Convenient rapid determination of picomole amounts of oxaloacetate and aspartate

The assay of oxaloacetate based on the citrate synthase catalyzed conversion of labeled acetyl-CoA to citrate has been greatly simplified by the development of a charcoal separation method for the selective adsorption of acetyl-CoA. An application of this procedure for the determination of oxaloacetate in rat livers is described. By coupling to glutamate oxaloacetate transaminase, the procedure enables determination of aspartate. It allows also a sensitive assay of glutamate oxaloacetate transaminase activity.     

Oxaloacetate keto-enol tautomerase from bovine heart mitochondrial matrix

Bovine heart mitochondrial matrix contains two proteins possessing the oxaloacetate keto-enol tautomerase (EC 5.3.2.2) activity. A procedure for the isolation and purification of the enzymes to an electrophoretically homogeneous state has been developed. The purified proteins have molecular masses of 37 kD and 80 kD and catalyze the keto-enol oxaloacetate tautomerization reaction with the turnover numbers of approximately 3000 and approximately 2000 min-1. The both enzymes were found to differ significantly in all their physicochemical and kinetic properties. Fractionation of rat liver mitochondria revealed that the oxaloacetate keto-enol tautomerase activity is predominantly localized in the mitochondrial matrix. The essential role of oxaloacetate keto-enol tautomerase in the operation of the Krebs cycle is discussed.     

Mammalian and avian liver phosphoenolpyruvate carboxykinase. Alternate substrates and inhibition by analogues of oxaloacetate

Phosphoenolpyruvate carboxykinase from chicken liver mitochondria and rat liver cytosol catalyzes the phosphorylation of alpha-substituted carboxylic acids such as glycolate, thioglycolate, and DL-beta-chlorolactate in reactions with absolute requirements for divalent cation activators. 31P NMR analysis of the reaction products indicates that phosphorylation occurs at the alpha-position to generate the corresponding O- or S-bridged phosphate monoesters. In addition, the enzymes catalyze the bicarbonate-dependent phosphorylation of hydroxylamine. The chicken liver enzyme also catalyze the bicarbonate-dependent phosphorylation of hydroxylamine. The chicken liver enzyme also catalyzes the bicarbonate-dependent phosphorylation of fluoride ion. The kappa cat values for these substrates are 20-1000-fold slower than the kappa cat for oxaloacetate. Pyruvate and beta-hydroxypyruvate are not phosphorylated, since the enzyme does not catalyze the enolization of these compounds. Oxalate, a structural analogue of the enolate of pyruvate, is a competitive inhibitor of phosphoenolpyruvate carboxykinase (Ki of 5 microM) in the direction of phosphoenolpyruvate formation. Oxalate is also an inhibitor of the chicken liver enzyme in the direction of oxaloacetate formation and in the decarboxylation of oxaloacetate. The chicken liver enzyme is inhibited by beta-sulfopyruvate, an isoelectronic analogue of oxaloacetate. The extensive homologies between the reactions catalyzed by phosphoenolpyruvate carboxykinase and pyruvate kinase suggest that the divalent cation activators in these reactions may have similar functions. The substrate specificity indicates that phosphoenolpyruvate carboxykinase decarboxylates oxaloacetate to form the enolate of pyruvate which is then phosphorylated by MgGTP on the enzyme.     

Does the transport of oxaloacetate across the inner mitochondrial membrane during gluconeogenesis require carrier proteins other than those used in the malate-aspartate shuttle?

When authors of general biochemistry textbooks mention carrier proteins involved in the transport of oxaloacetate across the inner mitochondrial membrane for gluconeogenesis, they only make use of the two transporters involved in the malate-aspartate shuttle. As a result of only using the malate-2-oxoglutarate and the glutamate-aspartate carrier proteins, I show that the reaction describing the overall process is unsatisfactory since, in addition to oxaloacetate being transported from the mitochondrial matrix to the cytosol, 2-oxoglutarate is also transported in the reverse direction. I therefore point out that, if only oxaloacetate is to be transported from the mitochondrial matrix to the cytosol, then it is necessary to also make use of other carrier proteins in the inner mitochondrial membrane, namely, the dicarboxylate transporter and the phosphate transporter.     

