Your search keyword '"Malate Dehydrogenase chemistry"' showing total 24 results

1. Structural Comparison of hMDH2 Complexed with Natural Substrates and Cofactors: The Importance of Phosphate Binding for Active Conformation and Catalysis.

Author

Eo Y, Duong MTH, and Ahn HC

Subjects

Binding Sites, Catalysis, Crystallography, X-Ray, Glyoxylates, Humans, Ligands, NAD metabolism, Oxaloacetic Acid chemistry, Oxaloacetic Acid metabolism, Phosphates, Malate Dehydrogenase chemistry, Malates chemistry

Abstract

Malate dehydrogenase (MDH), which catalyzes a reversible conversion of L -malate to oxaloacetate, plays essential roles in common metabolic processes, such as the tricarboxylic acid cycle, the oxaloacetate-malate shuttle, and the glyoxylate cycle. MDH2 has lately been recognized as a promising anticancer target; however, the structural information for the human homologue with natural ligands is very limited. In this study, various complex structures of hMDH2, with its substrates and/or cofactors, were solved by X-ray crystallography, which could offer knowledge about the molecular and enzymatic mechanism of this enzyme and be utilized to design novel inhibitors. The structural comparison suggests that phosphate binds to the substrate binding site and brings the conformational change of the active loop to a closed state, which can secure the substate and cofactor to facilitate enzymatic activity.

Published

2022

2. l-Malate (-2) Protonation State is Required for Efficient Decarboxylation to l-Lactate by the Malolactic Enzyme of Oenococcus oeni .

Author

Acevedo W, Cañón P, Gómez-Alvear F, Huerta J, Aguayo D, and Agosin E

Subjects

Bacterial Proteins chemistry, Lactic Acid chemistry, Malate Dehydrogenase chemistry, Malates chemistry, Oenococcus enzymology

Abstract

Malolactic fermentation (MLF) is responsible for the decarboxylation of l-malic into lactic acid in most red wines and some white wines. It reduces the acidity of wine, improves flavor complexity and microbiological stability. Despite its industrial interest, the MLF mechanism is not fully understood. The objective of this study was to provide new insights into the role of pH on the binding of malic acid to the malolactic enzyme (MLE) of Oenococcus oeni. To this end, sequence similarity networks and phylogenetic analysis were used to generate an MLE homology model, which was further refined by molecular dynamics simulations. The resulting model, together with quantum polarized ligand docking (QPLD), was used to describe the MLE binding pocket and pose of l-malic acid (MAL) and its l-malate (-1) and (-2) protonation states (MAL - and MAL 2- , respectively). MAL 2- has the lowest ∆G binding , followed by MAL - and MAL, with values of -23.8, -19.6, and -14.6 kJ/mol, respectively, consistent with those obtained by isothermal calorimetry thermodynamic (ITC) assays. Furthermore, molecular dynamics and MM/GBSA results suggest that only MAL 2- displays an extended open conformation at the binding pocket, satisfying the geometrical requirements for Mn 2+ coordination, a critical component of MLE activity. These results are consistent with the intracellular pH conditions of O. oeni cells-ranging from pH 5.8 to 6.1-where the enzymatic decarboxylation of malate occurs.

Published

2020

3. Conformational changes on substrate binding revealed by structures of Methylobacterium extorquens malate dehydrogenase.

Author

González JM, Marti-Arbona R, Chen JCH, Broom-Peltz B, and Unkefer CJ

Subjects

Adenosine Diphosphate Ribose metabolism, Amino Acid Sequence, Apoenzymes chemistry, Apoenzymes genetics, Apoenzymes metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Catalytic Domain, Cloning, Molecular, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Hydrogen Bonding, Kinetics, Malate Dehydrogenase genetics, Malate Dehydrogenase metabolism, Malates metabolism, Methylobacterium extorquens enzymology, Models, Molecular, NAD metabolism, Oxaloacetic Acid metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Interaction Domains and Motifs, Protein Multimerization, Protons, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Substrate Specificity, Adenosine Diphosphate Ribose chemistry, Bacterial Proteins chemistry, Malate Dehydrogenase chemistry, Malates chemistry, Methylobacterium extorquens chemistry, NAD chemistry, Oxaloacetic Acid chemistry

Abstract

Three high-resolution X-ray crystal structures of malate dehydrogenase (MDH; EC 1.1.1.37) from the methylotroph Methylobacterium extorquens AM1 are presented. By comparing the structures of apo MDH, a binary complex of MDH and NAD + , and a ternary complex of MDH and oxaloacetate with ADP-ribose occupying the pyridine nucleotide-binding site, conformational changes associated with the formation of the catalytic complex were characterized. While the substrate-binding site is accessible in the enzyme resting state or NAD + -bound forms, the substrate-bound form exhibits a closed conformation. This conformational change involves the transition of an α-helix to a 3 10 -helix, which causes the adjacent loop to close the active site following coenzyme and substrate binding. In the ternary complex, His284 forms a hydrogen bond to the C2 carbonyl of oxaloacetate, placing it in a position to donate a proton in the formation of (2S)-malate.

