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.

     

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.     

Stimulation of ammonia and 2-oxoglutarate-dependent o(2) evolution in isolated chloroplasts by dicarboxylates and the role of the chloroplast in photorespiratory nitrogen recycling

Intact chloroplasts isolated from spinach (Spinacia oleracea L.) leaves showed a light-dependent O(2) evolution (5.5 +/- 0.75 micromoles per milligram chlorophyll per hour) when supplied with ammonia and 2-oxoglutarate. This (ammonia, 2-oxoglutarate)-dependent O(2) evolution was stimulated 2- to 4-fold by the dicarboxylates, malate, succinate, fumarate, glutarate, and l-tartarate. Evolution of O(2) in the presence of malate was dependent on the presence of both 2-oxoglutarate and NH(4)Cl; malate with only either 2-oxoglutarate and NH(4)Cl alone did not support O(2) evolution. Furthermore, in the presence of malate, the amount of O(2) evolved was solely dependent on the amount of NH(4)Cl or 2-oxoglutarate added and malate did not affect the ratio of O(2) evolved to NH(4)Cl or 2-oxoglutarate consumed. Studies with inhibitors (2-(3,4-dichlorophenyl)-1,1-dimethyl urea, methionine sulfoximine, and azaserine) indicated that the above activity was directly linked to glutamine synthetase and glutamate synthase activity in the chloroplast and was not caused by the metabolism of malate. The V(max)/2 of (ammonia, 2-oxoglutarate)-dependent O(2) evolution was reached at 32 micromolar NH(4)Cl and 6 millimolar (approximately) 2-oxoglutarate in the absence of malate, and at 22 micromolar NH(4)Cl and 73 micromolar 2-oxoglutarate when malate (3 millimolar) was present.Intact chloroplasts isolated from pea (Pisum sativum) leaves also showed a stimulation of (ammonia, 2-oxoglutarate)-dependent O(2) evolution by malate. However glutamine was required for this activity even though glutamine with only either NH(4)Cl or 2-oxoglutarate did not respond to malate stimulation.The measured rates of (ammonia, 2-oxoglutarate)-dependent O(2) evolution in isolated spinach chloroplasts in the presence of malate were about 19.5 +/- 4.5 micromoles O(2) evolved per milligram chlorophyll per hour. This is adequate to sustain photorespiratory NH(3) recycling and the refixation of NH(3) arising from NO(3) under ambient conditions in the light. The role of the chloroplast in photorespiratory NH(3) recycling and the nature of the associated transport of 2-oxoglutarate into the chloroplast is discussed.     

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.     

Light dependent reduction of nitrate by pea chloroplasts in the presence of nitrate reductase and C4-dicarboxylic acids

In the presence of purified nitrate reductase (NR) and 1 mM NADH, illuminated pea chloroplasts catalysed reduction of NO₃^? to NH₃ with the concomitant evolution of O₂. The rates were slightly less than those for reduction of NO₂^? to NH₃ and O₂, evolution by chloroplasts in the absence of NR and NADH (ca 6 μg atoms N/mg Chl/hr). Illuminated chloroplasts quantitatively reduced 0.2 mM oxaloacetate (OAA) to malate. In the presence of an extrachloroplast malate-oxidizing system comprised of NAD-specific malate dehydrogenase (NAD-MDH), NAD, NR and NO₃^?, illuminated chloroplasts supported OAA-dependent reduction of NO₃^? to NH₃ with the evolution of O₂. The reaction did not proceed in the absence of any of these supplements or in the dark but malate could replace OAA. The results are consistent with the reduction of NO₃^?by reducing equivalents from H₂O involving a malate/OAA shuttle. The ratios for O₂, evolved: C₄-acid supplied and N reduced: C₄-acid supplied in certain experiments imply recycling of the C₄-acids.     

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.     

