Radiochemical assay of adenylosuccinase: demonstration of parallel loss of activity toward both adenylosuccinate and succinylaminoimidazole carboxamide ribotide in liver of patients with the enzyme defect

A radiochemical assay for adenylosuccinase, an enzyme which intervenes twice in the biosynthesis of adenine nucleotides, has been developed. The two substrates of the enzyme, succinylaminoimidazole carboxamide ribotide (SAICAR) and adenylosuccinate (S-AMP), were synthesized in radioactive form by incubating [2,3-14C]fumarate and, respectively, AICAR and AMP with partially purified adenylosuccinase from yeast. Enzyme activities were determined by measuring the release of labeled fumarate after its separation from the substrate by chromatography on polyethyleneimine thin-layer plates. The ratio of the activity of adenylosuccinase measured with SAICAR compared to that with S-AMP was about 1 in crude extracts of rat liver and muscle and around 0.5 in human liver. In rat and human liver, but not in rat muscle, 20 to 40% of both activities of adenylosuccinase were lost after freezing at -80 degrees C followed by thawing. In the liver of patients with adenylosuccinase deficiency, in whom the deficiency had hitherto been measured only with S-AMP, the activity of the enzyme toward S-AMP and SAICAR was found to be lost in parallel. This is in accordance with the finding that both SAICA-riboside and succinyladenosine accumulate in adenylosuccinase-deficient patients.     

Staining of argininosuccinate lyase activity in polyacrylamide gel.

A procedure for the direct staining of argininosuccinate lyase activity in polyacrylamide gel is described. The method was based on coupling one of the enzymatic products fumarate with fumarase and malic enzyme catalyzed reactions. Fumarate was first converted to L-malate by fumarase. Malic enzyme then catalyzed the oxidative decarboxylation of L-malate to give CO2 and pyruvate with concomitant reduction of NADP+ to NADPH. Finally the reducing power of NADPH was coupled to phenazine methosulfate and in turn to nitroblue tetrazolium yielding a deeply colored insoluble formazan which may be quantitized or semiquantitized by densitometer.     

S-(1,2-dicarboxyethyl)glutathione and activity for its synthesis in rat tissues

The contents of S-(1,2-dicarboxyethyl)glutathione (DCE-GS) in several tissues of rat were determined by HPLC. The peptide was present at concentrations (nmol/g tissue) of 119 in lens, 71.6 in liver, and 27.4 in heart. It was, however, not detected in spleen, kidney, cerebrum, or cerebellum. In rat liver, DCE-GS was located primarily in the cytosolic fraction. The substrates for the enzymic synthesis of DCE-GS were GSH and L-malate. In rats, the DCE-GS-synthesizing activity was found to be highest in the liver and in the cytosol of rat liver subcellular fractions. The DCE-GS-synthesizing enzyme was partially purified from rat liver cytosolic fraction by ammonium sulfate fractionation, Phenyl Superose chromatography, hydroxyapatite chromatography, and gel filtration. The molecular mass of the enzyme was estimated to be 53 kDa by gel filtration and SDS-PAGE, showing it to be a monomeric protein. The Km values for GSH and L-malate were 2.3 and 4.0 mM at 37 degrees C, respectively. The enzyme did not utilize 1-chloro-2,4-dinitrobenzene, 1,2-dichloro-4-nitrobenzene, p-nitrophenyl bromide, trans-4-phenyl-3-buten-2-one, or p-nitrobenzyl chloride, which were substrates for previously characterized glutathione S-transferases. The isolated enzyme preparation showed no fumarase activity, which supported the conclusion that the formation of DCE-GS was not the result of a nonenzymic reaction following the synthesis of fumarate from L-malate by the isolated enzyme. The N-terminal amino acid of this polypeptide was presumably blocked since no sequence was obtained by automatic sequencing after electro-blotting onto a siliconized-glass fiber (SGF) sheet.     

Inhibition of the malic enzyme from Acinetobacter calcoaceticus by NADPH and NADH]

The malic enzyme enriched from Acinetobacter calcoaceticus is inhibited by NADPH and NADH. The inhibition afforded by the reduced coenzymes is not affected by NAD+, AMP and 3'.5'-AMP. Against L-malate, NADPH inhibits the enzyme in a noncompetitive linear fashion (Ki = 1.5 x 10(-4) M), against NADP+, competitively linearly (Ki = 5.0 x 10(-5) M). While NADPH acted as a product inhibitor, NADH seems to be an allosteric effector of the malic enzyme, because with L-malate as the variable substrate in the double reciprocal plot, a nonlinear curve is obtained.     

