator Model for the Transport of 2-Oxoglutarate and Glutamate in Chloroplasts during Ammonia Assimilation in the Light

This study examines the transport of 2-oxoglutarate (2-OG) and other dicarboxylates during ammonia assimilation in illuminated spinach chloroplasts. The transport of all dicarboxylates examined was strongly inhibited by NH₄Cl preincubation in the light. Treatment with NH₄Cl caused a rapid depletion of the endogenous glutamate pool and a corresponding increase in endogenous glutamine content. The inhibition of transport activity by NH₄Cl was apparently linked to its metabolism in the light because inhibition of glutamine synthetase activity by the addition of l-methionine sulfoximine or carbonylcyanide-m-chlorophenylhydrazone abolished this affect. Measurements of endogenous metabolite pools showed that malate was most rapidly exchanged during the uptake of all exogenous dicarboxylates examined. Depending on the exogenous substrates used, the apparent half-times of efflux measured for endogenous malate, aspartate and glutamate were 10, 10 to 30, and 15 to 240 seconds, respectively. The transport of 2-OG was also inhibited by malate. But chloroplasts preincubated with malate in the presence or absence of NH₄Cl were found to have high transport activity similar to untreated chloroplasts. A two-translocator model is proposed to explain the stimulation of 2-OG transport as well as the stimulation of (NH₃, 2-OG)-dependent O₂ evolution by malate (KC Woo, CB Osmond 1982 Plant Physiol 69: 591-596) in isolated chloroplasts. In this model the transport of 2-OG on the 2-OG translocator and glutamate on the dicarboxylate translocator is coupled to malate counter-exchange in a cascade-like manner. This results in a net 2-OG/glutamate exchange with no net malate transport. Thus, during NH₃ assimilation the transport of 2-OG into and the export of glutamate out of the chloroplast occurs via the 2-OG and the dicarboxylate translocators, respectively.     

N-ammonia assimilation, 2-oxoglutarate transport, and glutamate export in spinach chloroplasts in the presence of dicarboxylates in the light

The direct incorporation of ¹⁵NH₄Cl into amino acids in illuminated spinach (Spinacia oleracea L.) chloroplasts in the presence of 2-oxoglutarate plus malate was determined. The amido-N of glutamine was the most highly labeled N-atom during ¹⁵NH₄ assimilation in the presence of malate. In 4 minutes the ¹⁵N-label of the amido-N of glutamine was 37% enriched. In contrast, values obtained for both the N-atom of glutamate and the amino-N of glutamine were only about 20% while that of the N-atom of aspartate was only 3%. The addition of malate during the assimilation of ¹⁵NH₄Cl and Na¹⁵NO₂ greatly increased the ¹⁵N-label into glutamine but did not qualitatively change the order of the incorporation of ¹⁵N-label into all the amino acids examined. This evidence indicates the direct involvement of the glutamine synthetase/glutamate synthase pathway for ammonia and nitrite assimilation in isolated chloroplasts. The addition of malate or succinate during ammonia assimilation also led to more than 3-fold increase in [¹⁴C]2-oxoglutarate transport into the chloroplast as well as an increase in the export of [¹⁴C]glutamate out of the chloroplast. Little [¹⁴C]glutamine was detected in the medium of the chloroplast preparations. The stimulation of ¹⁵N-incorporation and [¹⁴C]glutamate export by malate could be directly attributed to the increase in 2-oxoglutarate transport activity (via the 2-oxoglutarate translocator) observed in the presence of exogenous malate.     

Ammonia assimilation and oxygen evolution by a reconstituted chloroplast system in the presence of 2-oxoglutarate and glutamate