C4-Dicarboxylic acid metabolism in bundle-sheath chloroplasts,mitochondria and strands of Eriochloa borumensis Hack., a phosphoenolpyruvate-carboxykinase type C4 species

C₄-acid metabolism by isolated bundlesheath chloroplasts, mitochondria and strands of Eriochloa borumensis Hack., a phosphoennolpyruvate-carboxykinase (PEP-CK) species, was investigated. Aspartate, oxaloacetate (OAA) and malate were decarboxylated by strands with several-fold stimulation upon illumination. There was strictly light-dependent decarboxylation of OAA and malate by the chloroplasts, but the chloroplasts did not decarboxylate aspartate in light or dark. PEP was a primary product of OAA or malate decarboxylation by the chloroplasts and its formation was inhibited by 3-(3,4-dichlorophenyl)-1, 1-dimethylurea or NH₄Cl. There was very little conversion of PEP to pyruvate by bundle-sheath chloroplasts, mitochondria or strands. Decarboxylation of the three C₄-acids by mitochondria was light-independent. Pyruvate was the only product of mitochondrial metabolism of C₄-acids, and was apparently transaminated in the cytoplasm since PEP and alanine were primarily exported out of the bundle-sheath strands. Light-dependent C₄-acid decarboxylation by the chloroplasts is suggested to be through the PEP-CK, while the mitochondrial C₄-acid decarboxylation may proceed through the NAD-malic enzyme (NAD-ME) system. In vivo both aspartate and malate are considered as transport metobolites from mesophyll to bundle-sheath cells in PEP-CK species. Aspartate would be metabolized by the mitochondria to OAA. Part of the OAA may be converted to malate and decarboxylated through NAD-ME, and part may be transported to the chloroplasts for decarboxylation through PEP-CK localized in the chloroplasts. Malate transported from mesophyll cells may serve as carboxyl donor to chloroplasts through the chloroplastic NAD-malate dehydrogenase and PEP-CK. Bundle-sheath strands and chloroplasts fixed ¹⁴CO₂ at high rates and exhibited C₄-acid-dependent O₂ evolution in the light. Studies with 3-mercaptopicolinic acid, a specific inhibitor of PEP-CK, have indicated that most (about 70%) of the OAA formed from aspartate is decarboxylated through the chloroplastic PEP-CK and the remaining (about 30%) OAA through the mitochondrial NAD-ME. Pyruvate stimulation of aspartate decarboxylation is discussed; a pyruvate-alanine shuttle and an aspartate-alanine shuttle are proposed between the mesophyll and bundle-sheath cells during aspartate decarboxylation through the PEP-CK and NAD-ME system respectively.Abbreviations CK carboxykinase - -Kg -ketoglutarate - ME malic enzyme - 3-MPA 3-mercaptopicolinic acid - OAA oxaloacetate - PEP phosphoenolpyruvate - R5P ribose-5-phosphate     

The Involvement of Aspartate and Glutamate in the Decarboxylation of Malate by Isolated Bundle Sheath Chloroplasts from Zea mays

Aspartate or glutamate stimulated the rate of light-dependent malate decarboxylation by isolated Zea mays bundle sheath chloroplasts. Stimulation involved a decrease in the apparent K_m (malate) and an increased maximum velocity of decarboxylation. In the presence of glutamate other dicarboxylates (succinate, fumarate) competitively inhibited malate decarboxylation by intact chloroplasts with respect to malate with an apparent K_i of about 6 millimolar. For comparison the K_i for inhibition of nicotinamide adenine dinucleotide phosphate-malic enzyme from freshly lysed chloroplasts by these dicarboxylates was 15 millimolar. A range of compounds structurally related to aspartate stimulated malate decarboxylation by intact chloroplasts. K_a values for stimulation at 5 millimolar malate were 1.7, 5, and 10 millimolar for l-glutamate, l-aspartate, and β-methyl-dl-aspartate, respectively. Certain compounds, notably cysteic acid, which stimulated malate decarboxylation by intact chloroplasts inhibited malate decarboxylation by nicotinamide adenine dinucleotide phosphate-malic enzyme obtained from lysed chloroplasts and assayed under comparable conditions. It was concluded that aspartate, glutamate, and related compounds affect the transport of malate into the intact chloroplasts and that malate translocation does not take place on the general dicarboxylate translocator previously reported for higher plant chloroplasts.     

