The structure of the Met144Leu mutant of copper nitrite reductase from <Emphasis Type="Italic">Alcaligenes xylosoxidans</Emphasis> provides the first glimpse of a protein–protein complex with azurin II

Cu-containing nitrite reductases (NiRs) perform the reduction of nitrite to NO via an ordered mechanism in which the delivery of a proton and an electron to the catalytic type 2 Cu site is highly orchestrated. Electron transfer from a redox partner protein, azurin or pseudoazurin, to the type 1 Cu site is assumed to occur through the formation of a protein-protein complex. We report here a new crystal form in space group P2(1)2(1)2(1) of the Met144Leu mutant of NiR from Alcaligenes xylosoxidans (AxNiR), revealing a head-to-head packing motif involving residues around the hydrophobic patch of domain 1. Superposition of the structure of azurin II with that of domain 1 of one of the Met144Leu molecules provides the first glimpse of an azurin II-NiR protein-protein complex. Mutations of two of the residues of AxNiR, Trp138His (Barrett et al. in Biochemistry 43:16311-16319, 2004) and Met87Leu, highlighted in the AxNiR-azurin complex, results in substantially decreased activity when azurin is used as the electron donor instead of methyl viologen, providing direct evidence for the importance of this region for complex formation.     

Proton-coupled electron transfer in the catalytic cycle of Alcaligenes xylosoxidans copper-dependent nitrite reductase

We demonstrated recently that two protons are involved in reduction of nitrite to nitric oxide through a proton-coupled electron transfer (ET) reaction catalyzed by the blue Cu-dependent nitrite reductase (Cu NiR) of Alcaligenes xylosoxidans (AxNiR). Here, the functionality of two putative proton channels, one involving Asn90 and the other His254, is studied using single (N90S, H254F) and double (N90S--H254F) mutants. All mutants studied are active, indicating that protons are still able to reach the active site. The H254F mutation has no effect on the catalytic activity, while the N90S mutation results in ~70% decrease in activity. Laser flash-photolysis experiments show that in H254F and wild-type enzyme electrons enter at the level of the T1Cu and then redistribute between the two Cu sites. Complete ET from T1Cu to T2Cu occurs only when nitrite binds at the T2Cu site. This indicates that substrate binding to T2Cu promotes ET from T1Cu, suggesting that the enzyme operates an ordered mechanism. In fact, in the N90S and N90S--H254F variants, where the T1Cu site redox potential is elevated by ～60 mV, inter-Cu ET is only observed in the presence of nitrite. From these results it is evident that the Asn90 channel is the main proton channel in AxNiR, though protons can still reach the active site if this channel is disrupted. Crystallographic structures provide a clear structural rationale for these observations, including restoration of the proton delivery via a significant movement of the loop connecting the T1Cu ligands Cys130 and His139 that occurs on binding of nitrite. Notably, a role for this loop in facilitating interaction of cytochrome c(551) with Cu NiR has been suggested previously based on a crystal structure of the binary complex.     

Laser-flash photolysis indicates that internal electron transfer is triggered by proton uptake by Alcaligenes xylosoxidans copper-dependent nitrite reductase

Enzyme-catalysed electron transfer reactions are often controlled by protein motions and coupled to chemical change such as proton transfer. We have investigated the nature of this control in the blue copper-dependent nitrite reductase from Alcaligenes xylosoxidans (AxNiR). Inter-Cu electron transfer from the T1Cu site to the T2Cu catalytic site in AxNiR occurs via a proton-coupled electron transfer mechanism. Here we have studied the kinetics of both electron and proton transfer independently using laser-flash photolysis for native AxNiR and its proton-channel mutant N90S. In native AxNiR, both inter-Cu electron transfer and proton transfer exhibit similar rates, and show an unusual dependence on the nitrite concentration. An initial decrease in the observed rates at low nitrite concentrations is followed by an increase in the observed rates at high nitrite concentrations (> 5 mm). In N90S, in which the T1Cu reduction potential is elevated by 60 mV, no inter-Cu electron transfer or proton transfer was observed in the absence of nitrite. Only in the presence of nitrite were both processes detected, with similar [nitrite] dependence, but the nitrite dependence was different compared with native enzyme. The substrate dependence in N90S was similar to that observed in steady-state assays, suggesting that this substitution resulted in proton-coupled electron transfer becoming rate-limiting. A pH perturbation experiment with native AxNiR revealed that protonation triggers inter-Cu electron transfer and generation of NO. Our results show a strong coupling of inter-Cu electron transfer and proton transfer for both native AxNiR and N90S, and provide novel insights into the controlled delivery of electrons and protons to the substrate-utilization T2Cu active site of AxNiR.     

