Pigeon liver malic enzyme

Summary Malic enzyme of pigeon liver is a tetrameric molecule with identical, or nearly-identical subunits. It catalyzes, in addition to oxidative decarboxylation of L-malate, the following metal activated component reactions: Oxalacetate decarboxylase; reductase with broad specificity on -ketocarboxylic acids; a NADP⁺-dependent dismutation of L-malate to L-lactate; and proton exchange between pyruvate and medium water. The kinetic mechanism of oxidative decarboxylase is sequential and ordered, with NADP⁺ adding first to the metal enzyme, followed by L-malate, and by the release of products CO₂, pyruvate, and NADPH. NADPH release, or a conformation change preceeding it, is rate-limiting in the overall reaction.Chemical modification studies indicate the presence of histidyl and lysyl residues at the nucleotide site, and tyrosyl residues at the carboxylic acid site. The involvement of protonated histidine(s) in NADPH binding is implicated by results of direct titration experiments, which also suggest a role of this residue as a proton sink in the catalytic reaction.A cysteinyl SH group is located near (but not at) each of the substrate-sites on the enzyme tetramer. Reaction of these groups with SH reagents causes selective loss of activities involving decarboxylation (i.e., oxidative decarboxylase, reductive carboxylase, and oxalacetate decarboxylase), owing to blockage of the reversible carbon-carbon cleavage step by the bulky substituent. All-of-the-sites reactivity is observed for non-specific thiol reagents such as 5,5 dithiobis-(2-nitrobenzoic acid), N-ethylmaleimide, iodoacetate, and iodoacetamide. While bromopyruvate, which is reduced by the enzyme to L-bromolactate under catalytic conditions, alkylates these groups in an active-site directed manner with half-of-the-sites stoichiometry. The remaining two SH groups are reactive toward non-specific reagents, but at rates 2.4 - 3.6 fold lower than do the same groups on the unalkylated enzyme. This behavior is interpreted in terms of the ligand-induced negative cooperativity concept of Koshland, et al. (Biochemistry 5: 365–385, 1966): Reaction of bromopyruvate induces a conformation change on the alkylated subunit which is transmitted to the unoccupied subunit neighbor, turning off its catalytic site for reaction with L-malate, as well as converting the initial fast SH groups into slow, or unreactive SH groups.In equilibrium binding experiments, all-of-the-sites reactivity is seen with nucleotide cofactors NADP⁺ and NADPH. Binding of Mn²⁺, or L-malate in the presence of Mn²⁺ and NADPH is biphasic, showing two tight sites with dissociation constants in the micromolar range, and two weak sites with 10–100 fold lower affinities. The presence of tight and weak L-malate sites is confirmed by fluorescence titration experiments which also yields similar affinities for the substrate molecule. In kinetic studies, two types of non-equivalent, and functionally distinct sites are detected. At saturating NADP⁺, and Mn²⁺ and L-malate levels corresponding to binding at tight sites, typical Michaelian behavior is observed. The reaction is inhibited uncompentitively by L-malate at higher concentrations corresponding to occupancy at all of the L-malate sites. Occupancy of Mn²⁺ at weak metal sites as well has no effect at low L-malate, but prevents substrate inhibition at high L-malate.A tentative half-of-the-sites model consistent with results of chemical modification, binding, and kinetic experiments is proposed for this enzyme. This model implicates involvement of subunit cooperativity in the catalytic process. Malic enzyme is depicted as a tetramer composed of inititally identical subunits, each containing an active-site capable of binding all reactants. Mn²⁺ and L-malate bind anticooperatively to the tight and weak sites, in contrast to NADP⁺ which binds equivalently to all sites. On the fully active enzymes, only half (or the tight) of the subunits are simultaneously undergoing catalysis. Binding of L-malate (but not Mn²⁺) at the adjacent weak subunits causes a slow isomerization of the enzyme, and inhibition of NADPH dissociation from the catalytic subunits. Binding of Mn²⁺ at the same sites prevents this change and thereby relieving substrate inhibition. This model is further supported by results of active-site titration experiments, such as the half-size burst of enzyme-bound NADPH in the transient state, and half-of-the-sites reactivity of oxalate, an analog for the transition state intermediate of the reaction.Abbreviations DTNB 5,5 dithiobis-(2-nitrobenzoic acid) - NEM N-ethylmaleimide - BP bromopyruvate - DTT dithiothreitol     

High malic enzyme activity in tumor cells and its cross-reaction with antipigeon liver malic enzyme serum

Summary Rabbit antibodies against pigeon liver malic enzyme (EC 1.1.1.40) were prepared. The antiserum gave single precipitation line with crude pigeon liver extract. Cross reaction was observed with partially purified malic enzyme or crude extract from chicken liver. Positive cross reaction was also observed with the concentrated cytosolic fraction of two human carcinoma cell lines which were demonstrated to contain high malic enzyme activity. All other proteins examined did not react with the antibodies. When purified pigeon liver malic enzyme was mixed with the antiserumin vitro, a time-dependent inactivation of the enzyme activity was observed. Protection of the enzyme activity against antiserum inactivation was afforded by NADP⁺ orL-malate. Metal Mn²⁺ gave little protection.     