Inhibition of Glutamine Transport in Rat Brain Mitochondria by Some Amino Acids and Tricarboxylic Acid Cycle Intermediates

Glutamine transport into rat brain synaptic and non-synaptic mitochondria has been monitored by the uptake of [³H]glutamine and by mitochondrial swelling. The concentration of glutamate in brain mitochondria is calculated to be high, 5–10 mM, indicating that phosphate activated glutaminase localized inside the mitochondria is likely to be dormant and the glutamine taken up not hydrolyzed. The uptake of [³H]glutamine is largely stereospecific. It is inhibited by glutamate, asparagine, aspartate, 2-oxoglutarate and succinate. Glutamate inhibits this uptake into synaptic and non-synaptic mitochondria by 95 and 85%, respectively. The inhibition by glutamate, asparagine, aspartate and succinate can be explained by binding to an inhibitory site whereas the inhibition by 2-oxoglutarate is counteracted by aminooxyacetic acid, which indicates that it is dependent on transamination. The glutamine-induced swelling, a measure of a very low affinity uptake, is inhibited by glutamate at a glutamine concentration of 100 mM, but this inhibition is abolished when the glutamine concentration is raised to 200 mM. This suggests that the very low affinity glutamine uptake is competitively inhibited by glutamate. Furthermore, glutamine-induced swelling is inhibited by 2-oxoglutarate, succinate and malate, similarly to that of the [³H]glutamine uptake. The properties of the mitochondrial glutamine transport are not identical with those of a recently purified renal glutamine carrier.     

Effect of photosynthetic intermediates on the magnesium inhibition of oxygen evolution by barley chloroplasts

Millimolar concentrations of Mg²⁺ inhibited CO₂-dependent O₂ evolution by barley (Hordeum vulgare L.) chloroplasts and also prevented the activation of NADP-glyceraldehyde-3-phosphate dehydrogenase, ribulose-5-phosphate kinase, and fructose-1,6-diphosphatase by light in intact chloroplasts. When added in the dark, 3-phosphoglycerate prevented the inhibition of O₂ evolution by Mg²⁺ and reduced the Mg²⁺ inhibition of enzyme activation by light. Fructose 1,6-diphosphate and ribulose 5-phosphate also prevented the inhibition of O₂ evolution by Mg²⁺ whereas glucose 1-phosphate, glucose 6-phosphate, ribulose 1,5-diphosphate, and citrate had no effect. Phosphoenolpyruvate gave an intermediate response. Metabolites that prevented the Mg²⁺ inhibition of O₂ evolution shortened the lag phase of CO₂-dependent O₂ evolution in the absence of M²⁺. Loading chloroplasts in the dark with 3-phosphoglycerate reduced both the lag phase of O₂ evolution and the inhibition of O₂ evolution by Mg²⁺. The results suggested that Mg²⁺ inhibition was lessened either by external metabolites that compete with inorganic phosphate for transport into the chloroplast or by a high concentration of internal metabolites.     

Nitrogen Metabolism in Plant Cell Suspension Cultures: II. Role of Organic Acids during Growth on Ammonia

Tobacco cells (Nicotiana tabacum) are capable of growth on ammonia as a sole nitrogen source only when succinate, malate, fumarate, citrate, α-ketoglutarate, glutamate, or pyruvate is added to the growth medium. A ratio between the molar concentrations of ammonia to succinate (as a complementary organic acid) in the growth medium of 1.5 was optimal. Succinate had no effect on the rate of uptake of ammonia from the medium into the cells although it did affect the intracellular concentration of ammonia. However, the changes were not sufficient to explain inhibition of growth as being due to ammonia toxicity. The radioactivity from ¹⁴C-succinate was incorporated into malate, glutamate, and aspartate within 2 minutes.     