Crystallography with online optical and X-ray absorption spectroscopies demonstrates an ordered mechanism in copper nitrite reductase

Nitrite reductases are key enzymes that perform the first committed step in the denitrification process and reduce nitrite to nitric oxide. In copper nitrite reductases, an electron is delivered from the type 1 copper (T1Cu) centre to the type 2 copper (T2Cu) centre where catalysis occurs. Despite significant structural and mechanistic studies, it remains controversial whether the substrates, nitrite, electron and proton are utilised in an ordered or random manner. We have used crystallography, together with online X-ray absorption spectroscopy and optical spectroscopy, to show that X-rays rapidly and selectively photoreduce the T1Cu centre, but that the T2Cu centre does not photoreduce directly over a typical crystallographic data collection time. Furthermore, internal electron transfer between the T1Cu and T2Cu centres does not occur, and the T2Cu centre remains oxidised. These data unambiguously demonstrate an ‘ordered’ mechanism in which electron transfer is gated by binding of nitrite to the T2Cu. Furthermore, the use of online multiple spectroscopic techniques shows their value in assessing radiation-induced redox changes at different metal sites and demonstrates the importance of ensuring the correct status of redox centres in a crystal structure determination. Here, optical spectroscopy has shown a very high sensitivity for detecting the change in T1Cu redox state, while X-ray absorption spectroscopy has reported on the redox status of the T2Cu site, as this centre has no detectable optical absorption.     

Stable copper-nitrosyl formation by nitrite reductase in either oxidation state

Nitrite reductase (NiR) is an enzyme that uses type 1 and type 2 copper sites to reduce nitrite to nitric oxide during bacterial denitrification. A copper-nitrosyl intermediate is a proposed, yet poorly characterized feature of the NiR catalytic cycle. This intermediate is formally described as Cu(I)-NO+ and is proposed to be formed at the type 2 copper site after nitrite binding and electron transfer from the type 1 copper site. In this study, copper-nitrosyl complexes were formed by prolonged exposure of exogenous NO to crystals of wild-type and two variant forms of NiR from Alcaligenes faecalis (AfNiR), and the structures were determined to 1.8 A or better resolution. Exposing oxidized wild-type crystals to NO results in the reverse reaction and formation of nitrite that remains bound at the active site. In a type 1 copper site mutant (H145A) that is incapable of electron transfer to the type 2 site, the reverse reaction is not observed. Instead, in both oxidized and reduced H145A crystals, NO is observed bound in a side-on manner to the type 2 copper. In AfNiR, Asp98 forms hydrogen bonds to both substrate and product bound to the type 2 Cu. In the D98N variant, NO is bound side-on but is more disordered when observed for the wild-type enzyme. The solution EPR spectra of the crystallographically characterized NiR-NO complexes indicate the presence of an oxidized type 2 copper site and thus are interpreted as resulting from stable copper-nitrosyls and formally assigned as Cu(II)-NO-. A reaction scheme in which a second NO molecule is oxidized to nitrite can account for the formation of a Cu(II)-NO- species after exposure of the oxidized H145A variant to NO gas.     

Structural investigations of the CuA centre of nitrous oxide reductase from Pseudomonas stutzeri by site-directed mutagenesis and X-ray absorption spectroscopy.

