Comparison of highly purified sheep liver and lung NADPH-cytochrome P-450 reductases by the analysis of kinetic and catalytic properties

1. Reductase was purified to electrophoretic homogeneity from sheep liver and lung microsomes. The specific activity of both enzymes ranged from 55 to 66 mumol cytochrome c reduced/min/mg protein. 2. Liver and lung reductases appeared to have similar kinetic and spectral properties. Km (NADPH) and Km (cytochrome c) values were calculated to be 14.3 +/- 1.23 microM and 22.2 +/- 2.78 microM for liver and 11.1 +/- 0.70 microM and 20.0 +/- 2.15 microM for lung reductase, respectively. Kinetic studies showed that cytochrome c can bind the oxidized form of the enzyme as well as its reduced form and both reductases operated through a ping-pong type mechanism. 3. These reductases cannot be distinguished on the basis of monomer molecular weights (Mr 78,000) except that the liver reductase was found to be more susceptible to proteolytic attack. 4. Both reductases supported aniline 4-hydroxylation and ethylmorphine N-demethylation reactions to the same extent in the reconstituted systems. However, sheep lung reductase appeared only 36.5 and 14.8% as effective in catalyzing benzo[a]pyrene reaction as an equivalent amount of reductase from liver in the presence of liver cytochrome P-450 and 3MC-treated rat liver cytochrome P-448, respectively.     

Heme ligation and conformational plasticity in the isolated c domain of cytochrome cd1 nitrite reductase

The heme ligation in the isolated c domain of Paracoccus pantotrophus cytochrome cd(1) nitrite reductase has been characterized in both oxidation states in solution by NMR spectroscopy. In the reduced form, the heme ligands are His69-Met106, and the tertiary structure around the c heme is similar to that found in reduced crystals of intact cytochrome cd1 nitrite reductase. In the oxidized state, however, the structure of the isolated c domain is different from the structure seen in oxidized crystals of intact cytochrome cd1, where the c heme ligands are His69-His17. An equilibrium mixture of heme ligands is present in isolated oxidized c domain. Two-dimensional exchange NMR spectroscopy shows that the dominant species has His69-Met106 ligation, similar to reduced c domains. This form is in equilibrium with a high-spin form in which Met106 has left the heme iron. Melting studies show that the midpoint of unfolding of the isolated c domain is 320.9 +/- 1.2 K in the oxidized and 357.7 +/- 0.6 K in the reduced form. The thermally denatured forms are high-spin in both oxidation states. The results reveal how redox changes modulate conformational plasticity around the c heme and show the first key steps in the mechanism that lead to ligand switching in the holoenzyme. This process is not solely a function of the properties of the c domain. The role of the d1 heme in guiding His17 to the c heme in the oxidized holoenzyme is discussed.     

Purification of a hexaheme cytochrome c552 from Escherichia coli K 12 and its properties as a nitrite reductase

Anaerobic cytochrome c552 was purified to electrophoretic homogeneity by ion-exchange chromatography and gel filtration from a mutant of Escherichia coli K 12 that synthesizes an increased amount of this pigment. Several molecular and enzymatic properties of the cytochrome were investigated. Its relative molecular mass was determined to be 69 000 by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. It was found to be an acidic protein that existed in the monomeric form in the native state. From its heme and iron contents, it was concluded to be a hexaheme protein containing six moles of heme c/mole protein. The amino-acid composition and other properties of the purified cytochrome c552 indicated its similarity to Desulfovibrio desulfuricans hexaheme cytochrome. The cytochrome c552 showed nitrite and hydroxylamine reductase activities with benzyl viologen as an artificial electron donor. It catalyzed the reduction of nitrite to ammonia in a six-electron transfer. FMN and FAD also served as electron donors for the nitrite reduction. The apparent Michaelis constants for nitrite and hydroxylamine were 110 microM and 18 mM, respectively. The nitrite reductase activity of the cytochrome c552 was inhibited effectively by cupric ion and cyanide.     