(Ammonia plus 2-oxoglutarate)-dependent O₂ evolution by intact chloroplasts was enhanced three- to five fold by 2 mM L- and D-malate, attaining rates of 9–15 μmol mg^-1 Chl h^-1. Succinate and fumarate also promoted activity but D-aspartate and, in the presence of aminooxyacetate, L-aspartate inhibited the malate-promoted rate. A reconstituted chloroplast system supported (ammonia plus 2-oxoglutarate)-dependent O₂ evolution at rates of 6-11 μmol mg^-1 Chl h^-1 in the presence of MgCl₂, NADP(H), ADP plus Pi (or ATP), ferredoxin and L-glutamate. The concentrations of L-glutamate and ATP required to support 0.5 V _max were 5 mM and 0.25 mM, respectively. When the reaction was initiated with NH₄Cl, O₂ evolution was preceded by a lag phase before attaining a constant rate. The lag phase was shortened by addition of low concentrations of L-glutamine or by preincubating in the dark in the presence of glutamate, ATP and NH₄Cl. Oxygen evolution was inhibited by 2 mM azaserine and, provided it was added initially, 2 mM methionine sulphoximine. The (ammonia plus 2-oxoglutarate)-dependent O₂ evolution was attributed to the synthesis of glutamine from NH₄Cl and glutamate which reacted with 2-oxoglutarate in a reaction catalysed by ferredoxin-specific glutamate synthase using H₂O as the ultimate electron donor. The lag phase was attributed to the establishment of a steady-state pool of glutamine. L-Malate did not affect the activity of the reconstituted system.     

The chloroplastic 2-oxoglutarate/malate transporter has dual function as the malate valve and in carbon/nitrogen metabolism

Transport of dicarboxylates across the chloroplast envelope plays an important role in transferring carbon skeletons to the nitrogen assimilation pathway and exporting reducing equivalent to the cytosol to prevent photo-inhibition (the malate valve). It was previously shown that the Arabidopsis plastidic 2-oxoglutarate/malate transporter (AtpOMT1) and the general dicarboxylate transporter (AtpDCT1) play crucial roles at the interface between carbon and nitrogen metabolism. However, based on the in vitro transport properties of the recombinant transporters, it was hypothesized that AtpOMT1 might play a dual role, also functioning as an oxaloacetate/malate transporter, which is a crucial but currently unidentified component of the chloroplast malate valve. Here, we test this hypothesis using Arabidopsis T-DNA insertional mutants of AtpOMT1. Transport studies revealed a dramatically reduced rate of oxaloacetate uptake into chloroplasts isolated from the knockout plant. CO(2) -dependent O(2) evolution assays showed that cytosolic oxaloacetate is efficiently transported into chloroplasts mainly by AtpOMT1, and supported the absence of additional oxaloacetate transporters. These findings strongly indicate that the high-affinity oxaloacetate transporter in Arabidopsis chloroplasts is AtpOMT1. Further, the knockout plants showed enhanced photo-inhibition under high light due to greater accumulation of reducing equivalents in the stroma, indicating malfunction of the malate valve in the knockout plants. The knockout mutant showed a phenotype consistent with reductions in 2-oxoglutarate transport, glutamine synthetase/glutamate synthase activity, subsequent amino acid biosynthesis and photorespiration. Our results demonstrate that AtpOMT1 acts bi-functionally as an oxaloacetate/malate transporter in the malate valve and as a 2-oxoglutarate/malate transporter mediating carbon/nitrogen metabolism.     

A polarographic study of glutamate synthase activity in isolated chloroplasts

Illuminated pea (Pisum sativum) chloroplasts actively catalyzed (glutamine plus alpha-ketoglutarate)-dependent O(2) evolution (average of 12 preparations 10.6 mumole mg chlorophyll per hour). The reaction was specific for glutamine and alpha-ketoglutarate; concentrations of 0.2 mm alpha-ketoglutarate and 0.6 mm glutamine, respectively, effected half-maximum rates of O(2) evolution. The reaction was inhibited by 3-(3,4-dichlorophenyl)-1-1-dimethylurea and did not occur in the dark. After osmotic shock chloroplasts did not catalyze O(2) evolution. The reaction was inhibited by azaserine and glutamate but not by 10 mm ammonia, 2.5 mm methionine sulfoximine, or 5 mm amino-oxyacetate; addition of amino-oxyacetate together with aspartate inhibited O(2) evolution. Arsenate (3 mm) enhanced O(2) evolution. The highest molar ratio for O(2) evolved per mole of alpha-ketoglutarate supplied was 0.40; the corresponding values for glutamine in the absence and presence of 3 mm arsenate were 0.20 and 0.24, respectively. The (glutamine plus alpha-ketoglutarate)-dependent O(2) evolution is attributed to photosynthetically coupled glutamate synthase activity and the activity is sufficient to account for the assimilation of inorganic nitrogen. The low molar ratio for glutamine is discussed.Chloroplasts also catalyzed (aspartate plus alpha-ketoglutarate)-dependent O(2) evolution but this reaction was inhibited by 5 mm amino-oxyacetate and it was insensitive to azaserine and methionine sulfoximine. This reaction was attributed to transaminase and photosynthetically coupled malate dehydrogenase activities.     

