Preference For NADPH Research Articles

Characterization and gene deletion analysis of four homologues of group 3 pyridine nucleotide disulfide oxidoreductases from Thermococcus kodakarensis.

elemental sulfur (S(0)) oxidoreductase (NSR) and NAD(P)H oxidase (NOX) activities. TK1299 exhibited NSR activity with a preference for NADPH and showed strict CoA-dependency similar to that of the Pyrococcus furiosus homologue PF1186. During the assays, the non-enzymatic formation of H2S from S(0) and free CoA-SH was observed, and the addition of enzyme and NADPH enhanced H2S evolution. A catalytic cycle of TK1299 was proposed suggesting that CoA-SH acted to solubilize S(0) by forming CoA persulfides, followed by reduction of an enzyme-S-S-CoA intermediate produced after both enzymatic and non-enzymatic evolution of H2S from the CoA persulfide, with NADPH as an electron donor. TK1481 showed NSR activity independently of CoA-SH, implying a direct reaction with S(0). TK1299, TK1481, and TK0304 exhibited high NOX activity, and the NADH-dependent activities were inhibited by the addition of free CoA-SH. Multiple disruptions of the four group 3 PNDOR homologues in T. kodakarensis demonstrated that none of these homologues were essential for S(0)-dependent growth. Many disruptants grew better than the parent strain, but a few multiple disruptants showed decreased growth properties after aerobic inoculation into a pyruvate-containing medium without S(0), suggesting the complicated participation of these group 3 PNDORs in sensitivity/resistance to dissolved oxygen when S(0) was absent.

Structural and biochemical characterization of MdaB from cariogenicStreptococcus mutansreveals an NADPH-specific quinone oxidoreductase

The smu.1420 gene from the cariogenic pathogen Streptococcus mutans encodes a putative protein which has sequence homology to NQO [ quinone oxidoreductase] family members, including mammalian NQO and bacterial MdaB (modulator of drug activity B). NQO can detoxify quinones by converting them to hydroquinones and prevent the generation of reactive oxygen species. Thus, comprehensive studies on Smu.1420 will be important for uncovering the antioxidation and antidrug mechanisms of S. mutans. Here, the catalytic properties of Smu.1420 have been characterized, and its structure was determined in complexes with NADP(+) and menadione, respectively. Smu.1420 binds menadione directly and exhibits a pronounced preference for NADPH over NADH as a substrate, demonstrating that it is an NADPH-specific quinone oxidoreductase. The structure of Smu.1420 shows a compact homodimer with two substrate pockets located in the cleft of the dimer interface. The nicotinamide moiety of NADP(+) is bound on top of the isoalloxazine moiety of the FAD cofactor and overlaps with the binding site of menadione, suggesting a hydride-transfer process from NADPH to FAD and then to menadione. Two strongly basic patches near the substrate pocket are expected to confer the preference for NADPH over NADH. These studies shed light on future drug development against the cariogenic pathogen S. mutans.

Actin Stimulates Reduction of the MICAL-2 Monooxygenase Domain

MICALs are large, multidomain flavin-dependent monooxygenases that use redox chemistry to cause actin to depolymerize. Little enzymology has been reported for MICALs, and none has been reported for MICAL-2, an enzyme vital for the proliferation of prostate cancer. The monooxygenase domains of MICALs resemble aromatic hydroxylases, but their substrate is the sulfur of a methionine of actin. In order to determine how closely MICAL-2 conforms to the aromatic hydroxylase paradigm, we studied its reaction with NAD(P)H. The enzyme has a strong preference for NADPH over NADH caused by a large difference in binding NADPH. A comparison of the reduction kinetics using protio-NADPH and [4R-(2)H]-NADPH showed that MICAL-2 is specific for the proR hydride of NADPH, as evidenced by a 4.8-fold kinetic isotope effect. The reductive half-reaction of the MICAL-2 hydroxylase domain is stimulated by f-actin. In the absence of actin, NADPH reduces the flavin relatively slowly; actin speeds that reaction significantly. The separate monooxygenase domain of MICAL-2 has the classic regulatory behavior of flavin-dependent aromatic hydroxylases (Class A monooxygenases): slow reduction of the flavin when the substrate to be oxygenated is absent. This prevents the wasteful consumption of reduced pyridine nucleotide and the production of harmful H2O2. Our results show that this strategy is used by MICAL-2. Thus, our data suggest that MICAL-2 could regulate catalysis through the monooxygenase domain alone; control by interactions with other domains of MICAL in the full-length enzyme may not be needed.

