Nitrate reductase of Neurospora crassa: the functional role of individual amino acids in the heme domain as examined by site-directed mutagenesis

The enzyme nitrate reductase, which catalyzes the reduction of nitrate to nitrite, is a multi-redox center homodimeric protein. Each polypeptide subunit is approximately 100 kDa in size and contains three separate domains, one each for a flavin, a heme-iron, and a molybdopterin cofactor. The heme-iron domain of nitrate reductase has homology with the simple redox protein, cytochrome b5, whose crystal structure was used to predict a three-dimensional structure for the heme domain. Two histidine residues have been identified that appear to coordinate the iron of the heme moiety, while other residues may be important in the folding or the function of the heme pocket. Site-directed mutagenesis was employed to obtain mutants that encode nitrate reductase derivatives with eight different single amino acid substitutions within the heme domain, including the two central histidine residues. Replacement of one of these histidines by alanine resulted in a completely nonfunctional enzyme whereas replacement of the other histidine resulted in a stable and functional enzyme with a lower affinity for heme. Certain amino acid substitutions appeared to cause a rapid turnover of the heme domain, whereas other substitutions were tolerated and yielded a stable and fully active enzyme. Three different single amino acid replacements within the heme domain led to a dramatic change in regulation of nitrate reductase synthesis, with significant expression of the enzyme even in the absence of nitrate induction.     

Mutational and structural analysis of the nitrate reductase heme domain of Nicotiana plumbaginifolia.

We have analyzed four Nicotiana plumbaginifolia null mutants presumably affected in the heme domain of nitrate reductase. The DNA sequence of this domain has been determined for each mutant and for the wild type. Two mutations were identified as single base changes leading to, respectively, the substitution of a histidine residue by an asparagine (mutant E56) and to the appearance of an ochre stop codon (mutant E64). Based on the amino acid sequence homology between the nitrate reductase heme domain and mammalian cytochrome b5, we have predicted the three-dimensional structure of this domain. This showed that the nitrate reductase heme domain is structurally very similar to cytochrome b5 and it also confirmed that the residue involved in E56 mutation is one of the two heme-binding histidines. The two other mutations (mutants A1 and K21) were found to be, respectively, -1 and +1 frameshift mutations resulting in the appearance of an opal stop codon. These sequence data confirmed previous genetic and biochemical hypotheses on nitrate reductase-deficient mutants. Northern blot analysis of these mutants indicated that mutant E56 overexpressed the nitrate reductase mRNA, whereas the nonsense mutations present in the other mutants led to reduced levels of nitrate reductase mRNA.     

The sequence of squash NADH:nitrate reductase and its relationship to the sequences of other flavoprotein oxidoreductases. A family of flavoprotein pyridine nucleotide cytochrome reductases.

Nucleotide sequences were determined for cDNA clones for squash NADH:nitrate oxidoreductase (EC 1.6.6.1), which is one of the most completely characterized forms of this higher plant enzyme. An open reading frame of 2754 nucleotides began at the first ATG. The deduced amino acid sequence contains 918 residues, with a predicted Mr = 103,376. The amino acid sequence is very similar to sequences deduced for other higher plant nitrate reductases. The squash sequence has significant similarity to the amino acid sequences of sulfite oxidase, cytochrome b5, and NADH:cytochrome b5 reductase. Alignment of these sequences with that of squash defines domains of nitrate reductase that appear to bind its 3 prosthetic groups (molybdopterin, heme-iron, and FAD). The amino acid sequence of the FAD domain of squash nitrate reductase was aligned with FAD domain sequences of other NADH:nitrate reductases, NADH:cytochrome b5 reductases, NADPH:nitrate reductases, ferredoxin:NADP+ reductases, NADPH:cytochrome P-450 reductases, NADPH:sulfite reductase flavoproteins, and Bacillus megaterium cytochrome P-450BM-3. In this multiple alignment, 14 amino acid residues are invariant, which suggests these proteins are members of a family of flavoenzymes. Secondary structure elements of the structural model of spinach ferredoxin:NADP+ reductase were used to predict the secondary structure of squash nitrate reductase and the other related flavoenzymes in this family. We suggest that this family of flavoenzymes, nearly all of which reduce a hemoprotein, be called "flavoprotein pyridine nucleotide cytochrome reductases."     

Regulation of the Neurospora crassa assimilatory nitrate reductase.

