Crystal structure of Escherichia coli malate dehydrogenase. A complex of the apoenzyme and citrate at 1.87 A resolution.

The crystal structure of malate dehydrogenase from Escherichia coli has been determined with a resulting R-factor of 0.187 for X-ray data from 8.0 to 1.87 A. Molecular replacement, using the partially refined structure of porcine mitochondrial malate dehydrogenase as a probe, provided initial phases. The structure of this prokaryotic enzyme is closely homologous with the mitochondrial enzyme but somewhat less similar to cytosolic malate dehydrogenase from eukaryotes. However, all three enzymes are dimeric and form the subunit-subunit interface through similar surface regions. A citrate ion, found in the active site, helps define the residues involved in substrate binding and catalysis. Two arginine residues, R81 and R153, interacting with the citrate are believed to confer substrate specificity. The hydroxyl of the citrate is hydrogen-bonded to a histidine, H177, and similar interactions could be assigned to a bound malate or oxaloacetate. Histidine 177 is also hydrogen-bonded to an aspartate, D150, to form a classic His.Asp pair. Studies of the active site cavity indicate that the bound citrate would occupy part of the site needed for the coenzyme. In a model building study, the cofactor, NAD, was placed into the coenzyme site which exists when the citrate was converted to malate and crystallographic water molecules removed. This hypothetical model of a ternary complex was energy minimized for comparison with the structure of the binary complex of porcine cytosolic malate dehydrogenase. Many residues involved in cofactor binding in the minimized E. coli malate dehydrogenase structure are homologous to coenzyme binding residues in cytosolic malate dehydrogenase. In the energy minimized structure of the ternary complex, the C-4 atom of NAD is in van der Waals' contact with the C-3 atom of the malate. A catalytic cycle involves hydride transfer between these two atoms.     

Introduction of unnatural amino acids into chalcone isomerase.

The active site cysteine residue of chalcone isomerase was rapidly and selectively modified under denaturing conditions with a variety of electrophilic reagents. These denatured and modified enzyme were renatured to produce enzyme derivatives containing a series of unnatural amino acids in the active site. Addition of methyl, ethyl, butyl, heptyl, and benzyl groups to the cysteine sulfur does not abolish catalytic activity, although the activity decreases as the steric bulk of the amino acid side-chain increases. Modification of the cysteine to introduce a charged homoglutamate or a neutral homoglutamine analogue results in retention of 22% of the catalytic activity. Addition of a methylthio group (SMe) to the cysteine residue of native chalcone isomerase preserves 85% of the catalytic activity measured with 2',4',4-trihydroxychalcone, 2',4',6',4-tetrahydroxychalcone, or 2'-hydroxy-4-methoxychalcone as substrates. The competitive inhibition constant for 4',4-dihydroxychalcone, the substrate inhibition constant for 2',4',4-trihydroxychalcone, and other steady-state kinetic parameters for the methanethiolated enzyme are very similar to those of the native enzyme. The strong binding of 4',4-dihydroxychalcone to the methanethiolated enzyme shows that there is no steric repulsion between this modified amino acid residue and the substrate analogue. This structure-activity study clearly demonstrates that the active site cysteine residue does not function as an acid-base or nucleophilic group in producing the catalysis or substrate inhibition observed with chalcone isomerase. The method presented in this paper allows for the rapid introduction of a series of unnatural amino acids into the active site as a means of probing the structure-function relationship.     

Limited proteolysis of inactive tetrameric chloroplast NADP-malate dehydrogenase produces active dimers

Carboxy-terminal amino acids of NADP-dependent malate dehydrogenase (EC 1.1.1.82) from pea chloroplasts were removed by treatment with carboxypeptidase Y. This results in the activation of the inactive oxidized enzyme, while activation by light in vivo is thought to occur via reduction of an intrasubunit disulfide bridge. After proteolytic activation the oxidized enzyme had a specific activity of 100 U/mg protein, which is 50% of the maximal activity of the control enzyme in the reduced state. When the truncated enzyme was reduced with dithiothreitol (DTT), the specific activity was further increased to 1200 U/mg. While the native enzyme is composed of four identical subunits of 38,900 Da, the truncated malate dehydrogenase forms dimers composed of two subunits of 38,000 Da. No further change of molecular mass or activity was noticed subsequent to prolonged incubation of native NADP-malate dehydrogenase with carboxypeptidase Y for several days. When the enzyme is denatured by 2 M guanidine-HCl, the proteolytic activation proceeds more rapidly, but only transiently. The truncated enzyme is less accessible to activation by reduced thioredoxin, but the stimulation of activity by DTT alone is more rapid than that of the native enzyme. These results indicate that only a small carboxy-terminal peptide of native NADP-malate dehydrogenase from pea chloroplasts is accessible to proteolytic degradation and that this peptide is involved in the regulation of activity, tetramer formation, and thioredoxin binding. While the pH optimum for catalytic activity of the intact reduced enzyme is at pH 8.0-8.5, it is shifted to more acidic values upon proteolysis of NADP-malate dehydrogenase. At pH values below 8 the reduced truncated enzyme exhibits substrate inhibition by oxaloacetate.     

