Identification of cytoplasmic nodule-associated forms of malate dehydrogenase involved in the symbiosis between Rhizobium leguminosarum and Pisum sativum

The malate dehydrogenase activity (EC 1.1.1.37), present in the cytoplasm of Pisum sativum root nodules, can be separated by ion-exchange chromatography into four different fractions. Malate dehydrogenase activity present in the cytoplasm of roots elutes mainly as a single peak. During nodule development an increase in malate dehydrogenase activity per gram of material was observed. This increase occurred concomitantly with the increase in nitrogenase activity. The kinetic properties of the separated malate dehydrogenases of root nodule cytoplasm and root cytoplasm were studied. The Km values for malate (2.6 mM), NAD+ (27 microM), oxaloacetate (18 microM) and NADH (13 microM) of the dominant form of the root nodule cytoplasm are much lower than those of the dominant malate dehydrogenase root form (64 mM, 4.4 mM, 89 microM and 70 microM respectively). Binding of malate by the enzyme-NADH complex from root nodules results in an abortive complex, thereby blocking the further reduction of oxaloacetate by NADH. The dominant root malate dehydrogenase does not form the abortive complex. From the kinetic data it is concluded, first, that the root nodule forms of the enzyme are capable of catalysing at a high rate the reduction of oxaloacetate, to meet the demands for malate governed by the bacteroid and the infected plant cell. The second conclusion, drawn from the kinetic data, is that under physiological conditions the conversion of oxaloacetate can be controlled just by the malate concentration. Consequently the major root nodule forms of malate dehydrogenase are able to allow a high flux of malate production from oxaloacetate but also to establish a sufficient oxaloacetate concentration necessary for the assimilation and transport of fixed nitrogen.     

Purification and properties of mitochondrial malate dehydrogenase of Toxocara canis muscle

Mitochondrial malate dehydrogenase was purified from muscle extracts of Toxocara canis by means of Sephadex G-100 gel filtration, DEAE-Sephadex ion-exchange chromatography and 5'AMP-Sepharose 4B affinity chromatography. The purified enzyme showed an optimum pH for the reduction of oxaloacetate of 7.3 in Tris-HCl buffer and of pH 7.5-7.8 in phosphate buffer. The m-MDH showed values of 3.2 kcal/mol and 10.5 kcal/mol for the energy of activation, calculated from the Arrhenius equation. The mitochondrial enzyme was found to be more susceptible to thermal inactivation as compared with the cytosolic isoenzyme. Kinetic experiments showed that the m-MDH of Toxocara canis is inhibited by excess oxaloacetate but not by excess NADH. The apparent Km for oxaloacetate reduction was 53 microM and 0.54 mM for L-malate oxidation.     

Determination of the mechanism of human malic enzyme with natural and alternate dinucleotides by isotope effects.

Human malic enzyme was studied by steady state kinetics, deuterium isotope effects, and 13C isotope effects with both the physiological dinucleotide cofactor and several alternate cofactors. The log V vs pH profile with NAD revealed two pK(a) values too close to be separately determined, but with an average value of 7.33. The log V/K vs pH profile with NAD revealed two pK(a) values at 7.4 and 5.6. Deuterium and 13C isotope effects indicate that the mechanism of human malic enzyme is stepwise with both NAD and epsilonNAD, but that hyperconjugation in the transition state for hydride transfer is detectable only with the former. With thioNAD and APAD, the isotope effects do not clearly indicate whether the mechanism is stepwise or concerted. The intrinsic 13C isotope effect for decarboxylation was calculated to be 1.0485 by measurement of the partition ratio of oxaloacetate in the presence of NADH and human malic enzyme (decarboxylation to pyruvate/reduction to malate = 2.33). The isotope effect and partitioning data suggest that the energy barrier for decarboxylation of oxaloacetate is not as high relative to the barrier for reduction of oxaloacetate as with the chicken liver enzyme.     

A 1H NMR study of succinate synthesis from exogenous precursors in oxygen-deprived rat heart mitochondria

Succinate synthesis from exogenous malate, alpha-ketoglutarate, oxaloacetate and L-glutamate in isolated oxygen-deprived rat heart mitochondria was studied using 1H NMR. The highest rate of succinate synthesis was observed during incubation of mitochondria with a mixture of L-glutamate and oxaloacetate. When mitochondria were incubated with [U-13C] glutamate and oxaloacetate the [U-13C] succinate/succinate and aspartate/succinate ratios were equal to 2. This suggests that the succinate produced from [U-13C] alpha-keto-glutarate formed via transamination of [U-13C] glutamate with oxaloacetate by aspartate aminotransferase exceeds twofold that synthesized via oxaloacetate reduction. It may thus be expected that GTP yield in a reaction catalyzed by the succinic thiokinase will be 2 times higher that of ATP production coupled with NADH-dependent fumarate reduction.     