Reduced nicotinamide adenine dinucleotide phosphate (NADPH)-nitrate reductase from Neurospora crassa was purified and found to be stimulated by certain amino acids, citrate, and ethylenediaminetetraacetic acid (EDTA). Stimulation by citrate and the amino acids was dependent upon the prior removal of EDTA from the enzyme preparations, since low quantities of EDTA resulted in maximal stimulation. Removal of EDTA from enzyme preparations by dialysis against Chelex-containing buffer resulted in a loss of nitrate reductase activity. Addition of alanine, arginine, glycine, glutamine, glutamate, histidine, tryptophan, and citrate restored and stimulated nitrate reductase activity from 29- to 46-fold. The amino acids tested altered the Km of NADPH-nitrate reductase for NADPH but did not significantly change that for nitrate. The Km of nitrate reductase for NADPH increased with increasing concentrations of histidine but decreased with increasing concentrations of glutamine. Amino acid modulation of NADPH-nitrate reductase activity is discussed in relation to the conservation of energy (NADPH) by Neurospora when nitrate is the nitrogen source.     

Nit-3, the structural gene of nitrate reductase in Neurospora crassa: nucleotide sequence and regulation of mRNA synthesis and turnover

Summary The nit-3 gene of the filamentous fungus Neurospora crassa encodes the enzyme nitrate reductase, which catalyzes the first reductive step in the highly regulated nitrate assimilatory pathway. The nucleotide sequence of nit-3 was determined and translates to a protein of 982 amino acid residues with a molecular weight of approximately 108 kDa. Comparison of the deduced nit-3 protein sequence with the nitrate reductase protein sequences of other fungi and higher plants revealed that a significant amount of homology exists, particularly within the three cofactor-binding domains for molybdenum, heme and FAD. The synthesis and turnover of the nit-3 mRNA were also examined and found to occur rapidly and efficiently under changing metabolic conditions.     

Synthesis and bacterial expression of a gene encoding the heme domain of assimilatory nitrate reductase

Assimilatory NADH:nitrate reductase (EC 1.6.6.1), a complex Mo-pterin-, cytochrome b(557)-, and FAD-containing protein, catalyzes the regulated and rate-limiting step in the utilization of inorganic nitrogen by higher plants. A codon-optimized gene has been synthesized for expression of the central cytochrome b(557)-containing fragment, corresponding to residues A542-E658, of spinach assimilatory nitrate reductase. While expression of the full-length synthetic gene in Escherichia coli did not result in significant heme domain production, expression of a Y647* truncated form resulted in substantial heme domain production as evidenced by the generation of "pink" cells. The histidine-tagged heme domain was purified to homogeneity using a combination of NTA-agarose and size-exclusion FPLC, resulting in a single protein band following SDS-PAGE analysis with a molecular mass of approximately 13 kDa. MALDI-TOF mass spectrometry yielded an m/z ratio of 12,435 and confirmed the presence of the heme prosthetic group (m/z=622) while cofactor analysis indicated a 1:1 heme to protein stoichiometry. The oxidized heme domain exhibited spectroscopic properties typical of a b-type cytochrome with a visible Soret maximum at 413 nm together with epr g-values of 2.98, 2.26, and 1.49, consistent with low-spin bis-histidyl coordination. Oxidation-reduction titrations of the heme domain indicated a standard midpoint potential (E(o)') of -118 mV. The isolated heme domain formed a 1:1 complex with cytochrome c with a K(A) of 7 microM (micro=0.007) and reconstituted NADH:cytochrome c reductase activity in the presence of a recombinant form of the spinach nitrate reductase flavin domain, yielding a k(cat) of 1.4 s(-1) and a K(m app) for cytochrome c of 9 microM. These results indicate the efficient expression of a recombinant form of the heme domain of spinach nitrate reductase that retained the spectroscopic and thermodynamic properties characteristic of the corresponding domain in the native spinach enzyme.     

