Determination of the hydride transfer stereospecificity of nicotinamide adenine dinucleotide linked oxidoreductases by proton magnetic resonance

Binding profile of quinonoid-dihydrobiopterin to quinonoid-dihydropteridine reductase examined by in silico and in vitro analyses

Quinonoid dihydropteridine reductase (QDPR) catalyses the reduction of quinonoid-form dihydrobiopterin (qBH2) to tetrahydrobiopterin (BH4). BH4 metabolism is a drug target for neglected tropical disorders because trypanosomatid protozoans, including Leishmania and Trypanosoma, require exogenous sources of biopterin for growth. Although QDPR is a key enzyme for maintaining intracellular BH4 levels, the precise catalytic properties and reaction mechanisms of QDPR are poorly understood due to the instability of quinonoid-form substrates. In this study, we analysed the binding profile of qBH2 to human QDPR in combination with in silico and in vitro methods. First, we performed docking simulation of qBH2 to QDPR to obtain possible binding modes of qBH2 at the active site of QDPR. Then, among them, we determined the most plausible binding mode using molecular dynamics simulations revealing its atomic-level interactions and confirmed it with the in vitro assay of mutant enzymes. Moreover, it was found that not only qBH2 but also quinonoid-form dihydrofolate (qDHF) could be potential physiological substrates for QDPR, suggesting that QDPR may be a bifunctional enzyme. These findings in this study provide important insights into biopterin and folate metabolism and would be useful for developing drugs for neglected tropical diseases.

Stereospecificity of hydride transfer and molecular docking in FMN-dependent NADH-indigo reductase of Bacillus smithii

In this study, we investigated the stereospecificity of hydride transfer from NADH to flavin mononucleotide (FMN) in reactions catalyzed by the FMN‐dependent NADH‐indigo reductase expressed by thermophilic Bacillus smithii. We performed ¹H‐NMR spectroscopy using deuterium‐labeled NADH (4R‐²H‐NADH) and molecular docking simulations to reveal that the pro‐S hydrogen at the C4 position of the nicotinamide moiety in NADH was specifically transferred to the flavin‐N5 atom of FNM. Altogether, our findings may aid in the improvement of the indigo dyeing (Aizome) process.

On the biogenic origins of homochirality

Homochirality, the single-handedness of optically asymmetric chemical structures, is present in all major biological macromolecules. Terrestrial life's preference for one isomer over its mirror image in D-sugars and L-amino acids has both fascinated and puzzled biochemists for over a century. But the contrasting case of the equally fundamental phospholipids has received less attention. Although the phospholipid glycerol headgroups of archaea and bacteria are both exclusively homochiral, the stereochemistries between the two domains are opposite. Here I argue that the reason for this "dual homochirality" was a simple evolutionary choice at the independent origin of the two synthesizing enzymes. More broadly, this points to a trivial biogenic cause for the evolution of homochirality: the enzymatic processes that produce chiral biomolecules are stereospecific in nature. Once an orientation has been favored, shifting to the opposite is both difficult and unnecessary. Homochirality is thus the simplest and most parsimonious evolutionary case.

Stereochemistry of furfural reduction by a Saccharomyces cerevisiae aldehyde reductase that contributes to in situ furfural detoxification

Ari1p from Saccharomyces cerevisiae, recently identified as an intermediate-subclass short-chain dehydrogenase/reductase, contributes in situ to the detoxification of furfural. Furfural inhibits efficient ethanol production by yeast, particularly when the carbon source is acid-treated lignocellulose, which contains furfural at a relatively high concentration. NADPH is Ari1p's best known hydride donor. Here we report the stereochemistry of the hydride transfer step, determined by using (4R)-[4-(2)H]NADPD and (4S)-[4-(2)H]NADPD and unlabeled furfural in Ari1p-catalyzed reactions and following the deuterium atom into products 2-furanmethanol or NADP(+). Analysis of the products demonstrates unambiguously that Ari1p directs hydride transfer from the si face of NADPH to the re face of furfural. The singular orientation of substrates enables construction of a model of the Michaelis complex in the Ari1p active site. The model reveals hydrophobic residues near the furfural binding site that, upon mutation, may increase specificity for furfural and enhance enzyme performance. Using (4S)-[4-(2)H]NADPD and NADPH as substrates, primary deuterium kinetic isotope effects of 2.2 and 2.5 were determined for the steady-state parameters k(cat)(NADPH) and k(cat)/K(m)(NADPH), respectively, indicating that hydride transfer is partially rate limiting to catalysis.

Correction of pre-steady-state KIEs for isotopic impurities and the consequences of kinetic isotope fractionation

We show, both experimentally and by kinetic modeling, that enzymatic single-turnover (pre-steady-state) H-transfer reactions can be significantly complicated by kinetic isotope fractionation. This fractionation results in the formation of more protiated than deuterated product and is a unique problem for pre-steady-state reactions. When observed rate constants are measured using rapid-mixing (e.g., stopped flow) methodologies, kinetic isotope fractionation can lead to a large underestimation of both the magnitude and temperature dependence of kinetic isotope effects (KIEs). This fractionation is related to the isotopic purity of the substrates used and highlights a major problem with experimental studies which measure KIEs with substrates that are not isotopically pure. As it is not always possible to prepare isotopically pure substrates, we describe two general methods for the correction, for known isotope impurities, of KIEs calculated from pre-steady-state measurements.

