From analysis to synthesis: new ligand binding sites on the lactate dehydrogenase framework. Part II

Tropinone reductase: A comprehensive review on its role as the key enzyme in tropane alkaloids biosynthesis

TAs, including hyoscyamine and scopolamine, were used to treat neuromuscular disorders ranging from nerve agent poisoning to Parkinson's disease. Tropinone reductase I (TR-I; EC 1.1.1.206) catalyzed the conversion of tropinone into tropine in the biosynthesis of TAs, directing the metabolic flow towards hyoscyamine and scopolamine. Tropinone reductase II (TR-II; EC 1.1.1.236) was responsible for the conversion of tropinone into pseudotropine, diverting the metabolic flux towards calystegine A3. The regulation of metabolite flow through both branches of the TAs pathway seemed to be influenced by the enzymatic activity of both enzymes and their accessibility to the precursor tropinone. The significant interest in the utilization of metabolic engineering for the efficient production of TAs has highlighted the importance of TRs as crucial enzymes that govern both the direction of metabolic flow and the yield of products. This review discussed recent advances for the TRs sources, properties, protein structure and biocatalytic mechanisms, and a detailed overview of its crucial role in the metabolism and synthesis of TAs was summarized. Furthermore, we conducted a detailed investigation into the evolutionary origins of these two TRs. A prospective analysis of potential challenges and applications of TRs was presented.

Molecular cloning and characterization of a novel lactate dehydrogenase gene from Clonorchis sinensis

From a Clonorchis sinensis adult worm cDNA library, we isolated a cDNA clone encoding a novel lactate dehydrogenase (LDH) gene which encoded a putative protein with a predicted molecular weight of 35.6 kDa. The optimum pH and temperature for the enzyme were 7.5 and 50 degrees C in the pyruvate reduction while 11 and 80 degrees C in the lactate oxidation reaction, respectively. CsLDH showed no substrate inhibition by high lactate and NAD(+) concentration, and the optimal pyruvate and optimal NADH concentrations were 10 and 0.5 mmol/l, respectively. The relative activities of these 2-oxocarboxylic acids were pyruvic acid>2-ketobutyrate>oxalacetic acid>alpha-ketoglutaric acid>phenylpyruvate. The cofactor 3-acetylpyridine adenine dinucleotide was much more effective than NAD(+). The cofactor analogs in which the nicotinamide ring is replaced by 3-pyridinealdehyde were lower activity cofactors, while the nicotinamide ring is replaced by nicotinic acid or thionicotinamide which is not a cofactor to CsLDH. The succinic acid and malic acid are not substrates of CsLDH. Cu(2+), Fe(2+), and Zn(2+) greatly inhibited the CsLDH activity both in the direction of pyruvate reduction and in the direction of lactate oxidation. The inhibition of CsLDH by gossypol may make gossypol a potential therapy drug or a lead compound for C. sinensis. Accordingly, the CsLDH may be a novel potential drug target.

Designer gene therapy using an Escherichia coli purine nucleoside phosphorylase/prodrug system

Activation of prodrugs by Escherichia coli purine nucleoside phosphorylase (PNP) provides a method for selectively killing tumor cells expressing a transfected PNP gene. This gene therapy approach requires matching a prodrug and a known enzymatic activity present only in tumor cells. The specificity of the method relies on avoiding prodrug cleavage by enzymes already present in the host cells or the intestinal flora. Using crystallographic and computer modeling methods as guides, we have redesigned E. coli PNP to cleave new prodrug substrates more efficiently than does the wild-type enzyme. In particular, the M64V PNP mutant cleaves 9-(6-deoxy-alpha-L-talofuranosyl)-6-methylpurine with a kcat/Km over 100 times greater than for native E. coli PNP. In a xenograft tumor experiment, this compound caused regression of tumors expressing the M64V PNP gene.

From malate dehydrogenase to phenyllactate dehydrogenase. Incorporation of unnatural amino acids to generate an improved enzyme-catalyzed activity

Malate dehydrogenase (MDH) from Escherichia coli is highly specific for its keto acid substrate. The placement of the active site-binding groups in MDH effectively discriminates against both the shorter and the longer keto dicarboxylic acids that could potentially serve as alternative substrates. A notable exception to this specificity is the alternative substrate phenylpyruvate. This aromatic keto acid can be reduced by MDH, albeit at a somewhat slower rate and with greatly diminished affinity, despite the presence of several substrate-binding arginyl residues and the absence of a hydrophobic pocket in the active site. The specificity of MDH for phenylpyruvate has now been enhanced, and that for the physiological substrate oxaloacetate has been diminished, through the replacement of one of the binding arginyl residues with several unnatural alkyl and aryl amino acid analogs. This approach, called site-specific modulation, incorporates systematic structural variations at a site of interest. Molecular modeling studies have suggested a structural basis for the affinity of native MDH for phenylpyruvate and a rationale for the improved catalytic activity that is observed with these new, modified phenyllactate dehydrogenases.

The putative L-lactate dehydrogenase from Methanococcus jannaschii is an NADPH-dependent L-malate dehydrogenase

The enzyme encoded by Methanococcus jannaschii open reading frame (ORF) 0490 was purified and characterized. It was shown to be an NADPH-dependent [lactate dehydrogenase (LDH)-like] L-malate dehydrogenase (MalDH) and not an L-lactate dehydrogenase, as had been suggested previously on the basis of amino acid sequence similarity. The results show the importance of biochemical data in the assignment of ORF function in genomic sequences and have implications for the phylogenetic distribution of members of the MalDH/LDH enzyme superfamilies within the prokaryotic kingdom.

