Photosynthesis in phosphoenolpyruvate carboxykinase-type C4 plants: photosynthetic activities of isolated bundle sheath cells from Urochloa panicoides

A method has been developed for rapidly preparing bundle sheath cell strands from Urochloa panicoides, a phosphoenolpyruvate (PEP) carboxykinase-type C4 plant. These cells catalyzed both HCO3(-)- and oxaloacetate-dependent oxygen evolution; oxaloacetate-dependent oxygen evolution was stimulated by ATP. For this activity oxaloacetate could be replaced by aspartate plus 2-oxoglutarate. Both oxaloacetate- and aspartate plus 2-oxoglutarate-dependent oxygen evolution were accompanied by PEP production and both were inhibited by 3-mercaptopicolinic acid, an inhibitor of PEP carboxykinase. The ATP requirement for oxaloacetate- and aspartate plus 2-oxoglutarate-dependent oxygen evolution could be replaced by ADP plus malate. The increased oxygen evolution observed when malate plus ADP was added with oxaloacetate was accompanied by pyruvate production. These results are consistent with oxaloacetate being decarboxylated via PEP carboxykinase. We suggest that the ATP required for oxaloacetate decarboxylation via PEP carboxykinase may be derived by phosphorylation coupled to malate oxidation in mitochondria. These bundle sheath cells apparently contain diffusion paths for the rapid transfer of compounds as large as adenine nucleotides.     

Photosynthesis in phosphoenolpyruvate carboxykinase-type C4 plants: activity and role of mitochondria in bundle sheath cells

Mitochondria from bundle sheath cells of the phosphoenolpyruvate carboxykinase-type C4 species Urochloa panicoides were shown to have metabolic properties consistent with a role in C4 photosynthesis predicted from earlier studies. The rate of O2 uptake in response to added malate plus ADP was at least five times the activity observed with NADH, glycine, or succinate. With malate plus ADP the O2 uptake rate averaged about 150 nmol O2 min-1 mg-1 protein, equivalent to about 0.6 mumol min-1 mg-1 of extracted chlorophyll. About half of this activity was apparently phosphorylation-linked with ADP/O2 ratios of about 4. Studies with electron transport inhibitors suggested that about 65% of this malate oxidation is cytochrome oxidase-terminated with a minor component mediated via the alternative oxidase. These mitochondria supported rapid rates of pyruvate production from malate and this activity was also stimulated by ADP but blocked by inhibitors of electron transport. Adding oxaloacetate increased pyruvate production but inhibited O2 uptake. The results were consistent with the notion that in this subgroup of C4 species mitochondrial-located NAD malic enzyme contributes substantially to total C4 acid decarboxylation. This enzyme is apparently also the primary source of NADH necessary to generate the ATP required for phosphoenolpyruvate carboxykinase-mediated oxaloacetate decarboxylation.     

The effect of inhibitors on the formation of phosphoenolpyruvate by rat liver mitochondria

1. Rat liver mitochondria oxidizing malate produce PEP (phosphoenolpyruvate) without the addition of ATP or other nucleotides. 2. The addition of oligomycin in the presence of 2,4-dinitrophenol did not abolish PEP formation and in some instances stimulated its formation. 3. Formation of PEP was inhibited by arsenate. 4. Arsenite decreased PEP formation and caused accumulation of pyruvate. 5. Added GTP and ITP had no effect on PEP formation. 6. PEP formed from malate in the presence of GTP and labelled P(i) had a specific radioactivity approximately the same as the P(i) with no contribution from the phosphate of the added GTP. 7. There was no parallelism between the effects of inhibitors on PEP formation from malate and their effects on the assayed activity of PEP carboxykinase. 8. In a direct comparison it was shown that the PEP carboxykinase content of mitochondria was insufficient to account for the PEP formation from malate. 9. Consideration of the kinetic characteristics of PEP carboxykinase and mitochondrial content of oxaloacetate and GTP show that this enzyme cannot account for the PEP formed from malate by mitochondria.     

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     

Mitochondria as a site of C4 acid decarboxylation in C4-pathway photosynthesis.