Effect of thiol reagents on the activity of NADP-dependent malate dehydrogenase isolated from bovine adrenal cortex cytoplasm

NADP-dependent malate dehydrogenase was rapidly inactivated in the presence of mercurous chloride. Titration of malate dehydrogenase by 5,5'-dithiobis (2-nitrobenzoic acid) (DTNB) in a solution of 8 M urea revealed 18 SH groups per molecule of the enzyme. Eight sulphydryl groups reacted with DTNB in native malate dehydrogenase and their modification was not accompanied by a loss of the enzyme activity. The interaction of p-chloromercury benzoate (PCMB) with malate dehydrogenase resulted in a 70% decrease in the enzyme activity. The binding of the thiol reagents by the malate dehydrogenase molecule appreciably increased the Michaelis constant value for the substrate. In the presence of magnesium ions, NADP and malate did not affect the process of malate dehydrogenase modification by DTNB and did not protect the enzyme from the inactivation by PCMB. It is suggested from the data obtained that the sulphyryl groups are involved in maintaining the active conformation of the enzyme.     

Regulation of mitochondrial malate dehydrogenase: kinetic modulation independent of subunit interaction

Porcine heart mitochondrial malate dehydrogenase (EC 1.1.1.37), a dimeric enzyme of Mr = 70,000, is both allosterically activated and inhibited by citrate. Using an affinity elution procedure based upon citrate binding to malate dehydrogenase, the isolation of pure heterodimer (a dimeric species with one active subunit and one iodoacetamide-inactivated subunit) has been achieved. Investigations utilizing this heterodimer in conjunction with resin-bound monomers of malate dehydrogenase have allowed the formulation of a definite conclusion concerning the role of subunit interactions in catalysis and regulation of this enzyme. The citrate kinetic effects, oxaloacetate inhibition, malate activation, and the effects of 2-thenoyl-trifluoroacetone (TTFA) are shown to be independent of interaction between catalytically active subunits. Previous kinetic data thought to support a reciprocating catalytic mechanism for this enzyme may be reinterpreted upon closer analysis in relation to an allosteric, conformationally specific binding model for malate dehydrogenase.     

Rational construction of a 2-hydroxyacid dehydrogenase with new substrate specificity

Using site-directed mutagenesis on the lactate dehydrogenase gene from Bacillus stearothermophilus, three amino acid substitutions have been made at sites in the enzyme which we suggest in part determine specificity toward different hydroxyacids (R-CHOH-COOH). To change the preferred substrates from the pyruvate/lactate pair (R = -CH3) to the oxaloacetate/malate pair (R = -CH2-COO-), the volume of the active site was increased (thr 246----gly), an acid was neutralized (asp-197----asn) and a base was introduced (gln-102 - greater than arg). The wild type enzyme has a catalytic specificity for pyruvate over oxaloacetate of 1000 whereas the triple mutant has a specificity for oxaloacetate over pyruvate of 500. Despite the severity and extent of these active site alterations, the malate dehydrogenase so produced retains a reasonably fast catalytic rate constant (20 s-1 for oxaloacetate reduction) and is still allosterically controlled by fructose-1,6-bisphosphate.     

Identification of an essential cysteine in the reaction catalyzed by aspartate-beta-semialdehyde dehydrogenase from Escherichia coli.