Nitrous oxide reductase is the terminal component of a respiratory chain that utilizes N2O in lieu of oxygen. It is a homodimer carrying in each subunit the electron transfer site, CuA, and the substrate-reducing catalytic centre, CuZ. Spectroscopic data have provided robust evidence for CuA as a binuclear, mixed-valence metal site. To provide further structural information on the CuA centre of N2O reductase, site directed mutagenesis and Cu K-edge X-ray absorption spectroscopic investigation have been undertaken. Candidate amino acids as ligands for the CuA centre of the enzyme from Pseudomonas stutzeri ATCC14405 were substituted by evolutionary conserved residues or amino acids similar to the wild-type residues. The mutations identified the amino acids His583, Cys618, Cys622 and Met629 as ligands of Cu1, and Cys618, Cys622 and His626 as the minimal set of ligands for Cu2 of the CuA centre. Other amino acid substitutions indicated His494 as a likely ligand of CuZ, and an indirect role for Asp580, compatible with a docking function for the electron donor. Cu binding and spectroscopic properties of recombinant N2O reductase proteins point at intersubunit or interdomain interaction of CuA and CuZ. Cu K-edge X-ray absorption spectra have been recorded to investigate the local environment of the Cu centres in N2O reductase. Cu K-edge Extended X-ray Absorption Fine Structure (EXAFS) for binuclear Cu chemical systems show clear evidence for Cu backscattering at approximately 2.5 A. The Cu K-edge EXAFS of the CuA centre of N2O reductase is very similar to that of the CuA centre of cytochrome c oxidase and the optimum simulation of the experimental data involves backscattering from a histidine group with Cu-N of 1.92 A, two sulfur atoms at 2.24 A and a Cu atom at 2. 43 A, and allows for the presence of a further light atom (oxygen or nitrogen) at 2.05 A. The interpretation of the CuA EXAFS is in line with ligands assigned by site-directed mutagenesis. By a difference spectrum approach, using the Cu K-edge EXAFS of the holoenzyme and that of the CuA-only form, histidine was identified as a major contributor to the backscattering. A structural model for the CuA centre of N2O reductase has been generated on the basis of the atomic coordinates for the homologous domain of cytochrome c oxidase and incorporating our current results and previous spectroscopic data.     

A random-sequential mechanism for nitrite binding and active site reduction in copper-containing nitrite reductase

The homotrimeric copper-containing nitrite reductase (NiR) contains one type-1 and one type-2 copper center per monomer. Electrons enter through the type-1 site and are shuttled to the type-2 site where nitrite is reduced to nitric oxide. To investigate the catalytic mechanism of NiR the effects of pH and nitrite on the turnover rate in the presence of three different electron donors at saturating concentrations were measured. The activity of NiR was also measured electrochemically by exploiting direct electron transfer to the enzyme immobilized on a graphite rotating disk electrode. In all cases, the steady-state kinetics fitted excellently to a random-sequential mechanism in which electron transfer from the type-1 to the type-2 site is rate-limiting. At low [NO(-)(2)] reduction of the type-2 site precedes nitrite binding, at high [NO(-)(2)] the reverse occurs. Below pH 6.5, the catalytic activity diminished at higher nitrite concentrations, in agreement with electron transfer being slower to the nitrite-bound type-2 site than to the water-bound type-2 site. Above pH 6.5, substrate activation is observed, in agreement with electron transfer to the nitrite-bound type-2 site being faster than electron transfer to the hydroxyl-bound type-2 site. To study the effect of slower electron transfer between the type-1 and type-2 site, NiR M150T was used. It has a type-1 site with a 125-mV higher midpoint potential and a 0.3-eV higher reorganization energy leading to an approximately 50-fold slower intramolecular electron transfer to the type-2 site. The results confirm that NiR employs a random-sequential mechanism.     

Characterization of a novel copper-haem c dissimilatory nitrite reductase from Ralstonia pickettii

NiRs (nitrite reductases) convert nitrite into NO in the denitrification process. RpNiR (Ralstonia pickettii NiR), a new type of dissimilatory Cu-containing NiR with a C-terminal haem c domain from R. pickettii, has been cloned, overexpressed in Escherichia coli and purified to homogeneity. The enzyme has a subunit molecular mass of 50515 Da, consistent with sequence data showing homology to the well-studied two-domain Cu NiRs, but with an attached C-terminal haem c domain. Gel filtration and combined SEC (size-exclusion chromatography)-SAXS (small angle X-ray scattering) analysis shows the protein to be trimeric. The metal content of RpNiR is consistent with each monomer having a single haem c group and the two Cu sites being metallated by Cu(2+) ions. The absorption spectrum of the oxidized as-isolated recombinant enzyme is dominated by the haem c. X-band EPR spectra have clear features arising from both type 1 Cu and type 2 Cu centres in addition to those of low-spin ferric haem. The requirements for activity and low apparent K(m) for nitrite are similar to other CuNiRs (Cu-centre NiRs). However, EPR and direct binding measurements of nitrite show that oxidized RpNiR binds nitrite very weakly, suggesting that substrate binds to the reduced type 2 Cu site during turnover. Analysis of SEC-SAXS data suggests that the haem c domains in RpNiR form extensions into the solvent, conferring a high degree of conformational flexibility in solution. SAXS data yield R(g) (gyration radius) and D(max) (maximum particle diameter) values of 43.4 ? (1 ?=0.1 nm) and 154 ? compared with 28 ? and 80 ? found for the two-domain CuNiR of Alcaligenes xylosoxidans.     