The citrate metabolic pathway in Leuconostoc mesenteroides: expression, amino acid synthesis, and alpha-ketocarboxylate transport.

Citrate metabolism in Leuconostoc mesenteroides subspecies mesenteroides is associated with the generation of a proton motive force by a secondary mechanism (C. Marty-Teysset, C. Posthuma, J. S. Lolkema, P. Schmitt, C. Divies, and W. N. Konings, J. Bacteriol. 178:2178-2185, 1996). The pathway consists of four steps: (i) uptake of citrate, (ii) splitting of citrate into acetate and oxaloacetate, (iii) pyruvate formation by decarboxylation of oxaloacetate, and (iv) reduction of pyruvate to lactate. Studies of citrate uptake and metabolism in resting cells of L. mesenteroides grown in the presence or absence of citrate show that the citrate transporter CitP and citrate lyase are constitutively expressed. On the other hand, oxaloacetate decarboxylase is under stringent control of the citrate in the medium and is not expressed in its absence, thereby blocking the pathway at the level of oxaloacetate. Under those conditions, the pathway is completely directed towards the formation of aspartate, which is formed from oxaloacetate by transaminase activity. The data indicate a role for citrate metabolism in amino acid biosynthesis. Internalized radiolabeled aspartate produced from citrate metabolism could be chased from the cells by addition of the amino acid precursors oxaloacetate, pyruvate, alpha-ketoglutarate, and alpha-ketoisocaproate to the cells, indicating a broad specificity of the transamination reaction. The alpha-ketocarboxylates are readily transported across the cytoplasmic membrane. alpha-Ketoglutarate uptake in resting cells of L. mesenteroides was dependent upon the presence of an energy source and was inhibited by inhibition of the proton motive force generating F(0)F(1) ATPase and by selective dissipation of the membrane potential and the transmembrane pH gradient. It is concluded that in L. mesenteroides alpha-ketoglutarate is transported via a secondary transporter that may be a general alpha-ketocarboxylate carrier.     

Competition between electron acceptors in photosynthesis: Regulation of the malate valve during CO2 fixation and nitrite reduction

For maximal rates of CO₂ assimilation in isolated intact spinach chloroplasts the generation of the adequate NADPH/ATP ratio is achieved either by cyclic electron flow around photosystem I or by linear electron transport to oxaloacetate, nitrite or oxygen (Mehler-reaction). The interrelationships between these poising mechanisms turn out to be strictly hierarchical. In the presence of antimycin A, an inhibitor of ferredoxin-dependent cyclic electron transport, the reduction of both, oxaloacetate and nitrite, but not that of oxygen restores CO₂ fixation. When oxaloacetate and nitrite are added at low concentrations simultaneously during steady-state CO₂ fixation, the reduction of nitrite is clearly preferred over the reduction of oxaloacetate, but CO₂ fixation is not influenced. Nitrite reduction is not decreased upon addition of oxaloacetate, but vice versa. This is due to the regulation of NADP-malate dehydrogenase activation by electron pressure via the ferredoxin/thioredoxin system on the one hand, and by the NADPH/(NADP+NADPH) ratio (anabolic reduction charge, ARC) on the other hand. Thus the closing of the malate valve prevents drainage of reducing equivalents from the chloroplast (1) when a low ARC indicates a high demand for NADPH in the stroma and (2) when nitrite reduction reduces the electron pressure at ferredoxin. The malate valve is opened when cyclic electron transport is inhibited by antimycin A. Under these conditions the rate of malate formation is higher than in the absence of the inhibitor even in the presence of oxaloacetate, thus indicating that the regulation of the malate valve functions at various redox states of the acceptor side of Photosystem I.Abbreviations ARC anabolic reduction charge (NADPH/(NADP+NADPH)) - Chl chlorophyll - DTT dithiothreitol; Fd-ferredoxin - NADP-MDH NADP-malate dehydrogenase - OAA oxaloacetate - PS photosystem - qN non-photochemical quenching - qP photochemical quenching - _E quantum efficiency of PS II Dedicated to Prof. Dr. Hans Walter Heldt on the occasion of his 60th birthday.     