Carbon metabolism in germinating Ricinus communis cotyledons. Purification, characterization and developmental profile of NADP-dependent malic enzyme

The possible implication of NADP-dependent malic enzyme (NADP-ME; L-malate:NADP oxidoreductase [oxaloacetate-decarboxylating], EC 1.1.1.40) in fatty acid synthesis was examined in Ricinus communis L. cotyledons, NADP-ME catalyses the conversion of L-malate to pyruvate and NADPH, potential substrates for fatty acid synthesis. NADP-ME activity and protein levels were monitored during germination, up to 20 days postimbibition. The developmental profile showed a peak in activity (6 times with respect to the basal value) and immunoreactive protein (a single 72-kDa band using anti-maize NADP-ME antibodies) around day 7. The enzyme was partially purified (41-fold) and its kinetics characterized. The optimum pH was around 7.1. K_m values for L-malate and NADP⁺ were 0.68 m M and 8.2 μ M respectively. The enzyme used Mg²⁺ or Mn²⁺ as essential cofactors. Several metabolites were assayed as potential enzyme modulators. Succinate, CoA, acetyl-CoA and palmitoyl-CoA were activators of NADP-ME, at saturating or sub-saturating substrate concentrations, K² values for CoA and derivative compounds were in the micromolar range (i.e., 0.8 μ M for acetyl-CoA). No significant effects were obtained with other Krebs cycle intermediates and amino acids (i.e. 2-oxoglutarate, glutamate, glutamine, fumarate). The activity was 29 times higher in the forward (decarboxylating) direction compared to the reverse direction. These results hint at cotyledon NADP-ME behaving as a regulatory enzyme in R. communis . Its activity is responsive to metabolites of the fatty acid synthesis pathway, and thus a role in this metabolism is suggested.     

Fermentation of fumarate and L-malate by Clostridium formicoaceticum.

The fermentation of fumarate and L-malate by Clostridium formicoaceticum was investigated. Growing and nongrowing cells degraded fumarate by dismutation to succinate, acetate, and CO2; on the other hand, only small amounts of succinate were detected when the organism was grown on L-malate. This dicarboxylic acid was mainly converted to acetate and CO2. The fermentation balances were modified if bicarbonate or formate were present in the medium. When C. formicoaceticum was grown in the presence of both dicarboxylic acids, fumarate was consumed before L-malate. The latter was mainly converted to acetate, whereas fumarate was fermented to acetate and succinate. Molar growth yields were determined to be 6 g of dry weight per mol of fumarate and 8 g of dry weight per mol of L-malate fermented.     

Oxidized NADP as a potential active-site-directed reagent of pigeon liver malic enzyme.

Pigeon liver malic enzyme (malate dehydrogenase (decarboxylating), EC 1.1.1.40) was reversibly inactivated by periodate-oxidized NADP in a biphasic manner. The reversibility could be made irreversible by treating the modified enzyme with sodium borohydride. The inactivation showed saturation kinetics and could be prevented by nucleotide (NADP or NADPH). Fully protection was afforded by the combination of NADP, Mn²⁺ and L-malate. Oxidized NADP was also found to be a coenzyme and noncompetitive inhibitor of L-malate in the oxidative decarboxylase reaction catalyzed by malic enzyme.     

Mechanisms of desorption and adsorption of liver cytosolic fumarase to cellular membranous components.

The cytosolic fumarase [EC 4.2.1.2[ of rat liver was bound, after dialysis, to the microsomal membrane in vitro. Binding of the enzyme was dependent on pH, and was facilitated in the pH range below 7.5. The binding reaction was completely inhibited by 0.5 mM fumarate, aurintricarboxylate or colchicine. The bound fumarase was released from the membrane by the substrates, isocitrate, citrate or 2,3-diphosphoglycerate at low concentrations. Desorption of the enzyme by metabolites was also dependent on pH, and was more rapid in the alkaline pH range. The enzyme desorption curves were sigmoidal, and kinetic studies suggested a biphasic cooperative mechanism for the action of the metabolites. The apparent desorption constants (concentrations necessary for 50% desorption of the enzyme) estimated at pH 7.3 for isocitrate, 2,3-diphosphoglycerate, L-malate, oxalacetate, fumarate, citrate, succinate, and KCl were 0.073, 0.074, 0.22, 0.39, 0.56, 2.9, and 19 mM, respectively. The bound fumarase showed little enzymatic activity, and its Km and Vmax values were fivefold and 31%, respectively, of those of the free enzyme.     