The enzyme L-aspartate-beta-semialdehyde dehydrogenase from Escherichia coli has been studied by oligonucleotide-directed mutagenesis. The focus of this investigation was to examine the role of a cysteine residue that had been previously identified by chemical modification with an active site directed reagent (Biellmann et al. (1980) Eur. J. Biochem. 104, 59-64). Substitution of this cysteine at position 135 with an alanine results in complete loss of enzyme activity. However, changing this cysteine to a serine yields a mutant enzyme with a maximum velocity that is 0.3% that of the native enzyme. This C135S mutant has retained essentially the same affinity for substrates as the native enzyme, and the same overall conformation as reflected in identical behavior on gel electrophoresis and in identical fluorescence spectra. The pH profile of the native enzyme shows a loss in catalytic activity upon protonation of a group with a pKa value of 7.7. The same activity loss is observed at this pH with the serine-135 mutant, despite the differences in the pKa values for a cysteine sulfhydryl and a serine hydroxyl group that have been measured in model compounds. This observed pKa value may reflect the protonation of an auxiliary catalyst that enhances the reactivity of the active site cysteine nucleophile in the native aspartate-beta-semialdehyde dehydrogenase.     

Structural analyses of a malate dehydrogenase with a variable active site

Malate dehydrogenase specifically oxidizes malate to oxaloacetate. The specificity arises from three arginines in the active site pocket that coordinate the carboxyl groups of the substrate and stabilize the newly forming hydroxyl/keto group during catalysis. Here, the role of Arg-153 in distinguishing substrate specificity is examined by the mutant R153C. The x-ray structure of the NAD binary complex at 2.1 A reveals two sulfate ions bound in the closed form of the active site. The sulfate that occupies the substrate binding site has been translated approximately 2 A toward the opening of the active site cavity. Its new location suggests that the low catalytic turnover observed in the R153C mutant may be due to misalignment of the hydroxyl or ketone group of the substrate with the appropriate catalytic residues. In the NAD.pyruvate ternary complex, the monocarboxylic inhibitor is bound in the open conformation of the active site. The pyruvate is coordinated not by the active site arginines, but through weak hydrogen bonds to the amide backbone. Energy minimized molecular models of unnatural analogues of R153C (Wright, S. K., and Viola, R. E. (2001) J. Biol. Chem. 276, 31151-31155) reveal that the regenerated amino and amido side chains can form favorable hydrogen-bonding interactions with the substrate, although a return to native enzymatic activity is not observed. The low activity of the modified R153C enzymes suggests that precise positioning of the guanidino side chain is essential for optimal orientation of the substrate.     

Brain succinic semialdehyde dehydrogenase. Reactions of sulfhydryl residues connected with catalytic activity.

Incubation of an NAD+-dependent succinic semialdehyde dehydrogenase from bovine brain with 4-dimethylaminoazobenzene-4-iodoacetamide (DABIA) resulted in a time-dependent loss of enzymatic activity. This inactivation followed pseudo first-order kinetics with a second-order rate constant of 168 m(-1).min(-1). The spectrum of DABIA-labeled enzyme showed a characteristic peak of the DABIA alkylated sulfhydryl group chromophore at 436 nm, which was absent from the spectrum of the native enzyme. A linear relationship was observed between DABIA binding and the loss of enzyme activity, which extrapolates to a stoichiometry of 8.0 mol DABIA derivatives per mol enzyme tetramer. This inactivation was prevented by preincubating the enzyme with substrate, succinic semialdehyde, but not by preincubating with coenzyme NAD+. After tryptic digestion of the enzyme modified with DABIA, two peptides absorbing at 436 nm were isolated by reverse-phase HPLC. The amino acid sequences of the DABIA-labeled peptides were VCSNQFLVQR and EVGEAICTDPLVSK, respectively. These sites are identical to the putative active site sequences of other brain succinic semialdehyde dehydrogenases. These results suggest that the catalytic function of succinic semialdehyde dehydrogenase is inhibited by the specific binding of DABIA to a cysteine residue at or near its active site.     

Chloramphenicol binding site of an fi− R-factor-specified variant of chloramphenicol acetyltransferase

