Identification of a novel conserved sequence motif in flavoprotein hydroxylases with a putative dual function in FAD/NAD(P)H binding.

A novel conserved sequence motif has been located among the flavoprotein hydroxylases. Based on the crystal structure and site-directed mutagenesis studies of p-hydroxybenzoate hydroxylase (PHBH) from Pseudomonas fluorescens, this amino acid fingerprint sequence is proposed to play a dual function in both FAD and NAD(P)H binding. In PHBH, the novel sequence motif (residues 153-166) includes strand A4 and the N-terminal part of helix H7. The conserved amino acids Asp 159, Gly 160, and Arg 166 are necessary for maintaining the structure. The backbone oxygen of Cys 158 and backbone nitrogens of Gly 160 and Phe 161 interact indirectly with the pyrophosphate moiety of FAD, whereas it is known from mutagenesis studies that the side chain of the moderately conserved His 162 is involved in NADPH binding.     

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.     

New enzymes for old: redesigning the coenzyme and substrate specificities of glutathione reductase.

A set of amino acid side chains that confer specificity for the coenzyme NADPH and the substrate glutathione in the flavoprotein disulphide oxidoreductase, glutathione reductase, has been identified. Systematic replacement of these amino acid residues in the coenzyme-binding site switches the specificity of the enzyme from its natural strong preference for NADPH to a marked preference for NADH. The amino acids replaced all lie in a structural motif within the dinucleotide-binding domain of the protein. Since this domain is a feature common to most dehydrogenases (reductases) that use nicotinamide coenzymes, it may be that the coenzyme specificities of all such enzymes can be manipulated in this way. Similarly, amino acid residues involved in the selective recognition of trypanothione by trypanothione reductase, an enzyme related to glutathione reductase and exclusive to trypanosomatids, were identified. Suitable mutation of the corresponding residues in E. coli glutathione reductase switched its substrate specificity towards trypanothione. A better understanding of the substrate specificity of these enzymes could open up a route to the chemotherapy of trypanosomal infections.     

Coenzyme specificity of human monomeric carbonyl reductase: contribution of Lys-15, Ala-37 and Arg-38

Short-chain dehydrogenases/reductases catalyze the oxidoreduction of alcohol and carbonyl compounds using either NAD or NADPH as coenzyme. Structural analysis suggests that specificity for NADPH is conferred by two highly conserved basic residues in the N-terminal part of the peptide chain, whereas specificity for NAD correlates with the presence of an Asp adjacent to the position of the distal basic residue in NADP-dependent enzymes. We carried out site-directed mutagenesis of the two basic residues: Lys-15 and Arg-38, as well as of Ala-37 of human monomeric carbonyl reductase in order to investigate their contribution to coenzyme binding and specificity. Substitution of Lys-15 or Arg-38 by Gln and, even more pronounced Asp decreased the catalytic efficiency (k(cat)/K(m,NADPH)) by more than three orders of magnitude. Similarly, substitution of Asp for Ala-37 decreased k(cat)/K(m,NADPH) 1000-fold but had little effect on k(cat)/K(m,NADH). The results demonstrate the importance of basic residues at positions 15 and 38 and the absence of an acidic residue at position 37 for NADPH binding and catalysis.     

Multiple and distinct effects of mutations of Tyr122, Glu123, Arg324, and Arg334 involved in interactions between the top part of second and fourth transmembrane helices in sarcoplasmic reticulum Ca2+-ATPase: changes in cytoplasmic domain organization during isometric transition of phosphoenzyme intermediate and subsequent Ca2+ release