Flexibility of coupling and stoichiometry of ATP formation in intact chloroplasts.

Since coupling between phosphorylation and electron transport cannot be measured directly in intact chloroplasts capable of high rates of photosynthesis, attempts were made to determine ATP/2 e ratios from the quamdum requirements of glycerate and phosphoglycerate reduction and from the extent of oxidation of added NADH via the malate shuttle during reduction of phosphoglycerate in light. These different approaches gave similar results. The quantum requirement of glycerate reduction, which needs 2 molecules of ATP per molecule of NADPH oxidized was found to be pH-dependent. 9-11 quanta were required at pH 7.6, and only about 6 at pH 7.0. The quantum requirement of phosphoglycerate reduction, which consumes ATP and NADPH in a 1/1 ratio, was about 4 both at pH 7.6 ant at 7.0. ATP/2 e ratios calculated from the quantum requirements and the extent of phosphoglycerate accumulation during glycerate reduction were usually between 1.2 and 1.4, occasionally higher, but they never approached 2. Although the chloroplast envelope is impermeable to pyridine nucleotides, illuminated chlrooplasts reduced added NAD via the malate shuttle in the absence of electron acceptors and also during the reduction of glycerate or CO2. When phosphoglycerate was added as the substrate, reduction of pyridine-nucleotides was replaced by oxidation and hydrogen was shuttled into the chloroplasts to be used for phosphoglycerate reduction even under light which was rate-limiting for reduction. This indicated formation of more ATP than NADPH by the electron transport chain. From the rates of oxidation of external NADH and of phosphoglycerate reduction at very low light intensities ATP/2e ratios were calculated to be between 1.1 and 1.4. Fully coupled chloroplasts reduced oxaloacetate in the light at rates reaching 80 and in some instances 130 mumoles times mg-1 chlorophyll times h-1 even though ATP is not consumed in this reaction. The energy transfer inhibitor phlorizin did not significantly suppress this reduction at concentrations which completely inhibited photosynthesis. Uncouplers stimulated oxaloacetate reduction by factors ranging from 1.5 to more than 10. Chloroplasts showing little uncoupler-induced stimulation of oxaloacetate reduction were highly active in photoreducing CO2. Measurements of light intensity dependence of quantum requirements for oxaloacetate reduction gave no indication for the existence of uncoupled or basal electron flow in intact chloroplasts. Rather reduction is brought about by loosely coupled electron transport. It is concluded that coupling of phosphorylation to electron transport in intact chloroplasts is flexible, not tight. Calculated ATP/2e ratios were obtained under con a decreENG     

The steady state activity of succinate dehydrogenase in the presence of opposing effectors

The extent of the deactivation of the mitochondrial succinate dehydrogenase by oxaloacetate is a function of the redox state of the enzyme. Oxidized enzyme is deactivated by much lower concentrations of oxaloacetate than those needed to deactivate reduced enzyme. An accurate method for measuring this relationship is the redox titration of the enzymic activity of succinate dehydrogenase, carried out in the presence of oxaloacetate. For each concentration of oxaloacetate a different redox titration curve was reported with the apparent mid-potential decreasing with increasing oxaloacetate. These results are compatible with a model which proposes that both oxidized and reduced enzymes can form the catalytically non-active complex with oxaloacetate, but that the complex formed the the oxidized enzyme is more stable than that formed by the reduced enzyme. When the oxaloacetate concentration is low, reduction of the enzyme will lower the fraction of the succinate dehydrogenase-oxaloacetate complex, a reaction which we observe as reductive activation of the enzyme. If this experiment is repeated in the presence of high concentration of oxaloacetate, no activation of the enzyme takes place, but the low stability of the reduced enzyme oxaloacetate complex is revealed by the rapid exchange of the enzyme-bound oxaloacetate with the free ligand. The rate of this exchange is extremely slow at high positive potential and becomes faster upon lowering of the poise potential. The reductive activation of the succinate dehydrogenase is regarded as a two step reaction. In the first step the reduced non-active complex releases the oxaloacetate and in the second step the active form of the enzyme is evolved. These two steps can be observed experimentally; Reductive activation at a redox potential higher than the mid-potential of the oxaloacetate-malate couple (minus 166 mV) is characterized by Ea = 18 Kca/mole, the final equilibrium level of activation decreases upon lowering of the temperature. Reduction activation of the enzyme at minus 240 mV is a very rapid reaction which goes to completion at all temperatures tested and has an activation energy of 12.5 Kcal/mole. The mechanism of the reductive activation and its possible role in the regulation of succinate dehydrogenase in the mitochondria is discussed.     