Roles of his205, his296, his303 and Asp259 in catalysis by NAD+-specific D-lactate dehydrogenase

The role of three histidine residues (His205, His296 and His303) and Asp259, important for the catalysis of NAD+-specific D-lactate dehydrogenase, was investigated using site-directed mutagenesis. None of these residues is presumed to be involved in coenzyme binding because Km for NADH remained essentially unchanged for all the mutant enzymes. Replacement of His205 with lysine resulted in a 125-fold reduction in kcat and a slight lowering of the Km value for pyruvate. D259N mutant showed a 56-fold reduction in kcat and a fivefold lowering of Km. The enzymatic activity profile shifted towards acidic pH by approximately 2 units. The H303K mutation produced no significant change in kcat values, although Km for pyruvate increased fourfold. Substitution of His296 with lysine produced no significant change in kcat values or in Km for substrate. The results obtained suggest that His205 and Asp259 play an important role in catalysis, whereas His303 does not. This corroborates structural information available for some members of the D-specific dehydrogenases family. The catalytic His296, proposed from structural studies to be the active site acid/base catalyst, is not invariant. Its function can be accomplished by lysine and this has significant implications for the enzymatic mechanism.

Enzymology takes a quantum leap forward

Enzymes are biological molecules that accelerate chemical reactions. They are central to the existence of life. Since the discovery of enzymes just over a century ago, we have witnessed an explosion in our understanding of enzyme catalysis, leading to a more detailed appreciation of how they work. A key breakthrough came from understanding how enzymes surmount the potential-energy barrier that separates reactants from products. The genetic engineering revolution has provided tools for dissecting enzyme structure and enabling design of novel function. Despite the huge efforts to redesign enzyme molecules for specific applications, progress in this area has been generally disappointing. This stems from our limited understanding of the subtleties by which enzymes enhance reaction rates. Based on current dogma, the vast majority of studies have concentrated on understanding how enzymes facilitate passage of the reaction over a static potential-energy barrier. However, recent studies have revealed that passage through, rather than over, the barrier can occur. These studies reveal that quantum mechanical phenomena, driven by protein dynamics, can play a pivotal role in enzyme action. The new millennium will witness a flurry of activity directed at understanding the role of quantum mechanics and protein motion in enzyme action. We discuss these new developments and how they will guide enzymology into the new millennium.

Molecular genetic characterization of the L-lactate dehydrogenase gene (ldhL) of Lactobacillus helveticus and biochemical characterization of the enzyme

The Lactobacillus helveticus L-(+)-lactate dehydrogenase (L-LDH) gene (ldhL) was isolated from a lambda library. The nucleotide sequence of the ldhL gene was determined and shown to have the capacity to encode a protein of 323 amino acids (35.3 kDa). The deduced sequence of the 35-kDa protein revealed a relatively high degree of identity with other lactobacillar L-LDHs. The highest identity (80.2%) was observed with the Lactobacillus casei L-LDH. The sizes and 5' end analyses of ldhL transcripts showed that the ldhL gene is a monocistronic transcriptional unit. The expression of ldhL, studied as a function of growth, revealed a high expression level at the logarithmic phase of growth. The ldhL gene is preceded by two putative -10 regions, but no corresponding -35 regions could be identified. By primer extension analysis, the ldhL transcripts were confirmed to be derived from the -10 region closest to the initiation codon. However, upstream of these regions additional putative -10/-35 regions could be found. The L-LDH was overexpressed in Escherichia coli and purified to homogeneity by two chromatographic steps. The purified L-LDH was shown to be a nonaliosteric enzyme, and amino acid residues involved in allosteric regulation were not conserved in L. helveticus L-LDH. However, a slight enhancement of enzyme activity was observed in the presence of fructose 1,6-diphosphate, particularly at neutral pH. A detailed enzymatic characterization of L-LDH was performed. The optimal reaction velocity was at pH 5.0, where the kinetic parameters K(m), and Kcat for pyruvate were 0.25 mM and 643 S-1, respectively.

D-2-hydroxy-4-methylvalerate dehydrogenase from Lactobacillus delbrueckii subsp. bulgaricus. II. Mutagenic analysis of catalytically important residues

Five residues involved in catalysis and coenzyme binding have been identified in D-2-hydroxy-4-methylvalerate dehydrogenase from Lactobacillus delbrueckii subsp. bulgaricus by using biochemical and genetical methods. Enzyme inactivation with diethylpyrocarbonate indicated that a single histidine residue was involved in catalysis. Since H296 is the only conserved histidine in the whole family of NAD-dependent D-2-hydroxyacid dehydrogenases, we constructed the H296Q and H296S mutants and showed that their catalytic efficiencies were reduced 10(5)-fold compared with the wild-type enzyme. This low residual activity was shown to be insensitive to diethylpyrocarbonate. Taken together these data demonstrate that H296 is responsible for proton exchange in the redox reaction. Two acidic residues (D259 and E264) were candidates for maintaining H296 in the protonated state and their roles were examined by mutagenesis. The D259N and E264Q mutant enzymes both showed similar and large reductions in their Kcat/K(m) ratios (200-800-fold, depending on pH), indicating that either D259 or E264 (or both) could partner H296. The conserved R235 residue was a candidate for binding the alpha-carboxyl group of the substrate and it was changed to lysine. The R235K mutant showed a 104-fold reduced Kcat/K(m) due to both an increased K(m) and a reduced Kcat for 2-oxo-4-methylvalerate. Thus R235 plays a role in binding the substrate carboxylate similar to R171 in the L-lactate dehydrogenases. Finally, we constructed the H205Q mutant to test the role of this partially conserved histidine residue (in 10/13 enzymes of the family). This mutant enzyme displayed a 7.7-fold increased Kcat and a doubled catalytic efficiency at pH 5, was as sensitive to diethylpyrocarbonate as the wild-type but showed a sevenfold increased K(m) for NADH and a 100-fold increase in Kd for NADH together with 10-30-fold lower substrate inhibition. The transient kinetic behaviour of the H205Q mutant is as predicted from our previous study on the enzymatic mechanism of D-2-hydroxy-4-methylvalerate dehydrogenase which showed that coenzyme binding is highly pH dependent and indicated that release of the oxidised coenzyme is a significant component of the rate-limiting processes in catalysis at pH 6.5.