Cytochrome c peroxidase activity of a protease-modified form of cytochrome c-552 from the denitrifying bacterium Pseudomonas perfectomarina

Protease activity present in aerobically grown cells of Pseudomonas perfectomarina, protease apparently copurified with cytochrome c-552, and trypsin achieved a limited proteolysis of the diheme cytochrome c-552. That partial lysis conferred cytochrome c peroxidase activity upon cytochrome c-552. The removal of a 4000-Da peptide explains the structural changes in the cytochrome c-552 molecule that resulted in the appearance of both cytochrome c peroxidase activity (with optimum activity at pH 8.6) and a high-spin heme iron. The oxidized form of the modified cytochrome c-552 bound cyanide to the high-spin ferric heme with a rate constant of (2.1 +/- 0.1) X 10(3) M-1 s-1. The dissociation constant was 11.2 microM. Whereas the intact cytochrome c-552 molecule can be half-reduced by ascorbate, the cytochrome c peroxidase was not reducible by ascorbate, NADH, ferrocyanide, or reduced azurin. Dithionite reduced the intact protein completely but only half-reduced the modified form. The apparent second-order rate constant for dithionite reduction was (7.1 +/- 0.1) X 10(2) M-1 s-1 for the intact protein and (2.2 +/- 0.1) X 10(3) M-1 s-1 for the modified form. In contrast with other diheme cytochrome c peroxidases, reduction of the low-spin heme was not necessary to permit ligand binding by the high-spin heme iron.     

Characterization of purified cytochrome c1 from Rhodobacter sphaeroides R-26

Cytochrome c1 from a photosynthetic bacterium Rhodobacter sphaeroides R-26 has been purified to homogeneity. The purified protein contains 30 nmol heme per mg protein, has an isoelectric point of 5.7, and is soluble in aqueous solution in the absence of detergents. The apparent molecular weight of this protein is about 150,000, determined by Bio Gel A-0.5 m column chromatography; a minimum molecular weight of 30,000 is obtained by sodium dodecylsulfate polyacrylamide gel electrophoresis. The absorption spectrum of this cytochrome is similar to that of mammalian cytochrome c1, but the amino acid composition and circular dichroism spectral characteristics are different. The heme moiety of cytochrome c1 is more exposed than is that of mammalian cytochrome c1, but less exposed than that of cytochrome c2. Ferricytochrome c1 undergoes photoreduction upon illumination with light under anaerobic conditions. Such photoreduction is completely abolished when p-chloromercuriphenylsulfonate is added to ferricytochrome c1, suggesting that the sulfhydryl groups of cytochrome c1 are the electron donors for photoreduction. Purified cytochrome c1 contains 3 +/- 0.1 mol of the p-chloromercuriphenylsulfonate titratable sulfhydryl groups per mol of protein. In contrast to mammalian cytochrome c1, the bacterial protein does not form a stable complex with cytochrome c2 or with mammalian cytochrome c at low ionic strength. Electron transfer between bacterial ferrocytochrome c1 and bacterial ferricytochrome c2, and between bacterial ferrocytochrome c1 and mammalian ferricytochrome c proceeds rapidly with equilibrium constants of 49 and 3.5, respectively. The midpoint potential of purified cytochrome c1 is calculated to be 228 mV, which is identical to that of mammalian cytochrome c1.     

Cytochrome c nitrite reductase from Wolinella succinogenes. Structure at 1.6 A resolution, inhibitor binding, and heme-packing motifs

Cytochrome c nitrite reductase catalyzes the 6-electron reduction of nitrite to ammonia. This second part of the respiratory pathway of nitrate ammonification is a key step in the biological nitrogen cycle. The x-ray structure of the enzyme from the epsilon-proteobacterium Wolinella succinogenes has been solved to a resolution of 1.6 A. It is a pentaheme c-type cytochrome whose heme groups are packed in characteristic motifs that also occur in other multiheme cytochromes. Structures of W. succinogenes nitrite reductase have been obtained with water bound to the active site heme iron as well as complexes with two inhibitors, sulfate and azide, whose binding modes and inhibitory functions differ significantly. Cytochrome c nitrite reductase is part of a highly optimized respiratory system found in a wide range of Gram-negative bacteria. It reduces both anionic and neutral substrates at the distal side of a lysine-coordinated high-spin heme group, which is accessible through two different channels, allowing for a guided flow of reaction educt and product. Based on sequence comparison and secondary structure prediction, we have demonstrated that cytochrome c nitrite reductases constitute a protein family of high structural similarity.     