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.     

Isolation and properties of oxaloacetate keto-enol-tautomerases from bovine heart mitochondria

Two highly purified proteins with quite different properties capable of oxaloacetate keto-enol-tautomerase activity (oxaloacetate keto-enol-isomerase, EC 5.3.2.2) were isolated from the bovine heart mitochondrial matrix. The first protein has an apparent molecular mass of 37 kDa as determined by SDS-gel electrophoresis and Sephacryl SF-200 gel filtration. It is quite stable upon storage at 40 degrees C and reaches the maximal catalytic activity at pH 8.5 with a half-maximal activity at pH 7.0. The enzyme is specifically inhibited by oxalate and diethyloxaloacetate. When assayed in the enol----ketone direction at 25 degrees C (pH 9.0), the enzyme obeys a simple substrate saturation kinetics with Km and Vmax values of 45 microM and 74 units per mg of protein, respectively; the latter value corresponds to the turnover number of 2700 min-1. The second protein has an apparent molecular mass of 80 kDa as determined by SDS-gel electrophoresis and Sephacryl SF-300 gel filtration. The enzyme is rapidly inactivated at 40 degrees C and shows a sharp pH optimum of activity at pH 9.0. The enzyme can be completely protected from thermal inactivation by oxaloacetate and dithiothreitol. The kinetic parameters of the enzyme as assayed in the enol----ketone direction at 25 degrees C (pH 9.0) are: Km = 220 microM and Vmax = 20 units per mg of protein; the latter corresponds to the turnover number of 1600 min-1. The enzyme activity is specifically inhibited by maleate and pyrophosphate. About 30% of the total oxaloacetate tautomerase activity in crude mitochondrial matrix is represented by the 37 kDa enzyme and about 70% by the 80 kDa protein.     

Quantitation of aspartate aminotransferase isoenzymes after electrophoretic separation

A scheme for the quantitative detection of aspartate aminotransferase isoenzymes and multiple forms after electrophoretic separation is described. Glutamate generated from the aminotransferase reaction is quantitated by using the glutamate dehydrogenase/diaphorase-coupled enzyme system to form a formazan dye. Product inhibition of aspartate aminotransferase by oxaloacetate is prevented by including oxaloacetate decarboxylase in the overlay reagent. Results compare favorably with those of an immunochemical precipitation procedure. The method can also be used to detect quantitatively subforms and atypical forms (genetic variants, immunoglobulin-enzyme complexes) of aspartate aminotransferase.     

A novel, definitive test for substrate channeling illustrated with the aspartate aminotransferase/malate dehydrogenase system.

A novel method is presented that establishes definitively the existence or nonexistence of direct metabolite transfer between consecutive enzymes in a metabolic sequence. The procedure is developed with the specific example of channeling of oxaloacetate between Escherichia coli aspartate aminotransferase (AATase) and malate dehydrogenase (MDH). The assay is carried out in the presence of a large excess of inactive variants of AATase. These mutants would outcompete the much smaller quantities of wild-type AATase for any docking sites on MDH and thus decrease the rate of the coupled L-aspartate to oxaloacetate to malate sequence only if the direct metabolite transfer mechanism is operative. The results show that oxaloacetate is not transferred directly from AATase to MDH because no decrease in rate was observed in the presence of approximately 100 microM inactive mutants. This concentration is 10 times the physiological AATase concentration, which was determined in this work. The methodology can be applied generally.     

