Influential factor contributing to the isoform-specific inhibition by ATP of human mitochondrial NAD(P)+-dependent malic enzyme: functional roles of the nucleotide binding site Lys346

Human mitochondrial NAD(P)(+)-dependent malic enzyme (m-NAD-ME) is a malic enzyme isoform with dual cofactor specificity, ATP inhibition and substrate cooperativity. The determinant of ATP inhibition in malic enzyme isoforms has not yet been identified. Sequence alignment of nucleotide-binding sites of ME isoforms revealed that Lys346 is conserved uniquely in m-NAD-ME. In other ME isoforms, this residue is serine. As the inhibitory effect of ATP is more pronounced on m-NAD-ME than on other ME isoforms, we have examined the possible role of Lys346 by replacing it to alanine, serine or arginine. Our kinetic data indicate that the K346S mutant enzyme displays a shift in its cofactor preference from NAD(+) to NADP(+) upon increasing k(cat,NADP) and decreasing K(m,NADP). Furthermore, the cooperative binding of malate becomes less significant in human m-NAD-ME after mutation of Lys346. The h value for the wild-type is close to 2, but those of the K346 mutants are approximately 1.5. The K346 mutants can also be activated by fumarate and the cooperative effect can be abolished by fumarate, suggesting that the allosteric property is retained in these mutants. Our data strongly suggest that Lys346 in human m-NAD-ME is required for ATP inhibition. Mutation of Lys346 to Ser or Ala causes the enzyme to be much less sensitive to ATP, similar to cytosolic NADP-dependent malic enzyme. Substitution of Lys to Arg did not change the isoform-specific inhibition of the enzyme by ATP. The inhibition constants of ATP are increased for K346S and K346A, but are similar to those of the wild-type for K346R, suggesting that the positive charge rather than group specificity is required for binding affinity of ATP. Thus, ATP inhibition is proposed to be determined by the electrostatic potential involving the positive charge on the side chain of Lys346.     

Structural studies of the pigeon cytosolic NADP(+)-dependent malic enzyme.

Malic enzymes are widely distributed in nature, and have important biological functions. They catalyze the oxidative decarboxylation of malate to produce pyruvate and CO(2) in the presence of divalent cations (Mg(2+), Mn(2+)). Most malic enzymes have a clear selectivity for the dinucleotide cofactor, being able to use either NAD(+) or NADP(+), but not both. Structural studies of the human mitochondrial NAD(+)-dependent malic enzyme established that malic enzymes belong to a new class of oxidative decarboxylases. Here we report the crystal structure of the pigeon cytosolic NADP(+)-dependent malic enzyme, in a closed form, in a quaternary complex with NADP(+), Mn(2+), and oxalate. This represents the first structural information on an NADP(+)-dependent malic enzyme. Despite the sequence conservation, there are large differences in several regions of the pigeon enzyme structure compared to the human enzyme. One region of such differences is at the binding site for the 2'-phosphate group of the NADP(+) cofactor, which helps define the cofactor selectivity of the enzymes. Specifically, the structural information suggests Lys362 may have an important role in the NADP(+) selectivity of the pigeon enzyme, confirming our earlier kinetic observations on the K362A mutant. Our structural studies also revealed differences in the organization of the tetramer between the pigeon and the human enzymes, although the pigeon enzyme still obeys 222 symmetry.     