Coupled spectrofluorometric assay for aminoglycoside phosphotransferases

In order to make accurate kinetic measurements for the substrates of aminoglycoside (AG) phosphotransferases (APHs), we have developed an assay which overcomes many of the limitations of currently used assays. We have adapted the coupled spectrophotometric assay (P. R. Goldman and D. B. Northrop (1976) Biochem. Biophys. Res. Commun. 68, 230-236) for use in a spectrofluorometer. At an excitation wavelength of 340 nm, NADH will emit an intensity peak at 450 nm; NAD does not emit under these conditions. Our assay can accurately measure differences of 0.25 microM. For the APH(3')-II encoded on Tn5, we have redetermined the Km's for the AGs, amikacin (AK), kanamycin (KM), and ribostamycin (Rib), and for ATP. Our values for AK (76 microM) were lower than those derived from the spectrophotometric assay; for KM and Rib we obtained Km values of 5.1 and 3.6 microM, respectively. These values were well below the limit of accuracy (10 microM) for the spectrophotometric assay. In addition, we have begun characterization of an APH from a clinical isolate with a low Km for AK. Thus far, we have determined that this enzyme has Km's of approximately 1 microM for both AK and KM. These results show that the assay is well suited for accurate determinations of kinetic constants for low Km substrates of APH enzymes.     

Fungal heme oxygenases: Functional expression and characterization of Hmx1 from Saccharomyces cerevisiae and CaHmx1 from Candida albicans

Heme oxygenases convert heme to free iron, CO, and biliverdin. Saccharomyces cerevisiae and Candida albicans express putative heme oxygenases that are required for the acquisition of iron from heme, a critical process for fungal survival and virulence. The putative heme oxygenases Hmx1 and CaHmx1 from S. cerevisiae and C. albicans, respectively, minus the sequences coding for C-terminal membrane-binding domains, have been expressed in Escherichia coli. The C-terminal His-tagged, truncated enzymes are obtained as soluble, active proteins. Purified ferric Hmx1 and CaHmx1 have Soret absorption maxima at 404 and 410 nm, respectively. The apparent heme binding Kd values for Hmx1 and CaHmx1 are 0.34 +/- 0.09 microM and 1.0 +/- 0.2 microM, respectively. The resonance Raman spectra of Hmx1 reveal a heme binding pocket similar to those of the mammalian and bacterial heme oxygenases. Several reductants, including ascorbate, yeast cytochrome P450 reductase (CPR), human CPR, spinach ferredoxin/ferredoxin reductase, and putidaredoxin/putidaredoxin reductase, are able to provide electrons for biliverdin production by Hmx1 and CaHmx1. Of these, ascorbate is the most effective reducing partner. Heme oxidation by Hmx1 and CaHmx1 regiospecifically produces biliverdin IXalpha. Spectroscopic analysis of aerobic reactions with H2O2 identifies verdoheme as a reaction intermediate. Hmx1 and CaHmx1 are the first fungal heme oxygenases to be heterologously overexpressed and characterized. Their heme degradation activity is consistent with a role in iron acquisition.     

Biochemical characterization of rat P450 2C11 fused to rat or bacterial NADPH-P450 reductase domains