Effect of inhibitors on ammonia-, 2-oxoglutarate-, and oxaloacetate-dependent o(2) evolution in illuminated chloroplasts

The evolution of O₂ in spinach chloroplasts in the presence of oxaloacetate (OAA) was inhibited by a wide range of dicarboxylates. In contrast, (ammonia, 2-oxoglutarate)-dependent O₂ evolution was stimulated by malate, succinate, fumarate, glutarate, maleiate, and l-tartrate although OAA has little effect. This increase in O₂ evolution was accompanied by a similar increase in ¹⁴C incorporation from [5-¹⁴C]oxoglutarate into amino acids which was sensitive to azaserine inhibition. Glutamate and aspartate inhibited (ammonia, 2-oxoglutarate)-dependent O₂ evolution, but this inhibition was relieved by the addition of succinate, malate, or fumarate. OAA-dependent O₂ evolution also was inhibited by glutamate and aspartate, but succinate, malate, or fumarate had little effect on this inhibition. Phthalonate and n-butyl malonate inhibited (ammonia, 2-oxoglutarate)-dependent O₂ evolution competitively with respect to 2-oxoglutarate and uncompetitively with respect to malate. Both these inhibitors inhibited OAA-dependent O₂ evolution competitively. This evidence suggests that different mechanisms might be involved in the transport of OAA, 2-oxoglutarate, and malate into the chloroplasts.     

Oxygen evolution by a reconstituted spinach chloroplast system in the presence ofl-glutamine and 2-oxoglutarate

Intact chloroplasts prepared from summer-grown spinach plants supported (aspartate plus 2-oxoglutarate)-dependent O₂ evolution but not (glutamine plus 2-oxoglutarate)-dependent O₂ evolution. The former activity, which was sensitive to amino oxyacetate, was attributed to transaminase activity and reduction of the resulting oxalo-acetate to malate using H₂O as eventual electron donor. A reconstituted chloroplast system which included chloroplast stroma, thylakoid membranes, ferredoxin and NADP(H) supported O₂ evolution in the presence ofl-glutamine and 2-oxoglutarate at rates of 15–22 μmol mg^-1 chlorophyll h^-1 although lower rates were obtained with material from winter-grown plants. Activity was not observed in the absence of ferredoxin and omission of NADP(H) decreased activity by 40%. The reaction was associated with the production of 0.49 mol O₂ mol^-1 2-oxoglutarate consumed and up to 0.46 mol O₂ mol^-1 glutamine supplied. The reaction, which was inhibited by azaserine but not by methionine sulphoximine or amino oxyacetate, was attributed to light-coupled glutamate synthase (EC 1.4.1.13) with H₂O serving as eventual electron donor. Activity was not affected significantly byl-malate. The reconstituted system also supported O₂ evolution in the presence of nitrite, oxaloacetate, (aspartate plus 2-oxoglutarate) and oxidised glutathione.     