One group of C₄, species utilize a NAD-malic enzyme to decarboxylate C₄ acids. This enzyme, together with a major isoenzyme of aspartate aminotransferase and a NAD-malate dehydrogenase, is localized in the mitochondria of the bundle sheath cells and the following pathway for C₄, acid decarboxylation has been proposed: aspartate → oxaloacetate → malate → CO₂ + pyruvate. The present study reports that mitochondria isolated from the bundle sheath cells of one of these species, Atriplex spongiosa, are capable of decarboxylating C₄, acids at rates between 5 and 8 μmol/min/mg chlorophyll. For maximum decarboxylating activities, these particles required aspartate, 2-oxoglutarate and phosphate as well as malate; in the absence of any one of these compounds, activity was reduced to 0.3–0.8 μmol/min/mg chlorophyll. Rates for C₄ acid decarboxylation were much greater than the respiratory activities of these particles, including the capacity to form citrate or to oxidize malate, succinate, pyruvate or 2-oxoglutarate (0.03–0.6 μmol/min/mg chlorophyll). A comparison of mitochondria prepared from leaves of various C₄, and C₃, species showed that only the mitochondria from the bundle sheath cells of plants with high NAD-malic enzyme have capacities for rapid C₄ acid decarboxylation. The effects of a variety of experimental conditions on C₄ acid decarboxylating activities are also reported. The role of these mitochondria in C₄ photosynthesis is discussed.     

Plant Desiccation and Protein Synthesis. IV. RNA Synthesis, Stability, and Recruitment of RNA into Protein Synthesis during Desiccation and Rehydration of the Desiccation-Tolerant Moss, Tortula ruralis

We have studied the effects of ATP and ADP on the oxidation of malate by coupled and uncoupled mitochondria prepared from etiolated hypocotyls of mung bean (Vigna radiata L.).

In coupled mitochondria, ATP (1 millimolar) increased pyruvate production and decreased oxaloacetate formation without altering the rate of oxygen consumption. ATP also significantly decreased oxaloacetate production and increased pyruvate production in mitochondria that were uncoupled by carbonyl cyanide p-trifluoromethoxyphenyl hydrazone plus oligomycin.

In coupled mitochondria, ADP (1 millimolar) increased the production of both pyruvate and oxaloacetate concomitantly with the acceleration of oxygen uptake to the state 3 rate. The effects of ADP were largely eliminated in uncoupled mitochondria. These results indicate that, whereas the ADP stimulation of oxaloacetate and pyruvate production in the coupled mitochondria is brought about primarily as the result of the accelerated rates of electron transport and NADH oxidation by the respiratory chain in state 3, ATP has significant regulatory effects independent of those that might be exerted by control of electron transport.

     

Malate Decarboxylation by Kalanchoë daigremontiana Mitochondria and Its Role in Crassulacean Acid Metabolism

Mitochondria isolated from Kalanchoë daigremontiana, a Crassulacean acid metabolism plant, decarboxylate added malate to pyruvate at rates of up to 100 micromoles per hour per milligram original chlorophyll in the presence of ADP. Omitting ADP reduces this rate by approximately 50%. Antimycin A inhibits malate decarboxylation and this inhibition could be relieved by addition of aspartate and α-ketoglutarate to the mitochondria. Increasing the pH of the external medium inhibited malate decarboxylation; a dramatic decrease in pyruvate production was observed between pH 7.2 and pH 7.4. It is suggested that cytoplasmic pH changes may regulate the contribution of mitochondria to malate decarboxylation in the light in vivo.     

Unusual C3 and C4 metabolism in the chemoautotroph Alcaligenes eutrophus.