Dithionite reduction kinetics of the dissimilatory copper-containing nitrite reductase of Alcalegenes xylosoxidans. The SO(2)(.-) radical binds to the substrate binding type 2 copper site before the type 2 copper is reduced

We report here the first detailed study of the dithionite reduction kinetics of a copper-containing dissimilatory nitrite reductase (NiR). The reduction of the blue type 1 copper (T1Cu) center of NiR preparations that contained both type 1 and type 2 copper atoms, followed biphasic kinetics. In contrast, NiR that was deficient in type 2 copper (T2DNiR), followed monophasic kinetics with a second-order rate constant (T2D)k = 3.06 x 10(6) m(-1) s(-1). In all cases the SO(2)(.-) radical rather than S(2)O(4)(2-) was the effective reductant. The observed kinetics were compatible with a reaction mechanism in which the T1Cu of the fully loaded protein is reduced both directly by dithionite and indirectly by the type 2 Cu (T2Cu) site via intramolecular electron transfer. Reduction kinetics of the T2Cu were consistent with SO(2)(.-) binding first to the T2Cu center and then transferring electrons (112 s(-1)) to reduce it. As SO(2)(.-) is a homologue of NO(2)(-), the NiR substrate, it is not unlikely that it binds to the catalytic T2Cu site. Effects on the catalytic activity of the enzyme using dithionite as a reducing agent are discussed. Reduction of the semireduced T1Cu(I)T2Cu(II) state followed either second-order kinetics with k(2) = 3.33 x 10(7) m(-1) s(-1) or first-order kinetics with 52.6 s(-1) < (T1red)k(1) < 112 s(-1). Values of formation constants of the T1Cu(II)T2Cu(II)-SO(2)(.-) and T1Cu(I)T2Cu(II)-SO(2)(.-) adducts showed that the redox state of T1Cu affected binding of SO(2)(.-) at the catalytic T2Cu center. Analysis of the kinetics required the development of a mathematical protocol that could be applied to a system with two intercommunicating sites but only one of which can be monitored. This novel protocol, reported for the first time, is of general application.     

Reconstitution of the type-1 active site of the H145G/A variants of nitrite reductase by ligand insertion

Variants of the copper-containing nitrite reductase (NiR) of Alcaligenes faecalis S6 were constructed by site-directed mutagenesis, by which the C-terminal histidine ligand (His145) of the Cu in the type-1 site was replaced by an alanine or a glycine. The type-1 sites in the NiR variants as isolated, are in the reduced form, but can be oxidized in the presence of external ligands, like (substituted) imidazoles and chloride. The reduction potential of the type-1 site of NiR-H145A reconstituted with imidazole amounts to 505 mV vs NHE (20 degrees C, pH 7, 10 mM imidazole), while for the native type-1 site it amounts to 260 mV. XRD data on crystals of the reduced and oxidized NiR-H145A variant show that in the reduced type-1 site the metal is 3-coordinated, but in the oxidized form takes up a ligand from the solution. With the fourth (exogenous) ligand in place the type-1 site is able to accept electrons at about the same rate as the wt NiR, but it is unable to pass the electron onto the type-2 site, leading to loss of enzymatic activity. It is argued that the uptake of an electron by the mutated type-1 site is accompanied by a loss of the exogenous ligand and a concomitant rise of the redox potential. This rise effectively traps the electron in the type-1 site.     