Glutamine transport and the role of the glutamine translocator in chloroplasts

The transport of l-[¹⁴C]glutamine in oat (Avena sativa L.) and spinach (Spinacia oleracea L.) chloroplasts was studied by a conventional single-layer and a newly developed stable double-layer silicone oil filtering system. [¹⁴C]Glutamine was actively transported into oat chloroplasts against a concentration gradient. Metabolite uptake was greatly affected by the endogenous dicarboxylate pools, which could be easily changed by preloading the chloroplast with specific exogenous substrate. Glutamine uptake was decreased by 44 to 75% in oat chloroplasts preloaded with malate, 2-oxoglutarate (2-OG), and aspartate, but increased by 52% in chloroplasts preloaded with l-glutamate. On the other hand, the uptake of the other four dicarboxylates was decreased by 47 to 79% in chloroplasts preloaded with glutamine. In glutamine-preloaded chloroplasts the uptake of glutamine was inhibited only by l-glutamate. The observed inhibition by l-glutamate was competitive with an apparent K_i value of 32.1 millimolar in oat and 6.7 millimolar in spinach chloroplasts. This study indicates that there are two components involved in glutamine transport in chloroplasts. The major component was mediated via a specific glutamine translocator. It was specific for glutamine and did not transport other dicarboxylates except l-glutamate. A K_0.5 value of 1.25 millimolar and V_max of 45.5 micromoles per milligram of chlorophyll per hour were determined for the glutamine translocator in oat chloroplasts. The respective values were 1.0 millimolar and 16.7 micromoles per milligram of chlorophyll per hour in spinach chloroplasts. A three translocator model, involving the glutamine, dicarboxylate, and 2-OG translocators, is proposed for the reassimilation of photorespiratory NH₃ in chloroplasts of C₃ species. In this three-translocator model the additional transport of glutamine into the chloroplast is coupled to the export of glutamate via the glutamine translocator. This is an extension of the two-translocator model, involving the dicarboxylate and 2-OG translocators, proposed for spinach chloroplasts, (KC Woo, UI Flügge, HW Heldt 1987 Plant Physiol 84: 624-632).     

Characteristics of 2-oxoglutarate and glutamate transport in spinach chloroplasts

The transport of glutamate, 2-oxoglutarate and malate in intact spinach chloroplasts was determined using a double-silicone-layer centrifugation technique in which the silicone layers stayed separated at the end of centrifugation. Glutamate was found to be transported via the dicarboxylate but not the 2-oxoglutarate translocator. Hence the kinetic parameters (i.e.K _m,K _i andV _max) determined in glutamate-preloaded chloroplasts represent the kinetic constants of the dicarboxylate translocator. Measurements from malate- or succinate-preloaded chloroplasts represent the aggregate values of both the dicarboxylate and the 2-oxoglutarate translocators. Calculations showed that the 2-oxoglutarate and glutamate transport required to support the high fluxes of photorespiratory NH₃ recycling could be achieved if the transport of these two dicarboxylates occurred on separate translocators. It is proposed that during photorespiration the transport of 2-oxoglutarate into and glutamate out of the chloroplast occurred via the 2-oxoglutarate and the dicarboxylate translocators, respectively. These transports are coupled to malate counter-exchange in a cascade-like manner resulting in a net 2-oxoglutarate/glutamate exchange with no net malate uptake.Abbreviation 2-OG 2-oxoglutarate     

Carbon and nitrogen metabolism in a barley (Hordeum vulgare L.) mutant with impaired chloroplast dicarboxylate transport

A mutant line, RPr79/2, of barley (Hordeum vulgare L. cv. Maris Mink) has been isolated that has an apparent defect in photorespiratory nitrogen metabolism. The metabolism of ¹⁴C-labelled glutamine, glutamate and 2-oxoglutarate indicates that the mutant has a greatly reduced ability to synthesise glutamate, especially in air, although in-vitro enzyme analysis indicates the presence of wild-type activities of glutamine synthetase (EC 6.3.1.2) glutamate synthase (EC 1.4.7.1 and EC 1.4.1.14) and glutamate dehydrogenase (EC 1.4.1.2). Several characteristics of RPr79/2 are very similar to those described for glutamate-synthase-deficient barley and Arabidopsis thaliana mutants, including the pattern of labelling following fixation of ¹⁴CO₂, and the rapid rise in glutamine content and fall in glutamate in leaves on transfer to air. The CO₂-fixation rate in RPr79/2 declines much more slowly on transfer from 1% O₂ to air than do the rates in glutamate-synthase-deficient plants, and RPr79/2 plants do not die in air unless the temperature and irradiance are high. Analysis of (glutamine+NH₃+2-oxoglutarate)-dependent O₂ evolution by isolated chloroplasts shows that chloroplasts from RPr79/2 require a fivefold greater concentration of 2-oxoglutarate than does the wild-type for maximum activity. The levels of 2-oxoglutarate in illuminated leaves of RPr79/2 in air are sevenfold higher than in Maris Mink. It is suggested that RPr79/2 is defective in chloroplast dicarboxylate transport.     

