Identification of N-terminal regions of wheat leaf ferredoxin NADP+ oxidoreductase important for interactions with ferredoxin.

Wheat leaves contain two isoproteins of the photosynthetic ferredoxin:NADP(+) reductase (pFNRI and pFNRII). Truncated forms of both enzymes have been detected in vivo, but only pFNRII displays N-terminal length-dependent changes in activity. To investigate the impact of N-terminal truncation on interaction with ferredoxin (Fd), recombinant pFNRII proteins, differing by deletions of up to 25 amino acids, were generated. During purification of the isoproteins found in vivo, the longer forms of pFNRII bound more strongly to a Fd affinity column than did the shorter forms, pFNRII(ISKK) and pFNRII[N-2](KKQD). Further truncation of the N-termini resulted in a pFNRII protein which failed to bind to a Fd column. Similar k(cat) values (104-140 s(-1)) for cytochrome c reduction were measured for all but the most truncated pFNRII[N-5](DEGV), which had a k(cat) of 38 s(-1). Stopped-flow kinetic studies, examining the impact of truncation on electron flow between mutant pFNRII proteins and Fd, showed there was a variation in k(obs) from 76 to 265 s(-1) dependent on the pFNRII partner. To analyze the sites which contribute to Fd binding at the pFNRII N-terminal, three mutants were generated, in which a single or double lysine residue was changed to glutamine within the in vivo N-terminal truncation region. The mutations affected binding of pFNRII to the Fd column. Based on activity measurements, the double lysine residue change resulted in a pFNRII enzyme with decreased Fd affinity. The results highlight the importance of this flexible N-terminal region of the pFNRII protein in binding the Fd partner.

Flavocytochrome P450 BM3 and the origin of CYP102 fusion species.

Flavocytochrome P450 (cytochrome P450) BM3 is an intensively studied model system within the P450 enzyme superfamily, and is a natural fusion of a P450 to its P450 reductase redox partner. The fusion arrangement enables efficient electron transfer within the enzyme and a catalytic efficiency that cannot be matched in P450 systems from higher organisms. P450 BM3's potential for industrially relevant chemical transformations is now recognized, and variants with biotechnological applications have been constructed. Simultaneously, structural and mechanistic studies continue to reveal the intricate mechanistic details of this enzyme, including its dimeric organization and the relevance of this quaternary structure to catalysis. Homologues of BM3 have been found in several bacteria and fungi, indicating important physiological functions in these microbes and enabling first insights into evolution of the enzyme family. This short paper deals with recent developments in our understanding of structure, function, evolution and biotechnological applications of this important P450 system.

CYP121, CYP51 and associated redox systems in Mycobacterium tuberculosis: towards deconvoluting enzymology of P450 systems in a human pathogen.

An extraordinary array of P450 (cytochrome P450) enzymes are encoded on the genome of the human pathogen Mycobacterium tuberculosis (Mtb) and in related mycobacteria and actinobacteria. These include the first characterized sterol 14alpha-demethylase P450 (CYP51), a known target for azole and triazole drugs in yeasts and fungi. To date, only two Mtb P450s have been characterized in detail: CYP51 and CYP121. The CYP121 P450 shows structural relationships with P450 enzymes involved in synthesis of polyketide antibiotics. Both P450s exhibit tight binding to a range of azole drugs (e.g. clotrimazole and fluconazole) and the same drugs also have potent effects on growth of mycobacteria (but not of e.g. Escherichia coli). Atomic structures are available for both Mtb CYP51 and CYP121, revealing modes of azole binding and intriguing mechanistic and structural aspects. This paper reviews our current knowledge of these and the other P450 systems in Mtb including recent data relating to the reversible conversion of the CYP51 enzyme between P450 (thiolate-co-ordinated) and P420 (thiol-co-ordinated) species on reduction of the haem iron in the absence of a P450 substrate. The accessory flavoprotein and iron-sulfur proteins required to drive P450 catalysis are also discussed, providing an overview of the current state of knowledge of Mtb P450 redox systems.

Flavocytochrome P450 BM3: an update on structure and mechanism of a biotechnologically important enzyme.