Kinetic mechanism of the cytosolic malic enzyme from human breast cancer cell line.

The kinetic mechanism of the cytosolic NADP(+)-dependent malic enzyme from cultured human breast cancer cell line was studied by steady-state kinetics. In the direction of oxidative decarboxylation, the initial-velocity and product-inhibition studies indicate that the enzyme reaction follows a sequential ordered Bi-Ter kinetic mechanism with NADP+ as the leading substrate followed by L-malate. The products are released in the order of CO2, pyruvate, and NADPH. The enzyme is unstable at high salt concentration and elevated temperature. However, it is stable for at least 20 min under the assay conditions. Tartronate (2-hydroxymalonate) was found to be a noncompetitive inhibitor for the enzyme with respect to L-malate. The kinetic mechanism of the cytosolic tumor malic enzyme is similar to that for the pigeon liver cytosolic malic enzyme but different from those for the mitochondrial enzyme from various sources.     

The substrate analog bromopyruvate as a substrate, an inhibitor and an alkylating agent of malic enzyme of pigeon liver

Bromopyruvate is an alkylating agent of pigeon liver malic enzyme (malate dehydrogenase (decarboxylating), EC 1.1.1.40). It combines first with the enzyme to give an enzyme-bromopyruvate complex, then reacts with a proximal -SH group, resulting in the formation of a pyruvate derivative. Bromopyruvate is also a substrate for the reductase partial reaction, and a non-competitive inhibitor of L-malate in the overall oxidative decarboxylase reaction catalyzed by this enzyme. Modification of the -SH group by this compound is accompanied by concomitant loss of both oxidative decarboxylase activity and reductase activity on bromopyruvate. Inactivation of the overall activity is partially prevented by NADP⁺ or NADPH, singly or in combination with L-malate.     

Purification and properties of the NAD(P)-dependent malic enzyme from human placental mitochondria

The NAD(P)-dependent malic enzyme from human term placental mitochondria was purified 108-fold with a final yield of 72% and specific activity of about 2 mumol per minute per milligram protein. The final preparation was completely free of fumarase, malic, and lactic dehydrogenases. Divalent cations were required for NAD(P)-dependent malic enzyme activity, Mn2+ and Co2+ were by far more effective activators than Mg2+ and Ni2+, whereas the reaction did not proceed in the presence of Ca2+. The optimum pH with NAD and NADP as coenzymes was at around 7.1 and 6.4, respectively. The ratio of the rate of NAD:NADP reduction was 7.4 and 1.3 at pH 7.1 and 6.4, respectively. The enzyme is activated by succinate and fumarate and inhibited by ATP. In the absence of fumarate the Michaelis constants for L-malate and NAD were 2.82 and 0.33 mM; and in the presence of fumarate 1.18 and 0.22 mM, respectively. This study presents the first report showing the purification and kinetic properties of NAD(P)-dependent malic enzyme from human tissue.     

Properties and function of malate enzyme from Pseudomonas putida

Malate enzyme (L-malate: NADP+ oxidoreductase (oxalacetate-decarboxylating, EC 1.1.1.40)) has been purified from Pseudomonas putida to 99 per cent homogeneity by heat, ammonium suphate fractionation, gel filtration and anion exchange chromatography. Sodium dodecylsulphate-(SDS)-polyacrylamide disc gel electrophoresis analysis showed an approximate tetrameric subunit with a molecular weight of 52,000. The purified enzyme showed a pH optimum between 8.0 and 8.5 (for Tris-HCl buffer) and required bivalent cations for catalysis; monovalent ions like K+ and NH4+ acted as very effective activators. The temperature-activity relationship for the malate enzyme from 35-80 degrees C showed broken Arrhenius plots with an inflexion at 65 degrees C. The enzyme halflife was 30s at 85 degrees C. The enzyme showed hyperbolic kinetics for both substrates with apparent Km values of 4.0 X 10(-4) M and 2.3 X 10(-5) M for L-malate and NADP+ respectively. From the study of the effects of some compounds on the enzyme, the physiological significance of those produced by fumarate, succinate and oxalacetate can be emphasized.     