Polarographic study of ammonia assimilation by isolated chloroplasts

Illuminated pea (Pisum sativum) chloroplasts catalyze (ammonia plus alpha-ketoglutarate [alpha-KG])-dependent O(2) evolution at rates which are commensurate with other estimates of the flux of assimilated nitrogen (mean of eight determinations, 8.3 mumole per mg chlorophyll per hour, sd 2.4). The reaction was usually initiated with 1 mm ammonia after preincubating chloroplasts in the presence of alpha-KG, ADP, pyrophosphate, and MgCl(2).Progressive increases in ammonia concentration gave V(max)/2 at 0.2 mm (approximately) and V(max) at about 1 mm. Higher concentrations were inhibitory; at 7 mm the rate was again about V(max)/2. The highest ratio of O(2) evolved per mol of ammonia supplied was 0.36.The (ammonia plus alpha-KG)-dependent reaction was inhibited by methionine sulfoximine, azaserine, and aspartate in the presence of amino-oxyacetate but not by amino-oxyacetate alone and not by l-glutamate. The rate of O(2) evolution in the presence of 1 mm ammonia and 2.5 mm alpha-KG was increased only slightly by addition of 5 mm glutamine. Similarly, the rate of O(2) evolution in the presence of 5 mm glutamine and 2.5 mm alpha-KG was increased only slightly by addition of 1 mm ammonia.The results are attributed to the incorporation of ammonia via glutamine synthetase and reductive transamination of the glutamine formed by photosynthetically coupled glutamate synthase using alpha-KG as the amino acceptor. Several lines of evidence rule out the possibility that photosynthetically coupled glutamate dehydrogenase is involved.     

Barley mutants lacking chloroplast glutamine synthetase-biochemical and genetic analysis

Eight mutants of barley (Hordeum vulgare cv Maris Mink) lacking the chloroplast isozyme of glutamine synthetase (EC 6.3.1.2.) were isolated by their inability to grow under photorespiratory conditions. The cytoplasmic isozyme of glutamine synthetase was present in the leaves of all the mutants, with activities comparable to the wild-type (10-12 nanokatals per gram fresh weight). The mutant plants developed normally and were fully fertile under conditions that minimize photorespiration. In 1% O₂ the rate of CO₂ fixation in leaves of one of the mutants, RPr 83/32, was the same as the wild-type, but in air this rate declined to 60% of the wild-type after 30 minutes. During this time the ammonia concentration in leaves of the mutant rose from 1 to 50 micromoles per gram fresh weight. Such ammonia accumulation in air was found in all the mutant lines. In back-crosses with the parent line, F₁ plants were viable in air. In the F₂ generation, nonviability in air and the lack of chloroplast glutamine synthetase co-segregated, in both the lines tested. These two lines and four others proved to be allelic; we designate them gln 2a-f. The characteristics of these mutants conclusively demonstrate the major role of chloroplast glutamine synthetase in photorespiration and its associated nitrogen recycling.     

A Metabolic Control Analysis of the Glutamine Synthetase/Glutamate Synthase Cycle in Isolated Barley (Hordeum vulgare L.) Chloroplasts

Ammonia assimilation in chloroplasts occurs via the glutamine synthetase/glutamate synthase (GS/GOGAT) cycle. To determine the extent to which these enzymes contribute to the control of ammonia assimilation, a metabolic control analysis was performed on isolated barley (Hordeum vulgare L.) leaf chloroplasts. Pathway flux was measured polarographically as ammonium-plus-2-oxoglutarate-plus-glutamine-dependent O2 evolution in illuminated chloroplasts. Enzyme activity was modulated by titration with specific, irreversible inhibitors of GS (phosphinothricin) and GOGAT (azaserine). Flux control coefficients (CJ0E0) were determined (a) by differentiation of best-fit hyperbolic curves of the data sets (flux versus enzyme activity), and (b) from estimates of the deviation indices (D/[prime]E0). Both analyses gave similar values for the coefficients. The control coefficient for GS was relatively high and the value did not change significantly with changes in 2-oxoglutarate concentration (C/0E0 = 0.58 at 5 mM 2-oxoglutarate and 0.40 at 20 mM 2-oxoglutarate). The control coefficient for GOGAT decreased with decreasing glutamine concentrations, from 0.76 at 20 mM glutamine to 0.19 at 10 mM glutamine. Thus, at high concentrations of glutamine, GOGAT exerts a major control over flux with a significant contribution also from GS. At lower concentrations of glutamine, however, GOGAT exerts far less control over pathway flux.     