Since its discovery in the 1980s, the fatty acid hydroxylase flavocytochrome P450 (cytochrome P450) BM3 (CYP102A1) from Bacillus megaterium has been adopted as a paradigm for the understanding of structure and mechanism in the P450 superfamily of enzymes. P450 BM3 was the first P450 discovered as a fusion to its redox partner--a eukaryotic-like diflavin reductase. This fact fuelled the interest in soluble P450 BM3 as a model for the mammalian hepatic P450 enzymes, which operate a similar electron transport chain using separate, membrane-embedded P450 and reductase enzymes. Structures of each of the component domains of P450 BM3 have now been resolved and detailed protein engineering and molecular enzymology studies have established roles for several amino acids in, e.g. substrate binding, coenzyme selectivity and catalysis. The potential of P450 BM3 for biotechnological applications has also been recognized, with variants capable of industrially important transformations generated using rational mutagenesis and forced evolution techniques. This paper focuses on recent developments in our understanding of structure and mechanism of this important enzyme and highlights important problems still to be resolved.

Flavoenzyme catalysed oxidation of amines: roles for flavin and protein-based radicals.

Amines are a carbon source for the growth of a number of bacterial species and they also play key roles in neurotransmission, cell growth and differentiation, and neoplastic cell proliferation. Enzymes have evolved to catalyse these reactions and these oxidoreductases can be grouped into the flavoprotein and quinoprotein families. The mechanism of amine oxidation catalysed by the quinoprotein amine oxidases is understood reasonably well and occurs through the formation of enzyme-substrate covalent adducts with TPQ (topaquinone), TTQ (tryptophan tryptophylquinone), CTQ (cysteine tryptophylquinone) and LTQ (lysine tyrosyl quinone) redox centres. Oxidation of amines by flavoenzymes is less well understood. The role of protein-based radicals and flavin semiquinone radicals in the oxidation of amines is discussed.

Biodiversity of cytochrome P450 redox systems.

P450s (cytochrome P450 mono-oxygenases) are a superfamily of haem-containing mono-oxygenase enzymes that participate in a wide range of biochemical pathways in different organisms from all of the domains of life. To facilitate their activity, P450s require sequential delivery of two electrons passed from one or more redox partner enzymes. Although the P450 enzymes themselves show remarkable similarity in overall structure, it is increasingly apparent that there is enormous diversity in the redox partner systems that drive the P450 enzymes. This paper examines some of the recent advances in our understanding of the biodiversity of the P450 redox apparatus, with a particular emphasis on the redox systems in the pathogen Mycobacterium tuberculosis.

Resonance Raman scattering of cytochrome P450 BM3 and effect of imidazole inhibitors.

Resonance Raman scattering from cytochrome P450 BM3 is obtained with a Raman microprobe using 406-nm excitation with an accumulation time of a few seconds. The small sample size and rapid measurement time make the routine characterization of P450 systems by resonance Raman spectroscopy easier. Addition of imidazole and imidazole derivatives as inhibitors causes the appearance of additional peaks due to vinyl modes, increases the relative intensity of symmetric modes that would be A(1g) in D(4h) symmetry, and causes a large drop in the intensity of nu(11). This information indicates that the ligation of imidazoles to the heme iron causes the alignment of the vinyl modes with the plane of the heme ring and reduces the out of plane distortion of the ring. The effect of both inhibitors is similar but there is a subtle difference in the extent of the reduction in the intensity of nu(11), which suggests that steric effects within the pocket are having some effect.

The TB structural genomics consortium: a resource for Mycobacterium tuberculosis biology.

The TB Structural Genomics Consortium is an organization devoted to encouraging, coordinating, and facilitating the determination and analysis of structures of proteins from Mycobacterium tuberculosis. The Consortium members hope to work together with other M. tuberculosis researchers to identify M. tuberculosis proteins for which structural information could provide important biological information, to analyze and interpret structures of M. tuberculosis proteins, and to work collaboratively to test ideas about M. tuberculosis protein function that are suggested by structure or related to structural information. This review describes the TB Structural Genomics Consortium and some of the proteins for which the Consortium is in the progress of determining three-dimensional structures.