Chiral products from non-pyridine nucleotide-dependent reductases and methods for NAD(P)H regeneration

Enoate reductase (EC 1.3.1.31) from a Clostridium tyrobutyricum strain catalyses the stereospecific reduction of many different alpha, beta-unsaturated carboxylates, aldehydes and even some ketones. The enzyme accepts electrons from NADH and, 1.5 times faster, from reduced methyl viologen (1,1'-dimethyl-4,4'-bipyridinium). Another new type of non-pyridine nucleotide-dependent reductase has an extremely broad substrate specificity for 2-oxo-carboxylates and 2-oxo-dicarboxylates. In crude extracts from Proteus mirabilis and Proteus vulgaris, specific activities of 2-12 mumol product formed per mg protein per min can be found when reduced methyl or benzyl viologen is used as electron donor. The products are (2R)-hydroxy acids. Enoate reductase and 2-oxo-carboxylate reductase are suitable for electro-enzymic reductions in which catalytic amounts of viologens are continuously reduced in an electrochemical cell. This procedure has three advantages: (1) regeneration of NAD(P)H by a second enzyme and substrate is not required, (2) the unstable pyridine nucleotides are not required in the reaction mixture, and (3) the rate of the reaction can be observed continuously by measuring an electric current. Several yeasts, as well as aerobic and anaerobic bacteria, catalyse the reduction of NAD(P)+ by reduced methyl viologen. Such cells can be used for electro-microbial reductions when only pyridine nucleotide-dependent reductases are present. Information about the enzymes which catalyse the reduction of NAD(P)+ at the expense of reduced methyl viologen is given.

Alpha-secondary isotope effects as probes of "tunneling-ready" configurations in enzymatic H-tunneling: insight from environmentally coupled tunneling models

Using alpha-secondary kinetic isotope effects (2 degrees KIEs) in conjunction with primary (1 degrees ) KIEs, we have investigated the mechanism of environmentally coupled hydrogen tunneling in the reductive half-reactions of two homologous flavoenzymes, morphinone reductase (MR) and pentaerythritol tetranitrate reductase (PETNR). We find exalted 2 degrees KIEs (1.17-1.18) for both enzymes, consistent with hydrogen tunneling. These 2 degrees KIEs, unlike 1 degrees KIEs, are independent of promoting motions-a nonequilibrium pre-organization of cofactor and active site residues that is required to bring the reactants into a "tunneling-ready" configuration. That these 2 degrees KIEs are identical suggests the geometries of the "tunneling-ready" configurations in both enzymes are indistinguishable, despite the fact that MR, but not PETNR, has a clearly temperature-dependent 1 degrees KIE. The work emphasizes the benefit of combining studies of 1 degrees and 2 degrees KIEs to report on pre-organization and local geometries within the context of contemporary environmentally coupled frameworks for H-tunneling.

The first archaeal l-aspartate dehydrogenase from the hyperthermophile Archaeoglobus fulgidus: Gene cloning and enzymological characterization

A gene encoding an L-aspartate dehydrogenase (EC 1.4.1.21) homologue was identified in the anaerobic hyperthermophilic archaeon Archaeoglobus fulgidus. After expression in Escherichia coli, the gene product was purified to homogeneity, yielding a homodimeric protein with a molecular mass of about 48 kDa. Characterization revealed the enzyme to be a highly thermostable L-aspartate dehydrogenase, showing little loss of activity following incubation for 1 h at up to 80 degrees C. The optimum temperature for L-aspartate dehydrogenation was about 80 degrees C. The enzyme specifically utilized L-aspartate as the electron donor, while either NAD or NADP could serve as the electron acceptor. The Km values for L-aspartate were 0.19 and 4.3 mM when NAD or NADP, respectively, served as the electron acceptor. The Km values for NAD and NADP were 0.11 and 0.32 mM, respectively. For reductive amination, the Km values for oxaloacetate, NADH and ammonia were 1.2, 0.014 and 167 mM, respectively. The enzyme showed pro-R (A-type) stereospecificity for hydrogen transfer from the C4 position of the nicotinamide moiety of NADH. This is the first report of an archaeal L-aspartate dehydrogenase. Within the archaeal domain, homologues of this enzyme occurred in many Methanogenic species, but not in Thermococcales or Sulfolobales species.

Secoisolariciresinol dehydrogenase: mode of catalysis and stereospecificity of hydride transfer in Podophyllum peltatum

Secoisolariciresinol dehydrogenase (SDH) catalyzes the NAD+ dependent enantiospecific conversion of secoisolariciresinol into matairesinol. In Podophyllum species, (-)-matairesinol is metabolized into the antiviral compound, podophyllotoxin, which can be semi-synthetically converted into the anticancer agents, etoposide, teniposide and Etopophos. Matairesinol is also a precursor of the cancer-preventative "mammalian" lignan, enterolactone, formed in the gut following ingestion of, for example, various high fiber dietary foods, as well as being an intermediate to numerous defense compounds in vascular plants. This study investigated the mode of enantiospecific Podophyllum SDH catalysis, the order of binding, and the stereospecificity of hydride abstraction/transfer from secoisolariciresinol to NAD+. SDH contains a highly conserved catalytic triad (Ser153, Tyr167 and Lys171), whose activity was abolished with site-directed mutagenesis of Tyr167Ala and Lys171Ala, whereas mutagenesis of Ser153Ala only resulted in a much reduced catalytic activity. Isothermal titration calorimetry measurements indicated that NAD+ binds first followed by the substrate, (-)-secoisolariciresinol. Additionally, for hydride transfer, the incoming hydride abstracted from the substrate takes up the pro-S position in the NADH formed. Taken together, a catalytic mechanism for the overall enantiospecific conversion of (-)-secoisolariciresinol into (-)-matairesinol is proposed.