Regulation of chloroplast photosynthetic activity by exogenous magnesium

Magnesium was most inhibitory to photosynthetic reactions by intact chloroplasts when the magnesium was added in the dark before illumination. Two millimolar MgCl₂, added in the dark, inhibited CO₂-dependent O₂ evolution by Hordeum vulgare L. and Spinacia oleracea L. (C₃ plants) chloroplasts 70 to 100% and inhibited (pyruvate + oxaloacetate)-dependent O₂ evolution by Digitaria sanguinalis L. (C₄ plant) mesophyll chloroplasts from 80 to 100%. When Mg²⁺ was added in the light, O₂ evolution was reduced only slightly. O₂ evolution in the presence of phosphoglycerate was less sensitive to Mg²⁺ inhibition than was CO₂-dependent O₂ evolution.

Magnesium prevented the light activation of several photosynthetic enzymes. Two millimolar Mg²⁺ blocked the light activation of NADP-malate dehydrogenase in D. sanguinalis mesophyll chloroplasts, and the light activation of phosphoribulokinase, NADP-linked glyceraldehyde-3-phosphate dehydrogenase, and fructose 1,6-diphosphatase in barley chloroplasts. The results suggest that Mg²⁺ inhibits chloroplast photosynthesis by preventing the light activation of certain enzymes.

     

d-Glycerate Transport by the Pea Chloroplast Glycolate Carrier : Studies on [1-C]d-Glycerate Uptake and d-Glycerate Dependent O(2) Evolution

Rapid direct conversion of exogenously supplied [¹⁴C]aspartate to [¹⁴C] asparagine and to tricarboxylic cycle acids was observed in alfalfa (Medicago sativa L.) nodules. Aspartate aminotransferase activity readily converted carbon from exogenously applied [¹⁴C]aspartate into the tricarboxylic acid cycle with subsequent conversion to the organic acids malate, succinate, and fumarate. Aminooxyacetate, an inhibitor of aminotransferase activity, reduced the flow of carbon from [¹⁴C]aspartate into tricarboxylic cycle acids and decreased ¹⁴CO₂ evolution by 99%. Concurrently, maximum conversion of aspartate to asparagine was observed in aminooxyacetate treated nodules (30 nanomoles asparagine per gram fresh weight per hour. Metabolism of [¹⁴C]aspartate and distribution of nodulefixed ¹⁴CO₂ suggest that two pools of aspartate occur in alfalfa nodules: (a) one involved in asparagine biosynthesis, and (b) another supplying a malate/aspartate shuttle. Conversion of [¹⁴C]aspartate to [¹⁴C]asparagine was not inhibited by methionine sulfoximine, a glutamine synthetase inhibitor, or azaserine, a glutmate synthetase, inhibitor. The data did not indicate that asparagine biosynthesis in alfalfa nodules has an absolute requirement for glutamine. Radioactivity in the xylem sap, derived from nodule ¹⁴CO₂ fixation, was markedly decreased by treating nodulated roots with aminooxyacetate, methionine sulfoximine, and azaserine. Inhibitors decreased the [¹⁴C]aspartate and [¹⁴]asparagine content of xylem sap by greater than 80% and reduced the total amino nitrogen content of xylem sap (including nonradiolabeled amino acids) by 50 to 80%. Asparagine biosynthesis in alfalfa nodules and transport in xylem sap are dependent upon continued aminotransferase activity and an uninterrupted assimilation of ammonia via the glutamine synthetase/glutamate synthase pathway. Continued assimilation of ammonia apparently appears crucial to continued root nodule CO₂ fixation in alfalfa.     

The roles of malate and aspartate in C4 photosynthetic metabolism of Flaveria bidentis (L.)

