Type 1, blue copper proteins constitute a respiratory nitrite-reducing system in Pseudomonas aureofaciens

Pseudomonas aureofaciens truncates the respiratory reduction of nitrate (denitrification) at the level of N2O. The nitrite reductase from this organism was purified to apparent electrophoretic homogeneity and found to be a blue copper protein. The enzyme contained 2 atoms of copper/85 kDa, both detectable by electron paramagnetic resonance (EPR) spectroscopy. The protein was dimeric, with subunits of identical size (40 +/- 3 kDa). Its pI was 6.05. The EPR spectrum showed an axial signal g at 2.21(8) and g at 2.04(5). The magnitude of the hyperfine splitting (A parallel = 6.36 mT) indicated the presence of type 1 copper only. The electronic spectrum had maxima at 280 nm, 474 nm and 595 nm (epsilon = 7.0 mM-1 cm-1), and a broad shoulder around 780 nm. A copper protein of low molecular mass (15 kDa), with properties similar to azurin, was also isolated from P. aureofaciens. The electronic spectrum of this protein showed a maximum at 624 nm in the visible range (epsilon = 2.5 mM-1 cm-1) and pronounced structures in the ultraviolet region. The EPR parameters were g parallel = 2.26(6) and g perpendicular = 2.05(6), with A parallel = 5.8 mT. The reduced azurin transferred electrons efficiently to nitrite reductase; the product of nitrite reduction was nitric oxide. The specific nitrite-reducing activity with ascorbate-reduced phenazine methosulfate as electron donor was 1 mumol substrate min-1 mg protein-1. The reaction product again was nitric oxide. Nitrous oxide was the reaction product from hydroxylamine and nitrite and from dithionite-reduced methyl viologen and nitrite. No 'oxidase' activity could be demonstrated for the enzyme. Our data disprove the presumed exclusiveness of cytochrome cd1 as nitrite reductase within the genus Pseudomonas.     

Interaction of nitric oxide with cytochrome P450 BM3

The interaction of nitric oxide with cytochrome P450 BM3 from Bacillus megaterium has been analyzed by spectroscopic techniques and enzyme assays. Nitric oxide ligates tightly to the ferric heme iron, inducing large changes in each of the main visible bands of the heme and inhibiting the fatty acid hydroxylase function of the protein. However, the ferrous adduct is unstable under aerobic conditions, and activity recovers rapidly after addition of NADPH to the flavocytochrome due to reduction of the heme via the reductase domain and displacement of the ligand. The visible spectral properties revert to that of the oxidized resting form. Aerobic reduction of the nitrosyl complex of the BM3 holoenzyme or heme domain by sodium dithionite also displaces the ligand. A single electron reduction destabilizes the ferric-nitrosyl complex such that nitric oxide is released directly, as shown by the trapping of released nitric oxide. Aerobically and in the absence of exogenous reductant, nitric oxide dissociates completely from the P450 over periods of several minutes. However, recovery of the nativelike visible spectrum is accompanied by alterations in the catalytic activity of the enzyme and changes in the resonance Raman spectrum. Specifically, resonance Raman spectroscopy identifies the presence of internally located nitrated tyrosine residue(s) following treatment with nitric oxide. Analysis of a Y51F mutant indicates that this is the major nitration target under these conditions. While wild-type P450 BM3 does not form an aerobically stable ferrous-nitrosyl complex, a site-directed mutant of P450 BM3 (F393H) does form an isolatable ferrous-nitrosyl complex, providing strong evidence for the role of this residue in controlling the electronic properties of the heme iron. We report here the spectroscopic characterization of the ferric- and ferrous-nitrosyl complexes of P450 BM3 and describe the use of resonance Raman spectroscopy to identify nitrated tyrosine residue(s) in the enzyme. Nitration of tyrosine in P450 BM3 may exemplify a typical mechanism by which the ubiquitous messenger molecule nitric oxide exerts a regulatory function over the cytochromes P450.     