DSD--an integrated, web-accessible database of Dehydrogenase Enzyme Stereospecificities

BACKGROUND

Dehydrogenase enzymes belong to the oxidoreductase class and utilise the coenzymes NAD and NADP. Stereo-selectivity is focused on the C4 hydrogen atoms of the nicotinamide ring of NAD(P). Depending upon which hydrogen is transferred at the C4 location, the enzyme is designated as A or B stereospecific.

DESCRIPTION

The Dehydrogenase Stereospecificity Database v1.0 (DSD) provides a compilation of enzyme stereochemical data, as sourced from the primary literature, in the form of a web-accessible database. There are two search engines, a menu driven search and a BLAST search. The entries are also linked to several external databases, including the NCBI and the Protein Data Bank, providing wide background information. The database is freely available online at: http://www.jenner.ac.uk/DSD/.

CONCLUSION

DSD is a unique compilation available on-line for the first time which provides a key resource for the comparative analysis of reductase hydrogen transfer stereospecificity. As databases increasingly form the backbone of science, largely complete databases such as DSD, are a vital addition.

L-Threonine dehydrogenase from the hyperthermophilic archaeon Pyrococcus horikoshii OT3: gene cloning and enzymatic characterization

A gene encoding the L-threonine dehydrogenase homologue has been identified in a hyperthermophlic archaeon Pyrococcus horikoshii OT3 via genome sequencing. The gene was cloned and expressed in Escherichia coli. The purified enzyme from the recombinant E. coli was extremely thermostable; the activity was not lost after incubation at 100 degrees C for 20 min. The enzyme (molecular mass: 192 kDa) is composed of a tetrameric structure with a type of subunit (41 kDa). The enzyme is specific for NAD and utilizes L-threonine, L-serine and DL-threo-3-phenylserine as the substrate. The enzyme required divalent cations such as Zn(2+), Mn(2+) and Co(2+) for the activity, and contained one zinc ion/subunit. The K(m) values for L-threonine and NAD at 50 degrees C were 0.20 mM and 0.024 mM, respectively. Kinetic analyses indicated that the L-threonine oxidation reaction proceeds via a random mechanism with regard to the binding of L-threonine and NAD. The enzyme showed pro-R stereospecificity for hydrogen transfer at the C4 position of the nicotinamide moiety of NADH. This is the first description of the characteristics of an L-threonine dehydrogenase from the archaea domain.

Stereospecificity of hydride transfer in NAD+-catalyzed 2-deoxy-scyllo-inosose synthase, the key enzyme in the biosynthesis of 2-deoxystreptamine-containing aminocyclitol antibiotics

The key enzyme in the biosynthesis of clinically important aminocyclitol antibiotics is 2-deoxy-scyllo-inosose synthase (DOIS), which converts ubiquitous d-glucose 6-phosphate (G-6-P) into the specific carbocycle, 2-deoxy-scyllo-inosose with an aid of NAD(+)-NADH recycling. The NAD(+)-dependent first step of the DOIS reaction was examined in detail by the use of 6-phosphonate and 6-homophosphonate analogs of G-6-P. Both analogs showed competitive inhibition against the DOIS reaction with K(i) values of 1.3 and 2.8 mM, respectively, due to their inability for the subsequent phosphate elimination. Based on the direct spectrophotometric observation of NADH formed by the hydride transfer from 6-phosphonate to NAD(+), the stereospecificity of the hydride transfer in the DOIS reaction was analyzed with 6-[4-(2)H]phosphonate and was found to be pro-R specific.

Purification and characterization of a novel mannitol dehydrogenase from a newly isolated strain of Candida magnoliae

Mannitol biosynthesis in Candida magnoliae HH-01 (KCCM-10252), a yeast strain that is currently used for the industrial production of mannitol, is catalyzed by mannitol dehydrogenase (MDH) (EC 1.1.1.138). In this study, NAD(P)H-dependent MDH was purified to homogeneity from C. magnoliae HH-01 by ion-exchange chromatography, hydrophobic interaction chromatography, and affinity chromatography. The relative molecular masses of C. magnoliae MDH, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and size-exclusion chromatography, were 35 and 142 kDa, respectively, indicating that the enzyme is a tetramer. This enzyme catalyzed both fructose reduction and mannitol oxidation. The pH and temperature optima for fructose reduction and mannitol oxidation were 7.5 and 37 degrees C and 10.0 and 40 degrees C, respectively. C. magnoliae MDH showed high substrate specificity and high catalytic efficiency (k(cat) = 823 s(-1), K(m) = 28.0 mM, and k(cat)/K(m) = 29.4 mM(-1) s(-1)) for fructose, which may explain the high mannitol production observed in this strain. Initial velocity and product inhibition studies suggest that the reaction proceeds via a sequential ordered Bi Bi mechanism, and C. magnoliae MDH is specific for transferring the 4-pro-S hydrogen of NADPH, which is typical of a short-chain dehydrogenase reductase (SDR). The internal amino acid sequences of C. magnoliae MDH showed a significant homology with SDRs from various sources, indicating that the C. magnoliae MDH is an NAD(P)H-dependent tetrameric SDR. Although MDHs have been purified and characterized from several other sources, C. magnoliae MDH is distinguished from other MDHs by its high substrate specificity and catalytic efficiency for fructose only, which makes C. magnoliae MDH the ideal choice for industrial applications, including enzymatic synthesis of mannitol and salt-tolerant plants.