Comparative characterization of novel ene‐reductases from cyanobacteria

The growing importance of biocatalysis in the syntheses of enantiopure molecules results from the benefits of enzymes regarding selectivity and specificity of the reaction and ecological issues of the process. Ene-reductases (ERs) from the old yellow enzyme family have received much attention in the last years. These flavo-enzymes catalyze the trans-specific reduction of activated C=C bonds, which is an important reaction in asymmetric synthesis, because up to two stereogenic centers can be created in one reaction. However, limitations of ERs described in the literature such as their moderate catalytic activity and their strong preference for NADPH promote the search for novel ERs with improved properties. In this study, we characterized nine novel ERs from cyanobacterial strains belonging to different taxonomic orders and habitats. ERs were identified with activities towards a broad spectrum of alkenes. The reduction of maleimide was catalyzed with activities of up to 35.5 U mg(-1) using NADPH. Ketoisophorone and (R)-carvone, which were converted to the highly valuable compounds (R)-levodione and (2R,5R)-dihydrocarvone, were reduced with reaction rates of up to 2.2 U mg(-1) with NADPH. In contrast to other homologous ERs from the literature, NADH was accepted at moderate to high rates as well: Enzyme activities of up to 16.7 U mg(-1) were obtained for maleimide and up to 1.3 U mg(-1) for ketoisophorone and (R)-carvone. Additionally, excellent stereoselectivities were achieved in the reduction of (R)-carvone (97-99% de). In particular, AnabaenaER3 from Anabaena variabilis ATCC 29413 and AcaryoER1 from Acaryochloris marina MBIC 11017 were identified as useful biocatalysts. Therefore, novel ERs from cyanobacteria with high catalytic efficiency were added to the toolbox for the asymmetric reduction of alkenes.

Characterization of Cupriavidus metallidurans CYP116B1 – A thiocarbamate herbicide oxygenating P450–phthalate dioxygenase reductase fusion protein

The novel cytochrome P450/redox partner fusion enzyme CYP116B1 from Cupriavidus metallidurans was expressed in and purified from Escherichia coli. Isolated CYP116B1 exhibited a characteristic Fe(II)CO complex with Soret maximum at 449 nm. EPR and resonance Raman analyses indicated low-spin, cysteinate-coordinated ferric haem iron at both 10 K and ambient temperature, respectively, for oxidized CYP116B1. The EPR of reduced CYP116B1 demonstrated stoichiometric binding of a 2Fe-2S cluster in the reductase domain. FMN binding in the reductase domain was confirmed by flavin fluorescence studies. Steady-state reduction of cytochrome c and ferricyanide were supported by both NADPH/NADH, with NADPH used more efficiently (K(m[NADPH]) = 0.9 ± 0.5 μM and K(m[NADH]) = 399.1 ± 52.1 μM). Stopped-flow studies of NAD(P)H-dependent electron transfer to the reductase confirmed the preference for NADPH. The reduction potential of the P450 haem iron was -301 ± 7 mV, with retention of haem thiolate ligation in the ferrous enzyme. Redox potentials for the 2Fe-2S and FMN cofactors were more positive than that of the haem iron. Multi-angle laser light scattering demonstrated CYP116B1 to be monomeric. Type I (substrate-like) binding of selected unsaturated fatty acids (myristoleic, palmitoleic and arachidonic acids) was shown, but these substrates were not oxidized by CYP116B1. However, CYP116B1 catalysed hydroxylation (on propyl chains) of the herbicides S-ethyl dipropylthiocarbamate (EPTC) and S-propyl dipropylthiocarbamate (vernolate), and the subsequent N-dealkylation of vernolate. CYP116B1 thus has similar thiocarbamate-oxidizing catalytic properties to Rhodoccocus erythropolis CYP116A1, a P450 involved in the oxidative degradation of EPTC.