In C₄ grasses belonging to the NADP-malic enzyme-type subgroup, malate is considered to be the predominant C₄ acid metabolized during C₄ photosynthesis, and the bundle sheath cell chloroplasts contain very little photosystem-II (PSII) activity. The present studies showed that Flaveria bidentis (L.), an NADP-malic enzyme-type C₄ dicotyledon, had substantial PSII activity in bundle sheath cells and that malate and aspartate apparently contributed about equally to the transfer of CO₂ to bundle sheath cells. Preparations of bundle sheath cells and chloroplasts isolated from these cells evolved O₂ at rates between 1.5 and 2 mol · min^–1 · mg^–1 chlorophyll (Chl) in the light in response to adding either 3-phosphoglycerate plus HCO ₃ ^– or aspartate plus 2-oxoglutarate. Rates of more than 2 mol O₂ · min^–1 · mg^–1 Chl were recorded for cells provided with both sets of these substrates. With bundle sheath cell preparations the maximum rates of light-dependent CO₂ fixation and malate decarboxylation to pyruvate recorded were about 1.7 mol · min^–1 · mg^–1 Chl. Compared with NADP-malic enzyme-type grass species, F. bidentis bundle sheath cells contained much higher activities of NADP-malate dehydrogenase and of aspartate and alanine aminotransferases. Time-course and pulse-chase studies following the kinetics of radiolabelling of the C-4 carboxyl of C₄ acids from ¹⁴CO₂ indicated that the photosynthetically active pool of malate was about twice the size of the aspartate pool. However, there was strong evidence for a rapid flux of carbon through both these pools. Possible routes of aspartate metabolism and the relationship between this metabolism and PSII activity in bundle sheath cells are considered.Abbreviations DHAP dihydroxyacetone phosphate - NADP-ME(-type) NADP-malic enzyme (type) - NADP-MDH NADP-malate dehydrogenase - OAA oxaloacetic acid - 2-OG 2-oxoglutarate - PEP phosphoenolpyruvate - PGA 3-phosphoglycerate - Pi orthophosphate - Ru5P ribulose 5-phosphate     

The tricarboxylic acid cycle in Dictyostelium discoideum. Metabolite concentrations, oxygen uptake and 14c-labelled amino acid labelling patterns.

Some aspects of tricarboxylic acid-cycle activity during differentiation and aging in Dictyostelium discoideum were examined. The concentrations of glutamate, aspartate, alanine, citrate, 2-oxoglutarate, succinate, fumarate, malate, oxaloacetate, pyruvate and acetyl-CoA were determined at four stages over the course of differentiation. The rate of O2 utilization was also determined over differentiation. In addition, experiments are described in which the specific radioactivities of citrate, 2-oxoglutarate, succinate, fumarate and malate were determined during a 30 min labelling of cells from the preculmination stage of development with [14C]glutamate, [14C]aspartate or [14C]alanine. A similar experiment was also performed with cells from the aggregation stage of development using [14C]glutamate.     

2-Oxoglutarate transport: A protential mechanism for regulating glutamate and tricarboxylic acid cycle intermediates in neurons

2-Oxoglutarate (-ketoglutarate) is transported into synaptosomal and synaptoneurosomal preparations by a Na⁺-dependent, high-affinity process that exhibits complex kinetics, and is differentially modulated by glutamate, glutamine, aspartate, malate, and a soluble, heat-labile substance of high molecular weight present in rat brain extracts. Glutamate and aspartate generally inhibit 2-oxoglutarate uptake, but under certain conditions may increase uptake. Glutamine generally increases 2-oxoglutarate uptake, but under certain conditions may inhibit uptake. One interpretation of our results is that 2-oxoglutarate uptake is mediated primarily by a transporter that exhibits negative cooperativity and possesses three regulatory sites that differentially modulate substrate affinity, V_max, and negative cooperativity. Glutamate, aspartate, malate, and 2-oxoglutarate itself may interact with a site that reduces substrate affinity; whereas glutamine, and possibly glutamate and aspartate, appear to interact with another site that increases V_max. A putative regulatory protein appears to abolish negative cooperativity and increases substrate affinity in the absence of glutamine. Based on the evidence that glutamatergic and GABAergic neurons depend on astrocytes to supply precursors to replenish their neurotransmitter and tricarboxylic acid cycle pools, the uptake of 2-oxoglutarate, presumably into synaptic terminals, may reflect a role for this metabolite in replenishing the transmitter and tricarboxylic acid pools, and a role for the transporter as a site at which these pools are regulated.Abbreviations used AAT aspartate aminotransferase - glu glutamate - gln glutamine - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - LDS low-density synaptosomes - OAA oxaloacetate - 2-OG 2-oxoglutarate (-ketoglutarate) - PC pyruvate carboxylase - PDH pyruvate dehydrogenase - TCA tricarboxylic acid Special issue dedicated to Dr. Claude Baxter.     