We explored, by mutational substitutions and kinetic analysis, possible roles of the four residues involved in the hydrogen-bonding or ionic interactions found in the Ca2+-bound structure of sarcoplasmic reticulum Ca2+-ATPase, Tyr(122)-Arg(324), and Glu(123)-Arg(334) at the top part of second transmembrane helix (M2) connected to the A domain and fourth transmembrane helix (M4) in the P domain. The observed substitution effects indicated that Glu(123), Arg(334), and Tyr(122) contributed to the rapid transition between the Ca2+-unbound and bound states of the unphosphorylated enzyme. Results further showed the more profound inhibitory effects of the substitutions in the M4/P domain (Arg(324) and Arg(334)) upon the isomeric transition of phosphorylated intermediate (EP) (loss of ADP sensitivity) and those in M2/A domain (Tyr(122) and Glu(123)) upon the subsequent processing and hydrolysis of EP. The observed distinct effects suggest that the interactions seen in the Ca2+-bound structure are not functionally important but indicate that Arg(334) with its positive charge and Tyr(122) with its aromatic ring are critically important for the above distinct steps. On the basis of the available structural information, the results strongly suggest that Arg(334) moves downward and forms new interactions with M2 (likely Asn(111)); it thus contributes to the inclination of the M4/P domain toward the M2/A domain, which is crucial for the appropriate gathering between the P domain and the largely rotated A domain to cause the loss of ADP sensitivity. On the other hand, Tyr(122) most likely functions in the subsequent Ca2+-releasing step to produce hydrophobic interactions at the A-P domain interface formed upon their gathering and thus to produce the Ca2+-released form of EP. During the Ca2+-transport cycle, the four residues seem to change interaction partners and thus contribute to the coordinated movements of the cytoplasmic and transmembrane domains.     

Structure and site-directed mutagenesis of a flavoprotein from Escherichia coli that reduces nitrocompounds: alteration of pyridine nucleotide binding by a single amino acid substitution

The crystal structure of a major oxygen-insensitive nitroreductase (NfsA) from Escherichia coli has been solved by the molecular replacement method at 1.7-A resolution. This enzyme is a homodimeric flavoprotein with one FMN cofactor per monomer and catalyzes reduction of nitrocompounds using NADPH. The structure exhibits an alpha + beta-fold, and is comprised of a central domain and an excursion domain. The overall structure of NfsA is similar to the NADPH-dependent flavin reductase of Vibrio harveyi, despite definite difference in the spatial arrangement of residues around the putative substrate-binding site. On the basis of the crystal structure of NfsA and its alignment with the V. harveyi flavin reductase and the NADPH-dependent nitro/flavin reductase of Bacillus subtilis, residues Arg(203) and Arg(208) of the loop region between helices I and J in the vicinity of the catalytic center FMN is predicted as a determinant for NADPH binding. The R203A mutant results in a 33-fold increase in the K(m) value for NADPH indicating that the side chain of Arg(203) plays a key role in binding NADPH possibly to interact with the 2'-phosphate group.     

The crystal structure of the FAD/NADPH-binding domain of flavocytochrome P450 BM3

We report the crystal structure of the FAD/NADPH-binding domain (FAD domain) of the biotechnologically important Bacillus megaterium flavocytochrome P450 BM3, the last domain of the enzyme to be structurally resolved. The structure was solved in both the absence and presence of the ligand NADP(+), identifying important protein interactions with the NADPH 2'-phosphate that helps to dictate specificity for NADPH over NADH, and involving residues Tyr974, Arg966, Lys972 and Ser965. The Trp1046 side chain shields the FAD isoalloxazine ring from NADPH, and motion of this residue is required to enable NADPH-dependent FAD reduction. Multiple binding interactions stabilize the FAD cofactor, including aromatic stacking with the adenine group from the side chains of Tyr860 and Trp854, and several interactions with FAD pyrophosphate oxygens, including bonding to tyrosines 828, 829 and 860. Mutagenesis of C773 and C999 to alanine was required for successful crystallization, with C773A predicted to disfavour intramolecular and intermolecular disulfide bonding. Multiangle laser light scattering analysis showed wild-type FAD domain to be near-exclusively dimeric, with dimer disruption achieved on treatment with the reducing agent dithiothreitol. By contrast, light scattering showed that the C773A/C999A FAD domain was monomeric. The C773A/C999A FAD domain structure confirms that Ala773 is surface exposed and in close proximity to Cys810, with this region of the enzyme's connecting domain (that links the FAD domain to the FMN-binding domain in P450?BM3) located at a crystal contact interface between FAD domains. The FAD domain crystal structure enables molecular modelling of its interactions with its cognate FMN (flavodoxin-like) domain within the BM3 reductase module.     