Characterization of malate dehydrogenase isozymes in wheat germ.

Malate dehydrogenase of wheat germ exists in multiple molecular forms (isozymes). Comparisons of some physical properties such as Stoke's radii, sedimentation constants, electrophoretic mobilities on polyacrylamide gel, chromatographic behaviors on DEAE-cellulose, stabilities to heat and iodacetamide inactivation, as well as kinetic parameters were described. When all these properties are considered together, at least five isozymes were found to associate with cytoplasm, mitochondria, glyoxysomes and proplastids of wheat germ. Wheat germ malate dehydrogenases are specific for the reduction of oxaloacetate and its monoesters. At least one carboxylic group of oxaloacetate must be free, in order to exhibit substrate activity, and maximum binding of oxaloacetate is achieved when both carboxylic groups are free. Soluble malate dehydrogenase and organelle-associated malate dehydrogenase can be differentiated readily in that the former can not utilize 4-ethyl oxaloaceode of ATP inhibition.     

Human recombinant glutamate oxaloacetate transaminase 1 (GOT1) supplemented with oxaloacetate induces a protective effect after cerebral ischemia

Blood glutamate scavenging is a novel and attractive protecting strategy to reduce the excitotoxic effect of extracellular glutamate released during ischemic brain injury. Glutamate oxaloacetate transaminase 1 (GOT1) activation by means of oxaloacetate administration has been used to reduce the glutamate concentration in the blood. However, the protective effect of the administration of the recombinant GOT1 (rGOT1) enzyme has not been yet addressed in cerebral ischemia. The aim of this study was to analyze the protective effect of an effective dose of oxaloacetate and the human rGOT1 alone and in combination with a non-effective dose of oxaloacetate in an animal model of ischemic stroke. Sixty rats were subjected to a transient middle cerebral artery occlusion (MCAO). Infarct volumes were assessed by magnetic resonance imaging (MRI) before treatment administration, and 24 h and 7 days after MCAO. Brain glutamate levels were determined by in vivo MR spectroscopy (MRS) during artery occlusion (80 min) and reperfusion (180 min). GOT activity and serum glutamate concentration were analyzed during the occlusion and reperfusion period. Somatosensory test was performed at baseline and 7 days after MCAO. The three treatments tested induced a reduction in serum and brain glutamate levels, resulting in a reduction in infarct volume and sensorimotor deficit. Protective effect of rGOT1 supplemented with oxaloacetate at 7 days persists even when treatment was delayed until at least 2 h after onset of ischemia. In conclusion, our findings indicate that the combination of human rGOT1 with low doses of oxaloacetate seems to be a successful approach for stroke treatment     

Fluorometric determination of alpha-ketosuccinamic acid in rat tissues

A method for the fluorometric determination of alpha-ketosuccinamic acid, the alpha-keto acid analog of asparagine, is described. The procedure involves the hydrolysis of alpha-ketosuccinamate to oxaloacetate by omega-amidase followed by NADH-dependent reduction of oxaloacetate to malate by malate dehydrogenase. A correction for endogenous oxaloacetate is made by using control samples lacking omega-amidase. Of the rat tissues investigated, liver contained the highest concentration, followed by kidney (53 +/- 6 (n = 11) and 18 +/- 3 (n = 3) mumol/kg wet wt, respectively). alpha-Ketosuccinamate was not detected in brain (less than 8 mumol/kg wet wt). Some chemical properties of alpha-ketosuccinamate were investigated. Concentrated solutions of sodium alpha-ketosuccinamate frozen for extended periods and the solid sodium salt of alpha-ketosuccinamate dimer heated to 130 degrees C are converted to at least 10 products by processes involving dimerization, dehydration, and decarboxylation. Isobutane chemical ionization mass spectral analysis (170-230 degrees C) of the free acid monomer yielded similar products. Many of the breakdown products were identified as di- and monoheterocyclic compounds, some of which are known to be of biological importance.     

