D88A mutant of cytochrome P450nor provides kinetic evidence for direct complex formation with electron donor NADH.

The haem-distal pocket of nitric oxide reductase cytochrome P450 contains many Arg and Lys residues that are clustered to form a putative access channel for NADH. Asp88 is the sole negatively charged amino acid in this positive charge cluster, and thus it would be interesting to know its functional role. Here we found the intriguing phenomenon that mutation at this site of P450nor (D88A or D88V) considerably decreased the overall nitric oxide reductase activity without blocking the reducing half reaction in which the ferric enzyme-NO complex is reduced with NADH to yield a specific intermediate (I). The results indicate that the catalytic turnover subsequent to the I formation was blocked by such mutation. This property of the mutants made it possible to perform kinetic analysis of the reduction step, which is impossible with the wild-type P450nor. These results are the first kinetic evidence for direct complex formation between P450nor and an electron donor (NADH or NADPH). The kinetic analysis also showed that the inhibition by chloride ions (Cl(-)) is competitive with respect to NAD(P)H, which highlights the importance of the binding site for Cl(-) (the anion hole) in the interaction with NAD(P)H. We also characterized another mutant (D393A) of P450nor. The results demonstrated that both Asp residues play important roles in the interaction with NADH, whereas the role of Asp88 is unique in that it must be essential for the release of NAD(+) rather than binding to NADH.     

Interaction of heme nonapeptide derived from cytochrome c with microsomal reductases

The interaction of heme nonapeptide (a proteolytic product of cytochrome c) with purified NADH:cytochrome b5 (EC 1.6.2.2) and NADPH:cytochrome P-450 (EC 1.6.2.4) reductases was investigated. In the presence of heme nonapeptide, NADH or NADPH were enzymatically oxidized to NAD+ and NADP+, respectively. NAD(P)H consumption was coupled to oxygen uptake in both enzyme reactions. In the presence of carbon monoxide the spectrum of a carboxyheme complex was observed during NAD(P)H oxidation, indicating the existence of a transient ferroheme peptide. NAD(P)H oxidation could be partially inhibited by cyanide, superoxide dismutase and catalase. Superoxide and peroxide ions (generated by enzymic xanthine oxidation) only oxidized NAD(P)H in the presence of heme nonapeptide. Oxidation of NAD(P)H was more rapid with O2- than O2-2. We suggest that a ferroheme-O2 and various heme-oxy radical complexes (mainly ferroheme-O-2 complex) play a crucial role in NAD(P)H oxidation.     

Structural evidence for direct hydride transfer from NADH to cytochrome P450nor

Nitric oxide reductase cytochrome P450nor catalyzes an unusual reaction, direct electron transfer from NAD(P)H to bound heme. Here, we succeeded in determining the crystal structure of P450nor in a complex with an NADH analogue, nicotinic acid adenine dinucleotide, which provides conclusive evidence for the mechanism of the unprecedented electron transfer. Comparison of the structure with those of dinucleotide-free forms revealed a global conformational change accompanied by intriguing local movements caused by the binding of the pyridine nucleotide. Arg64 and Arg174 fix the pyrophosphate moiety upon the dinucleotide binding. Stereo-selective hydride transfer from NADH to NO-bound heme was suggested from the structure, the nicotinic acid ring being fixed near the heme by the conserved Thr residue in the I-helix and the upward-shifted propionate side-chain of the heme. A proton channel near the NADH channel is formed upon the dinucleotide binding, which should direct continuous transfer of the hydride and proton. A salt-bridge network (Glu71-Arg64-Asp88) was shown to be crucial for a high catalytic turnover.     

Involvement of a Glu71–Arg64 Couple in the Access Channel for NADH in Cytochrome P450nor

Putative access channel for NADH in the heme-distal pocket of cytochrome P450nor (P450nor) comprises many charged amino acid residues. Characterization of the E71A mutant protein of P450nor highlights the existence of a unique mechanism for binding NADH that depends on the salt bridge network between Glu71, Arg64 and Asp88.     

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.     