Effects of flavin-binding motif amino acid mutations in the NADH-cytochrome b5 reductase catalytic domain on protein stability and catalysis

Porcine NADH-cytochrome b5 reductase catalytic domain (Pb5R) has the RXY(T/S)+(T/S) flavin-binding motif that is highly conserved among the structurally related family of flavoprotein reductases. Mutations were introduced that alter the Arg(63), Tyr(65), and Ser(99) residues within this motif. The mutation of Tyr(65) to either alanine or phenylalanine destabilized the protein, produced an accelerated release of FAD in the presence of 1.5 M guanidine hydrochloride, and decreased the k(cat) values of the enzyme. These results indicate that Tyr(65) contributes to the stability of the protein and is important in the electron transfer from NADH to FAD. The mutation of Ser(99) to either alanine or valine, and of Arg(63) to either alanine or glutamine increased both the K(m) values for NADH (K(m)(NADH)) and the dissociation constant for NAD(+) (K(d)(NAD+)). However, the mutation of Ser(99) to threonine and of Arg(63) to lysine had very little effect on the K(m)(NADH) and K(d)(NAD+) values, and resulted in small changes in the absorption and circular dichroism spectra. These results suggest that the hydroxyl group of Ser(99) and the positive charge of Arg(63) contribute to the maintenance of the properties of FAD and to the effective binding of Pb5R to both NADH and NAD(+). In addition, the mutation of Arg(63) to either alanine or glutamine increased the apparent K(m) values for porcine cytochrome b5 (Pb5), while changing Arg(63) to lysine did not. The positive charge of Arg(63) may regulate the electron transfer through the electrostatic interaction with Pb5. These results substantiate the important role of the flavin-binding motif in Pb5R.     

Towards a new interaction enzyme:coenzyme

Ferredoxin-NADP(+) reductase catalyses NADP(+) reduction, being specific for NADP(+)/H. To understand coenzyme specificity determinants and coenzyme specificity reversion, mutations at the NADP(+)/H pyrophosphate binding and of the C-terminal regions have been simultaneously introduced in Anabaena FNR. The T155G/A160T/L263P/Y303S mutant was produced. The mutated enzyme presents similar k(cat) values for NADPH and NADH, around 2.5 times slower than that reported for WT FNR with NADPH. Its K(m) value for NADH decreased 20-fold with regard to WT FNR, whereas the K(m) for NADPH remains similar. The combined effect is a much higher catalytic efficiency for NAD(+)/H, with a minor decrease of that for NADP(+)/H. In the mutated enzyme, the specificity for NADPH versus NADH has been decreased from 67,500 times to only 12 times, being unable to discriminate between both coenzymes. Additionally, giving the role stated for the C-terminal Tyr in FNR, its role in the energetics of the FAD binding has been analysed.     

Removal of a methyl group causes global changes in p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase (PHBH) is a homodimeric flavoprotein monooxygenase that catalyzes the hydroxylation of p-hydroxybenzoate to form 3,4-dihydroxybenzoate. Controlled catalysis is achieved by movement of the flavin and protein between three conformations, in, out, and open [Entsch, B., et al. (2005) Arch. Biochem. Biophys. 433, 297-311]. The open conformation is important for substrate binding and product release, the in conformation for reaction with oxygen and hydroxylation, and the out conformation for the reduction of FAD by NADPH. The open conformation is similar to the structure of Arg220Gln-PHBH in which the backbone peptide loop of residues 43-46, located on the si side of the flavin, is rotated. In this paper, we examine the structure and properties of the Ala45Gly-PHBH mutant enzyme. The crystal structure of the Ala45Gly enzyme is an asymmetric dimer, with one monomer similar (but not identical) to wild-type PHBH, while the other monomer has His72 flipped into solvent and replaced with Glu73 as one of several changes in the structure. The two structures correlate with evidence from kinetic studies for two forms of Ala45Gly-PHBH. One form of the enzyme dominates turnover and hydroxylates, while the other contributes little to turnover and fails to hydroxylate. Ala45Gly-PHBH favors the in conformation over alternative conformations. The effect of this mutation on the structure and function of PHBH illustrates the importance of the si side loop in the conformational state of PHBH and, consequently, the function of the enzyme. This work demonstrates some general principles of how enzymes use conformational movements to allow both access and egress of substrates and product, while restricting access to the solvent at a critical stage in catalysis.     