The Structure of an alternative form of Paracoccus pantotrophus cytochrome cd(1) nitrite reductase

Cytochrome cd(1) nitrite reductase is a bifunctional enzyme, which can catalyze the 1-electron reduction of nitrite to nitric oxide and the 4-electron reduction of dioxygen to water. Here we describe the structure of reduced nitrite reductase, crystallized under anaerobic conditions. The structure reveals substantial domain rearrangements with the c domain rotated by 60 degrees and shifted by approximately 20 A compared with previously known structures from crystals grown under oxidizing conditions. This alternative conformation gives rise to different electron transfer routes between the c and d(1) domains and points to the involvement of elements of very large structural changes in the function in this enzyme. In the present structure, the c heme has a His-69/Met-106 ligation, and this ligation does not change upon oxidation in the crystal. The d(1) heme is penta-coordinated, and the d(1) iron is displaced from the heme plane by 0.5 A toward the proximal ligand, His-200. After oxidation, the iron moves into the d(1) heme plane. A surprising finding is that although reduced nitrite reductase can be readily oxidized by dioxygen in the new crystal, it cannot turnover with its other substrate, nitrite. The results suggest that the rearrangement of the domains affects catalysis and substrate selectivity.     

On the purification of nitrite reductase from Thiobacillus denitrificans and its reaction with nitrite under reducing conditions.

Nitrite reductase (cytochrome $\text{cd}$) from $\text{T. denitrificans}$ has been crystallized in high yield in three simple and rapid steps. The spectral absorption ratio at 408 to 280 nm was 1.52. Light absorption spectra in the oxidized and reduced states were virtually identical to those of nitrite reductase from $\text{P. aeruginosa}$. EPR spectroscopy of nitrite reductase at 12° showed a low-spin ferric heme resonance with g-values at 2.52, 2.45 and 1.73 assigned to the d-heme. Reaction of nitrite reductase with nitrite in the presence of the reducing systems [(ascorbate + PMS) or sulfide] resulted in the formation of nitric oxide (confirmed by gas chromatography) which reacted with both $\text{c}$- and $\text{d}$-hemes of nitrite reductase yielding an EPR-detectable enzyme-NO complex with g-values at 2.07, 2.04 and 1.99 and a ¹⁴N hyperfine splitting constant of 22.5 gauss. The amount of nitric oxide produced enzymatically with sulfide as electron donor was only 5% of that found when ascorbate plus PMS served as reductant.To our knowledge the detection of the unique enzyme-NO complex is the first definitive EPR evidence for the mandatory liganding of nitric oxide with pure nitrite reductase during nitrite reduction.     

Electron-spin-resonance studies of the NADH-dependent nitrite reductase from Escherichia coli K12

The NADH-dependent nitrite reductase of Escherichia coli, which contains sirohaem, flavin, non-haem iron and labile sulphide, was examined by low-temperature e.s.r. spectroscopy. The enzyme, stored in the presence of nitrite and ascorbate, gave the spectrum of a nitrosyl derivative, with hyperfine splitting due to the nitrosyl nitrogen. On removal of these reagents, a series of signals centred around g = 6 was observed, typical of high-spin ferric haem. Cyanide converted this into a low-spin form. On reduction of the enzyme with NADH, an axial spectrum at g = 1.92, 2.01 was observed. The temperature-dependence of this signal is indicative of a [2Fe-2S] iron-sulphur cluster. The midpoint potential of this cluster was estimated to be -230 +/- 15 mV by two independent methods. Reduction of the enzyme with dithionite yielded further signals, which are at present unidentified, at g = 2.1-2.28. No signals were observed that could be assigned to a [4Fe-4S] cluster, such as is found in other sulphite reductases and nitrite reductases that contain sirohaem.     

Further Characterization of Ferredoxin Nitrite Reductase and the Relationship between the Enzyme and Methyl Viologen-dependent Nitrite Reductase

Ferredoxin-dependent nitrite reductase of spinach has been further characterized and the relationship between this enzyme and methyl viologen-dependent nitrite reductase studied.

Purified ferredoxin nitrite reductase, having a molecular weight of 86,000, showed 2.5 times higher ferredoxin-dependent activity than methyl viologen-linked activity. Besides 4 mol of labile sulfide the enzyme contained about 2 mol of siroheme per mol. When dithionite, methyl viologen and nitrite were added, ESR signals of a heme nitrosyl complex at g = 2.14, 2.07 and 2.02 were observed. Moreover, hyperfine splitting of the signal due to ¹⁴N nuclear spin was also observed at 2.033, 2.023 and 2.013. The sole addition of hydroxylamine to the ferric enzyme also caused the same but much less intense signals with the hyperfine splitting.