Published

2018

4. Structure of glyoxysomal malate dehydrogenase (MDH3) from Saccharomyces cerevisiae.

Author

Moriyama S, Nishio K, and Mizushima T

Subjects

Amino Acid Sequence, Apoenzymes chemistry, Apoenzymes genetics, Apoenzymes metabolism, Catalytic Domain, Cloning, Molecular, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Glyoxysomes chemistry, Glyoxysomes enzymology, Isoenzymes chemistry, Isoenzymes genetics, Isoenzymes metabolism, Malate Dehydrogenase genetics, Malate Dehydrogenase metabolism, Malates metabolism, Models, Molecular, NAD metabolism, Oxaloacetic Acid metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Multimerization, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, Substrate Specificity, Malate Dehydrogenase chemistry, Malates chemistry, NAD chemistry, Oxaloacetic Acid chemistry, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins chemistry

Abstract

Malate dehydrogenase (MDH), a carbohydrate and energy metabolism enzyme in eukaryotes, catalyzes the interconversion of malate to oxaloacetate (OAA) in conjunction with that of nicotinamide adenine dinucleotide (NAD + ) to NADH. Three isozymes of MDH have been reported in Saccharomyces cerevisiae: MDH1, MDH2 and MDH3. MDH1 is a mitochondrial enzyme and a member of the tricarboxylic acid cycle, whereas MDH2 is a cytosolic enzyme that functions in the glyoxylate cycle. MDH3 is a glyoxysomal enzyme that is involved in the reoxidation of NADH, which is produced during fatty-acid β-oxidation. The affinity of MDH3 for OAA is lower than those of MDH1 and MDH2. Here, the crystal structures of yeast apo MDH3, the MDH3-NAD + complex and the MDH3-NAD + -OAA ternary complex were determined. The structure of the ternary complex suggests that the active-site loop is in the open conformation, differing from the closed conformations in mitochondrial and cytosolic malate dehydrogenases.

Published

2018

5. Development of an Amperometric Biosensor Platform for the Combined Determination of L-Malic, Fumaric, and L-Aspartic Acid.

Author

Röhlen DL, Pilas J, Schöning MJ, and Selmer T

Subjects

Ammonia-Lyases chemistry, Animals, Bacterial Proteins chemistry, Clostridium kluyveri enzymology, Fumarate Hydratase chemistry, Malate Dehydrogenase chemistry, NADH Dehydrogenase chemistry, Swine, Aspartic Acid analysis, Biosensing Techniques methods, Electrochemical Techniques methods, Fumarates analysis, Malates analysis

Abstract

Three amperometric biosensors have been developed for the detection of L-malic acid, fumaric acid, and L -aspartic acid, all based on the combination of a malate-specific dehydrogenase (MDH, EC 1.1.1.37) and diaphorase (DIA, EC 1.8.1.4). The stepwise expansion of the malate platform with the enzymes fumarate hydratase (FH, EC 4.2.1.2) and aspartate ammonia-lyase (ASPA, EC 4.3.1.1) resulted in multi-enzyme reaction cascades and, thus, augmentation of the substrate spectrum of the sensors. Electrochemical measurements were carried out in presence of the cofactor β-nicotinamide adenine dinucleotide (NAD + ) and the redox mediator hexacyanoferrate (III) (HCFIII). The amperometric detection is mediated by oxidation of hexacyanoferrate (II) (HCFII) at an applied potential of + 0.3 V vs. Ag/AgCl. For each biosensor, optimum working conditions were defined by adjustment of cofactor concentrations, buffer pH, and immobilization procedure. Under these improved conditions, amperometric responses were linear up to 3.0 mM for L-malate and fumarate, respectively, with a corresponding sensitivity of 0.7 μA mM -1 (L-malate biosensor) and 0.4 μA mM -1 (fumarate biosensor). The L-aspartate detection system displayed a linear range of 1.0-10.0 mM with a sensitivity of 0.09 μA mM -1 . The sensor characteristics suggest that the developed platform provides a promising method for the detection and differentiation of the three substrates.

Published

2017

6. Metabolic engineering of Escherichia coli W3110 to produce L-malate.

Author

Dong X, Chen X, Qian Y, Wang Y, Wang L, Qiao W, and Liu L

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bioreactors, Escherichia coli genetics, Gene Deletion, Malate Dehydrogenase chemistry, Malate Dehydrogenase genetics, Malate Dehydrogenase metabolism, Malates analysis, NAD metabolism, Pyruvic Acid, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Escherichia coli metabolism, Malates metabolism, Metabolic Engineering methods

Abstract

A four-carbon dicarboxylic acid L-malate has recently attracted attention due to its potential applications in the fields of medicine and agriculture. In this study, Escherichia coli W3110 was engineered and optimized for L-malate production via one-step L-malate synthesis pathway. First, deletion of the genes encoding lactate dehydrogenase (ldhA), pyruvate oxidase (poxB), pyruvate formate lyase (pflB), phosphotransacetylase (pta), and acetate kinase A (ackA) in pta-ackA pathway led to accumulate 20.9 g/L pyruvate. Then, overexpression of NADP + -dependent malic enzyme C490S mutant in this multi-deletion mutant resulted in the direct conversion of pyruvate into L-malate (3.62 g/L). Next, deletion of the genes responsible for succinate biosynthesis further enhanced L-malate production up to 7.78 g/L. Finally, L-malate production was elevated to 21.65 g/L with the L-malate yield to 0.36 g/g in a 5 L bioreactor by overexpressing the pos5 gene encoding NADH kinase in the engineered E. coli F0931 strain. This study demonstrates the potential utility of one-step pathway for efficient L-malate production. Biotechnol. Bioeng. 2017;114: 656-664. © 2016 Wiley Periodicals, Inc., (© 2016 Wiley Periodicals, Inc.)

Published

2017

7. Impact of inhibitory peptides released by Saccharomyces cerevisiae BDX on the malolactic fermentation performed by Oenococcus oeni Vitilactic F.