D-2-hydroxy-4-methylvalerate dehydrogenase from Lactobacillus delbrueckii subsp. bulgaricus. I. Kinetic mechanism and pH dependence of kinetic parameters, coenzyme binding and substrate inhibition

The steady-state kinetics of D-2-hydroxy-4-methylvalerate dehydrogenase have been studied at pH 8.0 by initial velocity, product inhibition, and dead-end inhibition techniques. The mechanism is rapid-equilibrium ordered in the NAD+ plus D-2-hydroxy-4-methylvalerate direction, and steady-state ordered in the other direction. In both cases coenzyme is the first substrate added and both the E-NADH-D-2-hydroxy-4-methylvalerate and E-NAD+-2-oxo-4-methylvalerate give rise to abortive complexes which cause excess substrate inhibition. Steady-state measurements show that the rate-limiting step in both directions at pH 8.0 is between formation of the enzyme-coenzyme-substrate ternary complex and the release of the first product of the reaction. Transient kinetics combined with primary kinetic deuterium isotope effects show that in the NADH-->NAD+ direction there is a slow, rate-limiting rearrangement of the E-NADH-oxoacid complex while hydride transfer is very fast. The release of NAD+ at pH 8.0 is 200-times faster than Kcat (NADH-->NAD+) whereas the release of NADH is only 5-times faster than Kcat (NAD+-->NADH). The pH dependence of NADH binding depends upon the presence of two ionizable residues with a pKa of about 5.9. The pH dependence of kinetic parameters is explained by a third ionizable residue with pKa values 7.2 (in the E-NADH complex) and < or = 6.4 (in the E-NAD+ complex) which may be the proton donor and acceptor for the chemical reaction. At pH 6.5 the mechanism changes in the NADH-->NAD+ direction to be partly limited by the chemical step with a measured primary kinetic isotope effect of 5.7 and partly by an only slightly faster dissociation of NAD+. In addition the inhibition by excess oxo-4-methylvalerate is more pronounced. The mechanism implies that removing the positive charges created by the two groups which control coenzyme affinity could both enhance the catalytic rate at pH 6.5 and diminish excess substrate inhibition to provide an enzyme better suited to the bulk synthesis of D-2-hydroxyacids.

Sequence replacements in the central beta-turn of plastocyanin

The role of beta-turns in dictating the structure of a beta-barrel protein is assessed by probing the tolerance of the central beta-turn of poplar plastocyanin to substitution by arbitrary sequences. Native plastocyanin binds copper and is colored bright blue. However, when the wild-type Pro47-Ser48-Gly49-Val50 turn sequence is replaced by arbitrary tetrapeptides, the vast majority (92/98 = 94%) of mutant proteins cannot fold into the native blue structure. Characterization of the colorless mutant proteins demonstrates that the majority of substitutions in this type II beta-turn disrupt the native structure severely. Gross structural changes are indicated by major differences in the CD spectra of the mutants relative to the wild-type protein, and by the much larger apparent size of mutant proteins in gel filtration experiments. These mutant proteins do not bind copper. Furthermore, Cys84 forms a disulfide bond readily in the colorless mutant proteins, indicating that it has moved away from the buried position it occupies in the native copper binding site and has become exposed. These results indicate that the central beta-turn in plastocyanin is not merely a default structure arising in response to the surrounding context; rather, sequence information in this turn plays an active role in dictating the location of a chain reversal in the beta-barrel structure. These findings are discussed in terms of their implications for the folding of natural proteins, as well as the design of de novo proteins.

Extremely thermostable L(+)-lactate dehydrogenase from Thermotoga maritima: cloning, characterization, and crystallization of the recombinant enzyme in its tetrameric and octameric state

L(+)-lactate dehydrogenase (LDH; E.C.1.1.1.27) from the hyperthermophilic bacterium Thermotoga maritima has been shown to represent the most stable LDH isolated so far (Wrba A, Jaenicke R, Huber R, Stetter KO, 1990, Eur J Biochem 188:195-201). In order to obtain the enzyme in amounts sufficient for physical characterization, and to analyze the molecular basis of its intrinsic stability, the gene was cloned and expressed functionally in Escherichia coli. Growth of the cells and purification of the enzyme were performed aerobically at 26 degrees C, i.e., ca. 60 degrees below the optimal growth temperature of Thermotoga. Two enzyme species with LDH activity were purified to homogeneity. Crystals of the enzyme obtained at 4 degrees C show satisfactory diffraction suitable for X-ray analysis up to a resolution of 2.8 A. As shown by gel-permeation chromatography, chemical crosslinking, light scattering, analytical ultracentrifugation, and electron microscopy, the two LDH species represent homotetramers and homooctamers (i.e., dimers of tetramers), with a common subunit molecular mass of 35 kDa. The spectroscopic characteristics (UV absorption, fluorescence emission, near- and far-UV CD) of the two species are indistinguishable. The calculated alpha-helix content is 45%, in accordance with the result of homology modeling. Compared to the tetrameric enzyme, the octamer exhibits reduced specific activity, whereas KM is unalatered. The extreme intrinsic stability of the protein is reflected by its unaltered catalytic activity over 4 h at 85 degrees C; irreversible thermal denaturation becomes significant at approximately 95 degrees C. The anomalous resistance toward chemical denaturation using guanidinium chloride and urea confirms this observation. Both the high optimal temperature and the pH optimum of the catalytic activity correspond to the growth conditions of T. maritima in its natural habitat.