Regulation of coenzyme utilization by mitochondrial NAD(P)-dependent malic enzyme

1. Skeletal muscle mitochondrial NAD(P)-dependent malic enzyme [EC 1.1.1. 39, L-malate:NAD+ oxidoreductase (decarboxylating)] from herring could use both coenzymes, NAD and NADP, in a similar manner. 2. The coenzyme preference of mitochondrial NAD(P)-dependent malic enzyme was probed using dual wavelength spectroscopy and pairing the natural coenzymes, NAD or NADP with their respective thionicotinamide analogues, s-NADP or s-NAD, that have absorbance maxima in reduced forms at 400 nm. 3. s-NAD and s-NADP were found to be good alternate substrates for NAD(P)-dependent malic enzyme, the apparent Km values for the thioderivatives were similar to those of the corresponding natural coenzymes. 4. ATP produced greater inhibition of the NAD or s-NAD linked reactions than of the NADP or s-NADP-linked reactions of skeletal muscle mitochondrial NAD(P)-dependent malic enzyme. 5. At 5 mM malate concentration and in the presence of 2 mM ATP the NADP-linked reaction is favoured and the activity ratios, V(s-NADP)/V(NAD) or V(NADP)/V(s-NAD), are 6 and 26, respectively.     

Probing the role of lysine 116 and lysine 244 in the spinach ferredoxin-NADP+ reductase by site-directed mutagenesis

Two mutants of the spinach ferredoxin-NADP+ reductase (FNR) were constructed, expressed by using a heterologous expression system previously described (Aliverti, A., Jansen, T., Zanetti, G., Ronchi, S., Herrmann, R. G., and Curti, B. (1990) Eur. J. Biochem. 191, 551-555), and purified to homogeneity. The mutant enzymes FNR-Lys116Gln and FNR-Lys244Gln were similar to the wild-type enzyme in the physicochemical properties measured; however, both enzymes showed a lower activity. Steady-state kinetic analyses and NADP+ binding measurements of the mutant proteins have revealed that the Lys116Gln enzyme had a catalytic efficiency (kcat/KmNADPH) 500-fold lower than that of the wild-type enzyme, and its interaction with NADP+ was greatly impaired. The Lys244Gln enzyme instead had almost the same kcat in the ferricyanide reductase reaction as the wild-type enzyme, while higher values of KmNADPH and Kd for NADP+ were observed. Thus, protein engineering has enabled us to define the role of Lys-116 and Lys-244 in ferredoxin-NADP+ reductase; whereas Lys-244 contributes to the stabilization of the Michaelis complex, the Lys-116 side chain plays an important role also in the further steps of the catalytic cycle, because both Km and kcat are highly affected by the mutation.     

Study of properties of NADP malate dehydrogenase from corn leaves]

Kinetic properties of purified chloroplast isoenzyme of the "malic" enzyme from corn leaves were studied. The enzyme had optimum activity at pH 8.0 and 36 degrees C. Under standart conditions the Michaelis constants for the "malic" enzyme with Mn2+ as cofactor are 0.091 mM for malate and 0.04 mM for NADP. In case of Mg2+ as cofactor they are 0.66 and 0.02 mM respectively. Respective Km values for the cofactors Mn2+ and Mg2+ are 0.018 and 0.091 mM. The activity of the "malic" enzyme was inhibited by reduced NADP and NAD, ATP, ADP, fructose-1,6-diphosphate, oxaloacetic, oxalic, glyoxylic, glycolic and alpha-ketoglutaric acids, as well as by phosphate anions and pyrophosphate. The inhibitory effect of all metabolites and ions is more pronounced in case of Mn, rather than Mg, used as cofactors for the reaction. A possibility of metabolic regulation of NADP-"malic" enzyme activity in the leaves of C4-plants, is discussed.     

Role of aspartic acid 38 in the cofactor specificity of Drosophila alcohol dehydrogenase.