Author

Rizk Z, El Rayess Y, Ghanem C, Mathieu F, Taillandier P, and Nehme N

Subjects

Bacterial Proteins chemistry, Bacterial Proteins metabolism, Fermentation, Kinetics, Malate Dehydrogenase chemistry, Malate Dehydrogenase metabolism, Oenococcus drug effects, Peptides metabolism, Saccharomyces cerevisiae metabolism, Vitis metabolism, Vitis microbiology, Wine microbiology, Malates metabolism, Oenococcus metabolism, Peptides pharmacology, Saccharomyces cerevisiae chemistry

Abstract

A previous study has shown that the malolactic fermentation (MLF) was inhibited during sequential fermentations performed with the pair Saccharomyces cerevisiae BDX/Oenococcus oeni Vitilactic F in synthetic grape juices. A yeast peptidic fraction with an apparent MW of 5-10kDa was involved in the inhibition. In the present study, the MLF was also inhibited in Cabernet Sauvignon and Syrah wines. The inhibition due to the peptidic fraction was maintained despite high phenolic contents. Kinetic studies showed that the peptidic fraction was gradually released during the alcoholic fermentation (AF). Its highest anti-MLF effect was reached when isolated from late stages of the AF stationary phase. The peptidic fraction was tested in vitro on cell-free bacterial cytosolic extracts containing the malolactic enzyme in a pH range between 3.5 and 6.7. Results showed that it was able to directly inhibit the malolactic enzyme activity with an increasing inhibitory kinetic correlated to the AF time at which it was collected., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

8. Automatic bionalyzer using an integrated amperometric biosensor for the determination of L-malic acid in wines.

Author

Vargas E, Ruiz MA, Ferrero FJ, Campuzano S, Ruiz-Valdepeñas Montiel V, Reviejo AJ, and Pingarrón JM

Subjects

Enzymes, Immobilized chemistry, Heterocyclic Compounds chemistry, Malate Dehydrogenase chemistry, Malates chemistry, NADH Dehydrogenase chemistry, Biosensing Techniques, Malates analysis, Wine analysis

Abstract

A new automatic bioanalyzer for L-malic acid using an integrated amperometric biosensor as detector is reported for the first time in this work. The biosensor is constructed by gold film sputtering deposition on a stainless steel disk electrode and co-immobilization of the enzymes malate dehydrogenase (MDH) and diaphorase (DP) together with the redox mediator tetrathiafulvalene (TTF) by means of dialysis membrane. The analytical performance of the biosensor was evaluated when it was used as amperometric detector in three different analytical methodologies: stirred solutions, semiautomatic FIA system and automatic bioanalyzer. The bienzyme biosensor exhibited great analytical performance in terms of sensitivity, selectivity and reproducibility of the measurements and its usefulness was demonstrated by analyzing wine reference materials with certified content of L-malic acid. The attractive analytical and operational characteristics demonstrated by the automatic bioanalyzer make it a promising simple, rapid and field-based tool for routine wine and fruit control., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

9. Directed evolution of thermotolerant malic enzyme for improved malate production.

Author

Morimoto Y, Honda K, Ye X, Okano K, and Ohtake H

Subjects

Biocatalysis, Enzyme Assays, Gene Library, Kinetics, Malate Dehydrogenase chemistry, Malate Dehydrogenase genetics, NAD metabolism, NADP metabolism, Oxidation-Reduction, Point Mutation genetics, Pyruvic Acid metabolism, Substrate Specificity, Thermococcus enzymology, Directed Molecular Evolution, Malate Dehydrogenase metabolism, Malates metabolism, Protein Engineering

Abstract

The directed evolution of the thermotolerant NADP(H)-dependent malic enzyme from Thermococcus kodakarensis was conducted to alter the cofactor preference of the enzyme from NADP(H) to NAD(H). The construction and screening of two generations of mutant libraries led to the isolation of a triple mutant that exhibited 6-fold higher kcat/Km with NAD(+) than the wild type. We serendipitously found that, in addition to the change in the cofactor preference, the reaction specificity of the mutant enzyme was altered. The reductive carboxylation of pyruvate to malate catalyzed by the wild type enzyme is accompanied by HCO(3)(-)-independent reduction of pyruvate and gives lactate as a byproduct. The reaction specificity of the triple mutant was significantly shifted to malate production and the mutant gave a less amount of the byproduct than the wild type. When the triple mutant enzyme was used as a catalyst for pyruvate carboxylation with NADH, the enzyme gave 1.2 times higher concentration of malate than the wild type with NADPH. Single-point mutation analysis revealed that the substitution of Arg221 with Gly is responsible for the shift in reaction specificity. This finding may shed light on the catalytic mechanisms of malic enzymes and other related CO2- and/or HCO(3)(-)-fixing enzymes., (Copyright © 2013 The Society for Biotechnology, Japan. Published by Elsevier B.V. All rights reserved.)

Published

2014

10. Immobilization of malate dehydrogenase on carbon nanotubes for development of malate biosensor.

Author

Ruhal A, Rana JS, Kumar S, and Kumar A

Subjects

Electrochemistry methods, Microscopy, Electron, Scanning, Spectroscopy, Fourier Transform Infrared, Biosensing Techniques methods, Enzymes, Immobilized chemistry, Enzymes, Immobilized metabolism, Malate Dehydrogenase chemistry, Malate Dehydrogenase metabolism, Malates analysis, Nanotubes, Carbon chemistry

Abstract

An amperometric malic acid biosensor was developed by immobilizing malate dehydrogenase on multi-walled carbon nanotubes (MWCNT) coated on screen printed carbon electrode. The screen printed carbon electrode is made up of three electrodes viz., carbon as working, platinum as counter and silver as reference electrode. Detection of L-malic acid concentration provides important information about the ripening and shelf life of the fruits. The NADP specific malate dehydrogenase was immobilized on carboxylated multiwalled carbon nanotubes using cross linker EDC [1-Ethyl-3-(3-dimethylaminopropyl) carbodiimide] on screen printed carbon electrode. An amperometric current was measured by differential pulse voltammetry (DPV) which increases with increasing concentrations of malic acid at fixed concentration of NADP. Enzyme electrode was characterized by scanning electron microscopy (SEM) and Fourier transform infrared (FTIR) spectroscopy. The detection limit of malic acid by the sensor was 60 - 120 μM and sensitivity of the sensor was 60 μM with a response time of 60s. The usual detection methods of malic acid are nonspecific, time consuming and less sensitive. However, an amperometric malic acid nanosensor is quick, specific and more sensitive for detection of malic acid in test samples.