Functional analysis by site-directed mutagenesis of individual amino acid residues in the flavin domain of Neurospora crassa nitrate reductase

Nitrate reductase of Neurospora crassa is a complex multi-redox protein composed of two identical subunits, each of which contains three distinct domains, an amino-terminal domain that contains a molybdopterin cofactor, a central heme-containing domain, and a carboxy-terminal domain which binds a flavin and a pyridine nucleotide cofactor. The flavin domain of nitrate reductase appears to have structural and functional similarity to ferredoxin NADPH reductase (FNR). Using the crystal structure of FNR and amino acid identities in numerous nitrate reductases as guides, site-directed mutagenesis was used to replace specific amino acids suspected to be involved in the binding of the flavin or pyridine nucleotide cofactors and thus important for the catalytic function of the flavin domain. Each mutant flavin domain protein was expressed in Escherichia coli and analyzed for NADPH: ferricyanide reductase activity. The effect of each amino acid substitution upon the activity of the complete nitrate reductase reaction was also examined by transforming each manipulated gene into a nit-3 ^– null mutant of N. crassa. Our results identify amino acid residues which are critical for function of the flavin domain of nitrate reductase and appear to be important for the binding of the flavin or the pyridine nucleotide cofactors.     

Electron paramagnetic resonance studies of Pseudomonas cytochrome c peroxidase

The EPR spectrum at 15 K of Pseudomonas cytochrome c peroxidase, which contains two hemes per molecule, is in the totally ferric form characteristic of low-spin heme giving two sets of g-values with gz 3.26 and 2.94. These values indicate an imidazole-nitrogen : heme-iron : methionine-sulfur and an imidazole-nitrogen : heme-iron : imidazole-nitrogen hemochrome structure, respectively. The spectrum is essentially identical at pH 6.0 and 4.6 and shows only a very small amount of high-spin heme iron (g 5--6) also at 77 K. Interaction between the two hemes is shown to exist by experiments in which one heme is reduced. This induces a change of the EPR signal of the other (to gz 2.83, gy 2.35 and gx 1.54), indicative of the removal of a histidine proton from that heme, which is axially coordinated to two histidine residues. If hydrogen peroxide is added to the partially reduced protein, its EPR signal is replaced by still other signals (gz 3.5 and 3.15). Only a very small free radical peak could be observed consistent with earlier mechanistic proposals. Contrary to the EPR spectra recorded at low temperature, the optical absorption spectra of both totally oxidized and partially reduced enzyme reveal the presence of high-spin heme at room temperature. It seems that a transition of one of the heme c moieties from an essentially high-spin to a low-spin form takes place on cooling the enzyme from 298 to 15 K.     

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.     

The choice of reducing substrate is altered by replacement of an alanine by a proline in the FAD domain of a bispecific NAD(P)H-nitrate reductase from birch.

Differences in the amino acid sequence between the bispecific NAD(P)H-nitrate reductase of birch (Betula pendula Roth) and the monospecific NADH-nitrate reductases of a variety of other higher plants have been found at the dinucleotide-binding site in the FAD domain. To pinpoint amino acid residues that determine the choice of reducing substrate, we introduced mutations into the cDNA coding for birch nitrate reductase. These mutations were aimed at replacing certain amino acids of the NAD(P)H-binding site by conserved amino acids located at identical positions in NADH-monospecific enzymes. The mutated cDNAs were integrated into the genome of tobacco by Agrobacterium-mediated transformation. Transgenic tobacco (Nicotiana tabacum) plants were grown on a medium containing ammonium as the sole nitrogen source to keep endogenous tobacco nitrate reductase activity low. Whereas some of the mutated enzymes showed a slight preference for NADPH, as does the nonmutated birch enzyme, the activity of some others greatly depended on the availability of NADH and was low with NADPH alone. Comparison of the mutations reveals that replacement of a single amino acid in the birch sequence (alanine871 by proline) is critical for the use of reducing substrate.     

Location of heme axial ligands in the cytochrome d terminal oxidase complex of Escherichia coli determined by site-directed mutagenesis

The cytochrome d terminal oxidase complex is one of two terminal oxidases which are components of the aerobic respiratory chain of Escherichia coli. This membrane-bound enzyme catalyzes the two-electron oxidation of ubiquinol and the four-electron reduction of oxygen to water. Enzyme turnover generates proton and voltage gradients across the bilayer. The oxidase is a heterodimer containing 2 mol of protoheme IX and 1 or 2 mol of heme d per mol of complex. To explain the functional properties of the enzyme, a simple model has been proposed in which it is speculated that the heme prosthetic groups define two separate active sites on opposite sides of the membrane at which the oxidation of quinol and the reduction of water, respectively, are catalyzed. This paper represents an initial effort to define the axial ligands of each of the three or four hemes within the amino acid sequence of the oxidase subunits. Each of the 10 histidine residues has been altered by site-directed mutagenesis with the expectation that histidine residues are likely candidates for heme ligands. Eight of the 10 histidine residues are not essential for enzyme activity, and 2 appear to function as heme axial ligands. Histidine 186 in subunit I is required for the cytochrome b558 component of the enzyme. This residue is likely to be located near the periplasmic surface of the membrane. Histidine 19, near the amino terminus of subunit I also appears to be a heme ligand. It is concluded that two of the four or five expected heme axial ligands have been tentatively identified, although further work is required to confirm these conclusions. A minimum of two additional axial ligands must be residues other than histidine.     