Overexpression and biochemical characterization of soluble pyridine nucleotide transhydrogenase from Escherichia coli

The soluble pyridine nucleotide transhydrogenase (STH) is an energy-independent flavoprotein that directly catalyzes hydride transfer between NAD(H) and NADP(H) to maintain homeostasis of these two redox cofactors. The sth gene in Escherichia coli was cloned and expressed as a fused protein (EcSTH). The purified EcSTH displayed maximal activity at 35 °C, pH 7.5. Heat-inactivation studies showed that EcSTH retains 50% activity after 5 h at 50 °C. The enzyme was stable at 4 °C for 25 days. The apparent K(m) values of EcSTH were 68.29 μM for NADPH and 133.2 μM for thio-NAD(+) . The k(cat) /K(m) ratios showed that EcSTH had a 1.25-fold preference for NADPH over thio-NAD(+) . Product inhibition studies showed that EcSTH activity was strongly inhibited by excess NADPH, but not by thio-NAD(+) . EcSTH activity was enhanced by 2 mM adenine nucleotide and inhibited by divalent metal ions: Mn(2+) , Co(2+) , Zn(2+) , Ni(2+) and Cu(2+) . However, after preincubation for 30 min, most divalent metal ions had little effect on EcSTH activity, except Zn(2+) , Ni(2+) and Cu(2+) . The enzymatic analysis could provide the important basic knowledge for EcSTH utilizations.

Identification and molecular characterization of a novel flavin-free NADPH preferred azoreductase encoded by azoB in Pigmentiphaga kullae K24

BackgroundMicrobial degradation of azo dyes is commonly initiated by the reduction of the azo bond(s) by a group of NADH or NADPH dependant azoreductases with many requiring flavin as a cofactor. In this study, we report the identification of a novel flavin-free NADPH preferred azoreductase encoded by azoB in Pigmentiphaga kullae K24.ResultsThe deduced amino acid sequence of azoB from P. kullae K24 showed 61% identity to a previously studied azoreductase (AzoA) from the same strain. azoB encoded a protein of 203 amino acids and heterologously expressed in Escherichia coli. The purified recombinant enzyme was a monomer with a molecular mass of 22 kDa. Both NADH and NADPH can be used as an electron donor for its activity with 4-(4-hydroxy-1-naphthylazo) benzenesulfonic acid (Orange I) as substrate. The apparent Km values for both NADH and Orange I were 170 and 8.6 μM, respectively. The Km of NADPH for the enzyme is 1.0 μM. When NADPH served as the electron donor, the activity of the enzyme is 63% higher than that when NADH was used. The pH and temperature optima for activity of the enzyme with Orange I as the substrate were at pH 6.0 and between 37 and 45°C. Phylogenetic analysis shows that AzoB belongs to the flavin-free azoreductase group which has a key fingerprint motif GXXGXXG for NAD(P)H binding at the N-terminus of the amino acid sequences. The 3D structure of AzoB was generated by comparative modeling approach. The structural combination of three conserved glycine residues (G7xxG10xxG13) in the pyrophosphate-binding loop with the Arg-32 explains the preference for NADPH of AzoB.ConclusionThe biochemical and structural properties of AzoB from P. kullae K24 revealed its preference for NADPH over NADH and it is a member of the monomeric flavin-free azoreductase group. Our studies show the substrate specificity of AzoB based on structure and cofactor requirement and the phylogenetic relationship among azoreductase groups.