Influence of pH,malic acid and glucose concentrations on malic acid consumption by Saccharomyces cerevisiae

Malic acid consumption by Saccharomyces cerevisiae was studied in a synthetic medium. The extent of malic acid degradation is affected by its initial concentration, the extent and the rate of deacidification increased with initial malate concentration up to 10 g/l. For malic acid consumption, an optimal pH range of 3–3.5 was found, confirming that non-dissociated organic acids enter S. cerevisiae cells by simple diffusion. A full factorial design has been employed to describe a statistical model of the effect of sugar and malic acid on the quantity of malate degraded (g/l) by a given amount of biomass (g/l). The results indicated that the initial malic acid concentration is very important for the ratio of malate consumption to quantity of biomass. The yeast was found to be most efficient at higher levels of malate.     

Cytoplasmic malic enzyme from mouse kidneys

NADP⁺-dependent cytoplasmic malic enzyme was purified to homogeneity from mouse kidneys by a two-step procedure involving 8-(6-aminohexyl)-amino-2, 5-ADP-Sepharose affinity chromatography and DEAE-Sephadex ion exchange chromatography. The biochemical properties of the purified enzyme from DBA/2J mice were characterized. These include the determination of molecular weight and amino acid compositions, steady-state kinetics, thermal stability and inactivations by iodoacetate and urea. The native enzyme is a tetramer with a molecular weight of 270,000.K_m's for NADP⁺, l-malate, NADPH and pyruvate were determined to be 3.3 µm,, 50 µm, 10.5 gm respectively. Similar to the pigeon liver enzyme, the mouse enzyme exhibits an ordered kinetic mechanism proceeding with the binding of coenzyme first. The enzyme is only weakly inhibited by ATP and other cellular metabolites. A remarkable similarity in amino acid compositions was found between the mouse and rat liver malic enzymes.Abbreviations DTNB 5,5-dithio, bis-nitrobenzoic acid     

Mitochondrial malic enzyme in human leukocytes

Leukocyte samples from 316 unrelated blood donors were screened for malic enzyme (MEM). The frequency of the common allele in this investigation was MEM1 = 0.63. There is evidence for the existence of a rare fourth allele MEM4.     

Two malic enzymes in Pseudomonas aeruginosa

Cell-free extract supernatant fluids of Pseudomonas aeruginosa were shown to lack malic dehydrogenase but possess a nicotinamide adenine dinucleotide (NAD)- or NAD phosphate (NADP)-dependent enzymatic activity, with properties suggesting a malic enzyme (malate + NAD (NADP) --> pyruvate + reduced NAD (NADH) (reduced NADP [NADPH] + CO(2)), in agreement with earlier findings. This was confirmed by determining the nature and stoichiometry of the reaction products. Differences in heat stability and partial purification of these activities demonstrated the existence of two malic enzymes, one specific for NAD and the other for NADP. Both enzymes require bivalent metal cations for activity, Mn(2+) being more effective than Mg(2+). The NADP-dependent enzyme is activated by K(+) and low concentrations of NH(4) (+). Both reactions are reversible, as shown by incubation with pyruvate, CO(2), NADH, or NADPH and Mn(2+). The molecular weights of the enzymes were estimated by gel filtration (270,000 for the NAD enzyme and 68,000 for the NADP enzyme) and by sucrose density gradient centrifugation (about 200,000 and 90,000, respectively).     

Nad malic enzyme from citrus fruit

NAD malic enzyme activity was found in the 15 000 g precipitate of citrus leaf and fruit tissues. The enzyme activity in juice vesicle tissue did not change during the fruit growing period, but doubled following ripening. Partially purified enzyme was activated by CoA or FDP. Affinity for malate changed depending on enzyme concentration. The dependency was lost by addition of tricarboxylic acids but not dicarboxylic acids.     

Studies on regulatory functions of malic enzymes. V. Comparative studies of malic enzymes in bacteria.