Published

2012

11. Creation of bioorthogonal redox systems depending on nicotinamide flucytosine dinucleotide.

Author

Ji D, Wang L, Hou S, Liu W, Wang J, Wang Q, and Zhao ZK

Subjects

Amino Acid Sequence, Bacteria chemistry, Bacteria genetics, Decarboxylation, Escherichia coli chemistry, Escherichia coli enzymology, Escherichia coli genetics, Flucytosine chemistry, Lactobacillus helveticus chemistry, Lactobacillus helveticus enzymology, Lactobacillus helveticus genetics, Malate Dehydrogenase chemistry, Malate Dehydrogenase genetics, Molecular Sequence Data, Mutation, Niacinamide chemistry, Nucleotides chemistry, Nucleotides metabolism, Oxidation-Reduction, Oxidoreductases chemistry, Oxidoreductases genetics, Bacteria enzymology, Flucytosine metabolism, Malate Dehydrogenase metabolism, Malates metabolism, Niacinamide metabolism, Oxidoreductases metabolism

Abstract

Many enzymes catalyzing biological redox chemistry depend on the omnipresent cofactor, nicotinamide adenine dinucleotide (NAD). NAD is also involved in various nonredox processes. It remains challenging to disconnect one particular NAD-dependent reaction from all others. Here we present a bioorthogonal system that catalyzes the oxidative decarboxylation of l-malate with a dedicated abiotic cofactor, nicotinamide flucytosine dinucleotide (NFCD). By screening the multisite saturated mutagenesis libraries of the NAD-dependent malic enzyme (ME), we identified the mutant ME-L310R/Q401C, which showed excellent activity with NFCD, yet marginal activity with NAD. We found that another synthetic cofactor, nicotinamide cytosine dinucleotide (NCD), also displayed similar activity with the ME mutants. Inspired by these observations, we mutated d-lactate dehydrogenase (DLDH) and malate dehydrogenase (MDH) to DLDH-V152R and MDH-L6R, respectively, and both mutants showed fully active with NFCD. When coupled with DLDH-V152R, ME-L310R/Q401C required only a catalytic amount of NFCD to convert l-malate. Our results opened the window to engineer bioorthogonal redox systems for a wide variety of applications in systems biology and synthetic biology., (© 2011 American Chemical Society)

Published

2011

12. Determination of malic Acid using a malate dehydrogenase reactor after purification and immobilization in non-denaturing conditions and staining with ponceau S.

Author

Shimazaki Y and Sakikawa T

Subjects

Amino Acid Sequence, Animals, Azo Compounds chemistry, Cytosol enzymology, Liver enzymology, Malate Dehydrogenase chemistry, Malate Dehydrogenase isolation & purification, Malates metabolism, Mice, Molecular Sequence Data, Protein Denaturation, Substrate Specificity, Enzymes, Immobilized metabolism, Malate Dehydrogenase metabolism, Malates analysis

Abstract

Mouse liver cytosolic malate dehydrogenase was separated by non-denaturing two-dimensional electrophoresis and identified. Furthermore, the activity of the enzyme was preserved even after separation, electroblotting onto a membrane and staining with Ponceau S in acidic buffer solution (pH 5.1). Using the membrane-immobilized enzyme, the malic acid content was estimated by measuring absorbance changes due to the conversion of nicotinamide adenine dinucleotide (NAD) to NADH. These results indicate that enzyme reactors can be systematically produced after purification, immobilization and staining with Ponceau S.

Published

2010

13. Functional role of fumarate site Glu59 involved in allosteric regulation and subunit-subunit interaction of human mitochondrial NAD(P)+-dependent malic enzyme.

Author

Hsieh JY, Chiang YH, Chang KY, and Hung HC

Subjects

Allosteric Regulation, Amino Acid Sequence, Amino Acid Substitution, Enzyme Activation, Humans, Kinetics, Malate Dehydrogenase genetics, Malate Dehydrogenase metabolism, Mitochondrial Proteins chemistry, Mitochondrial Proteins metabolism, Models, Molecular, Molecular Sequence Data, Mutation, Protein Multimerization, Protein Subunits chemistry, Protein Subunits metabolism, Recombinant Proteins chemistry, Fumarates metabolism, Malate Dehydrogenase chemistry, Malates metabolism