Modulation of redox potential and alteration in reactivity via the peroxide shunt pathway by mutation of cytochrome P450 around the proximal heme ligand

In the thermophilic cytochrome P450 from the thermoacidophilic crenarchaeon Sulfolobus tokodaii strain 7 (P450st), a phenylalanine residue at position 310 and an alanine residue at position 320 are located close to the heme thiolate ligand, Cys317. Single site-directed mutants F310A and A320Q and double mutant F310A/A320Q have been constructed. All mutant enzymes as well as wild-type (WT) P450st were expressed at high levels. The substitution of F310 with Ala and of A320 with Gln induced shifts in redox potential and blue shifts in Soret absorption of ferrous-CO forms, while spectral characterization showed that in the resting state, the mutants almost retained the structural integrity of the active site. The redox potential of the heme varied as follows: -481 mV (WT), -477 mV (A320Q), -453 mV (F310A), and -450 mV (F310A/A320Q). The trend in the Soret band of the ferrous-CO form was as follows: 450 nm (WT) < 449 nm (A320Q) < 446 nm (F310A) < 444 nm (F310A/A320Q). These results established that the reduction potential and electron density on the heme iron are modulated by the Phe310 and Ala320 residues in P450st. The electron density on the heme decreases in the following order: WT > A320Q > F310A > F310A/A320Q. The electron density on the heme iron infers an essential role in P450 activity. The decrease in electron density interferes with the formation of a high-valent oxo-ferryl species called Compound I. However, steady-state turnover rates of styrene epoxidation with H2O2 show the following trend: WT approximately equal to A320Q < F310A approximately equal to F310A/A320Q. The shunt pathway which can provide the two electrons and oxygen required for a P450 reaction instead of NAD(P)H and dioxygen can rule out the first and second heme reduction in the catalytic process. Because the electron density on the heme iron might be deeply involved in the k cat values in this system, the intermediate Compound 0 which is the precursor species of Compound I mainly appears to participate dominantly in epoxidation with H2O2.     

A positively charged cluster formed in the heme-distal pocket of cytochrome P450nor is essential for interaction with NADH

Arg and Lys residues are concentrated on the distal side of cytochrome P450nor (P450nor) to form a positively charged cluster facing from the outside to the inside of the distal heme pocket. We constructed mutant proteins in which the Arg and Lys residues were replaced with Glu, Gln, or Ala. The results showed that this cluster plays crucial roles in NADH interaction. We also showed that some anions such as bromide (Br(-)) perturbed the heme environment along with the reduction step in P450nor-catalyzed reactions, which was similar to the effects caused by the mutations. We determined by x-ray crystallography that a Br(-), termed an anion hole, occupies a key region neighboring heme, which is the terminus of the positively charged cluster and the terminus of the hydrogen bond network that acts as a proton delivery system. A comparison of the predicted mechanisms between the perturbations caused by Br(-) and the mutations suggested that Arg(174) and Arg(64) play a crucial role in binding NADH to the protein. These results indicated that the positively charged cluster is the unique structure of P450nor that responds to direct interaction with NADH.     

Involvement of a Glu71-Arg64 couple in the access channel for NADH in cytochrome p450nor

Putative access channel for NADH in the heme-distal pocket of cytochrome p450nor (p450nor) comprises many charged amino acid residues. Characterization of the E71A mutant protein of p450nor highlights the existence of a unique mechanism for binding NADH that depends on the salt bridge network between Glu71, Arg64 and Asp88.     

Role of protein and substrate dynamics in catalysis by Pseudomonas putida cytochrome P450cam

The role of protein structural flexibility and substrate dynamics in catalysis by cytochrome P450 enzymes is an area of current interest. We have addressed these in cytochrome P450(cam) (P450(cam)) and its Y96A mutant with camphor and its related compounds using fluorescence spectroscopy. Previously [Prasad et al. (2000) FEBS Lett. 477, 157-160], we provided experimental support to dynamic fluctuations in P450(cam), and substrate access into the active site region via the channel next to the flexible F-G helix-loop-helix segment. In the investigation described here, we show that the dynamic fluctuations in the enzyme are substrate dependent as reflected by tryptophan fluorescence quenching experiments. The orientation of tryptophan relative to heme (kappa(2)) for W42 obtained from time-resolved tryptophan fluorescence measurements show variation with type of substrate bound to P450(cam) suggesting regions distant from heme-binding site are affected by physicochemical and steric characteristics/protein-substrate interactions of P450(cam) active site. We monitored substrate dynamics in the active site region of P450(cam) by time-resolved substrate anisotropy measurements. The anisotropy decay of substrates bound to P450(cam) indicate that mobility of substrates is modulated by physicochemical and steric characteristics/protein-substrate interactions of local active site structure, and provides an understanding of factors controlling observed hydroxylated products for substrate bound P450(cam) complexes. The present study shows that P450(cam) local and peripheral structural flexibility and heterogeneity along with substrate mobility play an important role in regulating substrate binding orientation during catalysis and accommodating diverse range of substrates within P450(cam) heme pocket.     