Characterization by NMR of the heme-myoglobin adduct formed during the reductive metabolism of BrCCl3. Covalent bonding of the proximal histidine to the ring I vinyl group

The reductive debromination of BrCCl3 by ferrous deoxymyoglobin leads to the covalent bonding of the prosthetic heme to the protein. We have previously shown, by the use of peptide mapping and mass spectrometry, that histidine residue 93 is covalently bound to the heme moiety. In the present study the structure of the heme adduct was more completely determined by 1H and 13C NMR techniques. We have found that the ring I vinyl group of the prosthetic heme was altered by the addition of a histidine imidazole nitrogen to the alpha-carbon and a CCl2 moiety to the beta-carbon. The electronic absorption spectra of the oxidized and reduced states of the altered heme-protein indicated that the heme-iron exists in a bis-histidine-ligated form. Analysis of the crystal structure of native myoglobin suggested that for the altered heme-protein, histidine residues 97 and 64 are ligated to the heme-iron and that residue 97 has replaced the native proximal histidine residue 93. These movements, in effect a "histidine shuffle" at the active site, may be responsible for the enhanced reducing activity of the altered protein.     

Quaternary structure and composition of squash NADH:nitrate reductase

NADH:nitrate reductase (EC 1.6.6.1) was isolated from squash cotyledons (Cucurbita maxima L.) by a combination of Blue Sepharose and zinc-chelate affinity chromatographies followed by gel filtration on Bio-Gel A-1.5m. These preparations gave a single protein staining band (Mr = 115,000) on sodium dodecyl sulfate gel electrophoresis, indicating that the enzyme is homogeneous. The native Mr of nitrate reductase was found to be 230,000, with a minor form of Mr = 420,000 also occurring. These results indicate that the native nitrate reductase is a homodimer of Mr = 115,000 subunits. Acidic amino acids predominate over basic amino acids, as shown both by the amino acid composition of the enzyme and an isoelectric point for nitrate reductase of 5.7. The homogeneous nitrate reductase had a UV/visible spectrum typical of a b-type cytochrome. The enzyme was found to contain one each of flavin (as FAD), heme iron, molybdenum, and Mo-pterin/Mr = 115,000 subunit. A model is proposed for squash nitrate reductase in which two Mr = 115,000 subunits are joined to made the native enzyme. Each subunit contains 1 eq of FAD, cytochrome b, and molybdenum/Mo-pterin.     

Site-directed mutational analysis of the novel catalytic domains of <Emphasis Type="Italic">α</Emphasis>-aminoadipate reductase (Lys2p) from <Emphasis Type="Italic"> Candida albicans</Emphasis>

The alpha-aminoadipate reductase, a novel enzyme in the alpha-aminoadipic acid pathway for the biosynthesis of lysine in fungi, catalyzes the conversion of alpha-aminoadipic acid to alpha-aminoadipic-delta-semialdehyde in the presence of ATP, NADPH and MgCl(2). This reaction requires two distinct gene products, Lys2p and Lys5p. In the presence of CoA, Lys5p posttranslationally activates Lys2p for the alpha-aminoadipate reductase activity. Sequence alignments indicate the presence of all functional domains required for the activation, adenylation, dehydrogenation and alpha-aminoadipic acid binding in the Lys2p. In this report we present the results of site-directed mutational analysis of the conserved amino acid residues in the catalytic domains of Lys2p from the pathogenic yeast Candida albicans. Mutants were generated in the LYS2 sequence of pCaLYS2SEI by PCR mutagenesis and expressed in E. coli BL21 cells. Recombinant mutants and the wild-type Lys2p were analyzed for their alpha-aminoadipate reductase activity. Substitution of threonine 416, glycine 418, serine 419, and lysine 424 of the adenylation domain (TXGSXXXXK, residues 416-424) resulted in a significant reduction in alpha-aminoadipate reductase activity compared to the unmutagenized Lys2p control. Similarly replacement of glycine 978, threonine 980, glycine 981, phenylalanine 982, leucine 983 and glycine 984 of the NADPH binding domain (GXTGFLG, residues 978-984) caused a drastic decrease in alpha-aminoadipate reductase activity. Finally, substitution of histidine 460, aspartic acid 461, proline 462, isoleucine 463, glutamine 464, arginine 465, and aspartic acid 466 of the putative alpha-aminoadipic acid binding domain (HDPIQRD, residues 460-466) resulted in a highly reduced alpha-aminoadipate reductase activity. These results confirm the hypothesis that specific amino acid residues in highly conserved catalytic domains of Lys2p are essential for the alpha-aminoadipate reductase activity.     