Subcellular Localization of Oxaloacetate Decarboxylase and Its Isolation from Maize Leaves

The activity of oxaloacetate decarboxylase was revealed in leaves of a C₄ plant, maize (Zea mays L.). This activity was unrelated to decarboxylase activities of other enzymes, e.g., NAD-malate dehydrogenase (EC 1.1.1.38) or NADP-malate dehydrogenase (EC 1.1.1.40), and was located in chloroplasts (83.1%). Using a four-step purification procedure, an electrophoretically pure enzyme preparation of oxaloacetate decarboxylase was obtained from maize leaves. The specific activity of the enzyme was 3.150 EU/mg protein, the factor of purification was 40.4, and the yield was 11.0%. The enzyme exhibited Michaelis–Menten kinetics with K _m for oxaloacetate 30 ± 5 M and pH optimum 7.1 ± 0.5. The metabolite-mediated regulation of oxaloacetate decarboxylase activity has been investigated. It is found that sodium chloride (1.0 mM) activates the enzyme, whereas ATP inhibits the enzyme activity.     

A sensitive multienzymatic assay for the measurement of pyruvate, dihydroxyacetone phosphate, oxaloacetate, and acetoacetate in clear extracts from biological samples.

A multienzymatic method for the measurement of pyruvate, dihydroxyacetone phosphate, oxaloacetate, and acetoacetate is presented. The determination procedure is considered suitable because it is simple, sensitive, and its advantages could be demonstrated by comparison with the original methods.     

The effect of opposing effectors on activation level of succinate dehydrogenase: equilibrium and kinetic studies.

The activation of mitochondrial succinate dehydrogenase by various activators is a result of dissociation of oxaloacetate tightly bound to the nonactive enzyme. But, quantitative correlation between the effector concentrations and the active fraction of the enzyme was not at hand. In this study we measured the level of active succinate dehydrogenase equilibrated with a wide range of opposing effectors: oxaloacetate (1-500 muM) and activator (0.02-1.5 M NaBr). The results are compatible with a model assuming two stable forms of the enzyme: a nonactive enzyme-oxaloacetate complex and an active enzyme free of oxaloacetate. The active form is stabilized by binding two Br- and one H+. The rate of activation (ka) and exchange between enzyme bound and free oxaloacetate k(ex) were measured. Both ka and kex are hyperbolically dependent on Br- concentration but differ in magnitude and pH dependence. kex at infinite Br- concentration is pH dependent but ka is not. The two reactions, activation and exchange, also differ in their activation energy bein 32 and 21.5 kcal/mol, respectively. It is concluded that, in the course of activation, Br- interacts at two distinct steps. First to produce a ternary, nonactive [enzyme-oxaloacetate-Br-] complex. From this complex, oxaloacetate dissociates and the oxaloacetate-free enzyme assumes its active form. Finally, the active enzyme is stabilized by binding another Br-. The rate-limiting step in deactivation is binding of oxaloacetate to active enzyme. The complex formed undergoes a very rapid transformation to the stable nonactive form. This pathway, under certain conditions, can reverse its direction and contribute to the overall rate of activation. It is suggested that the equilibrium between the two stable forms of the enzyme can be reached by two parallel pathways, each contributing independently to the observed rate of activation, while the final equilibrium is determined by the free energy between the products and the reactants.     

The activity of phosphoenolpyruvate carboxykinase in rat tissues. Assay techniques and effects of dietary and hormonal changes

1. Phosphoenolpyruvate carboxykinase was assayed by three methods: (i) incorporation of H(14)CO(3) (-) into oxaloacetate: (ii) conversion of oxaloacetate into phosphoenolpyruvate, subsequently assayed enzymically; and (iii) transfer of (32)P from [gamma-(32)P]GTP to oxaloacetate. 2. Enzyme activity is increased in liver and epididymal adipose tissue in alloxan-diabetes and starvation, and in kidney in starved, acidotic and steroid-treated animals. 3. The ratios of the ;back' to the ;forward' reactions in liver, kidney and epididymal adipose tissue are different and characteristic of each tissue; they differ markedly from values reported for the purified mitochondrial enzyme. 4. The ratio of the ;back' to ;forward' reaction in any one tissue is constant in adrenalectomized, diabetic, acidotic and steroid-treated animals. 5. In starved animals, the ratio is increased in liver and kidney, but decreased in epididymal adipose tissue. 6. Administration of l-tryptophan results in an acute (1h) increase in activity measured in the ;forward' direction alone in liver and epididymal adipose tissue, but not in kidney.     