Drosophila alcohol dehydrogenase (ADH), an NAD(+)-dependent dehydrogenase, shares little sequence similarity with horse liver ADH. However, these two enzymes do have substantial similarity in their secondary structure at the NAD(+)-binding domain [Benyajati, C., Place, A. P., Powers, D. A. & Sofer, W. (1981) Proc. Natl Acad. Sci. USA 78, 2717-2721]. Asp38, a conserved residue between Drosophila and horse liver ADH, appears to interact with the hydroxyl groups of the ribose moiety in the AMP portion of NAD+. A secondary-structure comparison between the nucleotide-binding domain of NAD(+)-dependent enzymes and that of NADP(+)-dependent enzymes also suggests that Asp38 could play an important role in cofactor specificity. Mutating Asp38 of Drosophila ADH into Asn38 decreases Km(app)NADP 62-fold and increases kcat/Km(app)NADP 590-fold at pH 9.8, when compared with wild-type ADH. These results suggest that Asp38 is in the NAD(+)-binding domain and its substituent, Asn38, allows Drosophila ADH to use both NAD+ and NADP+ as its cofactor. The observations from the experiments of thermal denaturation and kinetic measurement with pH also confirm that the repulsion between the negative charges of Asp38 and 2'-phosphate of NADP+ is the major energy barrier for NADP+ to serve as a cofactor for Drosophila ADH.     

The role of malic enzyme in the malate dependent biosynthesis of progesterone in the mitochondrial fraction of human term placenta

Mitochondria isolated from human term placenta were able to form citrate from malate as the only added substrate. While mitochondria were incubated in the presence of Mn2+ the citrate formation was stimulated significantly both by NAD+ and NADP+ and was inhibited by hydroxymalonate, arsenite, butylmalonate and rotenone. It is concluded that NAD(P)-linked malic enzyme is involved in the conversion of malate to citrate in these mitochondria. It has also been shown that the conversion of cholesterol to progesterone by human term placental mitochondria incubated in the presence of malate was stimulated by NAD+ and NADP+ and inhibited by arsenite and fluorocitrate. This suggests that the stimulation by malate of progesterone biosynthesis depends not only on the generation of NADPH by NAD(P)-linked malic enzyme, but also on NADPH formed during further metabolism of pyruvate to isocitrate which is in turn efficiently oxidized by NADP+-linked isocitrate dehydrogenase.     

Purification and properties of cytosolic malic enzyme from human skeletal muscle

1. An NADP+-dependent malic enzyme was purified 7940-fold from the cytosolic fraction of human skeletal muscle with a final yield of 55.8% and a specific activity of 38.91 units/mg of protein. 2. The purification to homogeneity was achieved by ammonium sulfate fractionation, DEAE-Sepharose chromatography, affinity chromatography on NADP+-Agarose, gel filtration on Sephacryl S-300 and rechromatography on the affinity column. 3. Either Mn2+ or Mg2+ was required for activity: the pH optima with Mn2+ and Mg2+ were 8.1 and 7.5, respectively. The enzyme showed Michaelis-Menten kinetics. At pH 7.5 the apparent Km values with Mn2+ and Mg2+ for L-malate and NADP+ were 0.246 mM and 5.8 microM, and 0.304 mM and 5.8 microM, respectively. The Km values with Mn2+ for pyruvate, NADPH and bicarbonate were 8.6 mM, 6.1 microM and 22.2 mM, respectively. 4. The enzyme was also able to decarboxylate malate in the presence of NAD+. At pH 7.5 the reaction rate was approximately 10% of the rate in the presence of NADP+, with a Km value for NAD+ of 13.9 mM. 5. The following physical parameters were established: s0(20.w) = 10.48, Stokes' radius = 5.61 nm, pI = 5.72 Mr of the dissociated enzyme = 61,800. The estimates of the native apparent Mr yielded a value of 313,000 upon gel filtration, and 255,400 with f/fo = 1.33 by combining the chromatographic data with the sedimentation measurements. 6. The electron microscopy analysis of the uranyl acetate-stained enzyme revealed a tetrameric structure. 7. Investigations to detect sugar moieties indicated that the enzyme contains carbohydrate side chains, a property not previously reported for any other malic enzyme.     