Electron transfer in human cytochrome P450 reductase.

Cytochrome P450 reductase (CPR) is a diflavin enzyme responsible for electron donation to mammalian cytochrome P450 enzymes in the endoplasmic reticulum. Dissection of the enzyme into functional domains and studies by site-directed mutagenesis have enabled detailed characterization of the mechanism of electron transfer using stopped-flow and equilibrium-perturbation methods, and redox potentiometry. These studies and the mechanism of electron transfer in CPR are reported herein.

Cytochromes P450: novel drug targets in the war against multidrug-resistant Mycobacterium tuberculosis.

Novel drug strategies are desperately needed to combat the global threat posed by multidrug-resistant strains of Mycobacterium tuberculosis (Mtb). The genome sequence of Mtb has revealed an unprecedented number of cytochrome P450 enzymes in a prokaryote, suggesting fundamental physiological roles for many of these enzymes. Several azole drugs (known inhibitors of cytochromes P450) have been shown to have potent anti-mycobacterial activity, and the most effective azoles have extremely tight binding constants for one of the Mtb P450s (CYP121). The structure of CYP121 has been determined at atomic resolution, revealing novel features of P450 structure, including mixed haem conformations and putative proton-relay pathways from protein surface to haem iron. The structure provides both a platform for investigation of structure/mechanism of cytochrome P450, and for design of inhibitor molecules as novel anti-tubercular agents.

Use of high pressure to study elementary steps in P450 and nitric oxide synthase.

Chemical reactions are often highly pressure-dependent. A perturbation of the elementary steps by pressure therefore offers the possibility of a detailed characterization of enzyme mechanisms. We used this method to study distinct steps in the reaction of nitric-oxide synthase (NOS), and compared them to analogous steps in the reaction of cytochrome P450 BM3 (BM3). Our results indicate that, in BM3, electron transfer depends on electrostatic interactions. In NOS, pressure, similarly to chemical denaturants, can mimic the structural effects of Ca/calmodulin. This helps to better understand the structural basis of the regulatory effect of Ca/calmodulin. Furthermore, stopped-flow kinetics under high pressure show that CO binding to the heme iron is hindered by substrate in NOS, but not in BM3. This indicates a relatively large or flexible substrate binding site in BM3, and a more narrow and rigid binding site in NOS.

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.

Structural and spectroscopic analysis of the F393H mutant of flavocytochrome P450 BM3.

In the preceding paper in this issue [Ost, T. W. B., Miles, C. S., Munro, A. W., Murdoch, J., Reid, G. A., and Chapman, S. K. (2001) Biochemistry 40, 13421-13429], we have established that the primary role of the phylogenetically conserved phenylalanine in flavocytochrome P450 BM3 (F393) is to control the thermodynamic properties of the heme iron, so as to optimize electron-transfer both to the iron (from the flavin redox partner) and onto molecular oxygen. In this paper, we report a detailed study of the F393H mutant enzyme, designed to probe the structural, spectroscopic, and metabolic profile of the enzyme in an attempt to identify the factors responsible for causing the changes. The heme domain structure of the F393H mutant has been solved to 2.0 A resolution and demonstrates that the histidine replaces the phenylalanine in almost exactly the same conformation. A solvent water molecule is hydrogen bonded to the histidine, but there appears to be little other gross alteration in the environment of the heme. The F393H mutant displays an identical ferric EPR spectrum to wild-type, implying that the degree of splitting of the iron d orbitals is unaffected by the substitution, however, the overall energy of the d-orbitals have changed relative to each other. Magnetic CD studies show that the near-IR transition, diagnostic of heme ligation state, is red-shifted by 40 nm in F393H relative to wild-type P450 BM3, probably reflecting alteration in the strength of the iron-cysteinate bond. Studies of the catalytic turnover of fatty acid (myristate) confirms NADPH oxidation is tightly coupled to fatty acid oxidation in F393H, with a product profile very similar to wild-type. The results indicate that gross conformational changes do not account for the perturbations in the electronic features of the P450 BM3 heme system and that the structural environment on the proximal side of the P450 heme must be conformationally conserved in order to optimize catalytic function.