Abstract

Here we report on the role of Glu59 in the fumarate-mediated allosteric regulation of the human mitochondrial NAD(P)+-dependent malic enzyme (m-NAD-ME). In the present study, Glu59 was substituted by Asp, Gln or Leu. Our kinetic data strongly indicated that the charge properties of this residue significantly affect the allosteric activation of the enzyme. The E59L enzyme shows nonallosteric kinetics and the E59Q enzyme displays a much higher threshold in enzyme activation with elevated activation constants, K(A,Fum) and alphaK(A,Fum). The E59D enzyme, although retaining the allosteric property, is quite different from the wild-type in enzyme activation. The K(A,Fum) and alphaK(A,Fum) of E59D are also much greater than those of the wild-type, indicating that not only the negative charge of this residue but also the group specificity and side chain interactions are important for fumarate binding. Analytical ultracentrifugation analysis shows that both the wild-type and E59Q enzymes exist as a dimer-tetramer equilibrium. In contrast to the E59Q mutant, the E59D mutant displays predominantly a dimer form, indicating that the quaternary stability in the dimer interface is changed by shortening one carbon side chain of Glu59 to Asp59. The E59L enzyme also shows a dimer-tetramer model similar to that of the wild-type, but it displays more dimers as well as monomers and polymers. Malate cooperativity is not significantly notable in the E59 mutant enzymes, suggesting that the cooperativity might be related to the molecular geometry of the fumarate-binding site. Glu59 can precisely maintain the geometric specificity for the substrate cooperativity. According to the sequence alignment analysis and our experimental data, we suggest that charge effect and geometric specificity are both critical factors in enzyme regulation. Glu59 discriminates human m-NAD-ME from mitochondrial NADP+-dependent malic enzyme and cytosolic NADP+-dependent malic enzyme in fumarate activation and malate cooperativity.

Published

2009

14. Reverse reaction of malic enzyme for HCO3- fixation into pyruvic acid to synthesize L-malic acid with enzymatic coenzyme regeneration.

Author

Ohno Y, Nakamori T, Zheng H, and Suye S

Subjects

Alginates chemistry, Alginates metabolism, Glucosephosphate Dehydrogenase chemistry, Glucosephosphate Dehydrogenase metabolism, Glucuronic Acid chemistry, Glucuronic Acid metabolism, Hexuronic Acids chemistry, Hexuronic Acids metabolism, Malate Dehydrogenase chemistry, Oxidation-Reduction, Carbon Dioxide metabolism, Malate Dehydrogenase metabolism, Malates metabolism, NAD metabolism, Pseudomonas enzymology, Pyruvic Acid metabolism

Abstract

Malic enzyme [L-malate: NAD(P)(+) oxidoreductase (EC 1.1.1.39)] catalyzes the oxidative decarboxylation of L-malic acid to produce pyruvic acid using the oxidized form of NAD(P) (NAD(P)(+)). We used a reverse reaction of the malic enzyme of Pseudomonas diminuta IFO 13182 for HCO(3)(-) fixation into pyruvic acid to produce L-malic acid with coenzyme (NADH) generation. Glucose-6-phosphate dehydrogenase (EC1.1.1.49) of Leuconostoc mesenteroides was suitable for coenzyme regeneration. Optimum conditions for the carboxylation of pyruvic acid were examined, including pyruvic acid, NAD(+), and both malic enzyme and glucose-6-phosphate dehydrogenase concentrations. Under optimal conditions, the ratio of HCO(3)(-) and pyruvic acid to malic acid was about 38% after 24 h of incubation at 30 degrees C, and the concentration of the accumulated L-malic acid in the reaction mixture was 38 mM. The malic enzyme reverse reaction was also carried out by the conjugated redox enzyme reaction with water-soluble polymer-bound NAD(+).

Published

2008

15. Identification of domains involved in tetramerization and malate inhibition of maize C4-NADP-malic enzyme.

Author

Detarsio E, Alvarez CE, Saigo M, Andreo CS, and Drincovich MF

Subjects

Allosteric Site, Binding Sites, Dimerization, Hydrogen-Ion Concentration, Kinetics, Malate Dehydrogenase metabolism, Photosynthesis, Plant Proteins chemistry, Protein Conformation, Protein Isoforms, Malate Dehydrogenase antagonists & inhibitors, Malate Dehydrogenase chemistry, Malates pharmacology, Zea mays enzymology

Abstract

C(4) photosynthetic NADP-malic enzyme (ME) has evolved from non-C(4) isoforms and gained unique kinetic and structural properties during this process. To identify the domains responsible for the structural and kinetic differences between maize C(4) and non-C(4)-NADP-ME several chimeras between these isoforms were constructed and analyzed. By using this approach, we found that the region flanked by amino acid residues 102 and 247 is critical for the tetrameric state of C(4)-NADP-ME. In this way, the oligomerization strategy of these NADP-ME isoforms differs markedly from the one that present non-plant NADP-ME with known crystal structures. On the other hand, the region from residue 248 to the C-terminal end of the C(4) isoform is involved in the inhibition by high malate concentrations at pH 7.0. The inhibition pattern of the C(4)-NADP-ME and some of the chimeras suggested an allosteric site responsible for such behavior. This pH-dependent inhibition could be important for regulation of the C(4) isoform in vivo, with the enzyme presenting maximum activity while photosynthesis is in progress.

Published

2007

16. Characterization of the interactions between Asp141 and Phe236 in the Mn2+-l-malate binding of pigeon liver malic enzyme.

Author

Chen YI, Chen YH, Chou WY, and Chang GG

Subjects

Animals, Binding Sites, Columbidae, Kinetics, Malate Dehydrogenase genetics, Malate Dehydrogenase isolation & purification, Metals chemistry, Mutagenesis, Site-Directed, Protein Binding genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Thermodynamics, Aspartic Acid chemistry, Liver enzymology, Malate Dehydrogenase chemistry, Malates chemistry, Manganese chemistry, Phenylalanine chemistry