Regulation of Photosynthetic Electron Transport in Intact Spinach Chloroplasts: II. MECHANISM OF SALT-INDUCED INCREASE IN OXALOACETATE PHOTOREDUCTION

The main focus of this study was to determine the mechanism by which certain exogenous monovalent salts stimulate rates of net O₂ evolution linked to oxaloacetate reduction in intact spinach chloroplasts. The influence of salts on the dicarboxylate translocator involved in the transport of oxaloacetate and on the activity and activation of the chloroplast enzyme NADP-malate dehydrogenase, which mediates electron transport to oxaloacetate, was examined. High concentrations of KCl (155 millimolar) increased the apparent K_m for oxaloacetate but did not significantly alter the maximal velocity of uptake. Likewise, external salts (KCl, MgCl₂, or KH₂PO₄) had minimal effects on the magnitude of light activation of NADP-malate dehydrogenase. In contrast, measurements of chloroplast NADP-malate dehydrogenase activity (after release by osmotic shock) showed a marked dependence on salt concentration. Rates were stimulated approximately 2-fold by both monovalent (optimally 75 millimolar) and divalent (optimally 20 millimolar) salts. It was inferred that the salt-induced increase in net rates of O₂ evolution linked to oxaloacetate reduction is due, at least in part, to stimulation of NADP-malate dehydrogenase caused by monovalent cation permeability of the chloroplast inner envelope membrane.     

Crystalline NAD/NADP-dependent malate dehydrogenase; the enzyme from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius

Malate dehydrogenase from Sulfolobus acidocaldarius has been purified 240-fold to apparent electrophoretic homogeneity. The enzyme shows a specific activity of 277 U/mg and crystallizes readily. The relative molecular mass of the native enzyme is estimated as 128,500 by ultracentrifugation. After cross-linking a relative molecular mass of 134,000 is found by sodium dodecyl sulfate gel electrophoresis. Malate dehydrogenase from S. acidocaldarius is composed of four subunits of identical size with a relative molecular mass of 34,000. Active-enzyme sedimentation in the analytical ultracentrifuge indicates that the tetramer is the catalytically active species. Kinetic studies in the direction of oxaloacetate reduction showed a Km for NADH of 4.1 microM and a Km for oxaloacetate of 52 microM. Oxaloacetate exhibits substrate inhibition at higher concentrations, L-malate, NAD and NADP were found to be product inhibitors. The enzymatic activity is inhibited by 2-oxoglutarate but not by the adenosine nucleotides AMP, ADP and ATP. Only low activity is detected in the direction of malate oxidation. Malate dehydrogenase from S. acidocaldarius utilizes both NADH and NADPH to reduce oxaloacetate. The enzyme shows A-side stereospecificity for both nicotinamide dinucleotides.     

Oxaloacetate deficiency in MCT-induced ketogenesis.

This study was an attempt to discover whether a deficiency in hepatic oxaloacetate can explain the acceleration of ketogenesis observed after the ingestion of medium-chain triglycerides (MCT, constituent fatty acids from C8 to C12). The method of investigation used consisted in supplying oxaloacetate (by intraperitoneal injection of oxaloacetate, aspartate, or L-tryptophan) to rats that had ingested MCT. The indirectly given oxaloacetate caused a decrease in ketone body levels in the liver. The stimulation of ketogenesis induced by an exogenous supply of MCT is therefore at least partly due to a deficiency of oxaloacetate. The results show that this can be explained both by a leakage of this metabolite into the pathway of gluconeogenesis and by its reduction into malate. Since the acetyl-CoA derived from oxidized medium-chain fatty acids cannot enter into the Krebs cycle, it is diverted to the production of ketone bodies.     

Regulation of succinate oxidation by NAD+ in mitochondria purified from potato tubers

NAD⁺ supplied to purified Solanum tuberosum mitochondria caused progressive inhibition of succinate oxidation in State 3. This inhibition was especially pronounced at alkaline pH and at low succinate concentrations. Glutamate counteracted the inhibition. NAD⁺ promoted oxaloacetate accumulation in State 3; supplied oxaloacetate inhibited O₂ uptake in the presence of succinate much more severely in State 3 than in State 4. NAD reduction linked to succinate oxidation by ATP-dependent reverse electron transport was likewise inhibited by oxaloacetate. We conclude that NAD⁺-induced inhibition of succinate oxidation is due to an inhibition of succinate dehydrogenase resulting from increased accumulation of oxaloacetate generated from malate oxidation via malate dehydrogenase. The results are discussed in the context of the known regulatory characteristics of plant succinate dehydrogenase.     