A single intersubunit salt bridge affects oligomerization and catalytic activity in a bacterial quinone reductase

YhdA, a thermostable NADPH:FMN oxidoreductase from Bacillus subtilis, reduces quinones via a ping-pong bi-bi mechanism with a pronounced preference for NADPH. The enzyme occurs as a stable tetramer in solution. The two extended dimer surfaces are packed against each other by a 90 rotation of one dimer with respect to the other. This assembly is stabilized by the formation of four salt bridges between K109 and D137 of the neighbouring protomers. To investigate the importance of the ion pair contacts, the K109L and D137L single replacement variants, as well as the K109L/D137L and K109D/D137K double replacement variants, were generated, expressed, purified, crystallized and biochemically characterized. The K109L and D137L variants form dimers instead of tetramers, whereas the K109L/D137L and K109D/D137K variants appear to exist in a dimer-tetramer equilibrium in solution. The crystal structures of the K109L and D137L variants confirm the dimeric state, with the K109L/D137L and K109D/D137K variants adopting a tetrameric assembly. Interestingly, all protein variants show a drastically reduced quinone reductase activity in steady-state kinetics. Detailed analysis of the two half reactions revealed that the oxidative half reaction is not affected, whereas reduction of the bound FMN cofactor by NADPH is virtually abolished. Inspection of the crystal structures indicates that the side chain of K109 plays a dual role by forming a salt bridge to D137, as well as stabilizing a glycine-rich loop in the vicinity of the FMN cofactor. In all protein variants, this glycine-rich loop exhibits a much higher mobility, compared to the wild-type. This appears to be incompatible with NADPH binding and thus leads to abrogation of flavin reduction.

Engineering of a matched pair of xylose reductase and xylitol dehydrogenase for xylose fermentation by Saccharomyces cerevisiae

Metabolic engineering of Saccharomyces cerevisiae for xylose fermentation has often relied on insertion of a heterologous pathway consisting of nicotinamide adenine dinucleotide (phosphate) NAD(P)H-dependent xylose reductase (XR) and NAD(+)-dependent xylitol dehydrogenase (XDH). Low ethanol yield, formation of xylitol and other fermentation by-products are seen for many of the S. cerevisiae strains constructed in this way. This has been ascribed to incomplete coenzyme recycling in the steps catalyzed by XR and XDH. Despite various protein-engineering efforts to alter the coenzyme specificity of XR and XDH individually, a pair of enzymes displaying matched utilization of NAD(H) and NADP(H) was not previously reported. We have introduced multiple site-directed mutations in the coenzyme-binding pocket of Galactocandida mastotermitis XDH to enable activity with NADP(+), which is lacking in the wild-type enzyme. We describe four enzyme variants showing activity for xylitol oxidation by NADP(+) and NAD(+). One of the XDH variants utilized NADP(+) about 4 times more efficiently than NAD(+). This is close to the preference for NADPH compared with NADH in mutants of Candida tenuis XR. Compared to an S. cerevisiae-reference strain expressing the genes for the wild-type enzymes, the strains comprising the gene encoding the mutated XDH in combination a matched XR mutant gene showed up to 50% decreased glycerol yield without increase in ethanol during xylose fermentation.

Nitroreductase from Bacillus licheniformis: A stable enzyme for prodrug activation

5-Aziridinyl-2,4-dinitrobenzamide (CB1954) has potential applications in enzyme/prodrug targeted anti-cancer therapies since it can be activated by nitroreductases to form a cytotoxic, bifunctional hydroxylamine derivative. A nitroreductase that can activate CB1954 has been previously isolated from Escherichia coli, but its usefulness is limited by its poor stability and low catalytic efficiency for CB1954. We now report the identification and characterization of a nitroreductase enzyme from the thermophilic bacterium Bacillus licheniformis. Although there is only 28% amino acid sequence identity between this enzyme and the previously isolated E. coli nitroreductase, the two enzymes have a number of characteristics in common. Both enzymes have been shown to reduce both CB1954 and menadione in the presence of NADH and NADPH. However, whereas E. coli nitroreductase produces equimolar amounts of the 2- and 4- hydroxylamine derivative of CB1954, the B. licheniformis enzyme produces only the desired 4-hydroxylamine derivative. It has a preference for NADPH as cosubstrate, and is also active with a range of CB1954 derivatives as substrate and reduced pyridinium cofactor analogues. Moreover, the enzyme is much more thermostable than the E. coli nitroreductase and shows maximum activity at 30 °C. These characteristics suggest that the B. licheniformis nitroreductase may be a possible candidate enzyme for enzyme/prodrug therapies due to its bacterial origin, the high activity observed with CB1954 and its enhanced stability.