Chloramphenicol acetyltransferase (EC 2.3.1.28) specified by the fi^? R-factor (type II) is highly sensitive to sulfhydryl reagents. When this variant was treated with stoichiometric amounts of 2, 2′dithiobispyridine, 90% of the enzymatic activity was lost with concomitant introduction of 0.9to 1.0 thiopyridine groups per mole of enzyme protomer. In the presence of stoichiometric amounts of the substrate, chloramphenicol, the enzyme was neither inactivated nor modified by the sulfhydryl reagents. Acetyl-coenzyme A exerted no protective effects when present in the reaction mixture. The enzyme was also inactivated by cyanylation with a stoichiometric amount of 2-nitro-5-thiocyanobenzoic acid. Labeling native type II enzyme with iodo[¹⁴C]acetamide and subsequently subjecting it to peptic digestion yielded one radioactive peptide. This cysteine-containing peptide had the same sequence as that found near the cysteine close to the chloramphenicol binding site of the commonly occurring type 1 enzyme. In conclusion, this cysteine residue is essential for the catalytic activity of both types of enzyme and is located in or near the chloramphenicol binding site. It also seems that the cysteine in type II is more sensitive to sulfhydryl reagents than the homologous cysteine in type I, probably because it is more available for modification.     

On the effect on specificity of Thr246----Gly mutation in L-lactate dehydrogenase of Bacillus sterothermophilus

The function of the amino acid Thr246 in L-lactate dehydrogenase from Bacillus stearothermophilus has been investigated by site-directed replacement with glycine. Kinetic experiments with a number of 2-oxo acids showed strongly reduced activity for the mutated enzyme. However, the mutant enzyme shows a relative preference for the large hydrophobic sidechains of alpha-keto acids and an even higher specific activity than the wild-type lactate dehydrogenase for the polar oxaloacetate substrate. Graphic analyses indicate that the loss of one hydrogen bond, or intrusion of water into the active site, might be responsible for the reduced activity. The kinetic results suggest that the binding modes of bulky hydrophobic or polar substrates compensate to some degree for the partially disrupted active site.     

New properties of Bacillus subtilis succinate dehydrogenase altered at the active site. The apparent active site thiol of succinate oxidoreductases is dispensable for succinate oxidation.

Mammalian and Escherichia coli succinate dehydrogenase (SDH) and E. coli fumarate reductase apparently contain an essential cysteine residue at the active site, as shown by substrate-protectable inactivation with thiol-specific reagents. Bacillus subtilis SDH was found to be resistant to this type of reagent and contains an alanine residue at the amino acid position equivalent to the only invariant cysteine in the flavoprotein subunit of E. coli succinate oxidoreductases. Substitution of this alanine, at position 252 in the flavoprotein subunit of B. subtilis SDH, by cysteine resulted in an enzyme sensitive to thiol-specific reagents and protectable by substrate. Other biochemical properties of the redesigned SDH were similar to those of the wild-type enzyme. It is concluded that the invariant cysteine in the flavoprotein of E. coli succinate oxidoreductases corresponds to the active site thiol. However, this cysteine is most likely not essential for succinate oxidation and seemingly lacks an assignable specific function. An invariant arginine in juxtaposition to Ala-252 in the flavoprotein of B. subtilis SDH, and to the invariant cysteine in the E. coli homologous enzymes, is probably essential for substrate binding.     

Crystalline NAD/NADP-dependent malate dehydrogenase; the enzyme from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius

Malate dehydrogenase from Sulfolobus acidocaldarius has been purified 240-fold to apparent electrophoretic homogeneity. The enzyme shows a specific activity of 277 U/mg and crystallizes readily. The relative molecular mass of the native enzyme is estimated as 128,500 by ultracentrifugation. After cross-linking a relative molecular mass of 134,000 is found by sodium dodecyl sulfate gel electrophoresis. Malate dehydrogenase from S. acidocaldarius is composed of four subunits of identical size with a relative molecular mass of 34,000. Active-enzyme sedimentation in the analytical ultracentrifuge indicates that the tetramer is the catalytically active species. Kinetic studies in the direction of oxaloacetate reduction showed a Km for NADH of 4.1 microM and a Km for oxaloacetate of 52 microM. Oxaloacetate exhibits substrate inhibition at higher concentrations, L-malate, NAD and NADP were found to be product inhibitors. The enzymatic activity is inhibited by 2-oxoglutarate but not by the adenosine nucleotides AMP, ADP and ATP. Only low activity is detected in the direction of malate oxidation. Malate dehydrogenase from S. acidocaldarius utilizes both NADH and NADPH to reduce oxaloacetate. The enzyme shows A-side stereospecificity for both nicotinamide dinucleotides.     