Effects of environment on flavin reactivity in morphinone reductase: analysis of enzymes displaying differential charge near the N-1 atom and C-2 carbonyl region of the active-site flavin.

The side chain of residue Arg(238) in morphinone reductase (MR) is located close to the N-1/C-2 carbonyl region of the flavin isoalloxazine ring. During enzyme reduction negative charge develops in this region of the flavin. The positioning of a positively charged side chain in the N-1/C-2 carbonyl region of protein-bound flavin is common to many flavoprotein enzymes. To assess the contribution made by Arg(238) in stabilizing the reduced flavin in MR we isolated three mutant forms of the enzyme in which the position of the positively charged side chain was retracted from the N-1/C-2 carbonyl region (Arg(238)-->Lys), the positive charge was removed (Arg(238)-->Met) or the charge was reversed (Arg(238)-->Glu). Each mutant enzyme retains flavin in its active site. Potentiometric studies of the flavin in the wild-type and mutant forms of MR indicate that the flavin semiquinone is not populated to any appreciable extent. Reduction of the flavin in each enzyme is best described by a single Nernst function, and the values of the midpoint reduction potentials (E(12)) for each enzyme fall within the region of -247+/-10 mV. Stopped-flow studies of NADH binding to wild-type and mutant MR enzymes reveal differences in the kinetics of formation and decay of an enzyme-NADH charge-transfer complex, reflecting small perturbations in active-site geometry. Reduced rates of hydride transfer in the mutant enzymes are attributed to altered geometrical alignment of the nicotinamide coenzyme with FMN rather than major perturbations in reduction potential, and this is supported by an observed entropy-enthalpy compensation effect on the hydride transfer reaction throughout the series of enzymes. The data indicate, in contrast with dogma, that the presence of a positively charged side chain close to the N-1/C-2 carbonyl region of the flavin in MR is not required to stabilize the reduced flavin. This finding may have general implications for flavoenzyme catalysis, since it has generally been assumed that positive charge in this region has a stabilizing effect on the reduced form of flavin.

Expression, purification and characterization of cytochrome P450 Biol: a novel P450 involved in biotin synthesis in Bacillus subtilis.

The bioI gene has been sub-cloned and over-expressed in Escherichia coli, and the protein purified to homogeneity. The protein is a cytochrome P450, as indicated by its visible spectrum (low-spin haem iron Soret band at 419 nm) and by the characteristic carbon monoxide-induced shift of the Soret band to 448 nm in the reduced form. N-terminal amino acid sequencing and mass spectrometry indicate that the initiator methionine is removed from cytochrome P450 BioI and that the relative molecular mass is 44,732 Da, consistent with that deduced from the gene sequence. SDS-PAGE indicates that the protein is homogeneous after column chromatography on DE-52 and hydroxyapatite, followed by FPLC on a quaternary ammonium ion-exchange column (Q-Sepharose). The purified protein is of mixed spin-state by both electronic spectroscopy and by electron paramagnetic resonance [g values=2.41, 2.24 and 1.97/1.91 (low-spin) and 8.13, 5.92 and 3.47 (high-spin)]. Magnetic circular dichroism and electron paramagnetic resonance studies indicate that P450 BioI has a cysteine-ligated b-type haem iron and the near-IR magnetic circular dichroism band suggests strongly that the sixth ligand bound to the haem iron is water. Resonance Raman spectroscopy identifies vibrational signals typical of cytochrome P450, notably the oxidation state marker v4 at 1,373 cm(-1) (indicating ferric P450 haem) and the splitting of the spin-state marker v3 into two components (1,503 cm(-1) and 1,488 cm(-1)), indicating cytochrome P450 BioI to be a mixture of high- and low-spin forms. Fatty acids were found to bind to cytochrome P450 BioI, with myristic acid (Kd=4.18+/-0.26 microM) and pentadecanoic acid (Kd=3.58+/-0.54 microM) having highest affinity. The fatty acid analogue inhibitor 12-imidazolyldodecanoic acid bound extremely tightly (Kd<1 microM), again indicating strong affinity for fatty acid chains in the P450 active site. Catalytic activity was demonstrated by reconstituting the P450 with either a soluble form of human cytochrome P450 reductase, or a Bacillus subtilis ferredoxin and E. coli ferredoxin reductase. Substrate hydroxylation at the omega-terminal position was demonstrated by turnover of the chromophoric fatty acid para-nitrophenoxydodecanoic acid, and by separation of product from the reaction of P450 BioI with myristic acid.