Malate metabolism by Desulfovibrio gigas and its link to sulfate and fumarate reduction: purification of the malic enzyme and detection of NAD(P)+ transhydrogenase activity

Malate metabolism was investigated in lactate grown cells of Desulfovibrio gigas ; 3 mol of malate are converted into 2 mol succinate and 1 mol acetate. The malic enzyme (L-malate:NADP+ oxidoreductase) was purified to homogeneity and partially characterized. The enzyme is monomeric with molecular weight of 45 kDa. Its spectrum has no visible absorption and the activity is stimulated by K+ and Mg2+. The presence of an NAD(P)+ transhydrogenase, the observation of partial reduction of adenylylsulfate reductase by NADH (via NADH-rubredoxin oxidoreductase) and evidence for NADH-linked fumarate reductase activity support the involvement of pyridine nucleotides in the electron pathway toward the reduction of sulfur compounds and/or fumarate. An electron transfer chain to fumarate is proposed, taking into consideration these results and the stoichiometry of end-products derived from malate dismutation.     

Oxalacetate decarboxylase and pyruvate carboxylase activities, and effect of sulfhydryl reagents in malic enzyme from Sulfolobus solfataricus

Malic enzyme (S)-malate: NADP+ oxidoreductase (oxaloacetate-decarboxylating, EC 1.1.1.40) purified from the thermoacidophilic archaebacterium Sulfolobus solfataricus, strain MT-4, catalyzed the metal-dependent decarboxylation of oxaloacetate at optimum pH 7.6 at a rate comparable to the decarboxylation of L-malate. The oxaloacetate decarboxylase activity was stimulated about 50% by NADP but only in the presence of MgCl2, and was strongly inhibited by L-malate and NADPH which abolished the NADP activation. In the presence of MnCl2 and in the absence of NADP, the Michaelis constant and Vm for oxaloacetate were 1.7 mM and 2.3 mumol.min-1.mg-1, respectively. When MgCl2 replaced MnCl2, the kinetic parameters for oxaloacetate remained substantially unvaried, whereas the Km and Vm values for L-malate have been found to vary depending on the metal ion. The enzyme carried out the reverse reaction (malate synthesis) at about 70% of the forward reaction, at pH 7.2 and in the presence of relatively high concentrations of bicarbonate and pyruvate. Sulfhydryl residues (three cysteine residues per subunit) have been shown to be essential for the enzymatic activity of the Sulfolobus solfataricus malic enzyme. 5,5'-Dithiobis(2-nitrobenzoic acid), p-hydroxymercuribenzoate and N-ethylmaleimide caused the inactivation of the oxidative decarboxylase activity, but at different rates. The inactivation of the overall activity by p-hydroxymercuribenzoate was partially prevented by NADP singly or in combination with both L-malate and MnCl2, and strongly enhanced by the carboxylic acid substrates; NADP + malate + MnCl2 afforded total protection. The inactivation of the oxaloacetate decarboxylase activity by p-hydroxymercuribenzoate treatment was found to occur at a slower rate than that of the oxidative decarboxylase activity.     

Molecular characterization of potato fumarate hydratase and functional expression in Escherichia coli.

The tricarboxylic acid cycle enzyme fumarase (fumarate hydratase; EC 4.2.1.2) catalyzes the reversible hydration of fumarate to L-malate. We report the molecular cloning of a cDNA (StFum-1) that encodes fumarase from potato (Solanum tuberosum L.). RNA blot analysis demonstrated that StFum-1 is most strongly expressed in flowers, immature leaves, and tubers. The deduced protein contains a typical mitochondrial targeting peptide and has a calculated molecular mass of 50.1 kD (processed form). Potato fumarase complemented a fumarase-deficient Escherichia coli mutation for growth on minimal medium that contains acetate or fumarate as the sole carbon source, indicating that functional plant protein was produced in the bacterium. Antiserum raised against the recombinant plant enzyme recognized a 50-kD protein in wild-type but not in StFum-1 antisense plants, indicating specificity of the immunoreaction. A protein of identical size was also detected in isolated potato tuber mitochondria. Although elevated activity of fumarase was previously reported for guard cells (as compared with mesophyll cells), additional screening and genomic hybridization data reported here do not support the hypothesis that a second fumarase gene is expressed in potato guard cells.     

H2-dependent anaerobic growth of Escherichia coli on L-malate: succinate formation.