Mutational Research on the Role of Lysine 21 in the Pichia stipitis Xylose Reductase

The xylose reductase of Pichia stipitis is one of the most important enzymes. It can be used to build up recombinant Saccharomyces cerevisiae strain for utilizing xylose and producing ethanol. Intercellular redox imbalance caused by NADPH preference over NADH for Pichia stipitis xylose reductase (PsXR) has been considered to be one of the main factors for poor ethanol productivity. Some key amino acids of PsXR, which affect the activity or coenzyme preference, were investigated in our previous study. In this study, Lys21 was rationally designed for site-directed mutagenesis to alter the coenzyme specificity of PsXR from NADPH and NADH into single NADH. The wild gene and mutagenesis genes were ligated into pET28b, and were transferred into E. coli BL21 (DE3). After being induced by IPTG, the xylose reductases were purified. Purified mutants K21A (Lys21→Ala), K21R (Lys21→Arg) were characterized by steady-state kinetic analysis. The results showed that the coenzyme dependence of K21A was completely reversed to NADH.

A Novel Chromate Reductase from Thermus scotoductus SA-01 Related to Old Yellow Enzyme

Bacteria can reduce toxic and carcinogenic Cr(VI) to insoluble and less toxic Cr(III). Thermus scotoductus SA-01, a South African gold mine isolate, has been shown to be able to reduce a variety of metals, including Cr(VI). Here we report the purification to homogeneity and characterization of a novel chromate reductase. The oxidoreductase is a homodimeric protein, with a monomer molecular mass of approximately 36 kDa, containing a noncovalently bound flavin mononucleotide cofactor. The chromate reductase is optimally active at a pH of 6.3 and at 65 degrees C and requires Ca(2+) or Mg(2+) for activity. Enzyme activity was also dependent on NADH or NADPH, with a preference for NADPH, coupling the oxidation of approximately 2 and 1.5 mol NAD(P)H to the reduction of 1 mol Cr(VI) under aerobic and anaerobic conditions, respectively. The K(m) values for Cr(VI) reduction were 3.5 and 8.4 microM for utilizing NADH and NADPH as electron donors, respectively, with corresponding V(max) values of 6.2 and 16.0 micromol min(-1) mg(-1). The catalytic efficiency (k(cat)/K(m)) of chromate reduction was 1.14 x 10(6) M(-1) s(-1), which was >50-fold more efficient than that of the quinone reductases and >180-fold more efficient than that of the nitroreductases able to reduce Cr(VI). The chromate reductase was identified to be encoded by an open reading frame of 1,050 bp, encoding a single protein of 38 kDa under the regulation of an Escherichia coli sigma(70)-like promoter. Sequence analysis shows the chromate reductase to be related to the old yellow enzyme family, in particular the xenobiotic reductases involved in the oxidative stress response.

Molecular Modeling and Site-Directed Mutagenesis Reveal the Benzylisoquinoline Binding Site of the Short-Chain Dehydrogenase/Reductase Salutaridine Reductase

Recently, the NADPH-dependent short-chain dehydrogenase/reductase (SDR) salutaridine reductase (E.C. 1.1.1.248) implicated in morphine biosynthesis was cloned from Papaver somniferum. In this report, a homology model of the Papaver bracteatum homolog was created based on the x-ray structure of human carbonyl reductase 1. The model shows the typical alpha/beta-folding pattern of SDRs, including the four additional helices alphaF'-1 to alphaF'-4 assumed to prevent the dimerization of the monomeric short-chain dehydrogenases/reductases. Site-directed mutagenesis of asparagine-152, serine-180, tyrosine-236, and lysine-240 resulted in enzyme variants with strongly reduced performance or inactive enzymes, showing the involvement of these residues in the proton transfer system for the reduction of salutaridine. The strong preference for NADPH over NADH could be abolished by replacement of arginine residues 44 and 48 by glutamic acid, confirming the interaction between the arginines and the 2'-phosphate group. Docking of salutaridine into the active site revealed nine amino acids presumably responsible for the high substrate specificity of salutaridine reductase. Some of these residues are arranged in the right position by an additional alphaE' helix, which is not present in SDRs analyzed so far. Enzyme kinetic data from mutagenic replacement emphasize the critical role of these residues in salutaridine binding and provide the first data on the molecular interaction of benzylisoquinoline alkaloids with enzymes.