Hydrogen bonding of iron-coordinated histidine in heme proteins.

The hydrogen-bonding motifs of the proton on the N delta atom of iron-coordinated histidine residues in heme proteins have been classified into three categories: (1) Those in which the hydrogen-bond acceptor is either an amino acid residue (serine) directly adjacent to the histidine or a carbonyl group of the polypeptide chain less than five residues away from the histidine; (2) those in which the hydrogen-bonding acceptor is a carbonyl group of the polypeptide backbone associated with an amino acid residue 8 to 17 residues away from the histidine; and (3) those in which the hydrogen-bonding acceptor is an exogenous water molecule or an amino acid residue located far from the histidine in the amino acid sequence. Some biological functions are defined by this classification, whereas others span all classes.     

Deconstructing the electron transfer chain in a complex molybdoenzyme: Assimilatory nitrate reductase from Neurospora crassa

Nitrate reductase (NR) from the fungus Neurospora crassa is a complex homodimeric metallo-flavoenzyme, where each protomer contains three distinct domains; the catalytically active terminal molybdopterin cofactor, a central heme-containing domain, and an FAD domain which binds with the natural electron donor NADPH. Here, we demonstrate the catalytic voltammetry of variants of N. crassa NRs on a modified Au electrode with the electrochemically reduced forms of benzyl viologen (BV²⁺) and anthraquinone sulfonate (AQS^?) acting as artificial electron donors. The biopolymer chitosan used to entrap NR on the electrode non-covalently and the enzyme film was both stable and highly active. Electrochemistry was conducted on two distinct forms; one lacking the FAD cofactor and the other lacking both the FAD and heme cofactors. While both enzymes showed catalytic nitrate reductase activity, removal of the heme cofactor resulted in a more significant effect on the rate of nitrate reduction. Electrochemical simulation was carried out to enable kinetic characterisation of both the NR:nitrate and NR:mediator reactions.     

Coupling of heme attachment to import of cytochrome c into yeast mitochondria. Studies with heme lyase-deficient mitochondria and altered apocytochromes c

Cytochrome c is synthesized in the cytoplasm as apocytochrome c, lacking heme, and then imported into mitochondria. The relationship between attachment of heme to the apoprotein and its import into mitochondria was examined using an in vitro system. Apocytochrome c transcribed and translated in vitro could be imported with high efficiency into mitochondria isolated from normal yeast strains. However, no import of apocytochrome c occurred with mitochondria isolated from cyc3- strains, which lack cytochrome c heme lyase, the enzyme catalyzing covalent attachment of heme to apocytochrome c. In addition, amino acid substitutions in apocytochrome c at either of the 2 cysteine residues that are the sites of the thioether linkages to heme, or at an immediately adjacent histidine that serves as a ligand of the heme iron, resulted in a substantial reduction in the ability of the precursor to be translocated into mitochondria. Replacement of the methionine serving as the other iron ligand, on the other hand, had no detectable effect on import of apocytochrome c in this system. Thus, covalent heme attachment is a required step for import of cytochrome c into mitochondria. Heme attachment, however, can occur in the absence of mitochondrial import since we have detected CYC3-encoded heme lyase activity in solubilized yeast extracts and in an Escherichia coli expression system. These results suggest that protein folding triggered by heme attachment to apocytochrome c is required for import into mitochondria.     

Sequence of the gene encoding flavocytochrome c from Shewanella putrefaciens: a tetraheme flavoenzyme that is a soluble fumarate reductase related to the membrane-bound enzymes from other bacteria.