On treatment of the ferredoxin nitrite reductase (native enzyme) with DEAE-Sephadex A-50 chromatography, a modified nitrite reductase having a molecular weight of 61,000 and a protein fraction having an apparent molecular weight of 24,000 were separated. The modified enzyme contained about one mol of siroheme and 4 mol of labile sulfide per mol and showed essentially the same heme ESR signals as the native enzyme. Contrary to the native enzyme, this modified enzyme accepted electrons more efficiently from methyl viologen than ferredoxin and the reduction of nitrite to ammonia catalyzed by the modified enzyme was not stoichiometric. The observed nitrite to ammonia ratio was 1 to less than 0.6. Cyanide at concentrations between 0.02 to 0.2 mm inhibited the activity of the native enzyme almost completely but the modified enzyme was inhibited only partially.

From the results obtained, it is suggested that the native ferredoxin-linked nitrite reductase consists of two components (or subunits) and removal of the light component results in formation of a modified enzyme with increased relative affinity to methyl viologen.     

Nitrosylation of c heme in cd1-nitrite reductase is enhanced during catalysis

The reduction of nitrite into nitric oxide (NO) in denitrifying bacteria is catalyzed by nitrite reductase. In several species, this enzyme is a heme-containing protein with one c heme and one d₁ heme per monomer (cd₁NiR), encoded by the nirS gene.     

Oxidation of dithiothreitol during turnover of nitric oxide reductase: evidence for generation of nitroxyl with the enzyme from Paracoccus denitrificans.

The stoichiometric relationship between thiol oxidized and NO reduced was studied for the reaction catalyzed by nitric oxide reductase from Paracoccus denitrificans. The reaction systems consisted of dithiothreitol, ascorbate, phenazine methosulfate, enzyme and NO, or that system minus ascorbate. The mole ratio of thiol groups oxidized to NO reduced was observed to be 2.3 to 1.5 over a range of NO from 0.09 to 0.35 mumol. A ratio of 1.0 was expected for the simple reduction of NO by 1-electron to N2O. The oxidation of additional thiol is attributed to the trapping of nitrosyl hydride (nitroxyl, NO/NOH) by thiol.     

Isotope labeling studies on the mechanism of N-N bond formation in denitrification

The mechanism of the denitrification and nitrosation reactions catalyzed by the heme cd-containing nitrite reductase from Pseudomonas stutzeri JM 300 has been studied with whole cell suspensions using H2(18)O, 15NO, and 15NO-2. The extent of H2(18)O exchange with the enzyme-bound nitrosyl intermediate, as determined by the 18O content of product N2O, decreased with increasing nitrite concentration, which is consistent with production of N2O by sequential reaction of two nitrite ions with the enzyme. Reaction of NO with whole cells in H2(18)O gave amounts of 18O in the N2O product consistent with equilibration of nitric oxide with a small pool of free nitrite. Using 15NO and NH2OH, competition between denitrification and nitrosation reactions was demonstrated, as is required if the enzyme-nitrosyl complex is an intermediate in both nitrosation and denitrification reactions. The first evidence for exchange of 18O between H2(18)O and a nitrosation intermediate occurring after the enzyme-nitrosyl complex, presumably an enzyme-bound nitrosamine, has been obtained. The collective results are most consistent with denitrification N2O originating via attack of NO-2 on a coordinated nitrosyl, as proposed earlier (Averill, B. A., and Tiedje, J. M. (1982) FEBS Lett. 138, 8-11).     