Crystal Structures of Δ1-Piperideine-2-carboxylate/Δ1-Pyrroline-2-carboxylate Reductase Belonging to a New Family of NAD(P)H-dependent Oxidoreductases: CONFORMATIONAL CHANGE, SUBSTRATE RECOGNITION, AND STEREOCHEMISTRY OF THE REACTION

Delta(1)-Piperideine-2-carboxylate/Delta(1)-pyrroline-2-carboxylate reductase from Pseudomonas syringae pv. tomato belongs to a novel sub-class in a large family of NAD(P)H-dependent oxidoreductases distinct from the conventional MDH/LDH superfamily characterized by the Rossmann fold. We have determined the structures of the following three forms of the enzyme: the unliganded form, the complex with NADPH, and the complex with NADPH and pyrrole-2-carboxylate at 1.55-, 1.8-, and 1.7-A resolutions, respectively. The enzyme exists as a dimer, and the subunit consists of three domains; domain I, domain II (NADPH binding domain), and domain III. The core of the NADPH binding domain consists of a seven-stranded predominantly antiparallel beta-sheet fold (which we named SESAS) that is characteristic of the new oxidoreductase family. The enzyme preference for NADPH over NADH is explained by the cofactor binding site architecture. A comparison of the overall structures revealed that the mobile domains I and III change their conformations to produce the catalytic form. This conformational change plays important roles in substrate recognition and the catalytic process. The active site structure of the catalytic form made it possible to identify the catalytic Asp:Ser:His triad and investigate the catalytic mechanism from a stereochemical point of view.

Switching Pyridine Nucleotide Specificity in P450 BM3: MECHANISTIC ANALYSIS OF THE W1046H AND W1046A ENZYMES

Flavocytochrome P450 BM3 is a member of the diflavin reductase enzyme family. Members include cytochrome P450 reductase, nitric-oxide synthase, methionine synthase reductase, and novel oxidoreductase 1. These enzymes show a strong preference for NADPH over NADH as reducing coenzyme. An aromatic residue stacks over the FAD isoalloxazine ring in each enzyme, and in some cases it is important in controlling coenzyme specificity. In P450 BM3, the aromatic residue inferred from sequence alignments to stack over the FAD is Trp-1046. Mutation to Ala-1046 and His-1046 effected a remarkable coenzyme specificity switch. P450 BM3 W1046A/W106H FAD and reductase domains are efficient NADH-dependent ferricyanide reductases with selectivity coefficients (k(cat)/K(m)(NADPH)/k(cat)/K(m)(NADH)) of 1.5, 67, and 8571 for the W1046A, W1046H, and wild-type reductase domains, respectively. Stopped-flow photodiode array absorption studies indicated a charge-transfer intermediate accumulated in the W1046A FAD domain (and to a lesser extent in the W1046H FAD domain) and was attributed to formation of a reduced FADH(2)-NAD(P)(+) charge-transfer species, suggesting a relatively slow rate of release of NAD(P)(+) from reduced enzymes. Unlike wild-type enzymes, there was no formation of the blue semiquinone species observed during reductive titration of the W0146A/W146H FAD and reductase domains with dithionite or NAD(P)H. This was a consequence of elevation of the semiquinone/hydroquinone couple of the FAD with respect to the oxidized/semiquinone couple, and a concomitant approximately 100-mV elevation in the 2-electron redox couple for the enzyme-bound FAD (-320, -220, and -224 mV in the wild-type, W1046A, and W1046H FAD domains, respectively).