Interaction of ligands with pig heart citrate synthase: conformational changes and catalysis.

The fluorescence polarization of 8-hydroxypyrene (1,3,6)trisulfonate (HPT) increases upon interaction with pig heart citrate synthase. Titration of HPT with increasing concentrations of citrate synthase exhibits a hyperbolic saturation behavior, from which the dissociation constant of the enzyme-HPT complex (3.64 +/- 0.3 microM) was determined. The enzyme-HPT interaction is competitively inhibited by oxaloacetate (but not affected by acetyl CoA) with a Ki of 4.3 +/- 1.8 microM. This value is similar to the dissociation constant (Kd = 4.5 +/- 1.6 microM) for the enzyme-oxalocetate complex (determined in the absence of any effector ligand), as well as to the Km for oxaloacetate (3.9 +/- 0.7 microM) in a steady-state citrate synthase catalyzed reaction at a saturating concentration of acetyl CoA. However, the dissociation constant for the citrate synthase-oxaloacetate complex determined by the urea denaturation method is at least 25-fold lower than those determined by the other methods. This suggests an effector role of urea in strengthening the enzyme-oxaloacetate interaction. At low nondenaturing concentrations, urea inhibits the citrate synthase catalyzed reaction in an uncompetitive manner with respect to oxaloacetate, i.e., the Km for oxaloacetate decreases with an increase in urea concentration. This further suggests that urea stabilizes the interaction between citrate synthase and oxaloacetate. The effect of urea is specific for the substrate oxaloacetate, and not for the substrate analogue, HPT, although both these ligands bind citrate synthase with equal affinities, and protect the enzyme against thermal denaturation with equal magnitudes. The results presented herein are discussed in the light of known conformational states of the enzyme.     

Mechanism of citrate metabolism by an oxaloacetate decarboxylase-deficient mutant of Lactococcus lactis IL1403

Citrate metabolism in resting cells of Lactococcus lactis IL1403(pFL3) results in the formation of two end products from the intermediate pyruvate, acetoin and acetate (A. M. Pudlik and J. S. Lolkema, J. Bacteriol. 193:706-714, 2011). Pyruvate is formed from citrate following uptake by the transporter CitP through the subsequent actions of citrate lyase and oxaloacetate decarboxylase. The present study describes the metabolic response of L. lactis when oxaloacetate accumulates in the cytoplasm. The oxaloacetate decarboxylase-deficient mutant ILCitM(pFL3) showed nearly identical rates of citrate consumption, but the end product profile in the presence of glucose shifted from mainly acetoin to only acetate. In addition, in contrast to the parental strain, the mutant strain did not generate proton motive force. Citrate consumption by the mutant strain was coupled to the excretion of oxaloacetate, with a yield of 80 to 85%. Following citrate consumption, oxaloacetate was slowly taken up by the cells and converted to pyruvate by a cryptic decarboxylase and, subsequently, to acetate. The transport of oxaloacetate is catalyzed by CitP. The parental strain IL1403(pFL3) containing CitP consumed oxaloacetate, while the original strain, IL1403, not containing CitP, did not. Moreover, oxaloacetate consumption was enhanced in the presence of L-lactate, indicating exchange between oxaloacetate and L-lactate catalyzed by CitP. Hence, when oxaloacetate inadvertently accumulates in the cytoplasm, the physiological response of L. lactis is to excrete oxaloacetate in exchange with citrate by an electroneutral mechanism catalyzed by CitP. Subsequently, in a second step, oxaloacetate is taken up by CitP and metabolized to pyruvate and acetate.     

Kinetic analysis of the reaction mechanism of oxaloacetate decarboxylase from Klebsiella aerogenes