Escherichia coli grew anaerobically on L-malate only in the presence of H2; 91% of the L-malate utilized was converted to succinate. Anaerobically isolated membrane vesicles catalyzed the reduction of fumarate with H2 and contained a b-type cytochrome. Cytochrome c552 was present in the "periplasmic space."     

Mechanism of pigeon liver malic enzyme modification of histidyl residues by ethoxyformic anhydride.

Incubation of malic enzyme (L-malate:NADP+ oxidoreductase (oxaloacetate-decarboxylating), EC 1.1.1.40) with ethoxyformic anhydride caused the time-dependent loss of its ability to catalyze reactions requiring the nucleotide cofactor NADP+ or NADPH, such as the oxidative decarboxylase, the NADP+ - stimualted oxalacetate decarboxylase, the pyruvate reductase, and the pyruvate-medium proton exchange activities. Similar loss of oxidative decarboxylase and pyruvate reductase activities was affected by photo-oxidation in the presence of rose bengal. The inactivation of oxidative decarboxylase activity by ethoxyformic anhydride was accompanied by the reaction of greater than or equal to 2.3 histidyl residues per enzyme site and was strongly inhibited by NADP+. Ethoxyformylation also impaired the ability of malic enzyme to bind NADP+ or NADPH. These results support the involvement of histidyl residue(s) at the nucleotide binding site of malic enzyme.     

Two forms of ''malic'' enzyme with different regulatory properties in Trypanosoma cruzi.

1. Cell-free extracts from culture epimastigotes of Trypanosoma cruzi contained two forms of NADP+-linked 'malic' enzyme (EC 1.1.1.40), I and II, with the same molecular weight but different electrophoretic mobilities and kinetic and regulatory properties. 2. The apparent Km for L-malate was lower for 'malic' enzyme I, with hyperbolic kinetics, whereas the kinetic pattern for 'malic' enzyme II was slightly sigmoidal (h 1.4). The kinetics for NADPH were hyperbolic for 'malic' enzyme I, and very complex for 'malic' enzyme II, suggesting both positive and negative co-operativity. 3. 'Malic' enzyme II was markedly inhibited by adenine nucleotides; AMP was the the most effective, at least in the presence of an excess of MnCl2. 'Malic' enzyme I was much less affected by the nucleotides. Both enzyme forms were inhibited by oxaloacetate, competitively towards L-malate, but the apparent Ki for 'malic' enzyme I (9 microM) was 10-fold lower than the value for 'malic' enzyme II. 'Malic' enzyme II, but not 'malic' enzyme I, was activated by L-aspartate and succinate (apparent Ka of 0.12 and 0.5 mM respectively); the activators caused a decrease in the apparent Km for L-malate and, to a lesser extent, in the apparent Km for NADP+. L-Aspartate, but not succinate, increased the apparent Vmax. 4. The inhibition by AMP suggests regulation by energy charge, with the L-malate-decarboxylation reaction catalysed by 'malic' enzyme II fulfilling a biosynthetic role. The inhibition by oxaloacetate and the activation by succinate are probably involved in the regulation of the 'partial aerobic fermentation' of glucose which yields succinate as final product. The activation by L-aspartate would facilitate the catabolism of this amino acid, when present in excess in the growth medium.     

Duck liver malic enzyme: sequence of a tryptic peptide containing the cysteine residue labeled by the substrate analog bromopyruvate

Malic enzyme of duck liver is alkylated by bromopyruvate with half-of-the-sites stoichiometry, and with accompanying loss of oxidative decarboxylase and enhancement of pyruvate reductase activities as was previously shown for the pigeon enzyme (Hsu, R.Y. (1982) Mol. Cell. Biochem. 43, 3-26). In the present work, the alkylated enzyme is shown to bind NADPH, but not L-malate in the presence of MnCl2, indicating impairment of the enzyme site for the substrate and/or divalent metal. The enzyme was differentially labeled by 3-bromo-1-[14C]-pyruvate and digested with TPCK-treated trypsin. Two peptides bearing the susceptible residue were purified by high-performance liquid chromatography and sequenced. Peptide II has the sequence of FMPIVYTPTVGLAXQQYGLAFR, corresponding to residues 86-107 (temporary numbering) of the duck enzyme; cysteine-99(x) is not detected, indicating that it is the target of modification by bromopyruvate. Peptide I is a truncated form of peptide II lacking five amino acid residues at the C-terminal. Cysteine-99 is conserved in malic enzymes from duck, rat, mouse, maize, human, Flaveria trinervia and Bacillus stearothermophilus.