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.     

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.     

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.     

Heterologous expression of cytochrome P450 2D6 mutants, electron transfer, and catalysis of bufuralol hydroxylation: the role of aspartate 301 in structural integrity

Cytochrome P450 (P450) 2D6 is a polymorphic human enzyme involved in the oxidation of >50 drugs, most of which contain a basic nitrogen. In confirmation of previous work by others, substitutions at Asp301 decreased rates of substrate oxidation by P450 2D6. An anionic residue (Asp, Glu) at this position was found to be important in proper protein folding and heme incorporation, and positively charged residues were particularly disruptive in bacterial and also in baculovirus expression systems. Truncation of 20 N-terminal amino acids had no significant effect on catalytic activity except to attenuate P450 2D6 interaction with membranes and NADPH-P450 reductase. The truncation of the N-terminus increased the level of bacterial expression of wild-type P450 2D6 (Asp301) but markedly reduced expression of all codon 301 mutants, including Glu301. Reduction of ferric P450 2D6 by NADPH-P450 reductase was enhanced in the presence of the prototypic substrate bufuralol. Bacterial flavodoxin, an NADPH-P450 reductase homolog, binds tightly to P450 2D6 but is inefficient in electron transfer to the heme. These results collectively indicate that the acidic residue at position 301 in P450 2D6 has a structural role in addition to any in substrate binding and that the N-terminus of P450 2D6 is relatively unimportant to catalytic activity beyond a role in facilitating binding to NADPH-P450 reductase.     

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.     

Association and redox properties of the putidaredoxin reductase-nicotinamide adenine dinucleotide complex

Putidaredoxin reductase (PdR) is the flavin protein that carries out the first electron transfer involved in the cytochrome P450cam catalytic cycle. In PdR, the flavin adenine dinucleotide (FAD/FADH2) redox center acts as a transformer by accepting two electrons from soluble nicotinamide adenine dinucleotide (NAD+/NADH) and donating them in two separate, one-electron-transfer steps to the iron-sulfur protein putidaredoxin (Pdx). PdR, like the two more intensively studied monoflavin reductases, adrenodoxin reductase (AdR) and ferredoxin-NADP+ reductase (FNR), has no other active redox moieties (e.g., sulfhydryl groups) and can exist in three different oxidation states: (i) oxidized quinone, (ii) one-electron reduced semiquinone (stable neutral species (blue) or unstable radical anion (red)), and (iii) two-electron fully reduced hydroquinone. Here, we present reduction potential measurements for PdR in support of a thermodynamic model for the modulation of equilibria among the redox components in this initial electron-transfer step of the P450 cycle. A spectroelectrochemical technique was used to measure the midpoint oxidation-reduction potential of PdR that had been carefully purified of all residual NAD+, E0' = -369 +/- 10 mV at pH 7.6, which is more negative than previously reported and more negative than the pyridine nucleotide NADH/NAD+ (-330 mV). After addition of NAD+, the formation of the oxidized reductase-oxidized pyridine nucleotide complex was followed by the two-electron-transfer redox reaction, PdRox:NAD+ + 2e- --> PdRrd:NAD+, when the electrode potential was lowered. The midpoint potential was a hyperbolic function of increasing NAD+ concentration, such that at concentrations of pyridine nucleotide typically found in an intracellular environment, the midpoint potential would be E0' = -230 +/- 10 mV, thereby providing the thermodynamically favorable redox equilibria that enables electron transfer from NADH. This thermodynamic control of electron transfer is a shared mechanistic feature with the adrenodoxin P450 and photosynthetic electron-transfer systems but is different from the kinetic control mechanisms in the microsomal P450 systems where multiple reaction pathways draw on reducing power held by NADPH-cytochrome P450 reductase. The redox measurements were combined with protein fluorescence quenching of NAD+ binding to oxidized PdR to establish that the PdRox:NAD+ complex (KD = 230 microM) is about 5 orders of magnitude weaker than PdRrd:NAD+ binding. These results are integrated with known structural and kinetic information for PdR, as well as for AdR and FNR, in support of a compulsory ordered pathway to describe the electron-transfer processes catalyzed by all three reductases.     