Abstract

The cytosolic malic enzyme from pigeon liver is very sensitive to the metal-catalysed oxidation systems. Our previous studies using the Cu2+-ascorbate as the oxidation system showed that the enzyme was oxidized and cleaved at several positions, including Asp141. The recently resolved crystal structure of pigeon liver malic enzyme revealed that Asp141 was near to the metal-binding site, but was not a direct metal ligand. However, Asp141 is located next to Phe236, which directly follows the metal ligands Glu234 and Asp235. Mutation at Asp141 caused a drastic effect on the metal-binding affinity of the enzyme. Since Asp141 and Phe236 are highly conserved in most species of malic enzyme, we used a double-mutant cycle to study the possible interactions between these two residues. Four single mutants [D141A (Asp141-->Ala), D141N, F236A and F236L] and four double mutants (D141A/F236A, D141N/F236A, D141A/F236L and D141N/F236L), plus the wild-type enzyme were successfully cloned, expressed and purified to homogeneity. The secondary, tertiary and quaternary structures of these mutants, as assessed by CD, fluorescence and analytical ultracentrifuge techniques, were similar to that of the wild-type enzyme. Initial velocity experiments were performed to derive the various kinetic parameters, which were used to analyse further the free energy change and the coupling energy (DeltaDeltaG(int)) between any two residues. The dissociation constants for Mn2+ ( K (d,Mn)) of the D141A and F236A mutants were increased by approx. 6- and 65-fold respectively, compared with that of the wild-type enzyme. However, the K (d,Mn) for the double mutant D141A/F236A was only increased by 150-fold. A coupling energy of -2.12 kcal/mol was obtained for Asp141 and Phe236. We suggest that Asp141 is involved in the second sphere of the metal-binding network of the enzyme.

Published

2003

17. Alpha-secondary tritium kinetic isotope effects indicate hydrogen tunneling and coupled motion occur in the oxidation of L-malate by NAD-malic enzyme.

Author

Karsten WE, Hwang CC, and Cook PF

Subjects

Animals, Ascaris suum enzymology, Cattle, Deuterium chemistry, Kinetics, Oxidation-Reduction, Substrate Specificity, Tritium, Malate Dehydrogenase chemistry, Malates chemistry, NAD chemistry, Protons

Abstract

The NAD-malic enzyme from Ascaris suum catalyzes the divalent metal ion-dependent oxidative decarboxylation of L-malate to give pyruvate and CO2, with NAD+ as the oxidant. Alpha-secondary tritium kinetic isotope effects were measured with NAD+ or APAD+ and L-malate-2-H(D) and several different divalent metal ions. The alpha-secondary tritium kinetic isotope effects are slightly higher than 1 with NAD+ and L-malate as substrates, much larger than the expected inverse isotope effect for a hybridization change from sp2 to sp3. The alpha-secondary tritium kinetic isotope effects are reduced to values near 1 with L-malate-2-D as the substrate, regardless of the metal ion that is used. Data suggest the presence of quantum mechanical tunneling and coupled motion in the malic enzyme reaction when NAD+ and malate are used as substrates. Isotope effects were also measured using the D/T method with NAD+ and Mn2+ as the substrate pair. A Swain-Schaad exponent of 2.2 (less than the value of 3.26 expected for strictly semiclassical behavior) is estimated, suggesting the presence of other slow steps along the reaction pathway. With APAD+ and Mn2+ as the substrate pair, inverse alpha-secondary tritium kinetic isotope effects are observed, and a Swain-Schaad exponent of 3.3 is estimated, consistent with rate-limiting hydride transfer and no quantum mechanical tunneling or coupled motion. Data are discussed in terms of the malic enzyme mechanism and the theory developed by Huskey for D/T isotope effects as an indicator of tunneling [Huskey, W. P. (1991) J. Phys. Org. Chem. 4, 361-366].

Published

1999

18. Synthesis of (2R,3R)-erythro- and (2R,3S)-threo-fluoromalate using malic dehydrogenase; stereoselectivity of malic dehydrogenase.

Author

Urbauer JL, Bradshaw DE, and Cleland WW

Subjects

Animals, Catalysis, Cattle, Chickens, Deuterium, Fluorine, Hydrogen-Ion Concentration, Hydroxides, Magnesium chemistry, Magnetic Resonance Spectroscopy, Malates isolation & purification, Oxaloacetates chemistry, Oxidation-Reduction, Potassium Compounds, Protein Isoforms chemical synthesis, Protein Isoforms isolation & purification, Saccharomyces cerevisiae, Spectrometry, Mass, Fast Atom Bombardment, Stereoisomerism, Substrate Specificity, Malate Dehydrogenase chemistry, Malates chemical synthesis

Abstract

3-Fluorooxalacetate is a substrate for malic dehydrogenase. When enzymatic reduction is slower than the rate of epimerization of the two enantiomers, only (2R,3R)-erythro-fluoromalate is formed. Conversely, when a high enzyme level and excess of NADH lead to reduction that is fast relative to the epimerization rate, equal amounts of (2R,3R)-erythro- and (2R,3S)-threo-fluoromalate are formed. These data suggest that the V/K value for reduction of the R enantiomer to give the erythro isomer is approximately 100 times greater than for reduction of the S enantiomer to give the threo isomer. The equilibrium constant for the oxidation of fluoromalate is an order of magnitude less favorable than for oxidation of malate, while the equilibrium deuterium isotope effect from deuteration at C-2 of the substrate is 1.09 for fluoromalate versus 1.18 for malate. These effects reflect the inductive effect of fluorine at the 3-position.

Published

1998

19. Determination of the kinetic and chemical mechanism of malic enzyme using (2R,3R)-erythro-fluoromalate as a slow alternate substrate.