cDNAs coding for rat P450 2C11 fused to either a bacterial (the NADPH-cytochrome P450 BM3 reductase domain of P450 BM3) or a truncated form of rat NADPH-P450 reductases were expressed in Escherichia coli and characterized enzymatically. Measurements of NADPH cytochrome c reductase activity showed fusion-dependent increases in the rates of cytochrome c reduction by the bacterial or the mammalian flavoprotein (21 and 48%, respectively, of the rates observed with nonfused enzymes). Neither the bacterial flavoprotein nor the truncated rat reductase supported arachidonic acid metabolism by P450 2C11. In contrast, fusion of P450 2C11 to either reductase yielded proteins that metabolized arachidonic acid to products similar to those obtained with reconstituted systems containing P450 2C11 and native rat P450 reductase. Addition of a 10-fold molar excess of rat P450 reductase markedly increased the rates of metabolism by both fused and nonfused P450s 2C11. These increases occurred with preservation of the regioselectivity of arachidonic acid metabolism. The fusion-independent reduction of P450 2C11 by bacterial P450 BM3 reductase was shown by measurements of NADPH-dependent H(2)O(2) formation [73 +/- 10 and 10 +/- 1 nmol of H(2)O(2) formed min(-)(1) (nmol of P450)(-)(1) for the reconstituted and fused protein systems, respectively]. These studies demonstrate that (a) a self-sufficient, catalytically active arachidonate epoxygenase can be constructed by fusing P450 2C11 to mammalian or bacterial P450 reductases and (b) the P450 BM3 reductase interacts efficiently with mammalian P450 2C11 and catalyzes the reduction of the heme iron. However, fusion is required for metabolism and product formation.     

Activation of the cytochrome cd1 nitrite reductase from Paracoccus pantotrophus. Reaction of oxidized enzyme with substrate drives a ligand switch at heme c

Cytochromes cd(1) are dimeric bacterial nitrite reductases, which contain two hemes per monomer. On reduction of both hemes, the distal ligand of heme d(1) dissociates, creating a vacant coordination site accessible to substrate. Heme c, which transfers electrons from donor proteins into the active site, has histidine/methionine ligands except in the oxidized enzyme from Paracoccus pantotrophus where both ligands are histidine. During reduction of this enzyme, Tyr(25) dissociates from the distal side of heme d(1), and one heme c ligand is replaced by methionine. Activity is associated with histidine/methionine coordination at heme c, and it is believed that P. pantotrophus cytochrome cd(1) is unreactive toward substrate without reductive activation. However, we report here that the oxidized enzyme will react with nitrite to yield a novel species in which heme d(1) is EPR-silent. Magnetic circular dichroism studies indicate that heme d(1) is low-spin Fe(III) but EPR-silent as a result of spin coupling to a radical species formed during the reaction with nitrite. This reaction drives the switch to histidine/methionine ligation at Fe(III) heme c. Thus the enzyme is activated by exposure to its physiological substrate without the necessity of passing through the reduced state. This reactivity toward nitrite is also observed for oxidized cytochrome cd(1) from Pseudomonas stutzeri suggesting a more general involvement of the EPR-silent Fe(III) heme d(1) species in nitrite reduction.     

Purification of Vibrio fischeri nitrite reductase and its characterization as a hexaheme c-type cytochrome

Dissimilatory nitrite reductase was isolated from anaerobically nitrate-grown Vibrio fischeri cells and purified to electrophoretic homogeneity. The enzyme catalyzes the six-electron reduction of nitrite to ammonia. Upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis, under either nonreducing or reducing conditions, the purified nitrite reductase migrated as a single protein band of Mr 57,000. Gel filtration chromatography revealed a native molecular weight of 58,000, indicating the enzyme as isolated to be present in the monomeric form. Purified nitrite reductase exhibited typical c-type cytochrome absorption spectra with the reduced alpha-band at 552.5 nm. Heme content analysis using the purified preparation indicated the enzyme to contain 5.5 heme c groups per molecule. Iron analysis showed the presence of 5.62 g iron atoms per mole of enzyme and no nonheme irons were detected. These results clearly indicate that, similar to the dissimilatory nitrite reductases from Desulfovibrio desulfuricans, Wolinella succinogenes, and Escherichia coli, the V. fischeri nitrite reductase is a hexaheme c-type cytochrome. Amino acid composition of V. fischeri also revealed close similarities to those of the other three hexaheme nitrite reductases previously studied. Based on this information, it is concluded that the four ammonia-forming, dissimilatory nitrite reductases isolated to date represent a homologous group of proteins with the distinct property of being hexaheme c-type cytochromes.     