Vanadate-dependent NAD(P)H oxidation by microsomal enzymes

Vanadate-dependent NAD(P)H oxidation, catalyzed by rat liver microsomes and microsomal NADPH-cytochrome P450 reductase (P450 reductase) and NADH-cytochrome b5 reductase (b5 reductase), was investigated. These enzymes and intact microsomes catalyzed NAD(P)H oxidation in the presence of either ortho- or polyvanadate. Antibody to P450 reductase inhibited orthovanadate-dependent NADPH oxidation catalyzed by either purified P450 reductase or rat liver microsomes and had no effect on the rates of NADH oxidation catalyzed by b5 reductase. NADPH-cytochrome P450 reductase catalyzed orthovanadate-dependent NADPH oxidation five times faster than NADH-cytochrome b5 reductase catalyzed NADH oxidation. Orthovanadate-dependent oxidation of either NADPH or NADH, catalyzed by purified reductases or rat liver microsomes, occurred in an anaerobic system, which indicated that superoxide is not an obligate intermediate in this process. Superoxide dismutase (SOD) inhibited orthovanadate, but not polyvanadate-mediated, enzyme-dependent NAD(P)H oxidation. SOD also inhibited when pyridine nucleotide oxidation was conducted anaerobically, suggesting that SOD inhibits vanadate-dependent NAD(P)H oxidation by a mechanism independent of scavenging of O2-.     

Thermodynamic and kinetic analysis of the isolated FAD domain of rat neuronal nitric oxide synthase altered in the region of the FAD shielding residue Phe1395.

In rat neuronal nitric oxide synthase, Phe1395 is positioned over the FAD isoalloxazine ring. This is replaced by Trp676 in human cytochrome P450 reductase, a tryptophan in related diflavin reductases (e.g. methionine synthase reductase and novel reductase 1), and tyrosine in plant ferredoxin-NADP(+) reductase. Trp676 in human cytochrome P450 reductase is conformationally mobile, and plays a key role in enzyme reduction. Mutagenesis of Trp676 to alanine results in a functional NADH-dependent reductase. Herein, we describe studies of rat neuronal nitric oxide synthase FAD domains, in which the aromatic shielding residue Phe1395 is replaced by tryptophan, alanine and serine. In steady-state assays the F1395A and F1395S domains have a greater preference for NADH compared with F1395W and wild-type. Stopped-flow studies indicate flavin reduction by NADH is significantly faster with F1395S and F1395A domains, suggesting that this contributes to altered preference in coenzyme specificity. Unlike cytochrome P450 reductase, the switch in coenzyme specificity is not attributed to differential binding of NADPH and NADH, but probably results from improved geometry for hydride transfer in the F1395S- and F1395A-NADH complexes. Potentiometry indicates that the substitutions do not significantly perturb thermodynamic properties of the FAD, although considerable changes in electronic absorption properties are observed in oxidized F1395A and F1395S, consistent with changes in hydrophobicity of the flavin environment. In wild-type and F1395W FAD domains, prolonged incubation with NADPH results in development of the neutral blue semiquinone FAD species. This reaction is suppressed in the mutant FAD domains lacking the shielding aromatic residue.     

Nitric oxide reductase (P450nor) from Fusarium oxysporum

In the present review we wanted to highlight the characteristic features of cytochtome P450 NADH-NO reductase (P450nor) from Fusarium oxysporum which belongs to the heme-thiolate protein family. This enzyme catalyzes the reduction of two NO molecules to N2O. The discovery, isolation, identification and crystallography are described in detail. Special emphasis was focused on the mechanism of NO reduction and possible electronic configurations of the 444 nm intermediate were discussed. Among heme-thiolate proteins nitric oxide reductase (P450nor) is unique since it catalyzes the conversion to dinitrogen oxide as a reductive process. However, it joins the typical physical characteristics of other P450 proteins including the ferric NO complex which can be considered as the enzyme-substrate complex of the enzyme. At a closer look some of its properties like a tilted structure and a shorter Fe-N distance indicate properties for a facilitated hydride transfer from NADH. The resulting intermediate forms the product in a subsequent reaction with the NO radical. For this rate-limiting step at physiological NO levels electron transfer is postulated as a common feature with other heme-thiolate mechanisms. P450nor seems to have an important role in protecting the fungus from NO inhibition of mitochondria especially when dioxygen becomes limiting.     