Author

Urbauer JL, Bradshaw DE, and Cleland WW

Subjects

Animals, Carbon Isotopes, Catalysis, Cattle, Chickens, Coenzymes chemistry, Decarboxylation, Deuterium chemistry, Kinetics, Malate Dehydrogenase antagonists & inhibitors, NAD analogs & derivatives, NAD chemistry, NADP chemistry, Oxaloacetates chemistry, Rabbits, Substrate Specificity, Swine, Malate Dehydrogenase chemistry, Malates chemistry

Abstract

(2R,3R)-erythro-Fluoromalate, but not the threo isomer, is a slow substrate for chicken liver malic enzyme with either NADP or 3-acetylpyridine-NADP (APADP) as the other substrate. The Km for erythro-fluoromalate is similar to that of malate, but the turnover number with NADP is 3300-fold slower, although 5.5-fold faster with APADP than with NADP. Deuteration of fluoromalate at C-2 gave an isotope effect on V/K of 1.39 with NADP and 3.32 with APADP. With NADP, the 13C isotope effects at C-4 were 1.0490 with unlabeled and 1.0364 with deuterated fluoromalate. With APADP, the corresponding values were 1.0138 and 1.0087. These data show that the mechanism is stepwise with both nucleotide substrates, in contrast to the reaction of malate and APADP, which was postulated to be concerted by Karsten et al. [Karsten, W. E., and Cook, P. F. (1994) Biochemistry 33, 2096-2103], a conclusion recently shown to be correct by Edens et al. [Edens, W. A., Urbauer, J. L., and Cleland, W. W. (1997) Biochemistry 36, 1141-1147]. To explain the effect of deuteration on the 13C isotope effect with APADP, it is necessary to assume a secondary 13C isotope effect at C-4 on the hydride transfer step of approximately 1.0064 (assuming 5.7 as the intrinsic primary deuterium isotope effect and 1.054 as the product of the 13C equilibrium isotope effect on hydride transfer and the intrinsic 13C isotope effect on decarboxylation). The secondary 13C isotope effect on hydride transfer is thought to result from hyperconjugation between the carbonyl group and C-4 of the enzyme-bound fluorooxaloacetate intermediate.

Published

1998

20. [A system of coupled reactions for enzymatic synthesis of L-malate].

Author

Pavlovets VV

Subjects

Animals, Chromatography, Ion Exchange, Kinetics, Malates isolation & purification, Mice, L-Lactate Dehydrogenase chemistry, Lactic Acid chemistry, Malate Dehydrogenase chemistry, Malates chemical synthesis

Abstract

A simple and inexpensive process of synthesis of L-malic acid from lactic acid in a system of coupled reactions is described. The resulting L-malic acid was isolated from the reaction mixture by ion-exchange chromatography. This synthesis is promising for the full-scale production of high-purity malic acid.

Published

1998

21. Functional roles of the N-terminal amino acid residues in the Mn(II)-L-malate binding and subunit interactions of pigeon liver malic enzyme.

Author

Chou WY, Huang SM, and Chang GG

Subjects

Animals, Base Sequence, Columbidae, DNA Primers chemistry, Dimerization, Electrophoresis, Polyacrylamide Gel, Kinetics, Malate Dehydrogenase analysis, Malate Dehydrogenase genetics, Molecular Sequence Data, Mutagenesis, Site-Directed, Polymerase Chain Reaction, Recombinant Proteins analysis, Recombinant Proteins chemistry, Recombinant Proteins genetics, Liver enzymology, Malate Dehydrogenase chemistry, Malates metabolism, Manganese metabolism, Protein Conformation

Abstract

Pigeon liver malic enzyme has an N-terminal amino acid sequence of Met-Lys-Lys-Gly-Tyr-Glu-. In this work, various mutants of the enzyme with individual or combinational deletion (delta) or substitution at these amino acids were constructed and functionally expressed in Escherichia coli cells. A major protein band corresponding to an Mr of approximately 65000 was observed for all recombinant enzymes in sodium dodecyl sulfate polyacrylamide gel electrophoresis. However, when examining by polyacrylamide gel electrophoresis under native conditions, the recombinant enzymes were found to possess a tetrameric structure with Mr approximately 260000 or a mixture of tetramers and dimers with the exception of delta(K2K3G4) and delta(1-16) mutants, which existed exclusively as dimers at the protein concentration we employed. K3A and K3E also dissociated substantially. K(2,3)A was a tetramer but K(2,3)E essentially existed as dimers. All tetramers and dimers were enzymatically active in the gels. All mutants displayed a similar apparent Km value for NADP+. The apparent Km for L-malate and Mn(II), on the other hand, was increased by 4-27-fold for the delta(K2/K3) and the delta(1-16) mutants. The small binding affinity of delta(K2/K3) with Mn(II)-L-malate was specific. With additional deletion at positions 3 and/or 4, the delta(K2K3), delta(K2G4/K3G4) or delta(K2K3G4) mutants exhibited similar kinetic properties for the wild type. The lysine residues at the positions 2 or 3 seem to be crucial for the correct active site conformation. The results indicate that the N-terminus of malic enzyme is located at the Mn(II)-L-malate binding domain of the active center and is also near the subunit's interface. These results were interpreted with our asymmetric double-dimer model for the enzyme in which the N-terminus was involved in the head-to-tail monomer-monomer interactions but not the dimer-dimer interactions.

Published

1997

22. Role of the divalent metal ion in the NAD:malic enzyme reaction: an ESEEM determination of the ground state conformation of malate in the E:Mn:malate complex.