Structure of alpha-glycerophosphate oxidase from Streptococcus sp.: a template for the mitochondrial alpha-glycerophosphate dehydrogenase

The FAD-dependent alpha-glycerophosphate oxidase (GlpO) from Enterococcus casseliflavus and Streptococcus sp. was originally studied as a soluble flavoprotein oxidase; surprisingly, the GlpO sequence is 30-43% identical to those of the alpha-glycerophosphate dehydrogenases (GlpDs) from mitochondrial and bacterial sources. The structure of a deletion mutant of Streptococcus sp. GlpO (GlpODelta, lacking a 50-residue insert that includes a flexible surface region) has been determined using multiwavelength anomalous dispersion data and refined at 2.3 A resolution. Using the GlpODelta structure as a search model, we have also determined the intact GlpO structure, as refined at 2.4 A resolution. The first two domains of the GlpO fold are most closely related to those of the flavoprotein glycine oxidase, where they function in FAD binding and substrate binding, respectively; the GlpO C-terminal domain consists of two helix bundles and is not closely related to any known structure. The flexible surface region in intact GlpO corresponds to a segment of missing electron density that links the substrate-binding domain to a betabetaalpha element of the FAD-binding domain. In accordance with earlier biochemical studies (stabilizations of the covalent FAD-N5-sulfite adduct and p-quinonoid form of 8-mercapto-FAD), Ile430-N, Thr431-N, and Thr431-OG are hydrogen bonded to FAD-O2alpha in GlpODelta, stabilizing the negative charge in these two modified flavins and facilitating transfer of a hydride to FAD-N5 (from Glp) as well. Active-site overlays with the glycine oxidase-N-acetylglycine and d-amino acid oxidase-d-alanine complexes demonstrate that Arg346 of GlpODelta is structurally equivalent to Arg302 and Arg285, respectively; in both cases, these residues interact directly with the amino acid substrate or inhibitor carboxylate. The structural and functional divergence between GlpO and the bacterial and mitochondrial GlpDs is also discussed.     

Investigating the coenzyme specificity of phenylacetone monooxygenase from Thermobifida fusca

Type I Baeyer–Villiger monooxygenases (BVMOs) strongly prefer NADPH over NADH as an electron donor. In order to elucidate the molecular basis for this coenzyme specificity, we have performed a site-directed mutagenesis study on phenylacetone monooxygenase (PAMO) from Thermobifida fusca. Using sequence alignments of type I BVMOs and crystal structures of PAMO and cyclohexanone monooxygenase in complex with NADP⁺, we identified four residues that could interact with the 2′-phosphate moiety of NADPH in PAMO. The mutagenesis study revealed that the conserved R217 is essential for binding the adenine moiety of the nicotinamide coenzyme while it also contributes to the recognition of the 2′-phosphate moiety of NADPH. The substitution of T218 did not have a strong effect on the coenzyme specificity. The H220N and H220Q mutants exhibited a ~3-fold improvement in the catalytic efficiency with NADH while the catalytic efficiency with NADPH was hardly affected. Mutating K336 did not increase the activity of PAMO with NADH, but it had a significant and beneficial effect on the enantioselectivity of Baeyer–Villiger oxidations and sulfoxidations. In conclusion, our results indicate that the function of NADPH in catalysis cannot be easily replaced by NADH. This finding is in line with the complex catalytic mechanism and the vital role of the coenzyme in BVMOs.     