The mechanism of oxaloacetate decarboxylase of Klebsiella aerogenes was investigated by enzyme kinetic methods. The activity of the decarboxylase was strictly dependent on the presence of Na+ or Li+ ions. For Li+ the Km was about 17 times higher and the Vmax about 4 times lower than for Na+. No activity was detectable at Na+ concentrations less than 5 microM. The curve for initial velocity versus Na+ concentration was hyperbolic. Initial velocity patterns with oxaloacetate or Na+ as the varied substrate at various fixed concentrations of the cosubstrate produced a pattern of parallel lines which is characteristic for a ping-pong mechanism. Product inhibition by pyruvate was competitive versus oxaloacetate and noncompetitive versus Na+. Oxalate, a dead-end inhibitor, was competitive versus oxaloacetate and uncompetitive versus Na+. The inhibition patterns are not consistent with a ping-pong mechanism comprising a single catalytic site but are analogous to kinetic patterns observed with the related biotin enzyme transcarboxylase, for which a catalytic mechanism at two different and independent sites has been demonstrated. The kinetic and other data support an oxaloacetate decarboxylase mechanism at two different sites of the enzyme with the intermediate formation of a carboxybiotin-enzyme complex. The first site is the carboxyltransferase which is localized on the alpha chain and the second site is the carboxybiotin-enzyme decarboxylase which is probably localized on the beta and/or gamma subunit. Binding studies with oxalate indicated that this is bound with high affinity to the alpha chain. The affinity was not affected by Na+ or by complex formation with the beta and gamma subunits. Oxalate protected the decarboxylase from heat inactivation but not from tryptic hydrolysis. The carboxybiotin-enzyme intermediate prepared from oxaloacetate decarboxylase with high specific activity was rapidly decarboxylated in the presence of Na+ ions alone. The effect of pyruvate on this reaction, noted previously, probably results from inhomogeneity of the enzyme preparation used which contained a considerable amount of free alpha subunits.     

The NMR study of succinate formation from exogenous precursors in anaerobic rat heart mitochondria

Succinate formation during incubation of isolated rat heart mitochondria with exogenous precursors, malate, alpha-ketoglutarate, oxaloacetate and L-glutamate was studied in the absence of aeration. The formation of succinate, the end product of the tricarboxylic acid cycle, occurs via two pathways: through reduction of oxaloacetate or malate and via oxiation of alpha-ketoglutarate. The highest rate of succinate synthesis was observed when mitochondria were incubated with a mixture of 5 mM L-glutamate and 10 mM oxaloacetate, i.e., when both routes were used simultaneously. The [U-13C]succinate/succinate and aspartate/succinate ratios were equal to 2, when mitochondria were incubated with 5 mM [U-13C]glutamate and 10 mM oxaloacetate. Therefore, the amount of succinate formed from [13C]alpha-ketoglutarate via transamination of [13C]glutamate with oxaloacetate exceeds twice succinate production from oxialoacetate. These data suggest that GTP formation in the succinic thiokinase reaction should exceed twice the ATP yield coupled with NADH-dependent reduction of fumarate.     

Factors affecting the translocation of oxaloacetate and l-malate into rat liver mitochondria

1. The rates of translocation of oxaloacetate and l-malate into rat liver mitochondria were measured by a direct spectrophotometric assay. 2. Penetration obeyed Michaelis-Menten kinetics, and apparent K(m) values were 40mum for oxaloacetate and 0.13mm for l-malate. 3. Arrhenius plots of the temperature-dependence of rates of penetration gave activation energies of +10kcal./mole for oxaloacetate and +8kcal./mole for l-malate. 4. The translocation of both oxaloacetate and l-malate was competitively inhibited by d-malate, succinate, malonate, meso-tartrate, maleate and citraconate. The K(i) values of these inhibitors were similar for the penetration of both oxaloacetate and l-malate. 5. Rates of penetration were stimulated by NNN'N'-tetramethyl-p-phenylenediamine dihydrochloride plus ascorbate under aerobic conditions or by ATP under anaerobic conditions. 6. The energy-dependent stimulation of translocation was abolished by uncouplers of oxidative phosphorylation. Oligomycin A, aurovertin, octyl-guanidine and atractyloside prevented the stimulation by ATP, but did not inhibit the stimulation by NNN'N'-tetramethyl-p-phenylenediamine dihydrochloride plus ascorbate. 7. Mitochondria prepared in the presence of ethylene-dioxybis(ethyleneamino)tetra-acetic acid did not exhibit the energy-dependent translocation, but this could be restored by the addition of 50mum-calcium chloride. 8. Valinomycin or gramicidin plus potassium chloride enhanced the energy-dependent translocation of oxaloacetate and l-malate. 9. Addition of oxaloacetate stimulated the adenosine triphosphatase activity of the mitochondria, and the ratio of ;extra' oxaloacetate translocation to ;extra' adenosine triphosphatase activity was 1.6:1. 10. Possible mechanisms for the energy-dependent entry of oxaloacetate and l-malate into mitochondria are discussed in relation to the above results.