Phosphoenolpyruvate (PEP) carboxykinase was identified to be the only C3-carboxylating enzyme in Alcaligenes eutrophus. The enzyme requires GDP or inosine diphosphate (GTP or inosine triphosphate) for activity. Pyruvate- and other PEP-dependent CO2-fixing enzyme activities were not detected, regardless of whether the cells were grown autotrophically or heterotrophically. It is suggested that two pathways are present in the organism for the formation of PEP from C4 dicarboxylic acids. Besides decarboxylation of oxaloacetate by PEP carboxykinase, the consecutive action of NADP+-malic enzyme and PEP synthetase can also accomplish this synthesis. An oxaloacetate decarboxylase activity observed in the cell extracts may also contribute to the latter route. The properties of a mutant deficient in PEP synthetase supported the biochemical data. This mutant was unable to grow on pyruvate or lactate and grew slower than the wild type on direct or indirect metabolites of the tricarboxylic acid cycle such as succinate, glutamate, or acetate. Growth on fructose and autotrophic growth were not affected by the enzyme defect. The findings suggest that, depending on the growth substrate utilized, PEP carboxykinase can serve a dual physiological function in A. eutrophus, an anaplerotic function in oxaloacetate synthesis from PEP, or a gluconeogenic function in PEP synthesis from oxaloacetate.     

The regulation and glutamate metabolism by tricarboxylic acid-cycle activity in rat brain mitochondria

1. The interrelationship of metabolism of pyruvate or 3-hydroxybutyrate and glutamate transamination in rat brain mitochondria was studied. 2. If brain mitochondria are incubated in the presence of equimolar concentrations of pyruvate and glutamate and the K(+) concentration is increased from 1 to 20mm, the rate of pyruvate utilization is increased 3-fold, but the rate of production of aspartate and 2-oxoglutarate is decreased by half. 3. Brain mitochondria incubated in the presence of a fixed concentration of glutamate (0.87 or 8.7mm) but different concentrations of pyruvate (0 to 1mm) produce aspartate at rates that decrease as the pyruvate concentration is increased. At 1mm-pyruvate, the rate of aspartate production is decreased to 40% of that when zero pyruvate was present. 4. Brain mitochondria incubated in the presence of glutamate and malate alone produce 2-oxoglutarate at rates stoicheiometric with the rate of aspartate production. Both the 2-oxoglutarate and aspartate accumulate extramitochondrially. 5. Externally added 2-oxoglutarate has little inhibitory effect (K(i) approx. 31mm) on the production of aspartate from glutamate by rat brain mitochondria. 6. It is concluded that the inhibitory effect of increased C(2) flux into the tricarboxylic acid cycle on glutamate transamination is caused by competition for oxaloacetate between the transaminase and citrate synthase. 7. Evidence is provided from a reconstituted malate-aspartate (or Borst) cycle with brain mitochondria that increased C(2) flux into the tricarboxylic acid cycle from pyruvate may inhibit the reoxidation of exogenous NADH. These results are discussed in the light of the relationship between glycolysis and reoxidation of cytosolic NADH by the Borst cycle and the requirement of the brain for a continuous supply of energy.     

Oxaloacetate Production via Carboxylations in Crithidia fasciculata Preparations

SYNOPSIS. Fractions containing soluble enzymes from Crithidia fasciculata had an ADP-linked phosphoenolpyruvate (PEP) carboxykinase. The enzyme produced ATP and oxaloacetate (OAA) from PEP, ADP and HCO⁻₃. OAA was determined as the endproduct of reactions by forming the 2,4-dinitrophenylhydrazone derivative; the hydrazone was identified by thin-layer chromatography. Approximate Michaelis constants (PEP, Mg, HCO⁻₃, ADP) were determined spectrophotometrically by linking OAA production to malic dehydrogenase. The PEP carboxykinase did not utilize GDP, UDP or IDP as cofactors; the metal requirement was also satisfied by Mn. The enzyme was inhibited by the biotin antagonists avidin and desthiobiotin.
A pyruvate carboxylase was also present in the preparations, generating OAA from pyruvate and ATP. The role of both enzymes in OAA production and subsequent production of succinate is discussed with regard to C. fasciculata and other trypanosomatids.     