Mutation effects of a conserved threonine (Thr243) of cytochrome P450nor on its structure and function

Threonine 243 of cytochrome P450nor (fungal nitric oxide reductase) corresponds to the 'conserved' Thr in the long I helix of monooxygenase cytochrome P450s. In P450nor, the replacement of Thr243 with Asn, Ala or Val makes the enzymatic activity dramatically reduce. In order to understand the roles of Thr243 in the reduction reaction of NO by P450nor, the crystal structures of three Thr243 mutants (Thr243-->Asn, Thr243-->Val, Thr243-->Ala) of P450nor were determined at a 1.4-A resolution and at cryogenic temperature. However, the hydrogen-bonding pattern in the heme pocket of these mutants is essentially similar for that of the WT enzyme. This suggests that the determination of the structure of the NADH complex of P450nor is required, in order to evaluate the role of Thr243 in its enzymatic reaction. We attempted to crystallize the NADH complex under several conditions, but have not yet been successful.     

Thermophilic cytochrome P450 (CYP119) from Sulfolobus solfataricus: high resolution structure and functional properties

Crystal structures of a thermostable cytochrome P450 (CYP119) and a site-directed mutant, (Phe24Leu), from the acidothermophilic archaea Sulfolobus solfataricus were determined at 1.5-2.0 A resolution. We identify important crystallographic waters in the ferric heme pocket, observe protein conformational changes upon inhibitor binding, and detect a unique distribution of surface charge not found in other P450s. An analysis of factors contributing to thermostability of CYP119 of these high resolution structures shows an apparent increase in clustering of aromatic residues and optimum stacking. The contribution of aromatic stacking was investigated further with the mutant crystal structure and differential scanning calorimetry.     

Alteration of P450 distal pocket solvent leads to impaired proton delivery and changes in heme geometry

Distal pocket water molecules have been widely implicated in the delivery of protons required in O-O bond heterolysis in the P450 reaction cycle. Targeted dehydration of the cytochrome P450cam (CYP101) distal pocket through mutagenesis of a distal pocket glycine to either valine or threonine results in the alteration of spin state equilibria, and has dramatic consequences on the catalytic rate, coupling efficiency, and kinetic solvent isotope effect parameters, highlighting an important role of the active-site hydration level on P450 catalysis. Cryoradiolysis of the mutant CYP101 oxyferrous complexes further indicates a specific perturbation of proton-transfer events required for the transformation of ferric-peroxo to ferric-hydroperoxo states. Finally, crystallography of the 248Val and 248Thr mutants in both the ferric camphor bound resting state and ferric-cyano adducts shows both the alteration of hydrogen-bonding networks and the alteration of heme geometry parameters. Taken together, these results indicate that the distal pocket microenvironment governs the transformation of reactive heme-oxygen intermediates in P450 cytochromes.     

Functional interpretation and structural insights of Arabidopsis lyrata cytochrome P450 CYP71A13 involved in auxin synthesis

Cytochrome P450 CYP71A13 of Arabidopsis lyrata is a heme protein involved in biosynthesis of indole-3-acetonitrile which leads to the formation of indolyl-3-acetic acid. It catalyzes a unique reaction: formation of a carbon-nitrogen triple bond and dehydration of indolyl-3-acetaldoxime. Homology model of this 57 kDa polypeptide revealed that the heme existed between H-helix and J- helix in the hydrophobic pocket, although both helixes are involved in catalytic activity, where Gly305 and Thr308, 311 of H- helix were involved in its stabilization. The substrate indole-3-acetaldoxime was tightly fitted into the substrate pocket with the aromatic ring being surrounded by amino acid residues creating a hydrophobic environment. The smaller size of the substrate binding pocket in cytochrome P450 CYP71A13 was due to the bulkiness of the two amino acid residues Phe182 and Trp315 pointing into the substrate binding cavity. The apparent role of the heme in cytochrome P450 CYP71A13 was to tether the substrate in the catalysis by indole-3-acetaldoxime dehydratase. Since the crystal structure of cytochrome P450 CYP71A13 has not yet been solved, the modeled structure revealed mechanism of substrate recognition and catalysis.     

Phenylalanine 393 exerts thermodynamic control over the heme of flavocytochrome P450 BM3.