Aspartate 203 of the oxaloacetate decarboxylase beta-subunit catalyses both the chemical and vectorial reaction of the Na+ pump.

We report here a new mode of coupling between the chemical and vectorial reaction explored for the oxaloacetate decarboxylase Na+ pump from Klebsiella pneumoniae. The membrane-bound beta-subunit is responsible for the decarboxylation of carboxybiotin and the coupled translocation of Na+ ions across the membrane. The biotin prosthetic group which is attached to the alpha-subunit becomes carboxylated by carboxyltransfer from oxaloacetate. The two conserved aspartic acid residues within putative membrane-spanning domains of the beta-subunit (Asp149 and Asp203) were exchanged by site-directed mutagenesis. Mutants D149Q and D149E retained oxaloacetate decarboxylase and Na+ transport activities. Mutants D203N and D203E, however, had lost these two activities, but retained the ability to form the carboxybiotin enzyme. Direct participation of Asp203 in the catalysis of the decarboxylation reaction is therefore indicated. In addition, all previous and present data on the enzyme support a model in which the same aspartic acid residue provides a binding site for the metal ion catalysing its movement across the membrane. The model predicts that asp203 in its dissociated form binds Na+ and promotes its translocation, while the protonated residue transfers the proton to the acid-labile carboxybiotin which initiates its decarboxylation. Strong support for the model comes from the observation that Na+ transport by oxaloacetate decarboxylation is accompanied by H+ transport in the opposite direction. The inhibition of oxaloacetate decarboxylation by high Na+ concentrations in a pH-dependent manner is also in agreement with the model.     

Oxaloacetate decarboxylase from Pseudomonas stutzeri: purification and characterization

Oxaloacetate decarboxylase (OXAD), the enzyme that catalyzes the decarboxylation of oxaloacetate to pyruvic acid and carbon dioxide, was purified 245-fold to homogeneity from Pseudomonas stutzeri. The three-step purification procedure comprised anion-exchange chromatography, metal-chelate affinity chromatography, and biomimetic-dye affinity chromatography. Estimates of molecular mass from sodium dodecyl sulfate-polyacrylamide gel electrophoresis and native high-performance gel-filtration liquid chromatography were, respectively, 63 and 64 kDa, suggesting a monomeric protein. OXAD required for maximum activity divalent metal cations such as Mn2+ and Mg2+ but not monovalent cations. The enzyme is not inhibited by avidin, but is competitively inhibited by adenosine 5'-diphosphate, acetic acid, phosphoenolpyruvate, malic acid, and oxalic acid. Initial velocity, product inhibition, and dead-end inhibition studies suggested a rapid-equilibrium ordered kinetic mechanism with Mn2+ being added to the enzyme first followed by oxaloacetate, and carbon dioxide is released first followed by pyruvate. Inhibition data as well as pH-dependence profiles and kinetic parameters are reported and discussed in terms of the mechanism operating for oxaloacetate decarboxylation.     

Kinetic mechanism of NADP-malic enzyme from maize leaves

The kinetic mechanism of NADP-dependent malic enzyme purified from maize leaves was studied in the physiological direction. Product inhibition and substrate analogues studies with 3 aminopyridine dinucleotide phosphate and tartrate indicate that the enzyme reaction follows a sequential ordered Bi-Ter kinetic mechanism. NADP is the leading substrate followed by l-malate and the products are released in the order of CO₂, pyruvate and NADPH. The enzyme also catalyzes a slow, magnesium-dependent decarboxylation of oxaloacetate and reduction of pyruvate and oxaloacetate in the presence of NADPH to produce l-lactate and l-malate, respectively.     