On a new artificial mediator accepting NADP(H) oxidoreductase from Clostridium thermoaceticum

The purification and partial characterisation of an NADP(H) dependent artificial mediator accepting pyridine nucleotide oxidoreductase (AMAPOR) from the anaerobic Clostridium thermoaceticum is described. Depending on the redox potential of the artificial mediators the AMAPOR is able to regenerate NADP+ or NADPH rendering the enzyme useful for preparative work applying NADP(H) dependent oxidoreductases. At 37 degrees C crude extracts of C. thermoaceticum have an AMAPOR activity of 5-7 U mg(-1). This is 28 degrees under the optimal growth temperature of this microrganism. Out of apparently more than 10 AMAPOR active proteins in the crude cell extracts visible after electrophoresis and activity staining on the gel, two of these proteins were isolated. They seem to be two different oligomers. According to gel electrophoresis they show apparent molecular masses of about 200 and 400 kDa. These two forms showed after SDS gel electrophoresis two monomers with apparent molecular masses of 42 and 56 kDa which we call alpha and beta. The two oligomers may have the compositions alpha2beta2 and alpha4beta4. They contain Fe/S cluster and FAD. Various amounts of the FAD were lost during the purification procedure. This loss is partially reversible after addition of FAD. The AMAPOR reacts with rather different artificial mediators such as viologens, quinones e.g. 1,4-benzoquinone or anthraquinone-2,6-disulphonate, 2,6-dichloro-indophenol and clostridial rubredoxin. Two different ferredoxins from C. thermoaceticum, oxygen or lipoamide are no substrates indicating the here described AMAPOR is not a diaphorase in the usual sense.

Biosynthesis of terpenoids: 1-deoxy-D-xylulose-5-phosphate reductoisomerase from Escherichia coli is a class B dehydrogenase

1-Deoxy-D-xylulose-5-phosphate is converted into 2-C-methyl-D-erythritol-4-phosphate by the catalytic action of 1-deoxy-D-xylulose-5-phosphate reductoisomerase (Dxr protein) using NADPH as cofactor. The stereochemical features of this reaction were investigated in in vitro experiments with the recombinant Dxr protein of Escherichia coli using (4R)- or (4S)-[4-(2)H(1)]NADPH as coenzyme. The enzymatically formed 2-C-methyl-D-erythritol-4-phosphate was isolated and converted into 1,2:3,4-di-O-isopropylidene-2-C-methyl-D-erythritol; NMR spectroscopic investigation of this derivative indicated that only (4S)-[4-(2)H(1)]NADPH affords 2-C-methyl-D-erythritol-4-phosphate labelled exclusively in the H(Re) position of C-1. Stereospecific transfer of H(Si) from C-4 of the cofactor identifies the Dxr protein of E. coli as a class B dehydrogenase.

Stereochemical course and steady state mechanism of the reaction catalyzed by the GDP-fucose synthetase from Escherichia coli

Recently the genes encoding the human and Escherichia coli GDP-mannose dehydratase and GDP-fucose synthetase (GFS) protein have been cloned and it has been shown that these two proteins alone are sufficient to convert GDP mannose to GDP fucose in vitro. GDP-fucose synthetase from E. coli is a novel dual function enzyme in that it catalyzes epimerizations and a reduction reaction at the same active site. This aspect separates fucose biosynthesis from that of other deoxy and dideoxy sugars in which the epimerase and reductase activities are present on separate enzymes encoded by separate genes. By NMR spectroscopy we have shown that GFS catalyzes the stereospecific hydride transfer of the ProS hydrogen from NADPH to carbon 4 of the mannose sugar. This is consistent with the stereospecificity observed for other members of the short chain dehydrogenase reductase family of enzymes of which GFS is a member. Additionally the enzyme is able to catalyze the epimerization reaction in the absence of NADP or NADPH. The kinetic mechanism of GFS as determined by product inhibition and fluorescence binding studies is consistent with a random mechanism. The dissociation constants determined from fluorescence studies indicate that the enzyme displays a 40-fold stronger affinity for the substrate NADPH as compared with the product NADP and utilizes NADPH preferentially as compared with NADH. This study on GFS, a unique member of the short chain dehydrogenase reductase family, coupled with that of its recently published crystal structure should aid in the development of antimicrobial or anti-inflammatory compounds that act by blocking selectin-mediated cell adhesion.

Engineered glycolytic glyceraldehyde-3-phosphate dehydrogenase binds the anti conformation of NAD+ nicotinamide but does not experience A-specific hydride transfer