Site-directed mutants of the phylogenetically conserved phenylalanine residue F393 were constructed in flavocytochrome P450 BM3 from Bacillus megaterium. The high degree of conservation of this residue in the P450 superfamily and its proximity to the heme (and its ligand Cys400) infers an essential role in P450 activity. Extensive kinetic and thermodynamic characterization of mutant enzymes F393A, F393H, and F393Y highlighted significant differences from wild-type P450 BM3. All enzymes expressed to high levels and contained their full complement of heme. While the reduction and subsequent treatment of the mutant P450s with carbon monoxide led to the formation of the characteristic P450 spectra in all cases, the absolute position of the Soret absorption varied across the series WT/F393Y (449 nm), F393H (445 nm), and F393A (444 nm). Steady-state turnover rates with both laurate and arachidonate showed the trend WT > F393Y > F393H > F393A. Conversely, the trend in the pre-steady-state flavin-to-heme electron transfer was the reverse of the steady-state scenario, with rates varying F393A > F393H > F393Y approximately wild-type. These data are consistent with the more positive substrate-free [-312 mV (F393A), -332 mV (F393H)] and substrate-bound [-151 mV (F393A), -176 mV (F393H)] reduction potentials of F393A and F393H heme domains, favoring the stabilization of the ferrous-form in the mutant P450s relative to wild-type. Elevation of the heme iron reduction potential in the F393A and F393H mutants facilitates faster electron transfer to the heme. This results in a decrease in the driving force for oxygen reduction by the ferrous heme iron, so explaining lower overall turnover of the mutant P450s. We postulate that the nature of the residue at position 393 is important in controlling the delicate equilibrium observed in P450s, whereby a tradeoff is established between the rate of heme reduction and the rate at which the ferrous heme can bind and, subsequently, reduce molecular oxygen.     

Proximal cysteine residue is essential for the enzymatic activities of cytochrome P450cam.

To investigate the functional and structural roles of the proximal thiolate ligand in cytochrome P450cam, we prepared the C357H mutant of the enzyme in which the axial cysteine residue (Cys357) was replaced with a histidine residue. We obtained the unstable C357H mutant by developing a new preparation procedure involving in vitro folding of P450cam from the inclusion bodies. The C357H mutant in the ferrous-CO form exhibited the Soret peak at 420 nm and the Fe-CO stretching line at 498 cm-1, indicating a neutral histidine residue as the axial ligand. However, another internal ligand is coordinated to the heme iron as the sixth ligand in the ferric and ferrous forms of the C357H mutant, suggesting the collapse of the substrate-binding site. The C357H mutant showed no catalytic activity for camphor hydroxylation and the reduced heterolytic/homolytic ratio of the O-O bond scission in the reaction with cumene hydroperoxide. The present observations indicate that the thiolate coordination in P450cam is important for the construction of the heme pocket and the heterolysis of the O-O bond.     

Trp(359) regulates flavin thermodynamics and coenzyme selectivity in Mycobacterium tuberculosis FprA

Mtb (Mycobacterium tuberculosis) FprA (flavoprotein reductase A) is an NAD(P)H-dependent FAD-binding reductase that is structurally related to mammalian adrenodoxin reductase, and which supports the catalytic function of Mtb cytochrome P450s. Trp(359), proximal to the FAD, was investigated in light of its potential role in controlling coenzyme interactions, as observed for similarly located aromatic residues in diflavin reductases. Phylogenetic analysis indicated that a tryptophan residue corresponding to Trp(359) is conserved across FprA-type enzymes and in adrenodoxin reductases. W359A/H mutants of Mtb FprA were generated, expressed and the proteins characterized to define the role of Trp(359). W359A/H mutants exhibited perturbed UV-visible absorption/fluorescence properties. The FAD semiquinone formed in wild-type NADPH-reduced FprA was destabilized in the W359A/H mutants, which also had more positive FAD midpoint reduction potentials (-168/-181 mV respectively, versus the standard hydrogen electrode, compared with -230 mV for wild-type FprA). The W359A/H mutants had lower ferricyanide reductase k(cat) and NAD(P)H K(m) values, but this led to improvements in catalytic efficiency (k(cat)/K(m)) with NADH as reducing coenzyme (9.6/18.8 muM(-1).min(-1) respectively, compared with 5.7 muM(-1).min(-1) for wild-type FprA). Stopped-flow spectroscopy revealed NAD(P)H-dependent FAD reduction as rate-limiting in steady-state catalysis, and to be retarded in mutants (e.g. limiting rate constants for NADH-dependent FAD reduction were 25.4 s(-1) for wild-type FprA and 4.8 s(-1)/13.4 s(-1) for W359A/H mutants). Diminished mutant FAD content (particularly in W359H FprA) highlighted the importance of Trp(359) for flavin stability. The results demonstrate that the conserved Trp(359) is critical in regulating FprA FAD binding, thermodynamic properties, catalytic efficiency and coenzyme selectivity.     