Arginine to tryptophan substitution in the active site of a human lactate dehydrogenase variant--LDHB GUA1: postulated effects on subunit structure and catalysis

A variant of lactate dehydrogenase (LDHB GUA1) was previously identified among the Guaymi Indians of Panama and Costa Rica. The LDHB GUA1 variant is enzymatically inactive; however, the variant subunits alter the electrophoretic mobility of the tetramers that include active LDHA and LDHB subunits. The kinetic properties of the tetrameric enzyme, comprised of the inactive B plus active A subunits, are similar to properties of the heterotetramers with active B subunits, except for the reduced specific activity. We have determined that a single C.G to T.A transition changes an Arg to a Trp at amino acid residue 106. This substitution explains the increase in net negative charge observed by protein electrophoresis. This Arg 106 residue is absolutely conserved throughout evolution. Published high-resolution crystal structures of LDH reveal that this residue is within the hinge of a loop that closes over the active site of the subunit upon binding of substrate and cofactor and also has a direct role in catalysis. Computer modeling of the variant enzyme suggests that replacement of this Arg residue with a Trp does not induce significant change in the structure of the active site. However, this substitution would result in disruption of enzyme activity through the inability of the uncharged tryptophan side-chain to polarize the substrate carbonyl bond. This would explain the loss of the catalytic function with maintenance of normal kinetic properties in the heterotetramers containing the variant subunits. The ability to maintain normal, tissue-specific kinetic properties could explain the absence of clinical manifestations in the homozygous LDHB GUA1 individuals.

Structural Features That Stabilize Halophilic Malate Dehydrogenase from an Archaebacterium

The high-resolution structure of halophilic malate dehydrogenase (hMDH) from the archaebacterium Haloarcula marismortui was determined by x-ray crystallography. Comparison of the three-dimensional structures of hMDH and its nonhalophilic congeners reveals structural features that may promote the stability of hMDH at high salt concentrations. These features include an excess of acidic over basic residues distributed on the enzyme surface and more salt bridges present in hMDH compared with its nonhalophilic counterparts. Other features that contribute to the stabilization of thermophilic lactate dehydrogenase and thermophilic MDH-the incorporation of alanine into alpha helices and the introduction of negatively charged amino acids near their amino termini, both of which stabilize the alpha helix as a result of interaction with the positive part of the alpha-helix dipole-also were observed in hMDH.

Cloning, nucleotide sequence, and transcriptional analysis of the Pediococcus acidilactici L-(+)-lactate dehydrogenase gene

Recombinant plasmids containing the Pediococcus acidilactici L-(+)-lactate dehydrogenase gene (ldhL) were isolated by complementing for growth under anaerobiosis of an Escherichia coli lactate dehydrogenase-pyruvate formate lyase double mutant. The nucleotide sequence of the ldhL gene predicted a protein of 323 amino acids showing significant similarity with other bacterial L-(+)-lactate dehydrogenases and especially with that of Lactobacillus plantarum. The ldhL transcription start points in P. acidilactici were defined by primer extension, and the promoter sequence was identified as TCAAT-(17 bp)-TATAAT. This sequence is closely related to the consensus sequence of vegetative promoters from gram-positive bacteria as well as from E. coli. Northern analysis of P. acidilactici RNA showed a 1.1-kb ldhL transcript whose abundance is growth rate regulated. These data, together with the presence of a putative rho-independent transcriptional terminator, suggest that ldhL is expressed as a monocistronic transcript in P. acidilactici.

Semiempirical calculations of the oxygen equilibrium isotope effect on binding of oxamate to lactate dehydrogenase

Semiempirical methods have been used in an attempt to predict theoretically the experimentally observed value of 0.9840 for the oxygen isotope effect on binding of oxamate to lactate dehydrogenase. The overall strategy involved vibrational analysis of oxamate in two different environments; that of the active site residues and in aqueous solution. The comparison of calculated values with the experimentally determined isotope effect proved the AM1 Hamiltonian to be superior to the PM3 Hamiltonian in this modelling. While most tested methods of accounting for solvent effects on the vibrational frequencies of the solute yielded similar results it turned out that what was crucial for the purpose of determination of the isotope effect was the model of oxamate in the active site of the enzyme. In particular, the major factor responsible for the inverse value of this isotope effect can be ascribed to the formation of an ordered, bifurcated hydrogen bond between the oxamate carboxylate and the guanidinium group of the active site histidine.

NAD(+)-dependent D-2-hydroxyisocaproate dehydrogenase of Lactobacillus delbrueckii subsp. bulgaricus. Gene cloning and enzyme characterization

A genomic library from Lactobacillus delbrueckii subsp. bulgaricus was used to complement an Escherichia coli mutant strain deficient for both lactate dehydrogenase and pyruvate formate lyase, and thus unable to grow anaerobically. One recombinant clone was found to display a broad specificity NAD(+)-dependent D-2-hydroxyacid dehydrogenase activity. The corresponding gene (named hdhD) was subcloned and sequenced. The deduced amino acid sequence of the encoded enzyme indicates a 333-residue protein closely related to D-2-hydroxyisocaproate (i.e. 2-hydroxy-4-methyl-pentanoate) dehydrogenase (D-HO-HxoDH) of Lactobacillus casei and other NAD(+)-dependent D-lactate dehydrogenases (D-LDH) from several other bacterial species. The hdhD gene was overexpressed under the control of the lambda phage PL promoter and the enzyme was purified with a two-step method. The L. delbrueckii subsp. bulgaricus enzyme, like that of L. casei, was shown to be active on a wide variety of 2-oxoacid substrates except those having a branched beta-carbon.