Photosynthetic Metabolism of Aspartate in Mesophyll and Bundle Sheath Cells Isolated from Digitaria sanguinalis (L.) Scop., a NADP-Malic Enzyme C(4) Plant

Mesophyll cells and bundle sheath strands isolated from leaves of the C(4) plant Digitaria sanguinalis (L.) Scop. are capable of utilizing aspartate as a Hill oxidant. The resulting O(2) evolution upon illumination depends on the presence of 2-oxoglutarate, is inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea, and is stimulated by methylamine. The rate of aspartate-dependent O(2) evolution with mesophyll cells was similar to those with phosphoenolpyruvate + CO(2) or with oxalacetate. Amino-oxyacetate, an inhibitor of aspartate aminotransferase, inhibited the aspartate-dependent O(2) evolution. Aspartate aminotransferase and NADP(+) -malate dehydrogenase are located in the mesophyll chloroplasts. These data suggest that aspartate is converted to oxalacetate via aspartate aminotransferase in the chloroplasts of mesophyll cells and that oxalacetate is subsequently reduced to malate, which is coupled to the photochemical evolution of O(2). This suggestion is further verified by the inhibition of phosphoenolpyruvate-dependent (14)CO(2) fixation by aspartate + 2-oxoglutarate, which presumably acts as oxalacetate and competes with phosphoenolpyruvate + CO(2) for NADPH. dl-Glyceraldehyde inhibited aspartate-dependent O(2) evolution in the bundle sheath strands but not in the mesophyll cells. The data indicate that aspartate may be converted to malate in both mesophyll and bundle sheath cells. In NADP(+) -malic enzyme species, aspartate may exist as a C(4)-dicarboxylic acid reservoir which can contribute to the C(4) cycle through its conversion to malate.     

Inhibition of 3-Phosphoglycerate-Dependent O(2) Evolution by Phosphoenolpyruvate in C(4) Mesophyll Chloroplasts of Digitaria sanguinalis (L.) Scop

The effects of phosphoenolpyruvate (PEP), inorganic phosphate (Pi), and ATP on 3-phosphoglycerate (PGA)-dependent O₂ evolution by chloroplasts of Digitaria sanguinalis (L.) Scop. (crabgrass) were evaluated relative to possible mechanisms of PEP transport by the C₄ mesophyll chloroplast. Crude and Percoll purified chloroplast preparations exhibited rates of PGA-dependent O₂ evolution in the range of 90 to 135 micromoles O₂ per milligram chlorophyll per hour, and up to 180 micromoles O₂ per milligram chlorophyll per hour at optimal Pi concentrations (approximately 0.2 millimolar at 9 millimolar PGA). Higher concentrations of Pi were inhibitory. PEP inhibited O₂ evolution (up to 70%) in both chloroplast preparations when the PEP to PGA ratio was high (i.e. 9 millimolar PEP to 0.36 millimolar PGA). Usually no inhibition was seen when the PEP to PGA ratio was less than 2. PEP acted as a competitive inhibitor and, at a concentration of 9 millimolar, increased the apparent K_m (PGA) from 0.15 to 0.53 millimolar in Percoll purified chloroplasts. A low concentration of PGA and high ratio of PEP to PGA, which are considered unphysiological, were required to detect any inhibition of O₂ evolution by PEP. Similar results were obtained from crude versus Percoll purified preparations. Neither the addition of Pi nor ATP could overcome PEP inhibition. As PEP inhibition was competitive with respect to PGA concentration, and as addition of ATP or Pi could not prevent PEP inhibition of PGA-dependent O₂ evolution, the inhibition was not due to PEP exchange of adenylates or Pi out of the chloroplast. Analysis of the effect of Pi and PEP, separately and in combination, on PGA-dependent O₂ evolution suggests interactions between PEP, Pi, and PGA on the same translocator in the C₄ mesophyll chloroplast. C₃ spinach chloroplasts were also found to be sensitive to PEP, but to a lesser extent than crabgrass chloroplasts. The apparent K_i values (PEP) were 3 and 21 millimolar for crabgrass and spinach, respectively.     