A novel copper A containing menaquinol NO reductase from Bacillus azotoformans

The molecular biology and biochemistry of denitrification in gram-negative bacteria has been studied extensively. However, little is known about this process in gram-positive bacteria. We have purified the NO reductase from the cytoplasmic membrane of the gram-positive bacterium Bacillus azotoformans. The purified enzyme consists of two subunits with apparent molecular masses of 16 and 40 kDa based on SDS-PAGE. Analytical and spectroscopic determinations revealed the presence of one non-heme iron, two copper atoms and of two b-type hemes per enzyme complex. Heme c was absent. Using EPR and UV-visible spectroscopy, it was determined that one of the hemes is a low-spin heme b, in which the two axial histidine imidazole planes are positioned at an angle of 60-70 degrees. The second heme b is high-spin binding CO in the reduced state. The high-spin heme center and the non-heme iron are EPR silent. They are proposed to form a binuclear center where reduction of NO occurs. There are two novel features of this enzyme that distinguish it from other NO reductases. First, the enzyme contains copper in form of copper A, an electron carrier up to now only detected in cytochrome oxidases and nitrous oxide reductases. Second, the enzyme uses menaquinol as electron donor, whereas cytochrome c, which is the substrate of other NO reductases, is not used. Copper A and both hemes are reducible by menaquinol. This new NO reductase is thus a menaquinol:NO oxidoreductase. With respect to its prosthetic groups the B. azotoformans NO reductase is a true hybrid between copper A containing cytochrome oxidases and NO reductases present in gram-negative bacteria. It may represent the most ancient "omnipotent" progenitor of the family of heme-copper oxidases.     

Heterologous expression of an endogenous rat cytochrome b(5)/cytochrome b(5) reductase fusion protein: identification of histidines 62 and 85 as the heme axial ligands

The gene coding for expression of an endogenous soluble fusion protein comprising a b-type cytochrome-containing domain and a FAD-containing domain has been cloned from rat liver mRNA. The 1461-bp hemoflavoprotein gene corresponded to a protein of 493 residues with the heme- and FAD-containing domains comprising the amino and carboxy termini of the protein, respectively. Sequence analysis indicated the heme and flavin domains were directly analogous to the corresponding domains in microsomal cytochrome b(5) (cb5) and cytochrome b(5) reductase (cb5r), respectively. The full-length fusion protein was purified to homogeneity and demonstrated to contain both heme and FAD prosthetic groups by spectroscopic analyses and MALDI-TOF mass spectrometry. The cb5/cb5r fusion protein was able to utilize both NADPH and NADH as reductants and exhibited both NADPH:ferricyanide (k(cat) = 21.7 s(-1), K(NADPH)(m) = 1 microM. K(FeCN6)(m) = 8 microM) and NADPH:cytochrome c (k(cat) = 8.3 s(-1), K(NADPH)(m) = 1 microM. K(cyt c)(m) = 7 microM) reductase activities with a preference for NADPH as the reduced pyridine nucleotide substrate. NADPH-reduction was stereospecific for transfer of the 4R-proton and involved a hydride transfer mechanism with a kinetic isotope effect of 3.1 for NADPH/NADPD. Site-directed mutagenesis was used to examine the role of two conserved histidine residues, H62 and H85, in the heme domain segment. Substitution of either residue by alanine or methionine resulted in the production of simple flavoproteins that were effectively devoid of both heme and NAD(P)H:cytochrome c reductase activity while retaining NAD(P)H:ferricyanide activity, confirming that the former activity required a functional heme domain. These results have demonstrated that the rat cb5/cb5r fusion protein is homologous to the human variant and has identified the heme and FAD as the sites of interaction with cytochrome c and ferricyanide, respectively. Mutagenesis has confirmed the identity of both axial heme ligands which are equivalent to the corresponding residues in microsomal cytochrome b(5).     

An octaheme c-type cytochrome from Shewanella oneidensis can reduce nitrite and hydroxylamine

A c-type cytochrome from Shewanella oneidensis MR-1, containing eight hemes, has been previously designated as an octaheme tetrathionate reductase (OTR). The structure of OTR revealed that the active site contains an unusual lysine-ligated heme, despite the presence of a CXXCH motif in the sequence that would predict histidine ligation. This lysine ligation has been previously observed only in the pentaheme nitrite reductases, suggesting that OTR may have a possible role in nitrite reduction. We have now shown that OTR is an efficient nitrite and hydroxylamine reductase and that ammonium ion is the product. These results indicate that OTR may have a role in the biological nitrogen cycle.     