Lactobacillus plantarum ldhL gene: overexpression and deletion

Lactobacillus plantarum is a lactic acid bacterium that converts pyruvate to L-(+)- and D-(-)-lactate with stereospecific enzymes designated L-(+)- and D-(-)-lactate dehydrogenase (LDH), respectively. A gene (designated ldhL) that encodes L-(+)-lactate dehydrogenase from L. plantarum DG301 was cloned by complementation in Escherichia coli. The nucleotide sequence of the ldhL gene predicted a protein of 320 amino acids closely related to that of Lactobacillus pentosus. A multicopy plasmid bearing the ldhL gene without modification of its expression signals was introduced in L. plantarum. L-LDH activity was increased up to 13-fold through this gene dosage effect. However, this change had hardly any effect on the production of L-(+)- and D-(-)-lactate. A stable chromosomal deletion in the ldhL gene was then constructed in L. plantarum by a two-step homologous recombination process. Inactivation of the gene resulted in the absence of L-LDH activity and in exclusive production of the D isomer of lactate. However, the global concentration of lactate in the culture supernatant remained unchanged.

Substitution of the amino acid at position 102 with polar and aromatic residues influences substrate specificity of lactate dehydrogenase

The Gln residue at amino acid position 102 of Bacillus stearothermophilus lactate dehydrogenase was replaced with Ser, Thr, Tyr, or Phe to investigate the effect on substrate recognition. The Q102S and Q102T mutant enzymes were found to have a broader range of substrate specificity (measured by kcat/Km) than the wild-type enzyme. However, it is evident that either Ser or Thr at position 102 are of a size able to accommodate a wide variety of substrates in the active site and substrate specificity appears to rely largely on size discrimination in these mutants. The Q102F and Q102Y mutant enzymes have low catalytic efficiency and do not show this relaxed substrate specificity. However, their activities are restored by the presence of an aromatic substrate. All of the enzymes have a very low catalytic efficiency with branched chain aliphatic substrates.

Two tropinone reductases with different stereospecificities are short-chain dehydrogenases evolved from a common ancestor

In the biosynthetic pathway of tropane alkaloids, tropinone reductase (EC 1.1.1.236) (TR)-I and TR-II, respectively, reduce a common substrate, tropinone, stereospecifically to the stereoisomeric alkamines tropine and pseudotropine (psi-tropine). cDNA clones coding for TR-I and TR-II, as well as a structurally related cDNA clone with an unknown function, were isolated from the solanaceous plant Datura stramonium. The cDNA clones for TR-I and TR-II encode polypeptides containing 273 and 260 amino acids, respectively, and when these clones were expressed in Escherichia coli, the recombinant TRs showed the same strict stereospecificity as that observed for the native TRs that had been isolated from plants. The deduced amino acid sequences of the two clones showed an overall identity of 64% in 260-amino acid residues and also shared significant similarities with enzymes in the short-chain, nonmetal dehydrogenase family. Genomic DNA-blot analysis detected the TR-encoding genes in three tropane alkaloid-producing solanaceous species but did not detect them in tobacco. We discuss how the two TRs may have evolved to catalyze the opposite stereospecific reductions.

Dissecting the contributions of a specific side-chain interaction to folding and catalysis of Bacillus stearothermophilus lactate dehydrogenase

X-ray crystallography predicts hydrogen-bonding interactions between the side chains of Thr198 and two other amino acid residues, Glu194 (adjacent to the catalytic His195) and Ser318 (on the alpha-H helix which rearranges on substrate binding). In order to investigate the contribution of this conserved amino acid residue, Thr198, two mutants of Bacillus stearothermophilus lactate dehydrogenase were created (Val198 and Ile198). The steady-state kinetic parameters for both mutant enzymes were very similar with increased substrate Km and reduced kcat when compared with the wild-type enzyme. The mutation Val198 allowed non-productive binding of pyruvate to the unprotonated form of His195. Steady-state kinetic parameters determined for the Val198 mutant enzyme in high solvent viscosity suggested both an altered rate-limiting step in catalysis and implicated Thr198 in allosteric activation by the effector fructose 1,6-bisphosphate (Fru1,6P2). A shift in the Fru1,6P2 activation constant for the Val198 mutant enzyme suggested that Thr198 stabilises the catalytically competent (Fru1,6P2-activated) form of the enzyme by 6.6 kJ/mol. However, Thr198 was not important for maintaining the thermal stability of the Fru1,6P2-activated form. Equilibrium unfolding in guanidinium chloride indicated that Thr198 contributes 17.2 kJ/mol subunits towards the tertiary structural stability. The results emphasise the importance of the side chain-hydroxyl group of Thr198 which is required for (a) productive substrate binding, (b) allosteric activation and (c) protein conformational stability. The characteristics of the B. stearothermophilus lactate dehydrogenase mutations reported here were significantly different from those of the same mutations made in the corresponding position of the analogous enzyme Thermus flavus malate dehydrogenase [Nishiyama, M., Shimada, K., Horinouchi, S., & Beppu, T. (1991) J. Biol. Chem. 266, 14294-14299].