Glycolytic glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is a NAD-dependent oxidoreductase which catalyzes the oxidative phosphorylation of d-glyceraldehyde-3-phosphate (G3P) to form 1, 3-diphosphoglycerate. The currently accepted mechanism involves an oxidoreduction step followed by a phosphorylation. GAPDH is classified as a B-specific oxidoreductase. The inspection of several crystal structures of GAPDHs indicates that the efficient hydride transfer from the hemithioacetal intermediate to the C4 position of the pyridinium si face requires optimal nicotinamidium-protein contacts for a suitable pyridinium-ring orientation. In previous studies carried out on Escherichia coli GAPDH (C. Corbier, A. Mougin, Y. Mely, H. W. Adolph, M. Zeppezauer, D. Gerard, A. Wonacott, and G. Branlant, Biochimie 72, 545-554, 1990; J. Eyschen, C. Corbier, B. Vitoux, G. Branlant, and M. T. Cung, Protein Pept. Lett. 1, 19-24, 1994), the role of the invariant Asn 313 residue, as an anchor which favors the syn orientation of the nicotinamide ring, was examined. Here, we report further investigations on the molecular factors responsible for the cofactor stereospecificity. Two single [Gly317] and [Ala317] GAPDH mutants and one double [Thr313-Gly317] GAPDH mutant were constructed on the basis of a molecular modelling study from the crystal structure of holo GAPDH from E. coli (E. Duée, L. Olivier-Deyris, E. Fanchon, C. Corbier, G. Branlant, and O. Dideberg, J. Mol. Biol. 257, 814-838, 1996). The Kd constants of [Ala317], [Gly317], and [Thr313-Gly317] GAPDH mutants for NAD are 5, 13, and 300 times higher than that of wild-type GAPDH. Transferred nuclear Overhauser effect spectroscopy demonstrates that the wild-type syn orientation of bound nicotinamide remains unchanged in the [Gly317] and [Ala317] mutants, whereas a conformational equilibrium between the syn and anti forms occurs in the [Thr313-Gly317] double mutant with a preference for the anti conformer. Although the double mutant preferably binds the nicotinamide ring in an anti conformation, it still exhibits B hydride transfer stereospecificity. Yet, the catalytic efficiency is much less than that of the wild type. This indicates that the holo GAPDH mutant fraction with an anti orientation of bound NAD is not capable of forming the ternary complex with G3P which would be required for an efficient A-specific catalytic process. The reasons of this catalytic inefficiency are discussed in relation with the historical and functional models which were advanced to explain the stereospecificity of NAD(P)-dependent dehydrogenases.

New alcohol dehydrogenases for the synthesis of chiral compounds

The enantioselective reduction of carbonyl groups is of interest for the production of various chiral compounds such as hydroxy acids, amino acids, hydroxy esters, or alcohols. Such products have high economic value and are most interesting as additives for food and feed or as building blocks for organic synthesis. Enzymatic reactions or biotransformations with whole cells (growing or resting) for this purpose are described. Although conversions with whole cells are advantageous with respect to saving expensive isolation of the desired enzymes, the products often lack high enantiomeric excess and the process results in low time-space-yield. For the synthesis of chiral alcohols, only lab-scale syntheses with commercially available alcohol dehydrogenases have been described yet. However, most of these enzymes are of limited use for technical applications because they lack substrate specificity, stability (yeast ADH) or enantioselectivity (Thermoanaerobium brockii ADH). Furthermore, all enzymes so far described are forming (S)-alcohols. Quite recently, we found and characterized several new bacterial alcohol dehydrogenases, which are suited for the preparation of chiral alcohols as well as for hydroxy esters in technical scale. Remarkably, of all these novel ADHs the (R)-specific enzymes were found in strains of the genus Lactobacillus. Meanwhile, these new enzymes were characterized extensively. Protein data (amino acid sequence, bound cations) confirm that these catalysts are novel enzymes. (R)-specific as well as (S)-specific ADHs accept a broad variety of ketones and ketoesters as substrates. The applicability of alcohol dehydrogenases for chiral syntheses as an example for the technical use of coenzyme-dependent enzymes is demonstrated and discussed in this contribution. In particular NAD-dependent enzymes coupled with the coenzyme regeneration by formate dehydrogenase proved to be economically feasible for the production of fine chemicals.

A kinetic study and application of a novel carbonyl reductase isolated from Rhodococcus erythropolis

The newly described carbonyl reductase from Rhodococcus erythropolis (RECR) accepts a broad range of substrates. Based on the kinetic constants of a variety of methyl and ethyl ketones a hypothetical model of the substrate-binding site is proposed. Whether a substrate of interest may be reduced by the RECR can be predicted from this model together with the kinetic data. A study of initial velocities and product inhibition is presented, which shows that the kinetics of the RECR follow a Theorell-Chance mechanism. The pro-R hydride of NADH is transferred by the enzyme to the re face of the carbonyl compounds yielding (S)-alcohols. The reduction of methyl 3-oxobutanoate and ethyl 4-chloro-3-oxobutanoate catalyzed by the oxidoreductase lead to the corresponding hydroxy compounds with high enantiomeric purity [enantiomeric excess (e.e.) > or = 99%]. The synthesis of ethyl (2R,3S)-3-hydroxy-2-methylbutanoate was accomplished with high diastereoselectivity (diastereomeric excess = 95%) and enantioselectivity (e.e. > or = 95%).

Stereospecificity of hydrogen transfer by the NADP-linked alcohol dehydrogenase from the thermophilic bacterium Thermoanaerobium brockii

Class A and class B NAD(H)/NADP(H) coenzyme-dependent dehydrogenases distinguish between the diastereotopic hydrogens pro-R and pro-S at position 4 of the cofactor. We investigated the stereochemistry of hydride transfer in reactions catalyzed by an unusual thermophilic, zinc-containing, NADP-linked enzyme Thermoanaerobium brockii alcohol dehydrogenase (TBAD). Using proton NMR spectroscopy of monodeuterated alcohols and coenzymes we found that TBAD is a class A enzyme that transfers the pro-R hydrogen from the pyridine 4 position of the reduced coenzyme. This stereospecificity is stable over (a) a broad range of temperatures up to 70 degrees C, (b) different concentrations of the coenzyme (catalytic or stoichiometric) and (c) a wide scope of substrates. Although NAD+ is not an effective coenzyme for TBAD, NADP+ and its synthetic analogs, 3-acetylpyridine-ADP+ and thio-NADP+, can be used successfully.