Monovalent cation activation in Escherichia coli inosine 5'-monophosphate dehydrogenase

Inosine 5'-monophosphate dehydrogenase (IMPDH) catalyzes the oxidation of inosine 5'-monophosphate (IMP) to xanthosine 5'-monophosphate with the concomitant reduction of NAD to NADH. Escherichia coli IMPDH is activated by K(+), Rb(+), NH(+)(4), and Cs(+). K(+) activation is inhibited by Li(+), Na(+), Ca(2+), and Mg(2+). This inhibition is competitive versus K(+) at high K(+) concentrations, noncompetitive versus IMP, and competitive versus NAD. Thus monovalent cation activation is linked to the NAD site. K(+) increases the rate constant for the pre-steady-state burst of NADH production, possibly by increasing the affinity of NAD. Three mutant IMPDHs have been identified which increase the value of K(m) for K(+): Asp13Ala, Asp50Ala, and Glu469Ala. In contrast to wild type, both Asp13Ala and Glu469Ala are activated by all cations tested. Thus these mutations eliminate cation selectivity. Both Asp13 and Glu469 appear to interact with the K(+) binding site identified in Chinese hamster IMPDH. Like wild-type IMPDH, K(+) activation of Asp50Ala is inhibited by Li(+), Na(+), Ca(2+), and Mg(2+). However, this inhibition is noncompetitive with respect to K(+) and competitive with respect to both IMP and NAD. Asp50 interacts with residues that form a rigid wall in the IMP site; disruption of this wall would be expected to decrease IMP binding, and the defect could propagate to the proposed K(+) site. Alternatively, this mutation could uncover a second monovalent cation binding site.     

Kinetic and chemical mechanism of the dihydrofolate reductase from Mycobacterium tuberculosis

Dihydrofolate reductase from Mycobacterium tuberculosis (MtDHFR) catalyzes the NAD(P)-dependent reduction of dihydrofolate, yielding NAD(P)(+) and tetrahydrofolate, the primary one-carbon unit carrier in biology. Tetrahydrofolate needs to be recycled so that reactions involved in dTMP synthesis and purine metabolism are maintained. In this work, we report the kinetic characterization of the MtDHFR. This enzyme has a sequential steady-state random kinetic mechanism, probably with a preferred pathway with NADPH binding first. A pK(a) value for an enzymic acid of approximately 7.0 was identified from the pH dependence of V, and the analysis of the primary kinetic isotope effects revealed that the hydride transfer step is at least partly rate-limiting throughout the pH range analyzed. Additionally, solvent and multiple kinetic isotope effects were determined and analyzed, and equilibrium isotope effects were measured on the equilibrium constant. (D(2)O)V and (D(2)O)V/K([4R-4-(2)H]NADH) were slightly inverse at pH 6.0, and inverse values for (D(2)O)V([4R-4-(2)H]NADH) and (D(2)O)V/K([4R-4-(2)H]NADH) suggested that a pre-equilibrium protonation is occurring before the hydride transfer step, indicating a stepwise mechanism for proton and hydride transfer. The same value was obtained for (D)k(H) at pH 5.5 and 7.5, reaffirming the rate-limiting nature of the hydride transfer step. A chemical mechanism is proposed on the basis of the results obtained here.     

Cytochrome p450nor, a novel class of mitochondrial cytochrome P450 involved in nitrate respiration in the fungus Fusarium oxysporum

Fusarium oxysporum, an imperfect filamentous fungus performs nitrate respiration under limited oxygen. In the respiratory system, Cytochrome P450nor (P450nor) is thought to catalyze the last step; reduction of nitric oxide to nitrous oxide. We examined its intracellular localization using enzymatic, spectroscopic, and immunological analyses to show that P450nor is found in both the mitochondria and the cytosol. Translational fusions between the putative mitochondrial targeting signal on the amino terminus of P450nor and Escherichia coli beta-galactosidase resulted in significant beta-galactosidase activity in the mitochondrial fraction of nitrate-respiring cells, suggesting that one of the isoforms of P450nor (P450norA) is in anaerobic mitochondrion of F. oxysporum and acts as nitric oxide reductase. Furthermore, these findings suggest the involvement of P450nor in nitrate respiration in mitochondria.     

Transient-state and steady-state kinetic studies of the mechanism of NADH-dependent aldehyde reduction catalyzed by xylose reductase from the yeast Candida tenuis