The effect of 2-oxoglutarate or 3-hydroxybutyrate on pyruvate dehydrogenase complex in isolated cerebro-cortical mitochondria

The oxidation of pyruvate is mediated by the pyruvate dehydrogenase complex (PDHC; EC 1.2.4.1, EC 2.3.1.12 and EC 1.6.4.3) whose catalytic activity is influenced by phosphorylation and by product inhibition. 2-Oxoglutarate and 3-hydroxybutyrate are readily utilized by brain mitochondria and inhibit pyruvate oxidation. To further elucidate the regulatory behavior of brain PDHC, the effects of 2-oxoglutarate and 3-hydroxyburyrate on the flux of PDHC (as determined by [1-¹⁴C]pyruvate decarboxylation) and the activation (phosphorylation) state of PDHC were determined in isolated, non-synaptic cerebro-cortical mitochondria in the presence or absence of added adenine nucleotides (ADP or ATP). [1-¹⁴C]Pyruvate decarboxylation by these mitochondria is consistently depressed by either 3-hydroxybutyrate or 2-oxoglutarate in the presence of ADP when mitochondrial respiration is stimulated. In the presence of exogenous ADP, 3-hydroxybutyrate inhibits pyruvate oxidation mainly through the phosphorylation of PDHC, since the reduction of the PDHC flux parallels the depression of PDHC activation state under these conditions. On the other hand, in addition to the phosphorylation of PDHC, 2-oxoglutarate may also regulate pyruvate oxidation by product inhibition of PDHC in the presence of 0.5 mM pyruvate plus ADP or 5 mM pyruvate alone. This conclusion is based upon the observation that 2-oxoglutarate inhibits [1-¹⁴C]pyruvate decarboxylation to a much greater extent than that predicted from the PDHC activation state (i.e. catalytic capacity) alone. In conjunction with the results from our previous study (Lai, J. C. K. and Sheu, K.-F. R. (1985) J. Neurochem. 45, 1861–1868), the data of the present study are consistent with the notion that the relative importance of the various mechanisms that regulate brain and peripheral tissue PDHCs shows interesting differences.     

Intracellular distribution of some enzymes of the glutamine utilisation pathway in rat lymphocytes

In lymphocytes of the rat, pyruvate kinase, phosphoenolpyruvate carboxykinase and NADP+-linked malate dehydrogenase (decarboxylating) are distributed almost exclusively in the cytosol whereas pyruvate carboxylase is distributed almost entirely in the mitochondria. For NAD+-linked malate dehydrogenase and aspartate aminotransferase approximately 80% and 40%, respectively, are in the cytosolic compartment. Since glutaminase is present in the mitochondria, glutamine is converted to malate within the mitochondria but further metabolism of the malate is likely to occur in the cytosol. Hence pyruvate produced from this malate, via oxaloacetate and phosphoenolpyruvate carboxykinase, may be rapidly converted to lactate, so restricting the entry of pyruvate into the mitochondria and explaining why very little glutamine is completely oxidised in these cells despite a high capacity of the Krebs cycle.     

Evidence for succinate production by reduction of fumarate during hypoxia in isolated adult rat heart cells

It has been demonstrated that perfusion of myocardium with glutamic acid or tricarboxylic acid cycle intermediates during hypoxia or ischemia, improves cardiac function, increases ATP levels, and stimulates succinate production. In this study isolated adult rat heart cells were used to investigate the mechanism of anaerobic succinate formation and examine beneficial effects attributed to ATP generated by this pathway. Myocytes incubated for 60 min under hypoxic conditions showed a slight loss of ATP from an initial value of 21 +/- 1 nmol/mg protein, a decline of CP from 42 to 17 nmol/mg protein and a fourfold increase in lactic acid production to 1.8 +/- 0.2 mumol/mg protein/h. These metabolite contents were not altered by the addition of malate and 2-oxoglutarate to the incubation medium nor were differences in cell viability observed; however, succinate release was substantially accelerated to 241 +/- 53 nmol/mg protein. Incubation of cells with [U-14C]malate or [2-U-14C]oxoglutarate indicates that succinate is formed directly from malate but not from 2-oxoglutarate. Moreover, anaerobic succinate formation was rotenone sensitive. We conclude that malate reduction to succinate occurs via the reverse action of succinate dehydrogenase in a coupled reaction where NADH is oxidized (and FAD reduced) and ADP is phosphorylated. Furthermore, by transaminating with aspartate to produce oxaloacetate, 2-oxoglutarate stimulates cytosolic malic dehydrogenase activity, whereby malate is formed and NADH is oxidized. In the form of malate, reducing equivalents and substrate are transported into the mitochondria where they are utilized for succinate synthesis.     