Purification and characterisation of the NADH:acceptor reductase component of xylene monooxygenase encoded by the TOL plasmid pWW0 of Pseudomonas putida mt-2

The xylene monooxygenase system encoded by the TOL plasmid pWW0 of Pseudomonas putida catalyses the hydroxylation of a methyl side-chain of toluene and xylenes. Genetic studies have suggested that this monooxygenase consists of two different proteins, products of the xylA and xylM genes, which function as an electron-transfer protein and a terminal hydroxylase, respectively. In this study, the electron-transfer component of xylene monooxygenase, the product of xylA, was purified to homogeneity. Fractions containing the xylA gene product were identified by its NADH:cytochrome c reductase activity. The molecular mass of the enzyme was determined to be 40 kDa by SDS/PAGE, and 42 kDa by gel filtration. The enzyme was found to contain 1 mol/mol of tightly but not covalently bound FAD, as well as 2 mol/mol of non-haem iron and 2 mol/mol of acid-labile sulfide, suggesting the presence of two redox centers, one FAD and one [2Fe-2S] cluster/protein molecule. The oxidised form of the protein had absorbance maxima at 457 nm and 390 nm, with shoulders at 350 nm and 550 nm. These absorbance maxima disappeared upon reduction of the protein by NADH or dithionite. The NADH:acceptor reductase was capable of reducing either one- or two-electron acceptors, such as horse heart cytochrome c or 2,6-dichloroindophenol, at an optimal pH of 8.5. The reductase was found to have a Km value for NADH of 22 microM. The oxidation of NADH was determined to be stereospecific; the enzyme is pro-R (class A enzyme). The titration of the reductase with NADH or dithionite yielded three distinct reduced forms of the enzyme: the reduction of the [2Fe-2S] center occurred with a midpoint redox potential of -171 mV; and the reduction of FAD to FAD. (semiquinone form), with a calculated midpoint redox potential of -244 mV. The reduction of FAD. to FAD.. (dihydroquinone form), the last stage of the titration, occurred with a midpoint redox potential of -297 mV. The [2Fe-2S] center could be removed from the protein by treatment with an excess of mersalyl acid. The [2Fe-2S]-depleted protein was still reduced by NADH, giving rise to the formation of the anionic flavin semiquinone observed in the native enzyme, thus suggesting that the electron flow was NADH --> FAD --> [2Fe-2S] in this reductase. The resulting protein could no longer reduce cytochrome c, but could reduce 2,6-dichloroindophenol at a reduced rate.

Conformational equilibrium of an enzyme catalytic site in the allosteric transition

The dynamic equilibrium of a catalytic site between active and inactive conformations, the missing link between the structure and function of allosteric enzymes, was identified using protein engineering and NMR techniques. Kinetic analyses of the wild-type and three mutants of Thermus L-lactate dehydrogenase established that the allosteric property of the enzyme is associated with a concerted transition between the high-affinity (R) and low-affinity (T) states. By introducing mutations, we prepared an enzyme in which the R and T states were balanced. The conformation of the enzyme-bound coenzyme, NAD+, which interacts directly with the substrate, was analyzed using NMR spectroscopy. NAD+ bound to the mutant enzyme was in a conformational mixture of the active and inactive forms, while NAD+ took on predominantly one of the two forms when it was bound to the other enzymes we had analyzed. We interpret this to mean that the catalytic site is in equilibrium between the two conformations. The ratio of the conformers of each enzyme agreed with the [T]/[R] ratio as determined by kinetic analyses. Therefore, it is the identified conformational equilibrium of the catalytic site that governs the allosteric regulation of the enzyme activity.

Mechanistic and active-site studies on D(--)-mandelate dehydrogenase from Rhodotorula graminis

D(--)-Mandelate dehydrogenase, the first enzyme of the mandelate pathway in the yeast Rhodotorula graminis, catalyses the NAD(+)-dependent oxidation of D(--)-mandelate to phenylglyoxylate. D(--)-2-(Bromoethanoyloxy)-2-phenylethanoic acid ['D(--)-bromoacetylmandelic acid'], an analogue of the natural substrate, was synthesized as a probe for reactive and accessible nucleophilic groups within the active site of the enzyme. D(--)-Mandelate dehydrogenase was inactivated by D(--)-bromoacetylmandelate in a psuedo-first-order process. D(--)-Mandelate protected against inactivation, suggesting that the residue that reacts with the inhibitor is located at or near the active site. Complete inactivation of the enzyme resulted in the incorporation of approx. 1 mol of label/mol of enzyme subunit. D(--)-Mandelate dehydrogenase that had been inactivated with 14C-labelled D(--)-bromoacetylmandelate was digested with trypsin; there was substantial incorporation of 14C into two tryptic-digest peptides, and this was lowered in the presence of substrate. One of the tryptic peptides had the sequence Val-Xaa-Leu-Glu-Ile-Gly-Lys, with the residue at the second position being the site of radiolabel incorporation. The complete sequence of the second peptide was not determined, but it was probably an N-terminally extended version of the first peptide. High-voltage electrophoresis of the products of hydrolysis of modified protein showed that the major peak of radioactivity co-migrated with N tau-carboxymethylhistidine, indicating that a histidine residue at the active site of the enzyme is the most likely nucleophile with which D(--)-bromoacetylmandelate reacts. D(--)-Mandelate dehydrogenase was incubated with phenylglyoxylate and either (4S)-[4-3H]NADH or (4R)-[4-3H]NADH and then the resulting D(--)-mandelate and NAD+ were isolated. The enzyme transferred the pro-R-hydrogen atom from NADH during the reduction of phenylglyoxylate. The results are discussed with particular reference to the possibility that this enzyme evolved by the recruitment of a 2-hydroxy acid dehydrogenase from another metabolic pathway.