Determination of the redox properties of human NADPH-cytochrome P450 reductase.

Midpoint reduction potentials for the flavin cofactors in human NADPH-cytochrome P450 oxidoreductase were determined by anaerobic redox titration of the diflavin (FAD and FMN) enzyme and by separate titrations of its isolated FAD/NADPH and FMN domains. Flavin reduction potentials are similar in the isolated domains (FAD domain E(1) [oxidized/semiquinone] = -286 +/- 6 mV, E(2) [semiquinone/reduced] = -371 +/- 7 mV; FMN domain E(1) = -43 +/- 7 mV, E(2) = -280 +/- 8 mV) and the soluble diflavin reductase (E(1) [FMN] = -66 +/- 8 mV, E(2) [FMN] = -269 +/- 10 mV; E(1) [FAD] = -283 +/- 5 mV, E(2) [FAD] = -382 +/- 8 mV). The lack of perturbation of the individual flavin potentials in the FAD and FMN domains indicates that the flavins are located in discrete environments and that these environments are not significantly disrupted by genetic dissection of the domains. Each flavin titrates through a blue semiquinone state, with the FMN semiquinone being most intense due to larger separation (approximately 200 mV) of its two couples. Both the FMN domain and the soluble reductase are purified in partially reduced, colored form from the Escherichia coli expression system, either as a green reductase or a gray-blue FMN domain. In both cases, large amounts of the higher potential FMN are in the semiquinone form. The redox properties of human cytochrome P450 reductase (CPR) are similar to those reported for rabbit CPR and the reductase domain of neuronal nitric oxide synthase. However, they differ markedly from those of yeast and bacterial CPRs, pointing to an important evolutionary difference in electronic regulation of these enzymes.

Control of electron transfer in neuronal NO synthase.

The nitric oxide synthases (NOSs) are dimeric flavocytochromes consisting of an oxygenase domain with cytochrome P450-like Cys-ligated haem, coupled to a diflavin reductase domain, which is related to cytochrome P450 reductase. The NOSs catalyse the sequential mono-oxygenation of arginine to N-hydroxyarginine and then to citrulline and NO. The constitutive NOS isoforms (cNOSs) are regulated by calmodulin (CaM), which binds at elevated concentrations of free Ca(2+), whereas the inducible isoform binds CaM irreversibly. One of the main structural differences between the constitutive and inducible isoforms is an insert of 40-50 amino acids in the FMN-binding domain of the cNOSs. Deletion of the insert in rat neuronal NOS (nNOS) led to a mutant enzyme which binds CaM at lower Ca(2+) concentrations and which retains activity in the absence of CaM. In order to resolve the mechanism of action of CaM activation we determined reduction potentials for the FMN and FAD cofactors of rat nNOS in the presence and absence of CaM using a recombinant form of the reductase domain. The results indicate that CaM binding does not modulate the reduction potentials of the flavins, but appears to control electron transfer primarily via a large structural rearrangement. We also report the creation of chimaeric enzymes in which the reductase domains of nNOS and flavocytochrome P450 BM3 (Bacillus megaterium III) have been exchanged. Despite its very different flavin redox potentials, the BM3 reductase domain was able to support low levels of CaM-dependent NO synthesis, whereas the NOS reductase domain did not effectively substitute for that of cytochrome P450 BM3.

alpha Arg-237 in Methylophilus methylotrophus (sp. W3A1) electron-transferring flavoprotein affords approximately 200-millivolt stabilization of the FAD anionic semiquinone and a kinetic block on full reduction to the dihydroquinone.