The characterization and magnetic properties of the azide and imidazole derivatives of Pseudomonas nitrite reductase

Optical absorption, mcd, and epr spectroscopy have been used to characterize the azide and imidazole derivatives of oxidized Pseudomonas nitrite reductase. At pH 7.0 azide binds solely to heme d1 with an affinity constant, Kaff = 360 M-1, whereas imidazole binds to both hemes c and d1 with kaff = 35 and 55 M-1, respectively. Low-temperature mcd and epr spectroscopy indicate that c and d1 are low-spin ferrihemes in both derivatives, although the epr of the heme d1-azide component is very weak and requires explanation. Attempts to obtain a high-spin heme d1 in the intact enzyme using the weak field ligands fluoride and thiocyanate have proved unsuccessful. Electron paramagnetic resonance experiments involving an oxidized enzyme derivatives in which heme d1 is complexed by NO, and hence epr silent, have enabled unambiguous assignment of the epr spectrum of Pseudomonas nitrite reductase.     

Catalysis of nitrosyl transfer by denitrifying bacteria is facilitated by nitric oxide

Two denitrifying bacteria, Pseudomonas stutzeri and Achromobacter cycloclastes, were incubated with Na15NO2 and NaN3 under conditions that allowed catalysis of nitrosyl transfer from nitrite to azide. This transfer, which is presumed to be mediated by the heme- and copper-containing nitrite reductase of P. stutzeri and A. cycloclastes, respectively, leads to formation of isotopically mixed 14,15N2O, whereas denitrification leads to 15N2O. The conditions that emphasized nitrosyl transfer also partially inhibited the nitric oxide reductase system and led to accumulation of 15NO. Absorption of NO from the gas phase by acidic CrSO4 in a sidewell largely abolished nitrosyl transfer to azide. With these two organisms, which are thought to be representative of denitrifiers generally, catalysis of nitrosyl transfer seemed to depend on NO.     

Hexaheme nitrite reductase from Desulfovibrio desulfuricans. M?ssbauer and EPR characterization of the heme groups

M?ssbauer and EPR spectroscopy were used to characterize the heme prosthetic groups of the nitrite reductase isolated from Desulfovibrio desulfuricans (ATCC 27774), which is a membrane-bound multiheme cytochrome capable of catalyzing the 6-electron reduction of nitrite to ammonia. At pH 7.6, the as-isolated enzyme exhibited a complex EPR spectrum consisting of a low-spin ferric heme signal at g = 2.96, 2.28, and 1.50 plus several broad resonances indicative of spin-spin interactions among the heme groups. EPR redox titration studies revealed yet another low-spin ferric heme signal at g = 3.2 and 2.14 (the third g value was undetected) and the presence of a high-spin ferric heme. M?ssbauer measurements demonstrated further that this enzyme contained six distinct heme groups: one high-spin (S = 5/2) and five low-spin (S = 1/2) ferric hemes. Characteristic hyperfine parameters for all six hemes were obtained through a detailed analysis of the M?ssbauer spectra. D. desulfuricans nitrite reductase can be reduced by chemical reductants, such as dithionite or reduced methyl viologen, or by hydrogenase under hydrogen atmosphere. Addition of nitrite to the fully reduced enzyme reoxidized all five low-spin hemes to their ferric states. The high-spin heme, however, was found to complex NO, suggesting that the high-spin heme could be the substrate binding site and that NO could be an intermediate present in an enzyme-bound form.     

The pathway of nitrogen and reductive enzymes of denitrification

Some recent studies on the pathway of nitrogen and the reductases of denitrification are reviewed. The available evidence suggests that while the intermediates of denitrification can remain enzyme-bound (presumably to nitrite reductase) prior to formation of N₂O, NO and nitroxyl (HNO) can be released in part by certain bacteria. Release of NO is recognized by a nitrite/NO?¹⁵N exchange reaction and isotopic scrambling in product N₂O; release of nitroxyl by Pseudomonas stutzeri is recognized by isotopic scrambling of nitrite and NO in product N₂O in absence of exchange and affords evidence that the first N?N bond forms in denitrification at the N¹⁺ redox level. The recent purification and partial characterization of nitrous oxide reductase are described. The ability of the dissimilatory nitrite reductase to activate nitrite for nitrosyl transfer affords a new chemical probe into the mechanism of action of this central enzyme. It would appear that reduction of nitrite is subject to electrophilic catalysis. ¹⁸O studies show that dissociation of nitrite from nitrite reductase can be slow relative to competing reduction or nitrosyl transfer.     

Siroheme: a prosthetic group of the Neurospora crassa assimilatory nitrite reductase.