Coupling of "malic" enzyme and NADPH:NAD transhydrogenase in the energetics of Hymenolepis diminuta (Cestoda)

Acetylpyridine NADP replaced NADP in promoting the Mn2+ ion-requiring mitochondrial "malic" enzyme of Hymenolepis diminuta. Disrupted mitochondria displayed low levels of an apparent oxaloacetate-forming malate dehydrogenase activity when NAD or acetylpyridine NAD served as the coenzyme. Significant malate-dependent reduction of acetylpyridine NAD by H. diminuta mitochondria required Mn2+ ion and NADP, thereby indicating the tandem operation of "malic" enzyme and NADPH:NAD transhydrogenase. Incubation of mitochondrial preparations with oxaloacetate resulted in a non-enzymatic decarboxylation reaction. Coupling of malate oxidation with electron transport via the "malic" enzyme and transhydrogenase was demonstrated by polarographic assessment of mitochondrial reduced pyridine nucleotide oxidase activity.     

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).     

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.     

Crystal structures of substrate complexes of malic enzyme and insights into the catalytic mechanism

Malic enzymes catalyze the oxidative decarboxylation of L-malate to pyruvate and CO(2) with the reduction of the NAD(P)(+) cofactor in the presence of divalent cations. We report the crystal structures at up to 2.1 A resolution of human mitochondrial NAD(P)(+)-dependent malic enzyme in different pentary complexes with the natural substrate malate or pyruvate, the dinucleotide cofactor NAD(+) or NADH, the divalent cation Mn(2+), and the allosteric activator fumarate. Malate is bound deep in the active site, providing two ligands for the cation, and its C4 carboxylate group is out of plane with the C1-C2-C3 atoms, facilitating decarboxylation. The divalent cation is positioned optimally to catalyze the entire reaction. Lys183 is the general base for the oxidation step, extracting the proton from the C2 hydroxyl of malate. Tyr112-Lys183 functions as the general acid-base pair to catalyze the tautomerization of the enolpyruvate product from decarboxylation to pyruvate.     

Evidence for the role of malic enzyme in the rapid oxidation of malate by cod heart mitochondria

Mitochondria isolated from the heart of cod (Gadus morrhua callarias) oxidized malate as the only exogenous substrate very rapidly. Pyruvate only slightly increased malate oxidation by these mitochondria. This is in contrast with the mitochondria isolated from rat and rabbit heart which oxidized malate very slowly unless pyruvate was added. Arsenite and hydroxymalonate (an inhibitor of malic enzyme) inhibited the respiration rate of mitochondria isolated from cod heart, when malate was the only exogenous substrate. Inhibition caused by hydroxymalonate was reversed by the addition of pyruvate. In the presence of arsenite, malate was converted to pyruvate by cod heart mitochondria. Cod heart mitochondria incubated in the medium containing Triton X-100 catalyzed the reduction of NADP+ in the presence of L-malate and Mn2+ at relatively high rate (about 160 nmoles NADPH formed/min/mg mitochondrial protein). The oxidative decarboxylation of malate was also taking place when NADP+ was replaced by NAD+ (about 25 nmol NADH formed per min per mg mitochondrial protein). These results suggest that the mitochondria contain both NAD+- and NADP+-linked malic enzymes. These two activities were eluted from DEAE-Sephacel as two independent peaks. It is concluded that malic enzyme activity (presumably both NAD+- and NADP+-linked) is responsible for the rapid oxidation of malate (as the only external substrate) by cod heart mitochondria.     

Malic enzyme in human liver. Intracellular distribution, purification and properties of cytosolic isozyme