The midpoint reduction potentials of the FAD cofactor in wild-type Methylophilus methylotrophus (sp. W3A1) electron-transferring flavoprotein (ETF) and the alphaR237A mutant were determined by anaerobic redox titration. The FAD reduction potential of the oxidized-semiquinone couple in wild-type ETF (E'(1)) is +153 +/- 2 mV, indicating exceptional stabilization of the flavin anionic semiquinone species. Conversion to the dihydroquinone is incomplete (E'(2) < -250 mV), because of the presence of both kinetic and thermodynamic blocks on full reduction of the FAD. A structural model of ETF (Chohan, K. K., Scrutton, N. S., and Sutcliffe, M. J. (1998) Protein Pept. Lett. 5, 231-236) suggests that the guanidinium group of Arg-237, which is located over the si face of the flavin isoalloxazine ring, plays a key role in the exceptional stabilization of the anionic semiquinone in wild-type ETF. The major effect of exchanging alphaArg-237 for Ala in M. methylotrophus ETF is to engineer a remarkable approximately 200-mV destabilization of the flavin anionic semiquinone (E'(2) = -31 +/- 2 mV, and E'(1) = -43 +/- 2 mV). In addition, reduction to the FAD dihydroquinone in alphaR237A ETF is relatively facile, indicating that the kinetic block seen in wild-type ETF is substantially removed in the alphaR237A ETF. Thus, kinetic (as well as thermodynamic) considerations are important in populating the redox forms of the protein-bound flavin. Additionally, we show that electron transfer from trimethylamine dehydrogenase to alphaR237A ETF is severely compromised, because of impaired assembly of the electron transfer complex.

Rational re-design of the substrate binding site of flavocytochrome P450 BM3.

Bacillus megaterium P450 BM3 is a fatty acid hydroxylase with selectivity for long chain substrates (C(12)-C(20)). Binding or activity with substrates of chain length 13-fold with butyrate, while the L75T/L181K double mutant has k(cat)/K(M) increased >15-fold with hexanoate and binding (K(d)) improved >28-fold for butyrate. Removing the arginine 47/lysine 51 carboxylate binding motif at the mouth of the active site disfavours binding of all fatty acids, indicating its importance in the initial recognition of substrates.

Probing the NADPH-binding site of Escherichia coli flavodoxin oxidoreductase.

The structure of the Escherichia coli flavodoxin NADP(+) oxidoreductase (FLDR) places three arginines (R144, R174 and R184) in the proposed NADPH-binding site. Mutant enzymes produced by site-directed mutagenesis, in which each arginine was replaced by neutral alanine, were characterized. All mutants exhibited decreased NADPH-dependent cytochrome c reductase activity (R144A, 241.6 min(-1); R174A, 132.1 min(-1); R184A, 305.5 min(-1) versus wild type, 338.9 min(-1)) and increased K(m) for NADPH (R144A, 5.3 microM; R174A, 20.2 microM; R184A, 54.4 microM versus wild type, 3.9 microM). The k(cat) value for NADH-dependent cytochrome c reduction was increased for R174A (42.3 min(-1)) and R184A (50.4 min(-1)) compared with the wild type (33.0 min(-1)), consistent with roles for R174 and R184 in discriminating between NADPH/NADH by interaction with the adenosine ribose 2'-phosphate. Stopped-flow studies indicated that affinity (K(d)) for NADPH was markedly reduced in mutants R144A (635 microM) and R184A (2.3 mM) compared with the wild type (<5 microM). Mutant R184A displays the greatest change in pyridine nucleotide preference, with the NADH/NADPH K(d) ratio >175-fold lower than for wild-type FLDR. The rate constant for hydride transfer from NADPH to flavin was lowest for R174A (k(red)=8.82 s(-1) versus 22.63 s(-1) for the wild type), which also exhibited tertiary structure perturbation, as evidenced by alterations in CD and fluorescence spectra. Molecular modelling indicated that movement of the C-terminal tryptophan (W248) of FLDR is necessary to permit close approach of the nicotinamide ring of NADPH to the flavin. The positions of NADPH phosphates in the modelled structure are consistent with the kinetic data, with R174 and R184 located close to the adenosine ribose 2'-phosphate group, and R144 likely to interact with the nicotinamide ribose 5'-phosphate group.