Mutations that significantly change the stability, flexibility and quaternary structure of the l-lactate dehydrogenase from Bacillus megaterium

In order to investigate the physical basis of protein stability, two mutant L-lactate dehydrogenases (LDH) and the wild-type enzyme from Bacillus megaterium were analyzed for differences in quaternary structure, global protein conformation, thermal stability, stability against guanidine hydrochloride, and polypeptide chain flexibility. One mutant enzyme, ([T29A, S39A]LDH), differing at two positions in the alpha-B helix, exhibited a 20 degrees C increase in thermostability. Hydrogen/deuterium exchange revealed a rigid structure of this enzyme at room temperature. The substitutions Ala37 to Val and Met40 to Leu destabilize the protein. This is observable in a greater susceptibility to thermal denaturation and in an unusual monomer/dimer/tetramer equilibrium in the absence of fructose 1,6-bisphosphate Fru(1,6)P2. The stability, flexibility and protein-conformation measurements were all performed in the presence of 5 mM Fru(1,6)P2, i.e. under conditions where the three investigated LDH species are stable tetramers. Tryptophan fluorescence was used to monitor the unfolding in guanidine HCl of two local structures in or very close to the beta-sheets at the protein surface. The LDHs form folding intermediates in guanidine HCl that aggregate at elevated temperatures. Pronounced differences between the three investigated enzymes are found in their ability to aggregate. The exchange of Thr29 and Ser39 for Ala leads to significantly less aggregation in guanidine HCl than is observed for wild-type LDH. Using 8-anilinonaphthalene-1-sulfonic acid, the folding intermediates were shown to be in accordance with molten-globule-like structures. We have found, by means of molecular sieve chromatography, that the [T29A, S39A]LDH with its increased thermostability has lower susceptibility to disintegrate into monomers in guanidine HCl at 25 degrees C. Despite the differences in aggregation at low guanidine HCl concentrations and temperatures above 25 degrees C, the molten-globule-like structures of the three investigated LDH species are structurally similar, as shown by molecular-sieve chromatography. Although the thermostabilities of the three LDH species are so different in aqueous buffers, their stabilities in guanidine HCl at 20 degrees C are, surprisingly, almost identical. Some comments are made as to the origin of the observed difference between thermal and guanidine HCl stabilities of the LDH. Near-ultraviolet and far-ultraviolet circular dichroism measurements, as well as differences in the amount of activation by Fru(1,6)P2, point to small global structural rearrangements caused by the mutations. Conformational changes upon Fru(1,6)P2 binding or point mutations in the alpha-B helix show that the Fru(1,6)P2-binding site and the alpha-B helix are structurally linked together.(ABSTRACT TRUNCATED AT 400 WORDS)

Cloning, nucleotide sequence, expression, and chromosomal location of ldh, the gene encoding L-(+)-lactate dehydrogenase, from Lactococcus lactis

A gene (designated ldh) that encodes fructose-1,6-bisphosphate-activated L-(+)-lactate dehydrogenase was cloned from Lactococcus lactis subsp. lactis. Plasmids containing ldh conferred fructose-1,6-bisphosphate-activated L-(+)-lactate dehydrogenase activity on Escherichia coli cells. This activity was conferred only when a promoter had been introduced into the plasmid to express the cloned ldh. The nucleotide sequence of ldh predicted a chain length of 324 amino acids and a subunit molecular weight of 34,910 for the enzyme, after removal of the N-terminal methionine residue. Northern analyses of L. lactis subsp. lactis RNA showed that a 4.1-kb transcript hybridized strongly with ldh and that 1.2- and 1.1-kb transcripts hybridized to much lesser extents. Promoter- and terminator-cloning studies in which we used the vectors pGKV210 and pGKV259 in L. lactis subsp. lactis revealed that the 5' flanking DNA of ldh is devoid of transcription initiation signals and that transcription entering the 3' flanking DNA from either direction is efficiently terminated. These data and the data from Northern analyses led to the conclusion that ldh is expressed as the 3' gene of the 4.1-kb transcript and suggested that posttranscriptional processing yielded the shorter transcripts. We determined that ldh is located on the L. lactis subsp. lactis chromosome between coordinates 1.619 and 1.669 of the previously reported physical map (D. L. Tulloch, L. R. Finch, A. J. Hillier, and B. E. Davidson, J. Bacteriol. 173:2768-2775, 1991).

Cloning and overexpression of Lactobacillus helveticus D-lactate dehydrogenase gene in Escherichia coli

NAD(+)-dependent D-lactate dehydrogenase from Lactobacillus helveticus was purified to apparent homogeneity, and the sequence of the first 36 amino acid residues determined. Using forward and reverse oligonucleotide primers, based on the N-terminal sequence and amino acid residues 220-215 of the Lactobacillus bulgaricus enzyme [Kochhar, S., Hunziker, P. E., Leong-Morgenthaler, P. & Hottinger, H. (1992) J. Biol. Chem. 267, 8499-8513], a 0.6-kbp DNA fragment was amplified from L. helveticus genomic DNA by the polymerase chain reaction. This amplified DNA fragment was used as a probe to identify two recombinant clones containing the D-lactate dehydrogenase gene. Both plasmids overexpressed D-lactate dehydrogenase (greater than 60% total soluble cell protein) and were stable in Escherichia coli, compared to plasmids carrying the L. bulgaricus and Lactobacillus plantarum genes. The entire nucleotide sequence of the L. helveticus D-lactate dehydrogenase gene was determined. The deduced amino acid sequence indicated a polypeptide consisting of 336 amino acid residues, which showed significant amino acid sequence similarity to the recently identified family of D-2-hydroxy-acid dehydrogenases [Kochhar, S., Hunziker, P. E., Leong-Morgenthaler, P. & Hottinger, H. (1992) Biochem. Biophys. Res. Commun. 184, 60-66]. The physicochemical and catalytic properties of recombinant D-lactate dehydrogenase were identical to those of the wild-type enzyme, e.g. alpha 2 dimeric subunit structure, isoelectric pH, Km and Kcat for pyruvate and other 2-oxo-acid substrates. The kinetic profiles of 2-oxo-acid substrates showed some marked differences from that of L-lactate dehydrogenase, suggesting different mechanisms for substrate binding and specificity.