Site-Directed Mutagenesis of Cytochrome P450scc (CYP11A1). Effect of Lysine Residue Substitution on Its Structural and Functional Properties

Our previous chemical modification and cross-linking studies identified some positively charged amino acid residues of cytochrome P450scc that may be important for its interaction with adrenodoxin and for its functional activity. The present study was undertaken to further evaluate the role of these residues in the interaction of cytochrome P450scc with adrenodoxin using site-directed mutagenesis. Six cytochrome P450scc mutants containing replacements of the surface-exposed positively charged residues (Lys103Gln, Lys110Gln, Lys145Gln, Lys394Gln, Lys403Gln, and Lys405Gln) were expressed in E. coli cells, purified as a substrate-bound high-spin form, and characterized as compared to the wild-type protein. The replacement of the surface Lys residues does not dramatically change the protein folding or the heme pocket environment as judged from limited proteolysis and spectral studies of the cytochrome P450 mutants. The replacement of Lys in the N-terminal sequence of P450scc does not dramatically affect the activity of the heme protein. However, mutant Lys405Gln revealed rather dramatic loss of cholesterol side-chain cleavage activity, efficiency of enzymatic reduction in a reconstituted system, and apparent dissociation constant for adrenodoxin binding. The present results, together with previous findings, suggest that the changes in functional activity of mutant Lys405Gln may reflect the direct participation of this amino acid residue in the electrostatic interaction of cytochrome P450scc with its physiological partner, adrenodoxin.     

The P450cam G248E mutant covalently binds its prosthetic heme group

Previous studies on mammalian peroxidases and cytochrome P450 family 4 enzymes have shown that a carboxylic group positioned close to a methyl group of the prosthetic heme is required for the formation of a covalent link between a protein carboxylic acid side chain and the heme. To determine whether there are additional requirements for covalent bond formation in the P450 enzymes, a glutamic acid or an aspartic acid has been introduced into P450(cam) close to the heme 5-methyl group. Spectroscopic and kinetic studies of the resulting G248E and G248D mutants suggest that the carboxylate group coordinates with the heme iron atom, as reported for a comparable P450(BM3) mutant [Girvan, H. M., Marshall, K. R., Lawson, R. J., Leys, D., Joyce, M. G., Clarkson, J., Smith, W. E., Cheesman, M. R., and Munro, A. W. (2004) J. Biol. Chem. 279, 23274-23286]. The two P450(cam) mutants have low catalytic activity, but in contrast to the P450(BM3) mutant, incubation of the G248E (but not G248D) mutant with camphor, putidaredoxin, putidaredoxin reductase, and NADH results in partial covalent binding of the heme to the protein. No covalent attachment is observed in the absence of camphor or any of the other reaction components. Pronase digestion of the G248E P450(cam) mutant after covalent attachment of the heme releases 5-hydroxyheme, establishing that the heme is covalently attached through its 5-methyl group as predicted by in silico modeling. The results establish that a properly positioned carboxyl group is the sole requirement for autocatalytic formation of a heme-protein link in P450 enzymes, but also show that efficient covalent binding requires placement of the carboxyl close to the methyl but in a manner that prevents strong coordination to the iron atom.     

Changing the heme ligation in flavocytochrome b 2: substitution of histidine-66 by cysteine

Substitution by cysteine of one of the heme iron axial ligands (His66) of flavocytochrome b2 (L-lactate:cytochrome c oxidoreductase from Saccharomyces cerevisiae) has resulted in an enzyme (H66C-b2) which remains a competent L-lactate dehydrogenase (kcat 272+/-6 s(-1), L-lactate KM 0.60+/-0.06 mM, 25 degrees C, I 0.10, Tris-HCl, pH 7.5) but which has no cytochrome c reductase activity. As a result of the mutation, the reduction potential of the heme was found to be -265+5 mV, over 240 mV more negative than that of the wild-type enzyme, and therefore unable to be reduced by L-lactate. Surface-enhanced resonance Raman spectroscopy indicates similarities between the heme of H66C-b2 and those of cytochromes P450, with a nu4 band at 1,345 cm(-1) which is indicative of cysteine heme-iron ligation. In addition, EPR spectroscopy yields g-values at 2.33, 2.22 and 1.94, typical of low-spin ferric cytochromes P450, optical spectra show features between 600 and 900 nm which are characteristic of sulfur coordination of the heme iron, and MCD spectroscopy shows a blue-shifted NIR CT band relative to the wild-type, implying that the H66C-b2 heme is P450-like. Interestingly, EPR evidence also suggests that the second histidine heme-iron ligand (His43) is displaced in the mutant enzyme.     

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).