In human liver, almost 90% of malic enzyme activity is located within the extramitochondrial compartment, and only approximately 10% in the mitochondrial fraction. Extramitochondrial malic enzyme has been isolated from the post-mitochondrial supernatant of human liver by (NH4)2SO4 fractionation, chromatography on DEAE-cellulose, ADP-Sepharose-4B and Sephacryl S-300 to apparent homogeneity, as judged from polyacrylamide gel electrophoresis. The specific activity of the purified enzyme was 56 mumol.min-1.mg protein-1, which corresponds to about 10,000-fold purification. The molecular mass of the native enzyme determined by gel filtration is 251 kDa. SDS/polyacrylamide gel electrophoresis showed one polypeptide band of molecular mass 63 kDa. Thus, it appears that the native protein is a tetramer composed of identical-molecular-mass subunits. The isoelectric point of the isolated enzyme was 5.65. The enzyme was shown to carboxylate pyruvate with at least the same rate as the forward reaction. The optimum pH for the carboxylation reaction was at pH 7.25 and that for the NADP-linked decarboxylation reaction varied with malate concentration. The Km values determined at pH 7.2 for malate and NADP were 120 microM and 9.2 microM, respectively. The Km values for pyruvate, NADPH and bicarbonate were 5.9 mM, 5.3 microM and 27.9 mM, respectively. The enzyme converted malate to pyruvate (at optimum pH 6.4) in the presence of 10 mM NAD at approximately 40% of the maximum rate with NADP. The Km values for malate and NAD were 0.96 mM and 4.6 mM, respectively. NAD-dependent decarboxylation reaction was not reversible. The purified human liver malic enzyme catalyzed decarboxylation of oxaloacetate and NADPH-linked reduction of pyruvate at about 1.3% and 5.4% of the maximum rate of NADP-linked oxidative decarboxylation of malate, respectively. The results indicate that malic enzyme from human liver exhibits similar properties to the enzyme from animal liver.     

NADP+ -dependent malic enzyme of Rhizobium meliloti.

The bacterium Rhizobium meliloti, which forms N2-fixing root nodules on alfalfa, has two distinct malic enzymes; one is NADP+ dependent, while a second has maximal activity when NAD+ is the coenzyme. The diphosphopyridine nucleotide (NAD+)-dependent malic enzyme (DME) is required for symbiotic N2 fixation, likely as part of a pathway for the conversion of C4-dicarboxylic acids to acetyl coenzyme A in N2-fixing bacteroids. Here, we report the cloning and localization of the tme gene (encoding the triphosphopyridine nucleotide [NADP+]-dependent malic enzyme) to a 3.7-kb region. We constructed strains carrying insertions within the tme gene region and showed that the NADP+ -dependent malic enzyme activity peak was absent when extracts from these strains were eluted from a DEAE-cellulose chromatography column. We found that NADP+ -dependent malic enzyme activity was not required for N2 fixation, as tme mutants induced N2-fixing root nodules on alfalfa. Moreover, the apparent NADP+ -dependent malic enzyme activity detected in wild-type (N2-fixing) bacteroids was only 20% of the level detected in free-living cells. Much of that residual bacteroid activity appeared to be due to utilization of NADP+ by DME. The functions of DME and the NADP+ -dependent malic enzyme are discussed in light of the above results and the growth phenotypes of various tme and dme mutants.     

Enzymes of malate metabolism in Mesorhizobium ciceri CC 1192

Electrophoretic studies were performed on enzymes concerned with the oxidation of malate in free-living and bacteroid cells of Mesorhizobium ciceri CC 1192, which forms nitrogen-fixing symbioses with chickpea (Cicer arietinum L.) plants. Two malate dehydrogenases were detected in extracts from both types of cells in native polyacrylamide electrophoresis gels that were stained for enzyme activity. One band of malate dehydrogenase activity was stained only in the presence of NADP+, whereas the other band was revealed with NAD+ but not NADP+. Further evidence for the occurrence of separate NAD- and NADP-dependent malate dehydrogenases was obtained from preliminary enzyme kinetic studies with crude extracts from free-living M. ciceri CC 1192 cells. Activity staining of electrophoretic gels also indicated the presence of two malic enzymes in free-living and bacteroid cells of M. ciceri CC 1192. One malic enzyme was active with both NAD+ and NADP+, whereas the other was specific for NADP+. Possible roles of the multiple forms of malate dehydrogenase and malic enzyme in nitrogen-fixing symbioses are discussed.     