A cytochrome cd 1-type nitrite reductase mediates the first step of denitrification in Alcaligenes eutrophus

Respiratory nitrite reductase (NIR) has been purified from the soluble extract of denitrifying cells of Alcaligenes eutrophus strain H16 to apparent electrophoretic homogeneity. The enzyme was induced under anoxic conditions in the presence of nitrite. Purified NIR showed typical features of a cytochrome cd ₁-type nitrite reductase. It appeared to be a dimer of 60 kDa subunits, its activity was only weakly inhibited by the copper chelator diethyldithiocarbamate, and spectral analysis revealed absorption maxima which were characteristic for the presence of heme c and heme d ₁. The isoelectric point of 8.6 was considerably higher than the pI determined for cd ₁ nitrite reductases from pseudomonads. Eighteen amino acids at the N-terminus of the A. eutrophus NIR, obtained by protein sequencing, showed no significant homology to the N-terminal region of nitrite reductases from Pseudomonas stutzeri and Pseudomonas aeruginosa.     

Electrochemical, FT-IR and UV/VIS spectroscopic properties of the caa3 oxidase from T. thermophilus.

The caa3-oxidase from Thermus thermophilus has been studied with a combined electrochemical, UV/VIS and Fourier-transform infrared (FT-IR) spectroscopic approach. In this oxidase the electron donor, cytochrome c, is covalently bound to subunit II of the cytochrome c oxidase. Oxidative electrochemical redox titrations in the visible spectral range yielded a midpoint potential of -0.01 +/- 0.01 V (vs. Ag/AgCl/3m KCl, 0.218 V vs. SHE') for the heme c. This potential differs for about 50 mV from the midpoint potential of isolated cytochrome c, indicating the possible shifts of the cytochrome c potential when bound to cytochrome c oxidase. For the signals where the hemes a and a3 contribute, three potentials, = -0.075 V +/- 0.01 V, Em2 = 0.04 V +/- 0.01 V and Em3 = 0.17 V +/- 0.02 V (0.133, 0.248 and 0.378 V vs. SHE', respectively) could be obtained. Potential titrations after addition of the inhibitor cyanide yielded a midpoint potential of -0.22 V +/- 0.01 V for heme a3-CN- and of Em2 = 0.00 V +/- 0.02 V and Em3 = 0.17 V +/- 0.02 V for heme a (-0.012 V, 0.208 V and 0.378 V vs. SHE', respectively). The three phases of the potential-dependent development of the difference signals can be attributed to the cooperativity between the hemes a, a3 and the CuB center, showing typical behavior for cytochrome c oxidases. A stronger cooperativity of CuB is discussed to reflect the modulation of the enzyme to the different key residues involved in proton pumping. We thus studied the FT-IR spectroscopic properties of this enzyme to identify alternative protonatable sites. The vibrational modes of a protonated aspartic or glutamic acid at 1714 cm-1 concomitant with the reduced form of the protein can be identified, a mode which is not present for other cytochrome c oxidases. Furthermore modes at positions characteristic for tyrosine vibrations have been identified. Electrochemically induced FT-IR difference spectra after inhibition of the sample with cyanide allows assigning the formyl signals upon characteristic shifts of the nu(C=O) modes, which reflect the high degree of similarity of heme a3 to other typical heme copper oxidases. A comparison with previously studied cytochrome c oxidases is presented and on this basis the contributions of the reorganization of the polypeptide backbone, of individual amino acids and of the hemes c, a and a3 upon electron transfer to/from the redox active centers discussed.     