Microbial xylose reductase, a representative aldo-keto reductase of primary sugar metabolism, catalyzes the NAD(P)H-dependent reduction of D-xylose with a turnover number approximately 100 times that of human aldose reductase for the same reaction. To determine the mechanistic basis for that physiologically relevant difference and pinpoint features that are unique to the microbial enzyme among other aldo/keto reductases, we carried out stopped-flow studies with wild-type xylose reductase from the yeast Candida tenuis. Analysis of transient kinetic data for binding of NAD(+) and NADH, and reduction of D-xylose and oxidation of xylitol at pH 7.0 and 25 degrees C provided estimates of rate constants for the following mechanism: E + NADH right arrow over left arrow E.NADH right arrow over left arrow E.NADH + D-xylose right arrow over left arrow E.NADH.D-xylose right arrow over left arrow E.NAD(+).xylitol right arrow over left arrow E.NAD(+) right arrow over left arrow E.NAD(+) right arrow over left arrow E + NAD(+). The net rate constant of dissociation of NAD(+) is approximately 90% rate limiting for k(cat) of D-xylose reduction. It is controlled by the conformational change which precedes nucleotide release and whose rate constant of 40 s(-)(1) is 200 times that of completely rate-limiting E.NADP(+) --> E.NADP(+) step in aldehyde reduction catalyzed by human aldose reductase [Grimshaw, C. E., et al. (1995) Biochemistry 34, 14356-14365]. Hydride transfer from NADH occurs with a rate constant of approximately 170 s(-1). In reverse reaction, the E.NADH --> E.NADH step takes place with a rate constant of 15 s(-1), and the rate constant of ternary-complex interconversion (3.8 s(-1)) largely determines xylitol turnover (0.9 s(-1)). The bound-state equilibrium constant for C. tenuis xylose reductase is estimated to be approximately 45 (=170/3.8), thus greatly favoring aldehyde reduction. Formation of productive complexes, E.NAD(+) and E.NADH, leads to a 7- and 9-fold decrease of dissociation constants of initial binary complexes, respectively, demonstrating that 12-fold differential binding of NADH (K(i) = 16 microM) vs NAD(+) (K(i) = 195 microM) chiefly reflects difference in stabilities of E.NADH and E.NAD(+). Primary deuterium isotope effects on k(cat) and k(cat)/K(xylose) were, respectively, 1.55 +/- 0.09 and 2.09 +/- 0.31 in H(2)O, and 1.26 +/- 0.06 and 1.58 +/- 0.17 in D(2)O. No deuterium solvent isotope effect on k(cat)/K(xylose) was observed. When deuteration of coenzyme selectively slowed the hydride transfer step, (D)()2(O)(k(cat)/K(xylose)) was inverse (0.89 +/- 0.14). The isotope effect data suggest a chemical mechanism of carbonyl reduction by xylose reductase in which transfer of hydride ion is a partially rate-limiting step and precedes the proton-transfer step.     

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.     

Covalently crosslinked complexes of bovine adrenodoxin with adrenodoxin reductase and cytochrome P450scc. Mass spectrometry and Edman degradation of complexes of the steroidogenic hydroxylase system.

NADPH-dependent adrenodoxin reductase, adrenodoxin and several diverse cytochromes P450 constitute the mitochondrial steroid hydroxylase system of vertebrates. During the reaction cycle, adrenodoxin transfers electrons from the FAD of adrenodoxin reductase to the heme iron of the catalytically active cytochrome P450 (P450scc). A shuttle model for adrenodoxin or an organized cluster model of all three components has been discussed to explain electron transfer from adrenodoxin reductase to P450. Here, we characterize new covalent, zero-length crosslinks mediated by 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide between bovine adrenodoxin and adrenodoxin reductase, and between adrenodoxin and P450scc, respectively, which allow to discriminate between the electron transfer models. Using Edman degradation, mass spectrometry and X-ray crystallography a crosslink between adrenodoxin reductase Lys27 and adrenodoxin Asp39 was detected, establishing a secondary polar interaction site between both molecules. No crosslink exists in the primary polar interaction site around the acidic residues Asp76 to Asp79 of adrenodoxin. However, in a covalent complex of adrenodoxin and P450scc, adrenodoxin Asp79 is involved in a crosslink to Lys403 of P450scc. No steroidogenic hydroxylase activity could be detected in an adrenodoxin -P450scc complex/adrenodoxin reductase test system. Because the acidic residues Asp76 and Asp79 belong to the binding site of adrenodoxin to adrenodoxin reductase, as well as to the P450scc, the covalent bond within the adrenodoxin-P450scc complex prevents electron transfer by a putative shuttle mechanism. Thus, chemical crosslinking provides evidence favoring the shuttle model over the cluster model for the steroid hydroxylase system.     

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.     