The Neurospora crassa assimilatory nitrite reductase (EC 1.6.6.4) catalyzes the NADPH-dependent reduction of nitrite to ammonia, a 6-electron transfer reaction. Highly purified preparations of this enzyme exhibit absorption spectra which suggest the presence of a heme component (wavelength maxima for oxidized senzyme: 390 and 578 nm). There is a close correspondence between nitrite reductase activity and absorbance at 400 nm when partially purified nitrite reductase preparations are subjected to sucrose gradient centrifugation. In addition, a role for an iron component in the formation of active nitrite reductase is indicated by the fact that nitrate-induced production of nitrite reductase activity in Neurospora mycelia in vivo requires the presence of iron in the induction medium. The heme chromophore present in Neurospora nitrite reductase preparations is reducible by NADPH. Complete reduction, however, requires the presence of added FAD. The NADPH-nitrite reductase activity of the enzyme is also dependent upon addition of FAD. A spectrally unique complex is formed between the heme chromophore and nitrite (or a reduction product thereof) when nitrite is added to NADPH-reducted enzyme. Carbon monoxide forms a complex with the heme chromophore of nitrite reductase with an intense alpha-band maximum at 590 nm and a beta-band of lower intensity at 550 nm. CO is an inhibitor of NADPH-nitrite reductase activity. Spectrophotometrically detectable CO complex formation and Co inhibition of enzyme activity share the following properties...     

Electron paramagnetic resonance observations on the cytochrome c-containing nitrous oxide reductase from Wolinella succinogenes.

Nitrous oxide reductase from Wolinella succinogenes, an enzyme containing one heme c and four Cu atoms/subunit of Mr = 88,000, was studied by electron paramagnetic resonance (EPR) at 9.2 GHz from 6 to 80 K. In the oxidized state, low spin ferric cytochrome c was observed with gz = 3.10 and an axial Cu resonance was observed with g parallel = 2.17 and g perpendicular = 2.035. No signals were detected at g values greater than 3.10. For the Cu resonance, six hyperfine lines each were observed in the g parallel and g perpendicular regions with average separations of 45.2 and 26.2 gauss, respectively. The hyperfine components are attributed to Cu(I)-Cu(II) S = 1/2 (half-met) centers. Reduction of the enzyme with dithionite caused signals attributable to heme c and Cu to disappear; exposure of that sample to N2O for a few min caused the reappearance of the g = 3.10 component and a new Cu signal with g parallel = 2.17 and g perpendicular = 2.055 that lacked the simple hyperfine components attributed to a single species of half-met center. The enzyme lost no activity as the result of this cycle of reduction and reoxidation. EPR provided no evidence for a Cu-heme interaction. The EPR detectable Cu in the oxidized and reoxidized forms of the enzyme comprised about 23 and 20% of the total Cu, respectively, or about one spin/subunit. The enzyme offers the first example of a nitrous oxide reductase which can have two states of high activity that present very different EPR spectra of Cu. These two states may represent enzyme in two different stages of the catalytic cycle.     

Nitric-oxide reductase. Structure and properties of the catalytic site from resonance Raman scattering

We have applied resonance Raman spectroscopy to investigate the properties of the dinuclear center of oxidized, reduced, and NO-bound nitric-oxide reductase from Paracoccus denitrificans. The spectra of the oxidized enzyme show two distinct nu(as)(Fe-O-Fe) modes at 815 and 833 cm(-1) of the heme/non-heme diiron center. The splitting of the Fe-O-Fe mode suggests that two different conformations (open and closed) are present in the catalytic site of the enzyme. We find evidence from deuterium exchange experiments that in the dominant conformation (833 cm(-1) mode, closed), the Fe-O-Fe unit is hydrogen-bonded to distal residue(s). The ferric nitrosyl complex of nitric-oxide reductase exhibits the nu(Fe(3+)-NO) and nu(N-O) at 594 and 1904 cm(-1), respectively. The nitrosyl species we detect is photolabile and can be photolyzed to generate a new form of oxidized enzyme in which the proximal histidine is ligated to heme b(3), in contrast to the resting form. Photodissociation of the NO ligand yields a five-coordinate high-spin heme b(3). Based on the findings reported here, the structure and properties of the dinuclear center of nitric- oxide reductase in the oxidized, reduced, and NO-bound form as well as its photoproduct can be described with certainty.     