Construction of a stable dimer of Bacillus stearothermophilus lactate dehydrogenase

A molecular graphics analysis of the features which prevent cytosolic malate dehydrogenase dimers from forming tetramers was evaluated by its success in predicting the synthesis of a version of the LDH framework which is a stable dimer. Surface residues responsible for malate dehydrogenases being dimers were revealed by superimposing the structures of two dimers of pig cytosolic malate dehydrogenase on one homologous tetramer of L-lactate dehydrogenase from Bacillus stearothermophilus. Four regions were identified as composing the P-axis dimer-dimer interface. Two regions of the dimer were surface loops that collided when built as a tetramer: a large loop (residues 203-207, KNOBI) and a small loop (residues 264-269, KNOBII), and these were candidates to explain the dimeric character of malate dehydrogenase. The analysis was tested by constructing a synthetic B. stearothermophilus lactate dehydrogenase (KNOBI) containing the large malate dehydrogenase loop (residues 203-207 being AYIKLQAKE, and extra four amino acids). The new construct was thermotolerant (90 degrees C) and enzymically active with kcat and KM (pyruvate) values similar to those of the wild-type enzyme. However, whereas the allosteric activator fructose 1,6-bisphosphate decreased KM 100 times for wild type, it had no influence on KNOBI. The molecular volumes of 1-120 microM concentrations of the construct were measured by time-resolved decay of tryptophan fluorescence anisotropy and by gel filtration. Both methods showed the molecular weight of wild type increased from dimer to tetramer with Kd about 20 microM dimer. KNOBI remained a dimer under these conditions.(ABSTRACT TRUNCATED AT 250 WORDS)

Complementary perturbation of the kinetic mechanism and catalytic effectiveness of dihydrofolate reductase by side-chain interchange

The variable residue Leu-28 of Escherichia coli dihydrofolate reductase (DHFR) and the corresponding residue Phe-31 in murine DHFR were interchanged, and the impact on catalysis was evaluated by steady-state and pre-steady-state analysis. The E. coli L28F mutant increased the pH-independent kcat from 11 to 50 s-1 but had little effect on Km(H2F). An increase in the rate constant for dissociation of H4F from E.H4F.NH (from 12 to 80 s-1) was found to be largely responsible for the increase in kcat. Unexpectedly, the rate constant for hydride transfer increased from 950 to 4000 s-1 with little perturbation of NADPH and NADP+ binding to E. Consequently, the flux efficiency of the E. coli L28F mutant rose from 15% to 48% and suggests a role in genetic selection for this variable side chain. The murine F31L mutant decreased the pH-independent kcat from 28 to 4.8 s-1 but had little effect on Km(H2F). A decrease in the rate constant for dissociation of H4F from E.H4F.NH (from 40 to 22 s-1) and E.H4F (from 15 to 0.4 s-1) was found to be mainly responsible for the decrease in kcat. The rate constant for hydride transfer decreased from 9000 to 5000 s-1 with minor perturbation of NADPH binding. Thus, the free energy differences along the kinetic pathway were generally similar in magnitude but opposite in direction to those incurred by the E. coli L28F mutant. This conclusion implies that DHFR hydrophobic active-site side chains impart their characteristics individually and not collectively.

From adenylate cyclase to guanylate cyclase. Mutational analysis of a change in substrate specificity

Adenylate and guanylate cyclases, having different but related substrates, are a paradigm for the study of substrate discrimination. A prokaryotic adenylate cyclase gene, phylogenetically related to eukaryotic counterparts, was screened for mutants remodelling the enzyme's specificity. In a first step, a mutant was selected displaying a significant level of guanylate cyclase activity. This was due to a point mutation destroying most of the adenylate cyclase activity. A second selection step restored most of the original activity. This resulted from an additional mutation in the same region, thus permitting the first identification of a functional domain in adenylate and guanylate cyclases.

Activity of heart and muscle lactate dehydrogenases in all-aqueous systems and in organic solvents with low amounts of water. Effect of guanidine chloride

The effect of urea and guanidine hydrochloride (GdmCl) on the activity of lactate dehydrogenases from heart and muscle was studied in standard water mixtures and in reverse micelles formed with n-octane, hexanol, cetyltrimethylammonium bromide and water in a concentration that ranged over 2.5-6.0% (by vol.). In all water mixtures GdmCl (0.15-0.75 M) and urea (0.5-3.0 M) inhibited the activity of the enzymes at non-saturating pyruvate concentrations. At concentrations of pyruvate that proved inhibitory for enzyme activity due to the formation of a ternary enzyme-NAD-pyruvate complex, GdmCl and urea increased the activity of the enzymes. This increase correlated with a decrease of the ternary complex, as evidenced by its absorbance at 320-325 nm. In the low-water system it was found that: (a) at all concentrations of pyruvate tested (0.74-30 mM), GdmCl enhanced the activity of the heart enzyme to a similar extent; (b) in the muscle enzyme, GdmCl inhibited or increased the activity through a process that depended on the concentration of pyruvate and GdmCl; (c) under optimal conditions, the activation by GdmCl was about two times lower in the muscle than in the heart enzyme, although in all-water media the activity of the muscle enzyme was twice as high. The expression of lactate dehydrogenase activity in the low-water system was higher with the heart than with the muscle enzyme compared to their activities in all-water media (about 260 and 600 mumol min-1 mg-1 in the heart and muscle enzymes respectively). Apparently for catalysis, the water requirement in the heart enzyme is lower than in the muscle enzyme. It is likely that the different response of the two enzymes to solvent is due to their distinct structural features.