Interactions of Phosphoenolpyruvate Carboxylase and Pyruvic Kinase in Developing Soybean Seeds

Developing soybean seeds contain phosphoenolpyruvate (PEP) carboxylase,pyruvic kinase, malate dehydrogenase, aspartate aminotransferase,alanine aminotransferase and malic enzyme activities. PEP carboxylasemay be important in competing with pyruvic kinase and directinga portion of glycolytic carbon towards oxaloacetate synthesis.The oxaloacetate can then be converted to aspartate and malate.Malic enzyme produces pyruvate and NADPH from malate, and thismay be an important additional source of reducing power forlipid biosynthesis. In the presence of high levels of PEP carboxylaseit is possible to demonstrate PEP formation by pyruvic kinase.PEP carboxylase and pyruvic kinase independently compete forPEP in a mixed system. Soybean seed extracts readily convertedradioactive PEP into alanine and aspartate when supplementedwith ADP, Mg²⁺, K+, HCO₃– and glutamate. Under varyingconditions of pH, metal ions, PEP, enzyme concentration andtime both alanine and aspartate were always produced. Possiblythe final products of glycolysis should be considered as pyruvateand oxaloacetate in plants. (Received April 22, 1981; Accepted June 26, 1981)     

Effect of glucagon on metabolite compartmentation in isolated rat liver cells during gluconeogenesis from lactate

1. The subcellular distribution of adenine nucleotides, acetyl-CoA, CoA, glutamate, 2-oxoglutarate, malate, oxaloacetate, pyruvate, phosphoenolpyruvate, 3-phosphoglycerate, glucose 6-phosphate, aspartate and citrate was studied in isolated hepatocytes in the absence and presence of glucagon by using a modified digitonin procedure for cell fractionation. 2. In the absence of glucagon, the cytosol contains about two-thirds of cellular ATP, some 40-50% of ADP, acetyl-CoA, citrate and phosphoenolpyruvate, more than 75% of total 2-oxoglutarate, glutamate, malate, oxaloacetate, pyruvate, 3-phosphoglycerate and aspartate, and all of glucose 6-phosphate. 3. In the presence of glucagon the cytosolic space shows an increase in the content of malate, phosphoenolpyruvate and 3-phosphoglycerate by more than 60%, and those of aspartate and glucose 6-phosphate rise by about 25%. Other metabolites remain unchanged. After glucagon treatment, cytosolic pyruvate is decreased by 37%, whereas glutamate and 2-oxoglutarate decrease by 70%. The [NAD(+)]/[NADH] ratios calculated from the cytosolic concentrations of the reactants of lactate dehydrogenase and malate dehydrogenase were the same. Glucagon shifts this ratio and also that of the [NADP(+)]/[NADPH] couple towards a more reduced state. 4. In the mitochondrial space glucagon causes an increase in the acetyl-CoA and ATP contents by 25%, and an increase in [phosphoenolpyruvate] by 50%. Other metabolites are not changed by glucagon. Oxaloacetate in the matrix is only slightly decreased after glucagon, yet glutamate and 2-oxoglutarate fall to about 25% of the respective control values. The [NAD(+)]/[NADH] ratios as calculated from the [3-hydroxybutyrate]/[acetoacetate] ratio and from the matrix [malate]/[oxaloacetate] couple are lowered by glucagon, yet in the latter case the values are about tenfold higher than in the former. 5. Glucagon and oleate stimulate gluconeogenesis from lactate to nearly the same extent. Oleate, however, does not produce the changes in cellular 2-oxoglutarate and glutamate as observed with glucagon. 6. The changes of the subcellular metabolite distribution after glucagon are compatible with the proposal that the stimulation of gluconeogenesis results from as yet unknown action(s) of the hormone at the mitochondrial level in concert with its established effects on proteolysis and lipolysis.     