Olefin oxidation by cytochrome P-450: evidence for group migration in catalytic intermediates formed with vinylidene chloride and trans-1-phenyl-1-butene

Oxidation of the carcinogen vinylidene chloride (VDC) by rat liver cytochrome P-450 (P-450) in microsomal and purified enzyme systems produced both ClCH2CO2H and Cl2CHCHO with concomitant suicide inactivation of three of the eight P-450 isozymes examined. The proposed intermediary role of VDC oxide in ClCH2CO2H and Cl2CHCHO production was evaluated by using chemical and kinetic studies. Aqueous decomposition of authentic VDC oxide, prepared by m-chloroperoxybenzoic acid oxidation of VDC and characterized by nuclear magnetic resonance (NMR) and mass spectrometry, failed to produce Cl2CHCHO and yielded ClCH2CO2H only at pH less than 2. Moreover, kinetic studies of VDC oxide production in the iodosobenzene-supported oxidation of VDC by P-450 did not support its proposed role as an obligate intermediate in the formation of ClCH2CO2H and Cl2CHCHO. [2,2-2H2]VDC was synthesized and found to be oxidized to Cl2C2HCO2H by microsomes supplemented with aldehyde dehydrogenase and NAD+, indicating transfer of deuterium in the formation of the precursor Cl2C2HC2HO. To test the hypothesis that the heme Fe(III) of P-450 acts as a Lewis acid in catalyzing the rearrangement of a transient epoxide intermediate to Cl2CHCHO, the decomposition of VDC oxide in the presence of Fe(III) was studied. While FeBr3-saturated CHCl3 effected approximately 50% rearrangement of epoxide to Cl2CHCHO, neither an equivalent concentration of (meso-tetraphenylporphyrinato)iron(III) chloride in CHCl3 nor highly purified cytochrome P-450 in aqueous buffer produced Cl2CHCHO from VDC oxide. Parallel studies using trans-1-phenylbutene 1,2-oxide, a stable model epoxide, indicated that, although binding of epoxide to P-450 did occur, ferric P-450 did not catalyze epoxide degradation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Rhodococcus L-phenylalanine dehydrogenase: kinetics, mechanism, and structural basis for catalytic specificity

Phenylalanine dehydrogenase catalyzes the reversible, pyridine nucleotide-dependent oxidative deamination of L-phenylalanine to form phenylpyruvate and ammonia. We have characterized the steady-state kinetic behavior of the enzyme from Rhodococcus sp. M4 and determined the X-ray crystal structures of the recombinant enzyme in the complexes, E.NADH.L-phenylalanine and E.NAD(+). L-3-phenyllactate, to 1.25 and 1.4 A resolution, respectively. Initial velocity, product inhibition, and dead-end inhibition studies indicate the kinetic mechanism is ordered, with NAD(+) binding prior to phenylalanine and the products' being released in the order of ammonia, phenylpyruvate, and NADH. The enzyme shows no activity with NADPH or other 2'-phosphorylated pyridine nucleotides but has broad activity with NADH analogues. Our initial structural analyses of the E.NAD(+).phenylpyruvate and E.NAD(+). 3-phenylpropionate complexes established that Lys78 and Asp118 function as the catalytic residues in the active site [Vanhooke et al. (1999) Biochemistry 38, 2326-2339]. We have studied the ionization behavior of these residues in steady-state turnover and use these findings in conjunction with the structural data described both here and in our first report to modify our previously proposed mechanism for the enzymatic reaction. The structural characterizations also illuminate the mechanism of the redox specificity that precludes alpha-amino acid dehydrogenases from functioning as alpha-hydroxy acid dehydrogenases.     

Denitrification by the fungus Cylindrocarpon tonkinense: anaerobic cell growth and two isozyme forms of cytochrome P-450nor.

We examined the denitrification system of the fungus Cylindrocapon tonkinense and found several properties distinct from those of the denitrification system of Fusarium oxysporum. C. tonkinense could form N2O from nitrite under restricted aeration but could not reduce nitrate by dissimilatory metabolism. Nitrite-dependent N2O formation and/or cell growth during the anaerobic culture was not affected by further addition of ammonium ions but was suppressed by respiration inhibitors such as rotenone or antimycin, suggesting that denitrification plays a physiological role in respiration. Dissimilatory nitrite reductase and nitric oxide reductase (Nor) activities could not be detected in cell extracts of the denitrifying cells. The Nor activity was purified and found to depend upon two isoenzymes of Cytochrome P-450nor (P-450nor), which were designated P-450nor1 and P-450nor2. These isozymes differed in the N-terminal amino acid sequence, isoelectric point, specificity to the reduced pyridine nucleotide (NADH or NADPH), and the reactivity to the antibody to P-450nor of F. oxysporum. the difference between the specificities to NADH and NADPH suggests that P-450nor1 and P-450nor2 play different roles in anaerobic energy acquisition.