Structural and functional properties of aldose xylose reductase from the D-xylose-metabolizing yeast Candida tenuis

The primary structure of the aldose xylose reductase from Candida tenuis (CtAR) is shown to be 39% identical to that of human aldose reductase (hAR). The catalytic tetrad of hAR is completely conserved in CtAR (Tyr51, Lys80, Asp46, His113). The amino acid residues involved in binding of NADPH by hAR (D.K. Wilson, et al., Science 257 (1992) 81-84) are 64% identical in CtAR. Like hAR the yeast enzyme is specific for transferring the 4-pro-R hydrogen of the coenzyme. These properties suggest that CtAR is a member of the aldo/keto reductase superfamily. Unlike hAR the enzyme from C. tenuis has a dual coenzyme specificity and shows similar specificity constants for NADPH and NADH. It binds NADP(+) approximately 250 times less tightly than hAR. Typical turnover numbers for aldehyde reduction by CtAR (15-20 s(-1)) are up to 100-fold higher than corresponding values for hAR, probably reflecting an overall faster dissociation of NAD(P)(+) in the reaction catalyzed by the yeast enzyme.     

Studies of the mechanism of phenol hydroxylase: mutants Tyr289Phe, Asp54Asn, and Arg281Met

Three residues in the active site of the flavoprotein phenol hydroxylase (PHHY) were independently changed by site-directed mutagenesis. One of the mutant forms of PHHY, Tyr289Phe, is reduced by NADPH much slower than is the wild-type enzyme, although it has a slightly higher redox potential than the wild-type enzyme. In the structure of the wild-type enzyme, residue Tyr289 is hydrogen-bonded with the FAD when the latter is at the "out" position but has no direct contact with the flavin when it is "in". The oxidative half-reaction of PHHY is not significantly affected by this mutation, contrary to the concept that Tyr289 is a critical residue in the hydroxylation reaction [Enroth, C., Neujahr, H., Schneider, G., and Lindqvist, Y. (1998) Structure 6, 605-617; Ridder, L., Mullholland, A. J., Rietjens, I. M. C. M., and Vervoort, J. (2000) J. Am. Chem. Soc. 122, 8728-8738]. Tyr289 may help stabilize the FAD in the out conformation where it can be reduced by NADPH. For the Asp54Asn mutant form of PHHY, the initial step of the oxidative half-reaction is significantly slower than for the wild-type enzyme. Asp54Asn utilizes less than 20% of the reduced flavin for hydroxylating the substrate with the remainder forming H(2)O(2). Similar changes are observed when Arg281, a residue between Asp54 and the solvent, is mutated to Met. These two residues are suggested to be part of the active site environment the enzyme provides for the flavin cofactor to function optimally in the oxidative half-reaction. In the construction of the mutant forms of PHHY, it was determined that 11 of the previously reported amino acid residues in the sequence of PHHY were incorrect.     

Phe161 and Arg166 variants of p-hydroxybenzoate hydroxylase. Implications for NADPH recognition and structural stability

Phe161 and Arg166 of p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens belong to a newly discovered sequence motif in flavoprotein hydroxylases with a putative dual function in FAD and NADPH binding [1]. To study their role in more detail, Phe161 and Arg166 were selectively changed by site-directed mutagenesis. F161A and F161G are catalytically competent enzymes having a rather poor affinity for NADPH. The catalytic properties of R166K are similar to those of the native enzyme. R166S and R166E show impaired NADPH binding and R166E has lost the ability to bind FAD. The crystal structure of substrate complexed F161A at 2.2 A is indistinguishable from the native enzyme, except for small changes at the site of mutation. The crystal structure of substrate complexed R166S at 2.0 A revealed that Arg166 is important for providing an intimate contact between the FAD binding domain and a long excursion of the substrate binding domain. It is proposed that this interaction is essential for structural stability and for the recognition of the pyrophosphate moiety of NADPH.     

Mechanism of coenzyme binding to human methionine synthase reductase revealed through the crystal structure of the FNR-like module and isothermal titration calorimetry