Determination of hydride transfer stereospecificity of NADH-dependent alcohol-aldehyde/ketone oxidoreductase from Sulfolobus solfataricus

This paper describes the determination of stereospecificity of hydride transfer reaction of an alcohol dehydrogenase isolated from the archaebacterium Sulfolobus solfataricus. The 1H-NMR and EI-MS data indicate that the enzyme transfers the pro-R hydrogen from coenzyme to substrate and is therefore an A-specific dehydrogenase.

Purification and characterisation of TOL plasmid-encoded benzyl alcohol dehydrogenase and benzaldehyde dehydrogenase of Pseudomonas putida

Benzyl alcohol dehydrogenase and benzaldehyde dehydrogenase, two enzymes of the xylene degradative pathway encoded by the plasmid TOL of a Gram-negative bacterium Pseudomonas putida, were purified and characterized. Benzyl alcohol dehydrogenase catalyses the oxidation of benzyl alcohol to benzaldehyde with the concomitant reduction of NAD+; the reaction is reversible. Benzaldehyde dehydrogenase catalyses the oxidation of benzaldehyde to benzoic acid with the concomitant reduction of NAD+; the reaction is irreversible. Benzyl alcohol dehydrogenase and benzaldehyde dehydrogenase also catalyse the oxidation of many substituted benzyl alcohols and benzaldehydes, respectively, though they were not capable of oxidizing aliphatic alcohols and aldehydes. The apparent Km value of benzyl alcohol dehydrogenase for benzyl alcohol was 220 microM, while that of benzaldehyde dehydrogenase for benzaldehyde was 460 microM. Neither enzyme contained a prosthetic group such as FAD or FMN, and both enzymes were inactivated by SH-blocking agents such as N-ethylmaleimide. Both enzymes were dimers of identical subunits; the monomer of benzyl alcohol dehydrogenase has a mass of 42 kDa whereas that of the monomer of benzaldehyde dehydrogenase was 57 kDa. Both enzymes transfer hydride to the pro-R side of the prochiral C4 of the pyridine ring of NAD+.

Stereospecificity of hydrogen transfer by bovine testicular 20 alpha-hydroxysteroid dehydrogenase

The stereospecificity of hydrogen transfer between steroid (17-hydroxyprogesterone) and both natural cofactors by bovine testicular 20 alpha-hydroxysteroid dehydrogenase (20 alpha-HSD) has been determined. Cofactors used in these studies, [4-pro-S-3H]NADH ([4B-3H]NADH) and [4-pro-S-3H]NADPH ([4B-3H]NADPH) were generated with human placental estradiol 17 beta-dehydrogenase (EC 1.1.1.62) utilizing [17 alpha-3H]estradiol-17 beta and NAD+ or NADP+, respectively. The resulting [4B-3H]NADH and [4B-3H]NADPH were purified by ion-exchange chromatography and separately incubated with molar excess of 17-hydroxyprogesterone as substrate in the presence of 20 alpha-HSD. Following incubation, steroid reactant and product were extracted, separated by HPLC and quantitated as to mass and content of tritium. The oxidized and reduced cofactors were separated by ion-exchange chromatography and quantitated as to mass and tritium content. In all incubations, equimolar amounts of 17,20 alpha-dihydroxy-4-pregnen-3-one and oxidized cofactor were obtained. Further, all recovered radioactivity remained with cofactor and none was found in the steroid product. In additional experiments, both reduced cofactors were separately incubated with glutamate dehydrogenase, an enzyme known to transfer from the B-side of the nicotinamide ring. Here radioactivity was present only in the unreacted cofactor fractions and in the product, glutamic acid. The results indicate that bovine testicular 20 alpha-HSD catalyzes transfer of the 4A-hydrogen from the dihydronicotinamide moiety of the reduced cofactor. Finally, this work described modifications that represent considerable improvement in the purification and assay of bovine 20 alpha-HSD as originally described.

Enzymatic synthesis of [4R-2H]NAD (P)H and [4S-2H]NAD(P)H and determination of the stereospecificity of 7 alpha- and 12 alpha hydroxysteroid dehydrogenase

The stereospecifically labeled coenzymes [4R-2H]NADH, [4R-2H]NADPH and [4S-2H]NAD(P)H were synthesized enzymatically in high yield and high isotopic purity (greater than or equal to 95%) with 2HCOO2H/formate dehydrogenase, (CH3)2C2HOH/alchol dehydrogenase from Thermoanaerobium brockii and [1-2H]glucose/glucose dehydrogenase, respectively. This set of deuterated coenzymes was used to determine the stereospecificity of the previously unstudied 7 alpha-hydroxysteroid dehydrogenase from Escherichia coli (NAD-dependent) and 12 alpha-hydroxysteroid dehydrogenase from Clostridium group P (NADP-dependent). H-NMR and EI-MS of the nicotinamide moiety after enzymatic oxidation of deuterated NAD(P)H with dehydrocholic acid as substrate showed that both dehydrogenases are B-sterospecific.