Discovery and characterization of a Coenzyme A disulfide reductase from Pyrococcus horikoshii

We have cloned NADH oxidase homologues from Pyrococcus horikoshii and P. furiosus, and purified the recombinant form of the P. horikoshii enzyme to homogeneity from Escherichia coli. Both enzymes (previously referred to as NOX2) have been shown to act as a coenzyme A disulfide reductases (CoADR: CoA-S-S-CoA + NAD(P)H + H+-->2CoA-SH + NAD(P)+). The P. horikoshii enzyme shows a kcat app of 7.2 s(-1) with NADPH at 75 degrees C. While the enzyme shows a preference for NADPH, it is able to use both NADPH and NADH efficiently, with both giving roughly equal kcats, while the Km for NADPH is roughly eightfold lower than that for NADH. The enzyme is specific for the CoA disulfide, and does not show significant reductase activity with other disulfides, including dephospho-CoA. Anaerobic reductive titration of the enzyme with NAD(P)H proceeds in two stages, with an apparent initial reduction of a nonflavin redox center with the first reduction resulting in what appears to be an EH2 form of the enzyme. Addition of a second of NADPH results in the formation of an apparent FAD-NAD(P)H complex. The behavior of this enzyme is quite different from the mesophilic staphylococcal version of the enzyme. This is only the second enzyme with this activity discovered, and the first from a strict anaerobe, an Archaea, or hyperthermophilic source. P. furiosus cells were assayed for small molecular mass thiols and found to contain 0.64 micromol CoA.g dry weight(-1) (corresponding to 210 microM CoA in the cell) consistent with CoA acting as a pool of disulfide reducing equivalents.

Structural and functional analysis of the gpsA gene product of Archaeoglobus fulgidus: A glycerol‐3‐phosphate dehydrogenase with an unusual NADP+ preference

NAD(+)-dependent glycerol-3-phosphate dehydrogenase (G3PDH) is generally absent in archaea, because archaea, unlike eukaryotes and eubacteria, utilize glycerol-1-phosphate instead of glycerol-3-phosphate for the biosynthesis of membrane lipids. Surprisingly, the genome of the hyperthermophilic archaeon Archaeoglobus fulgidus comprises a G3PDH ortholog, gpsA, most likely due to horizontal gene transfer from a eubacterial organism. Biochemical characterization proved G3PDH-like activity of the recombinant gpsA gene product. However, unlike other G3PDHs, the up to 85 degrees C thermostable A. fulgidus G3PDH exerted a 15-fold preference for NADPH over NADH. The A. fulgidus G3PDH bears the hallmarks of adaptation to halotolerance and thermophilicity, because its 1.7-A crystal structure showed a high surface density for negative charges and 10 additional intramolecular salt bridges compared to a mesophilic G3PDH structure. Whereas all amino acid residues required for dihydroxyacetone phosphate binding and reductive catalysis are highly conserved, the binding site for the adenine moiety of the NAD(P) cosubstrate shows a structural variation that reflects the observed NADPH preference, for example, by a putative salt bridge between R49 and the 2'-phosphate.

Coenzyme Site-directed Mutants of Photosynthetic A 4-GAPDH Show Selectively Reduced NADPH-dependent Catalysis, Similar to Regulatory AB-GAPDH Inhibited by Oxidized Thioredoxin

Chloroplast glyceraldehyde-3-phosphate dehydrogenase (GAPDH) of higher plants uses both NADP(H) and NAD(H) as coenzyme and consists of one (GapA) or two types of subunits (GapA, GapB). AB-GAPDH is regulated in vivo through the action of thioredoxin and metabolites, showing higher kinetic preference for NADPH in the light than in darkness due to a specific effect on k cat(NADPH). Previous crystallographic studies on spinach chloroplast A 4-GAPDH complexed with NADP or NAD showed that residues Thr33 and Ser188 are involved in NADP over NAD selectivity by interacting with the 2′-phosphate group of NADP. This suggested a possible involvement of these residues in the regulatory mechanism. Mutants of recombinant spinach GapA (A 4-GAPDH) with Thr33 or Ser188 replaced by Ala (T33A, S188A and double mutant T33A/S188A) were produced, expressed in Escherichia coli, and compared to wild-type recombinant A 4-GAPDH, in terms of crystal structures and kinetic properties. Affinity for NADPH was decreased significantly in all mutants, and k cat (NADPH) was lowered in mutants carrying the substitution of Ser188. NADH-dependent activity was unaffected. The decrease of k cat/ K m of the NADPH-dependent reaction in Ser188 mutants resembles the behaviour of AB-GAPDH inhibited by oxidized thioredoxin, as confirmed by steady-state kinetic analysis of native enzyme. A significant expansion of size of the A 4-tetramer was observed in the S188A mutant compared to wild-type A 4. We conclude that in the absence of interactions between Ser188 and the 2′-phosphate group of NADP, the enzyme structure relaxes to a less compact conformation, which negatively affects the complex catalytic cycle of GADPH. A model based on this concept might be developed to explain the in vivo light-regulation of the GAPDH.