Screening of four malic enzymes--NAD-linked enzyme [EC 1.1.1.38], NAD, NADP-linked enzyme [EC 1.1.1.39], NADP-linked enzyme [EC 1.1.1.40], and D-malic enzyme--was carried out with cell-free extracts of the following 16 strains of bacteria by the aid of Sepharose 6B column chromatography: 9 strains of enteric bacteria, 3 strains of Pseudomonas, Alcaligenes faecalis, Agrobacterium tumefaciens, Rhodospirillum rubrum, and Clostridium tetanomorphum. All the strains tested contained at least one malic enzyme. The NADP-linked enzyme activity was found in all the strains except C. tetanomorphum, the NAD-linked enzyme activity in 12 strains--8 strains of enteric bacteria, 2 strains of Pseudomonas, Ag. tumefaciens, and C. tetanomorphum--and D-malic enzyme activity in 4 strains--A, aerogenes (IFO 3319 and 12059), Ps. fluorescens, and R. rubrum. The NADP-linked and NAD-linked enzyme activities of two strains of Pseudomonas were not separated by the chromatography. The available evidence suggested that the NAD, NADP-linked enzyme was not present in these 16 strains. The comparative studies of molecular, enzymatic, and serological properties of the malic enzymes in these 16 strains revealed a close similarity of the same types of malic enzymes among enteric bacteria.     

Quaternary structure of pigeon liver malic enzyme

Pigeon liver malic enzyme (EC 1.1.1.40) has a double dimer quaternary structure. The NADP+ analogs, aminopyridine adenine dinucleotide phosphate and nicotinamide-1,N6-ethenoadenosine dinucleotide phosphate, bind to the enzyme anti-cooperatively. In the presence of non-cooperative competing ligand NADP+, the binding parameter Hill coefficients of these analogues changed very little. Binding of L-malate with enzyme-AADP+ complex first enhanced then reduced the nucleotide fluorescence. Two L-malate binding sites, with Kd values of 23-30 and 270-400 microM, respectively. for the tight and weak binding sites were postulated. A hybrid model between the sequential and pre-existing asymmetrical models was proposed for the pigeon liver malic enzyme.     

Determinants of nucleotide-binding selectivity of malic enzyme

Malic enzymes have high cofactor selectivity. An isoform-specific distribution of residues 314, 346, 347 and 362 implies that they may play key roles in determining the cofactor specificity. Currently, Glu314, Ser346, Lys347 and Lys362 in human c-NADP-ME were changed to the corresponding residues of human m-NAD(P)-ME (Glu, Lys, Tyr and Gln, respectively) or Ascaris suum m-NAD-ME (Ala, Ile, Asp and His, respectively). Kinetic data demonstrated that the S346K/K347Y/K362Q c-NADP-ME was transformed into a debilitated NAD⁺-utilizing enzyme, as shown by a severe decrease in catalytic efficiency using NADP⁺ as the cofactor without a significant increase in catalysis using NAD⁺ as the cofactor. However, the S346K/K347Y/K362H enzyme displayed an enhanced value for k _cat,NAD, suggesting that His at residue 362 may be more beneficial than Gln for NAD⁺ binding. Furthermore, the S346I/K347D/K362H mutant had a very large K _m,NADP value compared to other mutants, suggesting that this mutant exclusively utilizes NAD⁺ as its cofactor. Since the S346K/K347Y/K362Q, S346K/K347Y/K362H and S346I/K347D/K362H c-NADP-ME mutants did not show significant reductions in their K _m,NAD values, the E314A mutation was then introduced into these triple mutants. Comparison of the kinetic parameters of each triple-quadruple mutant pair (for example, S346K/K347Y/K362Q versus E314A/S346K/K347Y/K362Q) revealed that all of the K _m values for NAD⁺ and NADP⁺ of the quadruple mutants were significantly decreased, while either k _cat,NAD or k _cat,NADP was substantially increased. By adding the E314A mutation to these triple mutant enzymes, the E314A/S346K/K347Y/K362Q, E314A/S346K/K347Y/K362H and E314A/S346I/K347D/K362H c-NADP-ME variants are no longer debilitated but become mainly NAD⁺-utilizing enzymes by a considerable increase in catalysis using NAD⁺ as the cofactor. These results suggest that abolishing the repulsive effect of Glu314 in these quadruple mutants increases the binding affinity of NAD⁺. Here, we demonstrate that a series of E314A-containing c-NADP-ME quadruple mutants have been changed to NAD⁺-utilizing enzymes by abrogating NADP⁺ binding and increasing NAD⁺ binding.