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.     

Oxaloacetate permeation in rat kidney mitochondria: pyruvate/oxaloacetate and malate/oxaloacetate translocators

The mechanism of oxaloacetate efflux from rat kidney mitochondria has been investigated in view of its possible role both in gluconeogenesis and in transferring cytosolic reducing equivalents into mitochondria. Thus reconstruction of the malate/oxaloacetate shuttle made possible by the oxaloacetate carrier has been made. Moreover the existence of a separate translocator able to allow a bidirectional alpha-cyanocinnamate-insensitive pyruvate/oxaloacetate exchange has been ascertained. This carrier is specific of gluconeogenetic organs in particularly of kidney, where it shows a marked affinity for pyruvate (Km = 0.45 mM and Vmax = 38 nmoles oxaloacetate effluxed/min X mg mitochondrial protein at 20 degrees C). Some features of both pyruvate/oxaloacetate and malate/oxaloacetate exchanges are also described.     

Anaerobic metabolism of goldfish,Carassius auratus (L.). Influence of anoxia on mass-action ratios of transaminase reactions and levels of ammonia and succinate

Summary Changes in the concentrations of ammonia, glutamate, alanine, aspartate, -ketoglutarate, oxaloacetate and succinate were measured in freeze-clamped lateralred muscle, dorsal white muscle and liver, and in rapidly cooled blood of goldfish after 12 h of anoxia. Alanine accumulation, succinate accumulation and aspartate depletion are observed in all tissues examined; in the liver the concentrations of glutamate increase and those of ammonia decrease. The mass-action ratio of the glutamate-pyruvate transaminase-catalyzed reaction stays within one order of magnitude from thermodynamic equilibrium in the direction of alanine formation. The mass-action ratio of the glutamate-oxaloacetate transaminase reaction is far from equilibrium when measured oxaloacetate concentrations are used. When levels of free oxaloacetate are calculated from LDH and MDH equilibrium constants, the mass-action ratio of glutamate-oxaloacetate transamination is close to equilibrium in the direction of aspartate formation. Since neither alanine nor glutamate decreases, and since ammonia gradients suggest a continuous ammonia production in all tissues examined, anaerobic proteolysis is assumed. A possible coupling between amino acid catabolism and ethanol production is discussed.Abbreviations ALA alanine - ASP aspartate - EDTA ethylene diamine tetraacetate - FP _ox oxidated flavoprotein - FP _red reduced flavoprotein - FUM fumarate - GLU glutamate - GOT glutamate oxaloacetate transaminase - GPT glutamate pyruvate transaminase - IMP inosine monophosphate - KG -ketoglutarate - LDH lactate dehydrogenase - MAL malate - MAR mass action ratio - MDH malate dehydrogenase - OAA oxaloacetate - PYR pyruvate - sAMP adenylosuccinate - SDH succinate dehydrogenase - SUCC succinate     

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.     

Unidirectional inhibition of phosphoenolpyruvate carboxykinase from Rhodospirillum rubrum by ATP

The kinetic and regulatory properties of partially purified phosphoenolpyruvate (PEP) carboxykinase (EC 4.1.1.32) from Rhodospirillum rubrum were studied. The enzyme was active with guanosine-and inosinephosphates and must thus be classified as GTP (ITP): oxaloacetate carboxylyase (transphosphorylating). In the direction of oxaloacetate-formation, the enzyme was strongly inhibited by ATP (K_i=0.03 mM). ITP, UTP, CTP and GTP were less inhibitory. The inhibition was competitive with respect to GDP or IDP, but not with respect to PEP. In the direction of PEP-synthesis, the enzyme was not inhibited, but rather activated by ATP.