Identifying determinants of NADPH specificity in Baeyer–Villiger monooxygenases

The Baeyer-Villiger monooxygenase (BVMO), 4-hydroxyacetophenone monooxygenase (HAPMO), uses NADPH and O(2) to oxidize a variety of aromatic ketones and sulfides. The FAD-containing enzyme has a 700-fold preference for NADPH over NADH. Sequence alignment with other BVMOs, which are all known to be selective for NADPH, revealed three conserved basic residues, which could account for the observed coenzyme specificity. The corresponding residues in HAPMO (Arg339, Lys439 and Arg440) were mutated and the properties of the purified mutant enzymes were studied. For Arg440 no involvement in coenzyme recognition could be shown as mutant R440A was totally inactive. Although this mutant could still be fully reduced by NADPH, no oxygenation occurred, indicating that this residue is crucial for completing the catalytic cycle of HAPMO. Characterization of several Arg339 and Lys439 mutants revealed that these residues are indeed both involved in coenzyme recognition. Mutant R339A showed a largely decreased affinity for NADPH, as judged from kinetic analysis and binding experiments. Replacing Arg339 also resulted in a decreased catalytic efficiency with NADH. Mutant K439A displayed a 100-fold decrease in catalytic efficiency with NADPH, mainly caused by an increased K(m). However, the efficiency with NADH increased fourfold. Saturation mutagenesis at position 439 showed that the presence of an asparagine or a phenylalanine improves the catalytic efficiency with NADH by a factor of 6 to 7. All Lys439 mutants displayed a lower affinity for AADP(+), confirming a role of the lysine in recognizing the 2'-phosphate of NADPH. The results obtained could be extrapolated to the sequence-related cyclohexanone monooxygenase. Replacing Lys326 in this BVMO, which is analogous to Lys439 in HAPMO, again changed the coenzyme specificity towards NADH. These results indicate that the strict NADPH dependency of this class of monooxygenases is based upon recognition of the coenzyme by several basic residues.

A Novel NADH-linked L-Xylulose Reductase in the L-Arabinose Catabolic Pathway of Yeast

An NADH-dependent l-xylulose reductase and the corresponding gene were identified from the yeast Ambrosiozyma monospora. The enzyme is part of the yeast pathway for l-arabinose catabolism. A fungal pathway for l-arabinose utilization has been described previously for molds. In this pathway l-arabinose is sequentially converted to l-arabinitol, l-xylulose, xylitol, and d-xylulose and enters the pentose phosphate pathway as d-xylulose 5-phosphate. In molds the reductions are NADPH-linked, and the oxidations are NAD(+)-linked. Here we show that in A. monospora the pathway is similar, i.e. it has the same two reduction and two oxidation reactions, but the reduction by l-xylulose reductase is not performed by a strictly NADPH-dependent enzyme as in molds but by a strictly NADH-dependent enzyme. The ALX1 gene encoding the NADH-dependent l-xylulose reductase is strongly expressed during growth on l-arabinose as shown by Northern analysis. The gene was functionally overexpressed in Saccharomyces cerevisiae and the purified His-tagged protein characterized. The reversible enzyme converts l-xylulose to xylitol. It also converts d-ribulose to d-arabinitol but has no activity with l-arabinitol or adonitol, i.e. it is specific for sugar alcohols where, in a Fischer projection, the hydroxyl group of the C-2 is in the l-configuration and the hydroxyl group of C-3 is in the d-configuration. It also has no activity with C-6 sugars or sugar alcohols. The K(m) values for l-xylulose and d-ribulose are 9.6 and 4.7 mm, respectively. To our knowledge this is the first report of an NADH-linked l-xylulose reductase.