Human methionine synthase reductase (MSR) is a 78 kDa flavoprotein that regenerates the active form of cobalamin-dependent methionine synthase (MS). MSR contains one FAD and one FMN cofactor per polypeptide and functions in the sequential transfer of reducing equivalents from NADPH to MS via its flavin centers. We report the 1.9 A crystal structure of the NADP+-bound FNR-like module of MSR that spans the NADP(H)-binding domain, the FAD-binding domain, the connecting domain, and part of the extended hinge region, a feature unique to MSR. The overall fold of the protein is similar to that of the corresponding domains of the related diflavin reductase enzymes cytochrome P450 reductase and neuronal nitric oxide synthase (NOS). However, the extended hinge region of MSR, which is positioned between the NADP(H)/FAD- and FMN-binding domains, is in an unexpected orientation with potential implications for the mechanism of electron transfer. Compared with related flavoproteins, there is structural variation in the NADP(H)-binding site, in particular regarding those residues that interact with the 2'-phosphate and the pyrophosphate moiety of the coenzyme. The lack of a conserved binding determinant for the 2'-phosphate does not weaken the coenzyme specificity for NADP(H) over NAD(H), which is within the range expected for the diflavin oxidoreductase family of enzymes. Isothermal titration calorimetry reveals a binding constant of 37 and 2 microM for binding of NADP+ and 2',5'-ADP, respectively, for the ligand-protein complex formed with full-length MSR or the isolated FNR module. These values are consistent with Ki values (36 microM for NADP+ and 1.4 microM for 2',5'-ADP) obtained from steady-state inhibition studies. The relatively weaker binding of NADP+ to MSR compared with other members of the diflavin oxidoreductase family might arise from unique electrostatic repulsive forces near the 5'-pyrophosphate moiety and/or increased hydrophobic stacking between Trp697 and the re face of the FAD isoalloxazine ring. Small structural permutations within the NADP(H)-binding cleft have profound affects on coenzyme binding, which likely retards catalytic turnover of the enzyme in the cell. The biological implications of an attenuated mechanism of MS reactivation by MSR on methionine and folate metabolism are discussed.     

Probing the determinants of coenzyme specificity in Peptostreptococcus asaccharolyticus glutamate dehydrogenase by site-directed mutagenesis

Glutamate dehydrogenase (EC 1.4.1.2-4) from Peptostreptococcus asaccharolyticus has a strong preference for NADH over NADPH as a coenzyme, over 1000-fold in terms of kcat/Km values. Sequence alignments across the wider family of NAD(P)-dependent dehydrogenases might suggest that this preference is mainly due to a negatively charged glutamate at position 243 (E243) in the adenine ribose-binding pocket. We have examined the possibility of altering coenzyme specificity of the Peptostreptococcus enzyme, and, more specifically, the role of residue 243 and neighbouring residues in coenzyme binding, by introducing a range of point mutations. Glutamate dehydrogenases are unusual among dehydrogenases in that NADPH-specific forms usually have aspartate at this position. However, replacement of E243 with aspartate led to only a nine-fold relaxation of the strong discrimination against NADPH. By contrast, replacement with a more positively charged lysine or arginine, as found in NADPH-dependent members of other dehydrogenase families, allows a more than 1000-fold shift toward NADPH, resulting in enzymes equally efficient with NADH or NADPH. Smaller shifts in the same direction were also observed in enzymes where a neighboring tryptophan, W244, was replaced by a smaller alanine (approximately six-fold) or Asp245 was changed to lysine (32-fold). Coenzyme binding studies confirm that the mutations result in the expected major changes in relative affinities for NADH and NADPH, and pH studies indicate that improved affinity for the extra phosphate of NADPH is the predominant reason for the increased catalytic efficiency with this coenzyme. The marked difference between the results of replacing E243 with aspartate and with positive residues implies that the mode of NADPH binding in naturally occurring NADPH-dependent glutamate dehydrogenases differs from that adopted in E243K or E243D and in other dehydrogenases.     