Flavocytochrome c from the Gram-negative, food-spoiling bacterium Shewanella putrefaciens is a soluble, periplasmic fumarate reductase. We have isolated the gene encoding flavocytochrome c and determined the complete DNA sequence. The predicted amino acid sequence indicates that flavocytochrome c is synthesized with an N-terminal secretory signal sequence of 25 amino acid residues. The mature protein contains 571 amino acid residues and consists of an N-terminal cytochrome domain, of about 117 residues, with four heme attachment sites typical of c-type cytochromes and a C-terminal flavoprotein domain of about 454 residues that is clearly related to the flavoprotein subunits of fumarate reductases and succinate dehydrogenases from bacterial and other sources. A second reading frame that may be cotranscribed with the flavocytochrome c gene exhibits some similarity with the 13-kDa membrane anchor subunit of Escherichia coli fumarate reductase. The sequence of the flavoprotein domain demonstrates an even closer relationship with the product of the yeast OSM1 gene, mutations in which result in sensitivity to high osmolarity. These findings are discussed in relation to the function of flavocytochrome c.     

Structure and function of the mitochondrial bc1 complex. A mutational analysis of the yeast Rieske iron-sulfur protein

Respiratory-defective mutants of Saccharomyces cerevisiae assigned to a single complementation group (G12) have been determined to have lesions in the iron-sulfur protein (Rieske protein) of ubiquinol: cytochrome c reductase. Mutants capable of expressing the protein were chosen for further studies. The genes from 13 independent isolates were cloned and their mutations sequenced. Twelve mutations were ascertained to cause single amino acid substitutions in the carboxyl-terminal regions of the protein between residues 127 and 173. This region is proposed to be part of the catalytic domain with the ligands responsible for co-ordinating the two irons of the 2Fe-2S cluster. Based on the catalytic properties of the ubiquinol: cytochrome c reductase complex and the electron paramagnetic resonance (e.p.r.) signals of the iron-sulfur protein, the mutants describe two different phenotypes. A subset of mutants have no detectable iron-sulfur cluster and are completely deficient in ubiquinol: cytochrome c reductase activity. These strains identify mutations in residues considered to be essential for binding of the iron or for maintaining a proper tertiary structure of the catalytic domain. A second group of mutants have reduced levels of enzymatic activity and exhibit e.p.r. spectra characteristic of the Rieske iron-sulfur cluster. The mutations in the latter strains have been ascribed to residues that influence the redox properties of the cluster by distorting the iron-binding pocket. A secondary and tertiary structure model is presented of the carboxyl-terminal 65 residues constituting the catalytic domain of the iron-sulfur protein. It is postulated that the two irons of the cluster are co-ordinated by three cysteine and a single histidine residue located in a loop structure. The catalytic domain also contains two short alpha-helices and three beta-strands that form a partial beta-barrel. Most of the hydrophilic amino acids are present in turns that map to one pole of the domain. When viewed in the context of the model, mutations that abolish the iron-sulfur cluster are mostly in residues defining the boundaries of the alpha-helices and beta-strands. The notable exception is a cysteine residue that has been assigned to the loop with the iron ligands. This cysteine residue is proposed to co-ordinate one iron of the cluster. Mutations that reduce ubiquinol: cytochrome c reductase activity and alter the redox potential of the cluster occur in residues located in the loop that contains the ligands of the cluster.     

Crystal structure of inhibitor-bound P450BM-3 reveals open conformation of substrate access channel

P450BM-3 is an extensively studied P450 cytochrome that is naturally fused to a cytochrome P450 reductase domain. Crystal structures of the heme domain of this enzyme have previously generated many insights into features of P450 structure, substrate binding specificity, and conformational changes that occur on substrate binding. Although many P450s are inhibited by imidazole, this compound does not effectively inhibit P450BM-3. Omega-imidazolyl fatty acids have previously been found to be weak inhibitors of the enzyme and show some unusual cooperativity with the substrate lauric acid. We set out to improve the properties of these inhibitors by attaching the omega-imidazolyl fatty acid to the nitrogen of an amino acid group, a tactic that we used previously to increase the potency of substrates. The resulting inhibitors were significantly more potent than their parent compounds lacking the amino acid group. A crystal structure of one of the new inhibitors bound to the heme domain of P450BM-3 reveals that the mode of interaction of the amino acid group with the enzyme is different from that previously observed for acyl amino acid substrates. Further, required movements of residues in the active site to accommodate the imidazole group provide an explanation for the low affinity of imidazole itself. Finally, the previously observed cooperativity with lauric acid is explained by a surprisingly open substrate-access channel lined with hydrophobic residues that could potentially accommodate lauric acid in addition to the inhibitor itself.