Peroxidase activity of octaheme nitrite reductases from bacteria of the <Emphasis Type="Italic">Thioalkalivibrio</Emphasis> genus

Closely related penta- and octaheme nitrite reductases catalyze the reduction of nitrite, nitric oxide, and hydroxylamine to ammonium and of sulfite to sulfide. NrfA pentaheme nitrite reductase plays the key role in anaerobic nitrate respiration and the protection of bacterial cells from stresses caused by nitrogen oxides and hydrogen peroxide. Octaheme nitrite reductases from bacteria of the Thioalkalivibrio genus are less studied, and their function in the cell is unknown. In order to estimate the possible role of octaheme nitrite reductases in the cell resistance to oxidative stress, the peroxidase activity of the enzyme from T. nitratireducens (TvNiR) has been studied in detail. Comparative analysis of the active site structure of TvNiR and cytochrome c peroxidases has shown some common features, such as a five-coordinated catalytic heme and identical catalytic residues in active sites. A model of the possible productive binding of peroxide at the active site of TvNiR has been proposed. The peroxidase activity has been measured for TvNiR hexamers and trimers under different conditions (pH, buffers, the addition of CaCl₂ and EDTA). The maximum peroxidase activity of TvNiR with ABTS as a substrate (k _cat = 17 s^–1; k _cat/K _m = 855 mM^–1 s^–1) has been 100–300 times lower than the activity of natural peroxidases. The different activities of TvNiR trimers and hexamers indicate that the rate-limiting stage of the reaction is not the catalytic event at the active site but the electron transfer along the heme c electron-transport chain.     

Reduction of cytochrome c peroxidase compounds I and II by ferrocytochrome c. A stopped-flow kinetic investigation

The oxidation of yeast cytochrome c peroxidase by hydrogen peroxide produces a unique enzyme intermediate, cytochrome c peroxidase Compound I, in which the ferric heme iron has been oxidized to an oxyferryl state, Fe(IV), and an amino acid residue has been oxidized to a radical state. The reduction of cytochrome c peroxidase Compound I by horse heart ferrocytochrome c is biphasic in the presence of excess ferrocytochrome c as cytochrome c peroxidase Compound I is reduced to the native enzyme via a second enzyme intermediate, cytochrome c peroxidase Compound II. In the first phase of the reaction, the oxyferryl heme iron in Compound I is reduced to the ferric state producing Compound II which retains the amino acid free radical. The pseudo-first order rate constant for reduction of Compound I to Compound II increases with increasing cytochrome c concentration in a hyperbolic fashion. The limiting value at infinite cytochrome c concentration, which is attributed to the intracomplex electron transfer rate from ferrocytochrome c to the heme site in Compound I, is 450 +/- 20 s-1 at pH 7.5 and 25 degrees C. Ferricytochrome c inhibits the reaction in a competitive manner. The reduction of the free radical in Compound II is complex. At low cytochrome c peroxidase concentrations, the reduction rate is 5 +/- 3 s-1, independent of the ferrocytochrome c concentration. At higher peroxidase concentrations, a term proportional to the square of the Compound II concentration is involved in the reduction of the free radical. Reduction of Compound II is not inhibited by ferricytochrome c. The rates and equilibrium constant for the interconversion of the free radical and oxyferryl forms of Compound II have also been determined.     

The reaction of Pseudomonas nitrite reductase and nitrite. A stopped-flow and EPR study

The reaction between reduced Pseudomonas nitrite reductase and nitrite has been studied by stopped-flow and rapid-freezing EPR spectroscopy. The interpretation of the kinetics at pH 8.0 is consistent with the following reaction mechanism (where k1 and k3 much greater than k2). [formula: see text] The bimolecular step (Step 1) is very fast, being lost in the dead time of a rapid mixing apparatus; the stoichiometry of the complex has been estimated to correspond to one NO2- molecule/heme d1. The final species is the fully reduced enzyme with NO bound to heme d1; and at all concentrations of nitrite, there is no evidence for dissociation of NO or for further reduction of NO to N2O. Step 2 is assigned to an internal electron transfer from heme c to reduced NO-bound heme d1 occurring with a rate constant of 1 s-1; this rate is comparable to the rate of internal electron transfer previously determined when reducing the oxidized enzyme with azurin or cytochrome c551. When heme d1 is NO-bound, the rate at which heme c can accept electrons from ascorbate is remarkably increased as compared to the oxidized enzyme, suggesting an increase in the redox potential of the latter heme.