Flavoenzymes catalyzing oxidative aromatic ring-cleavage reactions

2-Methyl-3-hydroxypyridine-5-carboxylic acid (MHPC) oxygenase (MHPCO) and 5-pyridoxic acid oxygenase are flavoenzymes catalyzing an aromatic hydroxylation and a ring-cleavage reaction. Both enzymes are involved in biodegradation of vitamin B6 in bacteria. Oxygen-tracer experiments have shown that the enzymes are monooxygnases since only one atom of molecular oxygen is incorporated into the products. Kinetics of MHPCO has shown that the enzyme is similar to single-component flavoprotein hydroxylases in that the binding of MHPC is required prior to the flavin reduction by NADH, and C4a-hydroperoxy-FAD and C4a-hydroxy-FAD are found as intermediates. Investigation on the protonation status of the substrate upon binding to the enzyme has shown that only the tri-ionic form of MHPC is bound at the MHPCO active site. Using a series of FAD analogues with substituents at the 8-position of the isoalloxazine ring, the oxygenation of MHPC by the C4a-hydroperoxy-FAD was shown to occur via an electrophilic aromatic substitution mechanism. Recently, the X-ray structures of MHPCO and a complex of MHPC-MHPCO at 2.1 Å have been reported and show the presence of nine water molecules in the enzyme active site. Based on structural data, a few residues, Tyr82, Tyr223, Arg181, were suggested to be important for catalysis of MHPCO.     

Structures of bovine glutamate dehydrogenase complexes elucidate the mechanism of purine regulation

Glutamate dehydrogenase is found in all organisms and catalyses the oxidative deamination of l-glutamate to 2-oxoglutarate. However, only animal GDH utilizes both NAD(H) or NADP(H) with comparable efficacy and exhibits a complex pattern of allosteric inhibition by a wide variety of small molecules. The major allosteric inhibitors are GTP and NADH and the two main allosteric activators are ADP and NAD(+). The structures presented here have refined and modified the previous structural model of allosteric regulation inferred from the original boGDH.NADH.GLU.GTP complex. The boGDH.NAD(+).alpha-KG complex structure clearly demonstrates that the second coenzyme-binding site lies directly under the "pivot helix" of the NAD(+) binding domain. In this complex, phosphates are observed to occupy the inhibitory GTP site and may be responsible for the previously observed structural stabilization by polyanions. The boGDH.NADPH.GLU.GTP complex shows the location of the additional phosphate on the active site coenzyme molecule and the GTP molecule bound to the GTP inhibitory site. As expected, since NADPH does not bind well to the second coenzyme site, no evidence of a bound molecule is observed at the second coenzyme site under the pivot helix. Therefore, these results suggest that the inhibitory GTP site is as previously identified. However, ADP, NAD(+), and NADH all bind under the pivot helix, but a second GTP molecule does not. Kinetic analysis of a hyperinsulinism/hyperammonemia mutant strongly suggests that ATP can inhibit the reaction by binding to the GTP site. Finally, the fact that NADH, NAD(+), and ADP all bind to the same site requires a re-analysis of the previous models for NADH inhibition.     

The B' helix determines cytochrome P450nor specificity for the electron donors NADH and NADPH

Nitric oxide reductase (Nor) cytochrome P450nor (P450nor) is unique because it is catalytically self-sufficient, receiving electrons directly from NADH or NADPH. However, little is known about the direct binding of NADH to cytochrome. Here, we report that oxidized pyridine nucleotides (NAD(+) and NADP(+)) and an analogue induce a spectral perturbation in bound heme when mixed with P450nor. The P450nor isoforms are classified according to electron donor specificity for NADH or NADPH. One type (Fnor, a P450nor of Fusarium oxysporum) utilizes only NADH. We found that NAD(+) induced a type I spectral change in Fnor, whereas NADP(+) induced a reverse type I spectral change, although the K(d) values for both were comparable. In contrast, NADP(+) as well as NAD(+) caused a type I spectral change in Tnor, a P450nor isozyme from Trichosporon cutaneum that utilizes both NADH and NADPH as electron donors. The B' helix region of Tnor ((73)SAGGKAAA(80)) contains some Ala and Gly residues, whereas the sequence is replaced at a few sites with more bulky amino acid residues in Fnor ((73)SASGKQAA(80)). A single mutation (S75G) significantly improved the NADPH- dependent Nor activity of Fnor, and the overall activity was accelerated via the NADPH-enhanced reduction step. These results showed that pyridine nucleotide cofactors can bind P450nor and that only a few residues in the B' helix region determine cofactor specificity. We further showed that a poor electron donor (NADPH) could also bind Fnor, but an appropriate configuration for electron transfer is blocked by steric hindrance mainly by Ser(75) against the 2'-phosphate moiety. The present results along with previous observations together revealed a novel motif for cofactor binding.