Structural basis of substrate specificity in malate dehydrogenases: crystal structure of a ternary complex of porcine cytoplasmic malate dehydrogenase, alpha-ketomalonate and tetrahydoNAD

The structural basis for the extreme discrimination achieved by malate dehydrogenases between a variety of closely related substrates encountered within the cell has been difficult to assess because of the lack of an appropriate catalytically competent structure of the enzyme. Here, we have determined the crystal structure of a ternary complex of porcine cytoplasmic malate dehydrogenase with the alternative substrate alpha-ketomalonate and the coenzyme analogue 1,4,5,6-tetrahydronicotinamide. Both subunits of the dimeric porcine heart, and from the prokaryotes Escherichia coli and Thermus flavus. However, large changes are noted around the active site, where a mobile loop now closes to bring key residues into contact with the substrate. This observation substantiates a postulated mechanism in which the enzyme achieves high levels of substrate discrimination through charge balancing in the active site. As the activated cofactor/substrate complex has a net negative charge, a positive counter-charge is provided by a conserved arginine in the active site loop. The enzyme must, however, also discriminate against smaller substrates, such as pyruvate. The structure shows in the closed (loop down) catalytically competent complex two arginine residues (91 and 97) are driven into close proximity. Without the complimentary, negative charge of the substrate side-chain of oxaloacetate or alpha-ketomalonate, charge repulsion would resist formation production of this catalytically productive conformation, hence minimising the effectiveness of pyruvate as a substrate. By this mechanism, malate dehydrogenase uses charge balancing to achieve fivefold orders of magnitude in discrimination between potential substrates.     

Regulation of C4 photosynthesis: Physical and kinetic properties of active (dithiol) and inactive (disulfide) NADP-malate dehydrogenase from Zea mays

NADP-malate dehydrogenase was purified from leaves of Zea mays in the absence of thiol-reducing agents by (NH₄)₂SO₄, polyethylene glycol, and pH fractionation followed by dye-ligand affinity chromatography and gel filtration. The purified enzyme is completely inactive (no activity detected between pH 6 and 9) but can be reactivated by thiol-reducing agents including dithiothreitol and thioredoxin. The active enzyme shows distinctly alkaline pH optima when assayed in either direction; K_m values at pH 8.5 are oxaloacetate, 18 μm; malate, 24 mm; NADPH, 50 μm; and NADP, 45 μm. The reduction of oxaloacetate is inhibited by NADP (competitive with respect to NADPH, K_i = 50 μm). The molecular weight of the native inactive or active enzyme is 150,000 with subunits of M_r 38,000. Active enzyme is much more sensitive (>50-fold) to heat denaturation than is the inactive enzyme and is irreversibly inactivated by N-ethylmaleimide whereas the inactive enzyme is insensitive to this reagent. The active and inactive forms of NADP-malate dehydrogenase are assumed to correspond to dithiol and disulfide forms of the enzyme, respectively. The relative coenzyme-binding affinities of inactive NADP-malate dehydrogenase differ by a factor of 10² from the binding affinities for active NADP-malate dehydrogenase and 10⁴ for non-thiol-regulated NAD-specific malate dehydrogenase. It is proposed that the 100-fold change in differential binding of NADP and NADPH upon conversion of NADP-malate dehydrogenase to the disulfide form may sufficiently alter the equilibrium of the central enzyme-substrate complexes, and hence the catalytic efficiency of the enzyme, to explain the associated loss of activity.     

Chemical modification of bovine heart mitochondrial malate dehydrogenase. Selective modification of cysteine and histidine.

Bovine mitochondrial malate dehydrogenase (EC 1.1.1.37) was inactivated by the specific modifications of a single histidine residue upon reaction with iodoacetamide. NADH protected against this loss of activity and reaction with the histidine residue, suggesting that the histidine is at the NADH binding site. N-Ethylmaleimide also modified the enzyme by reacting with 1 sulfhydryl residue. The reaction rate with N-ethylmaleimide was increased by decreasing the pH from neutrality or by the addition of urea. NADH protected against the modification of the sulfhydryl group under all the conditions tested, again suggesting active site specificity for this inactivation. This enzyme has a subunit weight of 33,000 and is a dimer. The native malate dehydrogenase will bind only 1 mol of NADH and it is thus assumed that there is only a single active site per dimer.     