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.     

Uptake of ATP analogs by isolated pea chloroplasts and their effect on CO2 fixation and electron transport

1. The ATP analog, adenylyl-imidodiphosphate rapidly inhibited CO₂-dependent oxygen evolution by isolated pea chloroplasts. Both α, β- and β, γ-methylene adenosine triphosphate also inhibited oxygen evolution. The inhibition was relieved by ATP but only partially relieved by 3-phosphoglycerate. Oxygen evolution with 3-phosphoglycerate as substrate was inhibited by adenylyl-imidodiphosphate to a lesser extent than CO₂-dependent oxygen evolution. The concentration of adenylyl-imidodiphosphate required for 50% inhibition of CO₂-dependent oxygen evolution was 50 μM.2. Although non-cyclic photophosphorylation by broken chloroplasts was not significantly affected by adenylyl-imidodiphosphate, electron transport in the absence of ADP was inhibited by adenylyl-imidodiphosphate to the same extent as by ATP, suggesting binding of the ATP analog to the coupling factor of phosphorylation.3. The endogenous adenine nucleotides of a chloroplast suspension were labelled by incubation with [¹⁴C]ATP and subsequent washing. Addition of adenylyl-imidodiphosphate to the labelled chloroplasts resulted in a rapid efflux of adenine nucleotides suggesting that the ATP analog was transported into the chloroplasts via the adenine nucleotide translocator.4. It was concluded that uptake of ATP analogs in exchange for endogenous adenine nucleotides decreased the internal ATP concentration and thus inhibited CO₂ fixation. Oxygen evolution was inhibited to a lesser extent in spinach chloroplasts which apparently have lower rates of adenine nucleotide transport than pea chloroplasts.     

Inhibition of anion transport across the mitochondrial membrane by amytal

It has been found that amytal competitively inhibits succinate (+ rotenone) oxidation by intact uncoupled mitochondria. Similar results were obtained in metabolic state 3, the K_i value being 0.45 mM. Amytal did not effect succinate oxidation by broken mitochondria and submitochondrial particles (at a concentration which inhibited succinate oxidation by intact mitochondria). Amytal inhibited the swelling of mitochondria suspended in ammonium succinate or ammonium malate but was without effect on the swelling of mitochondria in ammonium phosphate and potassium phosphate in the presence of valinomycin+carbonylcyanide p-trifluoromethoxyphenylhydrazone.Using [¹⁴C] succinate and [¹⁴C] citrate it has been shown that amytal inhibited the succinate/succinate, succinate/P_i, succinate/malate, and citrate/citrate and citrate/malate exchanges. Amytal inhibited P_i transport across mitochondrial membrane only if preincubated with mitochondria. Other barbiturates: phenobarbital, dial, veronal were found to inhibit [¹⁴C]succinate/anion (P_i, succinate, malonate, malate) exchange reactions in a manner similar to amytal. It is concluded that barbiturates non-specifically inhibit the dicarboxylate carrier system, tricarboxylate carrier and P_i translocator. It is postulated that the inhibition of succinate oxidation by barbiturates is caused mainly by the inhibition of succinate and P_i translocation across the mitochondrial membrane.