Author

Tipton PA, Quinn TP, Peisach J, and Cook PF

Subjects

Animals, Ascaris suum, Binding Sites, Cations, Divalent chemistry, Deuterium, Electron Spin Resonance Spectroscopy, Malate Dehydrogenase metabolism, Manganese metabolism, NAD metabolism, Protein Binding, Spin Labels chemical synthesis, Stereoisomerism, Structure-Activity Relationship, Malate Dehydrogenase chemistry, Malates chemistry, Manganese chemistry, NAD chemistry, Protein Conformation

Abstract

The conformation of L-malate bound at the active site of Ascaris suum malic enzyme has been investigated by electron spin echo envelope modulation spectroscopy. Dipolar interactions between Mn2+ bound to the enzyme active site and deuterium specifically placed at the 2-position, the 3R-position, and the 3S-position of L-malate were observed. The intensities of these interactions are related to the distance between each deuterium and Mn2+. Several models of possible Mn-malate complexes were constructed using molecular graphics techniques, and conformational searches were conducted to identify conformers of malate that meet the distance criteria defined by the spectroscopic measurements. These searches suggest that L-malate binds to the enzyme active site in the trans conformation, which would be expected to be the most stable conformer in solution, not in the gauche conformer, which would be more similar to the conformation required for oxidative decarboxylation of oxalacetate formed from L-malate at the active site of the enzyme.

Published

1996

23. Involvement of Phe19 in the Mn(2+)-L-malate binding and the subunit interactions of pigeon liver malic enzyme.

Author

Chou WY, Liu MY, Huang SM, and Chang GG

Subjects

Amino Acid Sequence, Animals, Base Sequence, Binding Sites, Cloning, Molecular, Columbidae, Kinetics, Macromolecular Substances, Malate Dehydrogenase isolation & purification, Models, Structural, Molecular Sequence Data, Mutagenesis, Site-Directed, Oligodeoxyribonucleotides, Point Mutation, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Liver enzymology, Malate Dehydrogenase chemistry, Malate Dehydrogenase metabolism, Malates metabolism, Manganese metabolism, Phenylalanine

Abstract

A triple mutant, F19S/N250S/L353Q, of pigeon liver malic enzyme was found to have no detectable enzymatic activity [Chou, W.-Y., Huang, S.-M., & Chang, G.-G. (1994) Arch. Biochem. Biophys. 310, 158-166]. In the present study, point mutants at these positions (F19S, N250S, and L353Q) were prepared by site-directed mutagenesis. Both N250S and L353Q have kinetic properties similar to those of the wild-type. On the other hand, the K(m)(app) values for both Mn2+ and L-malate of F19S were increased by approximately 10-fold, while the kcat value was decreased by 5-fold, which results in a decrease of the apparent catalytic efficiency (kcat/K(mNADP)K(mMal)K(mMn) by approximately 300-fold. These results clearly indicate that the F19S mutation is mainly responsible for the undetectable enzyme activity of the triple mutant. Three more Phe19 mutants (F19Y, F19G, and F19A) were then prepared. There is a direct correlation between the size of the substitutes and the affinities for Mn2+ and L-malate. The kinetic parameters for F19Y were similar to those for wild-type. Both F19A and F19G reveal a 5-fold decrease of kcat values. Two K(dMn) values for the high- and low-affinity sites, respectively, were detectable for the wild-type. On the contrary, only one K(dMn) value was detected for the F19 mutants, which was increased in the order of F19G > F19A > F19S > F19Y, with F19G being the most affected mutant. The K(mMal) values of F19G and F19A were increased 100- and 6-fold, respectively. The catalytic efficiency (kcat/K(mNADP)K(dMal)K(dMn)) of F19G was decreased to only 0.01% of that of the wild-type. The above results clearly indicate that the hydrophobic aromatic ring at position 19 plays a critical role in L-malate and Mn2+ binding. Furthermore, all mutants that have a small residue at position 19 exist as monomers. Therefore, Phe19 may locate in or near the regions for Mn(2+)-L-malate binding as well as for the subunit contact. These results are compatible with the asymmetric model for the quaternary structure of malic enzyme we proposed previously [Chang, G.-G., Huang, T.-M., Huang, S.-M., & Chou, W.-Y. (1994) Eur. J. Biochem. 225, 1021-1027]. The possible roles of the N-terminus of malic enzyme were also addressed.

Published

1996

24. Modification of a thiol at the active site of the Ascaris suum NAD-malic enzyme results in changes in the rate-determining steps for oxidative decarboxylation of L-malate.

Author

Gavva SR, Harris BG, Weiss PM, and Cook PF

Subjects

Animals, Ascaris drug effects, Binding Sites drug effects, Cadmium pharmacology, Carbon Isotopes, Decarboxylation, Deuterium, Enzyme Activation, Kinetics, Magnesium pharmacology, Malates chemistry, Manganese pharmacology, Ascaris enzymology, Malate Dehydrogenase chemistry, Malates metabolism, Thiocyanates chemistry

Abstract

A thiol group at the malate-binding site of the NAD-malic enzyme from Ascaris suum has been modified to thiocyanate. The modified enzyme generally exhibits slight increases in KNAD and Ki metal and decreases in Vmax as the metal size increases from Mg2+ to Mn2+ to Cd2+, indicative of crowding in the site. The Kmalate value increases 10- to 30-fold, suggesting that malate does not bind optimally to the modified enzyme. Deuterium isotope effects on V and V/Kmalate increase with all three metal ions compared to the native enzyme concomitant with a decrease in the 13C isotope effect, suggesting a switch in the rate limitation of the hydride transfer and decarboxylation steps with hydride transfer becoming more rate limiting. The 13C effect decreases only slightly when obtained with deuterated malate, suggestive of the presence of a secondary 13C effect in the hydride transfer step, similar to data obtained with non-nicotinamide-containing dinucleotide substrates for the native enzyme (see the preceding paper in this issue). The native enzyme is inactivated in a time-dependent manner by Cd2+. This inactivation occurs whether the enzyme alone is present or whether the enzyme is turning over with Cd2+ as the divalent metal activator. Upon inactivation, only Cd2+ ions are bound at high stoichiometry to the enzyme, which eventually becomes denatured. Conversion of the active-site thiol to thiocyanate makes it more difficult to inactivate the enzyme by treatment with Cd2+.

Published

1991