Engineering the substrate specificity of glutathione reductase toward that of trypanothione reduction

Glutathione reductase (EC 1.6.4.2; CAS registry number 9001-48-3) and trypanothione reductase (CAS registry number 102210-35-5), which are related flavoprotein disulfide oxidoreductases, have marked specificities for glutathione and trypanothione, respectively. A combination of primary sequence alignments and molecular modeling, together with the high-resolution crystal structure of human glutathione reductase, identified certain residues as potentially being responsible for substrate discrimination. Site-directed mutagenesis of Escherichia coli glutathione reductase was used to test these predictions. The mutation of Asn-21 to Arg demonstrated that this single change was insufficient to generate the greater discrimination against trypanothione shown by human glutathione reductase compared with the E. coli enzyme. However, the mutation of Ala-18, Asn-21, and Arg-22 to the amino acid residues (Glu, Trp, and Asn, respectively) in corresponding positions in Trypanosoma congolense trypanothione reductase confirmed that this region of polypeptide chain is intimately involved in substrate recognition. It led to a mutant form of E. coli glutathione reductase that possessed essentially no activity with glutathione but that was able to catalyze trypanothione reduction with a kcat/Km value that was 10% of that measured for natural trypanothione reductases. These results should be of considerable importance in the design of trypanocidal drugs targeted at the differences between glutathione and trypanothione metabolism in trypanosomatids and their hosts.

Engineering of papain: selective alteration of substrate specificity by site-directed mutagenesis

The S2 subsite specificity of the plant protease papain has been altered to resemble that of mammalian cathepsin B by site-directed mutagenesis. On the basis of amino acid sequence alignments for papain and cathepsin B, a double mutant (Val133Ala/Ser205Glu) was produced where Val133 and Ser205 are replaced by Ala and Glu, respectively, as well as a triple mutant (Val133Ala/Val157Gly/Ser205Glu), where Val157 is also replaced by Gly. Three synthetic substrates were used for the kinetic characterization of the mutants, as well as wild-type papain and cathepsin B: CBZ-Phe-Arg-MCA, CBZ-Arg-Arg-MCA, and CBZ-Cit-Arg-MCA. The ratio of kcat/KM obtained by using CBZ-Phe-Arg-MCA as substrate over that obtained with CBZ-Arg-Arg-MCA is 8.0 for the Val133Ala/Ser205Glu variant, while the equivalent values for wild-type papain and cathepsin B are 904 and 3.6, respectively. This change in specificity has been achieved by replacing only two amino acids out of a total of 212 in papain and with little loss in overall enzyme activity. However, further replacement of Val157 by Gly as in Val133Ala/Val157Gly/Ser205Glu causes an important decrease in activity, although the enzyme still displays a cathepsin B like substrate specificity. In addition, the pH dependence of activity for the Val133Ala/Ser205Glu variant compares well with that of cathepsin B. In particular, the activity toward CBZ-Arg-Arg-MCA is modulated by a group with a pKa of 5.51, a behavior that is also encountered in the case of cathepsin B but is absent with papain.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning and nucleotide sequence of the Lactobacillus casei lactate dehydrogenase gene

An allosteric L-(+)-lactate dehydrogenase gene of Lactobacillus casei ATCC 393 was cloned in Escherichia coli, and the nucleotide sequence of the gene was determined. The gene was composed of an open reading frame of 981 bp, starting with a GTG codon and ending with a TAA codon. The sequences for the promoter and ribosome binding site were identified, and a sequence for a structure resembling a rho-independent transcription terminator was also found.

Activation of aspartase by site-directed mutagenesis

To elucidate the role of sulfhydryl groups in the enzymatic reaction of the aspartase from Escherichia coli, we used site-directed mutagenesis which showed that the enzyme was activated by replacement of Cys-430 with a tryptophan. This mutation produced functional alterations without appreciable structural change: The kcat values became 3-fold at pH 6.0; the Hill coefficient values became higher under both pH conditions; the dependence of enzyme activity on divalent metal ions increased; and hydroxylamine, a good substrate for the wild-type enzyme, proved a poor substrate for the mutant.

Native agarose-polyacrylamide gel electrophoresis allowing the detection of aminopeptidase, dehydrogenase, and esterase activities at the nanogram level: enzymatic patterns in some Frankia strains

Nanogram amounts of soluble aminopeptidases, dehydrogenases, and esterases were detected by nondenaturing ultralow gelling point agarose-polyacrylamide gel electrophoresis (ULGA-PAGE). Cytosolic fractions from Frankia sp. were electrophoresed at 4 degrees C in the presence of Co2+, Zn2+, or Mg2+ ions. Then, aminopeptidases and esterases were revealed by simultaneous capture staining by using fast garnet GBC diazonium salt as the chromogenic coupling compound. Dehydrogenases were revealed by using nitro blue tetrazolium salt as electron acceptor. A variety of aminopeptidases, dehydrogenases, and esterases could be identified by their migration in ULGA-PAGE and by their sensitivities to NaCl, CoSO4, ZnSO4, and MgCl2 when assayed "ingel." The presence of agarose was essential for the detection of the complex enzyme patterns. The patterns were remarkably similar for the five Frankia strains isolated from Allocasuarina and Casuarina host plants and differed from those of Frankia strains isolated from Comptonia and Hippophaë host plants. A nomenclature is proposed for aminopeptidases and other Frankia enzymes. The richness of the Frankia amino-peptidases and esterases zymograms makes them adequate marker enzymes for taxonomical, genetic, or biochemical studies. Dehydrogenases might also be useful, although a more restricted number of bands were found with L-lactic and L-malic acid as substrates.