The regulation of phosphoenolpyruvate synthesis in pigeon liver

1. The intracellular location and maximal activities of enzymes involved in phosphoenolpyruvate synthesis have been investigated in pigeon liver. Enolase and pyruvate kinase were cytoplasmic, and the activities were 50–60 and 180–210μmoles/min./g. dry wt. at 25° respectively. Phosphoenolpyruvate carboxykinase was present exclusively, and nucleoside diphosphokinase predominantly, in the mitochondria; the particles had to be disrupted to elicit maximal activities, which were 27–33 and 400–600μmoles/min./g. dry wt. at 25° respectively. The activities of all four enzymes did not change significantly during 48hr. of starvation. 2. Conditions for incubation of washed isolated mitochondria were established, to give high rates of synthesis of phosphoenolpyruvate, linear with time and proportional to mitochondrial concentration. Inorganic phosphate and added adenine nucleotides were stimulatory, whereas added Mg²⁺ inhibited, partly owing to activation of contaminant pyruvate kinase. Phosphoenolpyruvate formation occurred from oxaloacetate, malate, fumarate, succinate, α-oxoglutarate and citrate, in decreasing order of effectiveness. 3. The steady-state ATP/ADP ratio of mitochondrial suspensions was decreased in the presence of added 2·5mm-Mg²⁺ (owing to stimulation of adenylate kinase and possibly of an adenosine triphosphatase), 0·5mm-Ca²⁺ or 0·4mm-dinitrophenol. In each case the rate of substrate removal and oxygen uptake was increased, whereas phosphoenolpyruvate synthesis was inhibited. Citrate formation was enhanced, owing to de-inhibition of citrate synthase. These effects were not primarily related to changes in the oxaloacetate concentration. 4. Both phosphoenolpyruvate carboxykinase and nucleoside diphosphokinase were active within the atractylosidesensitive barrier to the mitochondrial metabolism of added adenine nucleotides. There was no correlation between the rate of substrate-level phosphorylation associated with the oxidation of α-oxoglutarate, and the synthesis of phosphoenolpyruvate. 5. The results suggest that phosphoenolpyruvate formation in pigeon-liver mitochondria is regulated partly by the phosphorylation state of the adenine and guanine nucleotides, and partly by variations in the oxaloacetate concentration, all in the mitochondrial matrix. 6. Phosphoenolpyruvate is assumed to be the metabolite transported from the mitochondria to the cytoplasm during gluconeogenesis from oxaloacetate in pigeon liver.     

Tricarboxylic Acid Cycle Activity in Mitochondria from Soybean Nodules and Cotyledons

Infected cells of soybean (Glycine max) nodules require NADH,ATP, and 2-oxoglutarate for ammonia assimilation. The role ofmitochondria in nodule metabolism was investigated by determiningtheir respiratory properties and comparing them with cotyledonmitochondria. Nodule mitochondria oxidized malate at a ratetwice that of any other NAD-linked substrate although theirmalic enzyme activity was very low, accounting for only 12%of malate oxidation at pH 6.4 compared to 56% for cotyledonmitochondria. The reduction of NAD⁺ in mitochondria of noduleson adding malate (determined by fluorescence) was rapid andreached a stable level, whereas in cotyledon mitochondria theNADH level declined rapidly as oxaloacetate accumulated. Anoxaloacetate scavenging system in the mitochondrial reactionmedium increased malate oxidation by cotyledon mitochondria4-fold, but increased that of nodule mitochondria by less than50%. This demonstrates that the efflux of oxaloacetate by theoxaloacetate carrier is highly regulated by the extra-mitochondrialoxaloacetate concentration in cotyledon mitochondria comparedto nodule mitochondria. The activity of TCA cycle enzymes, exceptmalate and succinate dehydrogenases, was low in nodule mitochondria.Their oxaloacetate export during malate oxidation was rapid.The aspartate amino transferase activity associated with nodulemitochondria was sufficient to account for significant formationof 2-oxoglutarate from oxaloacetate and glutamate. These resultssuggest that nodule mitochondria operate a truncated form ofthe TCA cycle and primarily oxidize malate to provide oxaloacetateand ATP for NH₃ assimilation. Key words: Glycine max (L.), nitrogen fixation, gluconeogenesis, respiration     

Lysine 213 and histidine 233 participate in Mn(II) binding and catalysis in Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase

Saccharomyces cerevisiae phosphoenolpyruvate (PEP) carboxykinase catalyses the reversible metal-dependent formation of oxaloacetate and ATP from PEP, ADP, and CO2 and plays a key role in gluconeogenesis. This enzyme also has oxaloacetate decarboxylase and pyruvate kinase-like activities. Mutations of PEP carboxykinase have been constructed where the residues Lys213 and His233, two residues of the putative Mn2+ binding site of the enzyme, were altered. Replacement of these residues by Arg and by Gln, respectively, generated enzymes with 1.9 and 2.8 kcal/mol lower Mn2+ binding affinity. Lower PEP binding affinity was inferred for the mutated enzymes from the protection effect of PEP against urea denaturation. Kinetic studies of the altered enzymes show at least a 5000-fold reduction in V(max) for the primary reaction relative to that for the wild-type enzyme. V(max) values for the oxaloacetate decarboxylase and pyruvate kinase-like activities of PEP carboxykinase were affected to a much lesser extent in the mutated enzymes. The mutated enzymes show a decreased steady-state affinity for Mn2+ and PEP. The results are consistent with Lys213 and His233 being at the Mn2+ binding site of S. cerevisiae PEP carboxykinase and the Mn2+ affecting the PEP interaction. The different effects of mutations in V(max) for the main reaction and the secondary activities suggest different rate-limiting steps for these reactions.     

The control of tricarboxylate-cycle oxidations in blowfly flight muscle. The steady-state concentrations of citrate, isocitrate 2-oxoglutarate and malate in flight muscle and isolated mitochondria.

1. Blowfly (Phormia regina) flight-muscle mitochondria were allowed to oxidize pyruvate under a variety of experimental conditions, and determinations of the citrate, isocitrate, 2-oxoglutarate and malate contents of both the mitochondria and the incubation medium were made. For each intermediate a substantial portion of the total was present within the mitochondria. 2. Activation of respiration by either ADP or uncoupling agent resulted in a decreased content of citrate and isocitrate and an increased content of 2-oxoglutarate and malate when the substrate was pyruvate, APT and HCO3 minus. Such a decrease in citrate content was obscured when the substrate was pyruvate and proline owing to a large rise in the total content of tricarboxylate-cycle intermediates in the presence of proline and ADP. 3. An experiment involving oligomycin and uncoupling agent demonstrated that the ATP/ADP ratio is the main determinant of flux through the tricarboxylate cycle, with the redox state of nicotinamide nucleotide being of lesser importance. 4. Addition of ADP and Ca-2+ to activate the oxidation of both glycerol 3-phosphate and pyruvate, simulating conditions on initiation of flight, gave a decrease in citrate and isocitrate and an increase in 2-oxoglutarate and malate content. 5. There was a good correlation between these results with isolated flight-muscle mitochondria and the changes found in fly thoraces after 30s and 2 mihorax. 6. It is concluded that NAD-isocitrate dehydrogenase (EC 1.1.1.41) controls the rate of pyruvate oxidation in both resting fly flight muscle in vivo and isolated mitochondria in state 4 (nomenclature of Change & Williams, 1955).     

Oxaloacetate as the Source of Carbon Dioxide for Photosynthesis in Bundle Sheath Cells of the C(4) Species Panicum maximum

3-Mercaptopicolinic acid (3-MPA), an inhibitor of phosphoenolpyruvate carboxykinase, was employed to study the role of organic acid decarboxylation during C(4) photosynthesis. Treatment of detached Panicum maximum leaves with 5 mm 3-MPA inhibited photosynthesis 70 to 75%. Oxygen was found to have no effect on the degree of inhibition. The postillumination (14)CO(2) burst associated with P. maximum photosynthesis was almost abolished by 5 mm 3-MPA. The turnover rates of malate and aspartate during C(4) photosynthesis were severely reduced as well as the rates of formation of C(3) cycle intermediates in P. maximum leaves treated with 3-MPA. These results are interpreted as direct evidence for the fixation of CO(2), arising from the decarboxylation of oxaloacetate, by the C(3) cycle in bundle sheath cells of P. maximum leaves.