Stereospecificity of C4 nicotinamide hydrogen transfer of the NADP-dependent glyceraldehyde-3-phosphate dehydrogenase

The stereospecificity of the reaction catalysed by the spinach chloroplast enzyme NADP-dependent glyceraldehyde-3-phosphate dehydrogenase (D-glyceraldehyde-3-phosphate: NADP+ oxidoreductase (phosphorylating), EC 1.2.1.13) with respect to the C4 nicotinamide hydrogen transfer was investigated. NADPH deuterated at the C4 HA position was synthesized using aldehyde dehydrogenase. 1H-NMR spectroscopy was used to examine the NADP+ product of the GPDH reaction for the presence or absence of the C4 deuterium atom. Chloroplast NADP-dependent glyceraldehyde-3-phosphate dehydrogenase retains the deuterium at the C4 HA position (removing the hydrogen atom), and is therefore a B (pro-S) specific dehydrogenase.

The 20 alpha-hydroxysteroid dehydrogenase of Streptomyces hydrogenans

In addition to the well-known 3 alpha,20 beta-hydroxysteroid dehydrogenase ('cortisone reductase'), Streptomyces hydrogenans produces a relatively stable, NAD-dependent 20 alpha-hydroxysteroid dehydrogenase of molecular mass approximately 48 kDa. This enzyme catalyzes the transfer of hydrogen from the 4-pro-S position of NADH.

Mitochondria catalyze the reduction of NAD by reduced methylviologen

Mitochondria from beef heart and yeast catalyze the reduction of NAD to NADH at the expense of reduced methylviologen (MV+). Based on protein the specific activity of mitochondria for this reaction is about 10 20-times higher than the consumption of oxygen in the presence of succinate or NADH. In 2H2O buffer (4S)-[4-2H]NADH is formed in high enantiomeric excess if the reduced methylviologen is electrochemically regenerated.

NMR studies of [1-2H]glucose metabolism in Zymomonas mobilis

In complementary experiments the metabolism of [1-2H]glucose in H2O and of unlabelled glucose in 2H2O by Zymomonas mobilis was examined. The utilization of [1-2H]glucose by Z. mobilis was monitored by high-resolution 2H NMR. The deuterium-labelling pattern and stereochemistry of the ethanols produced from the metabolism of [1-2H]glucose and unlabelled glucose in 2H2O were determined by a combination of 13C and 1H NMR and selective enzyme action. The labelling patterns were explained in terms of enzyme mechanisms and stereospecificity, and metabolite enolization.

Tetrahydrobiopterin biosynthesis. Studies with specifically labeled (2H)NAD(P)H and 2H2O and of the enzymes involved

The biosynthesis of tetrahydrobiopterin from either dihydroneopterin triphosphate, sepiapterin, dihydrosepiapterin or dihydrobiopterin was investigated using extracts from human liver, dihydrofolate reductase and purified sepiapterin reductase from human liver and rat erythrocytes. The incorporation of hydrogen in tetrahydrobiopterin was studied in either 2H2O or in H2O using unlabeled NAD(P)H or (R)-(4-2H)NAD(P)H or (S)-(4-2H)NAD(P)H. Dihydrofolate reductase catalyzed the transfer of the pro-R hydrogen of NAD(P)H during the reduction of 7,8-dihydrobiopterin to tetrahydrobiopterin. Sepiapterin reductase catalyzed the transfer of the pro-S hydrogen of NADPH during the reduction of sepiapterin to 7,8-dihydrobiopterin. In the presence of partially purified human liver extracts one hydrogen from the solvent is introduced at position C(6) and the 4-pro-S hydrogen from NADPH is incorporated at each of the C(1') and C(2') position of BH4. Label from the solvent is also introduced into position C(3'). These results suggest that dihydrofolate reductase is not involved in the biosynthesis of tetrahydrobiopterin from dihydroneopterin triphosphate. They are consistent with the assumption of the occurrence of a 6-pyruvoyl-tetrahydropterin intermediate, which is proposed to be formed upon triphosphate elimination from dihyroneopterin triphosphate, and via an intramolecular redox reaction. Our results suggest that the reduction of 6-pyruvoyl-tetrahydropterin might be catalyzed by sepiapterin reductase.

Stereospecificity for nicotinamide nucleotides in enzymatic and chemical hydride transfer reactions

The pyridine nucleotide (NAD and NADP)-linked enzymes are a large class of enzymes constituting approximately 17% of all classified enzymes. When these enzymes catalyze their reactions, the hydride transfer between the substrate and the reaction site (i.e., C-4 of the nicotinamide/dihydronicotinamide ring) of the coenzyme takes place in a stereospecific manner. Thus, in the reaction of oxidation of the reduced coenzyme, one group of enzymes catalyzes the extraction of only the hydrogen having the R configuration at the No. 4 carbon, while the other group catalyzes the removal of only that with the S configuration. Because this aspect of enzyme stereospecificity provides essential information for a given enzyme's reaction mechanism, active site structure, and evolutionary relationship with other enzymes, intensive effort has been made to establish the stereospecificities of as many enzymes as possible. This review presents the compilation of the stereospecificities of these enzymes. Some empirical rules, which are useful but not definitive, in predicting a given enzyme's stereospecificity are also described. In addition, the stereospecificity in enzymatic reactions is compared to the stereo-preference in chemical oxidoreduction of the coenzyme. In order to elucidate the mechanism for the enzyme stereospecificity, the conformations of the coenzyme in free-state and enzyme-bound state are extensively discussed here.