Molecular mechanism for the regulation of human mitochondrial NAD(P)+-dependent malic enzyme by ATP and fumarate

The regulation of human mitochondrial NAD(P)+-dependent malic enzyme (m-NAD-ME) by ATP and fumarate may be crucial for the metabolism of glutamine for energy production in rapidly proliferating tissues and tumors. Here we report the crystal structure at 2.2 A resolution of m-NAD-ME in complex with ATP, Mn2+, tartronate, and fumarate. Our structural, kinetic, and mutagenesis studies reveal unexpectedly that ATP is an active-site inhibitor of the enzyme, despite the presence of an exo binding site. The structure also reveals the allosteric binding site for fumarate in the dimer interface. Mutations in this binding site abolished the activating effects of fumarate. Comparison to the structure in the absence of fumarate indicates a possible molecular mechanism for the allosteric function of this compound.     

The mitochondrial malic enzymes. I. Submitochondrial localization and purification and properties of the NAD(P)+-dependent enzyme from adrenal cortex.

Rat and calf adrenal cortex homogenates were found to contain three different malic enzymes. Two were strictly NADP+-dependent and were localized, one each, in the cytosol and the mitochondrial fractions, respectively. These two enzymes appear to be identical to those described by Simpson and Estabrook (Simpson, E. R., and Estabrook, R. W. (1969) Arch. Biochem. Biophys. 129, 384-395). The third was NAD(P)+-linked and was present in the mitochondrial fraction only. All three malic enzymes separated as distinct bands during electrophoresis on 5 percent polyacrylamide slab gels at pH 9.0. Marker enzymes and the mitochondrial malic enzymes migrated together in intact mitochondria during sucrose density gradient centrifugations despite changes in the equilibrium position of the mitochondria promoted by energy-dependent calcium phosphate accumulation. In adrenal cortex mitochondria subfractionated by the method of Sottocasa et al. (SOTTOCASA, G.L., KUYLENSTIERNA, B., ERNSTER, L., and BERGSTAND, A. (1967) J. Cell Biol. 32, 415-438), both malic enzymes were associated with the inner membrane-matrix space. Sonication solubilized the two malic enzymes along with the matrix space marker enzymes. The NAD(P)+-dependent malic enzyme was purified 100-fold from calf adrenal cortex mitochondria. The final preparation was free of malic dehydrogenase, fumarase, the strictly NADP+-linked malic enzyme and adenylate kinase. Either Mn24 orMg2+ was required for activity and 1 mol of pyruvate was formed for each mole of NAD+ and NADP+ reduced. The pH optima with NAD+ and NADP+ were 6.5 tp 7.0 and 6.0 to 6.5, respectively. Michaelis-Menten kinetics were observed on the alkaline side. Fumarate, succinate, and isocitrate were positive and ATP and ADP were negative modulators of the regulatory enzyme. The modulators did not influence the stoichiometry and they were not metabolized during the reaction. Under Vmax conditions the ratios for the rate of NAD+:NADP+ reduction were 1.76 and 1.15 at pH 7.4 and 6.0, respectively. The apparent Michaelis constants also differed depending on the pH and the coenzyme. At pH 7.4 (in the presence of 5 mM fumarate) and at pH 6.0 (no fumarate) the Km values for (-)-malate, NAD+, and Mn2+ were 1.7, 0.16, and 0.15 mM, and 0.31, 0.06, and 0.09 mM, respectively. At pH 7.4 (5MM fumarate) and pH 6.0 (no fumarate), the Km values for (-)-malate, NADP+, and Mn2+ were 6.5, 0.62, and 0.59 mM, and 0.68. 0.12, and 0.31 mM, respectively. The apparent Ki values for ATP with NAD+ and NADP+ as coenzyme were 0.42 and 0.27 mM, respectively.     

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.