Insights into the mechanism of dihydropyrimidine dehydrogenase from site-directed mutagenesis targeting the active site loop and redox cofactor coordination

In mammals, the pyrimidines uracil and thymine are metabolised by a three-step reductive degradation pathway. Dihydropyrimidine dehydrogenase (DPD) catalyses its first and rate-limiting step, reducing uracil and thymine to the corresponding 5,6-dihydropyrimidines in an NADPH-dependent reaction. The enzyme is an adjunct target in cancer therapy since it rapidly breaks down the anti-cancer drug 5-fluorouracil and related compounds. Five residues located in functionally important regions were targeted in mutational studies to investigate their role in the catalytic mechanism of dihydropyrimidine dehydrogenase from pig. Pyrimidine binding to this enzyme is accompanied by active site loop closure that positions a catalytically crucial cysteine (C671) residue. Kinetic characterization of corresponding enzyme mutants revealed that the deprotonation of the loop residue H673 is required for active site closure, while S670 is important for substrate recognition. Investigations on selected residues involved in binding of the redox cofactors revealed that the first FeS cluster, with unusual coordination, cannot be reduced and displays no activity when Q156 is mutated to glutamate, and that R235 is crucial for FAD binding.     

4,4'-Bis dimethylaminodiphenylcarbinol: a new reagent for selective chemical modification. Interaction with porcine malate dehydrogenase

4,4-bis Dimethylaminodiphenylcarbinol (BDC-OH) has recently been reported to be a highly sensitive reagent for the quantitative determination of sulfhydryl residues in biological materials (1). In this communication the effectiveness of BDC-OH as a reagent for selective chemical modification of “active center” cysteine residues was investigated. The supernatant and mitochondrial forms of malate dehydrogenase were chosen for investigation by this reagent. Supernatant malate dehydrogenase which has never been found to contain an “active center” cysteine is unaffected by this reagent. Mitochondrial malate dehydrogenase (L malate: NAD⁺ oxidoreductase, EC 1.1.1.37) from porcine heart can be irreversibly inactivated by a 20 fold M excess of the reagent. Chemical modification of two essential sulfhydryl residues is prevented by the presence of the coenzyme, NAD⁺, suggesting that the site of interaction is located at or near the coenzyme binding site and hence at or near the enzymatic center of this enzyme.     

Malate Dehydrogenase and NAD Malic Enzyme in the Oxidation of Malate by Sweet Potato Mitochondria

Over a range of concentrations from less than 0.1 mm to more than 70 mm, sweet potato root mitochondria display a bimodal substrate saturation isotherm for malate. The high affinity portion of the isotherm has an apparent Km for malate of 0.85 mm and fits a rectangular hyperbolic function. The low affinity portion of the isotherm is sigmoid in character and gives an apparent S(0.5) of 40.6 mm and a Hill number of 3.7.Extracts of sweet potato mitochondria contain both malate dehydrogenase and NAD malic enzyme. The malate dehydrogenase, assayed in the forward direction at pH 7.2, shows typical Michaelis-Menten kinetics with a Km for malate of 0.38 mm. The NAD malic enzyme shows pronounced sigmoidicity in response to malate with a Hill number of 3.5 and an S(0.5) of 41.6 mm.On the basis of the normal kinetics, the Km, and the fact that oxaloacetate production from malate by mitochondria appears most active at low malate concentrations, the high affinity portion of the malate isotherm with mitochondria is attributed to malate dehydrogenase. The low affinity portion of the malate isotherm with mitochondria is thought, on the basis of the similarity of S(0.5) values, the Hill numbers, and the greater production of pyruvate from malate at high malate concentrations, to represent the activity of the NAD malic enzyme.     

Novel substrate specificity of designer 3-isopropylmalate dehydrogenase derived from Thermus thermophilus HB8

Redesigning of an enzyme for a new catalytic reaction and modified substrate specificity was exploited with 3-isopropylmalate dehydrogenase (IPMDH). Point-mutation on Gly-89, which is not in the catalytic site but near it, was done by changing it to Ala, Ser, Val, and Pro, and all the mutations changed the substrate specificity. The mutant enzymes showed higher catalytic efficiency (kcat/Km) than the native IPMDH when malate was used as a substrate instead of 3-isopropylmalate. More interestingly, an additional insertion of Gly between Gly-89 and Leu-90 significantly altered the substrate-specificity, although the overall catalytic activity was decreased. Particularly, this mutant turned out to efficiently accept D-lactic acid, which was not accepted as a substrate by wild-type IPMDH at all. These results demonstrate the opportunity for creating nove,enzymes by modification of amino acid residues that do not directly participate in catalysis, or by insertion of additional residues.