A low-redox potential heme in the dinuclear center of bacterial nitric oxide reductase: implications for the evolution of energy-conserving heme-copper oxidases.

Bacterial nitric oxide reductase (NOR) catalyzes the two-electron reduction of nitric oxide to nitrous oxide. It is a highly diverged member of the superfamily of heme-copper oxidases. The main feature by which NOR is distinguished from the heme-copper oxidases is the elemental composition of the active site, a dinuclear center comprised of heme b(3) and non-heme iron (Fe(B)). The visible region electronic absorption spectrum of reduced NOR exhibits a maximum at 551 nm with a distinct shoulder at 560 nm; these are attributed to Fe(II) heme c (E(m) = 310 mV) and Fe(II) heme b (E(m) = 345 mV), respectively. The electronic absorption spectrum of oxidized NOR exhibits a characteristic shoulder around 595 nm that exhibits complex behavior in equilibrium redox titrations. The first phase of reduction is characterized by an apparent shift of the shoulder to 604 nm and a decrease in intensity. This is due to reduction of Fe(B) (E(m) = 320 mV), while the subsequent bleaching of the 604 nm band represents reduction of heme b(3) (E(m) = 60 mV). This separation of redox potentials (>200 mV) allows the enzyme to be poised in the three-electron reduced state for detailed spectroscopic examination of the Fe(III) heme b(3) center. The low midpoint potential of heme b(3) represents a thermodynamic barrier to the complete (two-electron) reduction of the dinuclear center. This may avoid formation of a stable Fe(II) heme b(3)-NO species during turnover, which may be an inhibited state of the enzyme. It would also appear that the evolution of significant oxygen reducing activity by heme-copper oxidases was not simply a matter of the substitution of copper for non-heme iron in the dinuclear center. Changes in the protein environment that modulate the midpoint redox potential of heme b(3) to facilitate both complete reduction of the dinuclear center (a prerequisite for oxygen binding) and rapid heme-heme electron transfer were also necessary.     

Electron paramagnetic resonance and magnetic circular dichroism studies of a hexa-heme nitrite reductase from Wolinella succinogenes

The nature of the heme centers in the hexa-heme dissimilatory nitrite reductase from the bacterium Wolinella succinogenes has been investigated with EPR and magnetic circular dichroism spectroscopy. The EPR spectrum of the ferric enzyme is complex showing, in addition to magnetically isolated low-spin ferric hemes with g values of 2.93, 2.3 and 1.48, two sets of signals at g = 10.3, 3.7 and 4.8, 3.21, which we assign to two pairs of exchange coupled hemes. The MCD spectra show that the isolated hemes are bis-histidine coordinated and that there is one high-spin ferric heme. The exchange coupling is lost on treatment with SDS.     

Nitric oxide-reductase homologue that contains a copper atom and has cytochrome c-oxidase activity from an aerobic phototrophic bacterium Roseobacter denitrificans

A cytochrome cb-type enzyme with cytochrome c-oxidase activity was purified from an aerobic phototrophic bacterium Roseobacter denitrificans. The enzyme was solubilized with sucrose monodecanoate from the membranes of R. denitrificans grown aerobically under light conditions, and purified to electrophoretic homogeneity. Absorption spectra of the purified enzyme showed peaks at 410 nm and 530 nm in the oxidized state, and peaks at 420, 522, and 551 nm and a shoulder at around 560 nm in the reduced state. The enzyme is composed of two subunits with apparent molecular weights on SDS-PAGE of 37,000 and 18,000, the latter positive to heme staining. The protein contains heme c, heme b, and copper in a 1:2:1 stoichiometry. The spectral properties indicated that the heme c and one heme b are in low-spin states, while the other heme b is in a high-spin state. The base sequences of the genes and the deduced amino acid sequences are similar to those of known NorB and NorC subunits of nitric oxide reductases from other bacterial species. The enzyme is similar to nitric oxide reductase, but differs in that it contains copper. Virtually no nitric oxide reductase activity was detected in the purified enzyme.