Effect of sulphate on glutamate synthesis by intact spinach (Spinacia oleracea) chloroplasts.

During the course of NH4+ (or NO2-)-plus-alpha-oxoglutarate-dependent O2 evolution in spinach (Spinacia oleracea) chloroplasts, glutamate was continuously excreted out of the chloroplasts. Under these conditions, for each molecule of NO2- or NH4+ which disappeared, one molecule of glutamate accumulated in the medium and the concentration of glutamate in the stroma space was maintained constant. SO4(2-) (or SO3(2-) behave as inhibitors of NH4+ incorporation into glutamate by intact chloroplasts. This considerable inhibition of glutamate synthesis by SO4(2-) was correlated with a rapid decline in the stromal Pi concentration. The reloading of stromal Pi with either external Pi or PPi4- relieved SO4(2-)-induced inhibition of glutamate synthesis by intact chloroplasts. It was concluded that SO4(2-) induced a rapid efflux of stromal Pi out of the chloroplast, leading to a limitation of ATP synthesis and therefore to an arrest of ATP-dependent glutamine synthetase functioning.     

Isolation of Intact Chloroplasts from Dunaliella tertiolecta

Cells of Dunaliella tertiolecta from the log phase of growth were broken by rapid extrusion at low pressure through a Yeda press and the chloroplasts were isolated by centrifugation through a Percoll gradient. Osmolarity of the growth media, the suspending media, and the Percoll gradient was kept identical to minimize change in chloroplast volume and mitochondrial entrapment. The isolated intact chloroplasts were obtained in a 30 to 50% yield based on chlorophyll and were stable to washing with buffered medium. Isolated chloroplast yield and purity was dependent on cell culture condition; a cycle of 16 hours light and 8 hours dark with continuous high CO₂ was optimum. Isolated chloroplasts were about 90% intact by microscopic examination, ferricyanide-dependent O₂ evolution, and the distribution of four stromal enzymes. Enzymes associated with glycolate metabolism were not in the chloroplast fraction. The isolated chloroplasts with 10 millimolar bicarbonate evolved 24 micromoles of O₂ and fixed 21 micromoles of CO₂ per hour per milligram of chlorophyll, which rates were about one-third of those by whole cells. The inhibition of oxygen evolution by 10 millimolar phosphate was reversed by P-glycerate. Whole chloroplasts were also isolated from cells adapted to low CO₂ in air for 24 hours. On low CO₂ the cells excreted more gelatinous material, which had to be removed with additional washing of the cells, before it was possible to obtain good chloroplast preparations.     

Hill Reaction, Hydrogen Peroxide Scavenging, and Ascorbate Peroxidase Activity of Mesophyll and Bundle Sheath Chloroplasts of NADP-Malic Enzyme Type C(4) Species

Intact mesophyll and bundle sheath chloroplasts wee isolated from the NADP-malic enzyme type C₄ plants maize, sorghum (monocots), and Flaveria trinervia (dicot) using enzymic digestion and mechanical isolation techniques. Bundle sheath chloroplasts of this C₄ subgroup tend to be agranal and were previously reported to be deficient in photosystem II activity. However, following injection of intact bundle sheath chloroplasts into hypotonic medium, thylakoids had high Hill reaction activity, similar to that of mesophyll chloroplasts with the Hill oxidants dichlorophenolindophenol, p-benzoquinone, and ferricyanide (approximately 200 to 300 micromoles O₂ evolved per mg chlorophyll per hour). In comparison to that of mesophyll chloroplasts, the Hill reaction activity of bundle sheath chloroplasts of maize and sorghum was labile and lost activity during assay. Bundle sheath chloroplasts of maize also exhibited some capacity for 3-phosphoglycerate dependent O₂ evolution (29 to 58 micromoles O₂ evolved per milligram chlorophyll per hour). Both the mesophyll and bundle sheath chloroplasts were equally effective in light dependent scavenging of hydrogen peroxide. The results suggest that both chloroplast types have noncyclic electron transport and the enzymology to reduce hydrogen peroxide to water. The activities of ascorbate peroxidase from these chloroplast types was consistent with their capacity to scavenge hydrogen peroxide.