Biochemical and crystallographic studies of the Met144Ala, Asp92Asn and His254Phe mutants of the nitrite reductase from Alcaligenes xylosoxidans provide insight into the enzyme mechanism

Dissimilatory nitrite reductase catalyses the reduction of nitrite (NO(2)(-)) to nitric oxide (NO). Copper-containing nitrite reductases contain both type 1 and type 2 Cu sites. Electron transfer from redox partners is presumed to be mediated via the type 1 Cu site and used at the catalytic type 2 Cu centre along with the substrate nitrite. At the type 2 Cu site, Asp92 has been identified as a key residue in substrate utilisation, since it hydrogen bonds to the water molecule at the nitrite binding site. We have also suggested that protons enter the catalytic site via Asp92, through a water network that is mediated by His254. The role of these residues has been investigated in the blue copper nitrite reductase from Alcaligenes xylosoxidans (NCIMB 11015) by a combination of point mutation, enzymatic activity measurement and structure determination.In addition, it has been suggested that the enzyme operates via an ordered mechanism where an electron is transferred to the type 2 Cu site largely when the second substrate nitrite is bound and that this is controlled via the lowering of the redox potential of the type 2 site when it is loaded with nitrite. Thus, a small perturbation of the type 1 Cu site should result in a significant effect on the activity of the enzyme. For this reason a mutation of Met144, which is the weakest ligand of the type 1 Cu, is investigated. The structures of H254F, D92N and M144A have been determined to 1.85 A, 1.9 A and 2.2 A resolution, respectively. The D92N and H254F mutants have negligible or no activity, while the M144A mutant has 30 % activity of the native enzyme. Structural and spectroscopic data show that the loss of activity in H254F is due to the catalytic site being occupied by Zn while the loss/reduction of activity in D92N/M144A are due to structural reasons. The D92N mutation results in the loss of the Asp92 hydrogen bond to the Cu-ligated water. Therefore, the ligand is no longer able to perform proton abstraction. Even though the loss of activity in H254F is due to lack of catalytic Cu, the mutation does cause the disruption of the water network, confirming its key role in proton channel. The structure of the H254F mutant is the first case where full occupancy Zn at the type 2 Cu site is observed, but despite the previously noted similarity of this site to the carbonic anhydrase catalytic site, no carbonic anhydrase activity is observed. The H254F and D92N mutant structures provide, for the first time, observation of surface Zn sites which may act as a Zn sink and prevent binding of Zn at the catalytic Cu site in the native enzyme.     

High resolution structural studies of mutants provide insights into catalysis and electron transfer processes in copper nitrite reductase

We present high-resolution crystal structures and functional analysis of T1Cu centre mutants of nitrite reductase that perturb the redox potential and the Cys130-His129 "hard-wired" bridge through which electron transfer to the catalytic T2Cu centre occurs. These data provide insight into how activity can be altered through mutational manipulation of the electron delivery centre (T1Cu). The alteration of Cys to Ala results in loss of T1Cu and enzyme inactivation with azurin as electron donor despite the mutant enzyme retaining full nitrite-binding capacity. These data establish unequivocally that no direct transfer of electrons occurs from azurin to the catalytic type 2 Cu centre. The mutation of the axial ligand Met144 to Leu increases both the redox potential and catalytic activity, establishing that the rate-determining step of catalysis is the intermolecular electron transfer from azurin to nitrite reductase.     

A model of the copper centres of nitrous oxide reductase (Pseudomonas stutzeri). Evidence from optical, EPR and MCD spectroscopy.

Nitrous oxide reductase (N2OR), Pseudomonas stutzeri, catalyses the 2 electron reduction of nitrous oxide to di-nitrogen. The enzyme has 2 identical subunits (Mr approximately 70,000) of known amino acid sequence and contains approximately 4 Cu ions per subunit. By measurement of the optical absorption, electron paramagnetic resonance (EPR) and low-temperature magnetic circular dichroism (MCD) spectra of the oxidised state, a semi-reduced form and the fully reduced state of the enzyme it is shown that the enzyme contains 2 distinct copper centres of which one is assigned to an electron-transfer function, centre A, and the other to a catalytic site, centre Z. The latter is a binuclear copper centre with at least 1 cysteine ligand and cycles between oxidation levels Cu(II)/Cu(II) and Cu(II)/Cu(I) in the absence of substrate or inhibitors. The state Cu(II)/Cu(I) is enzymatically inactive. The MCD spectra provide evidence for a second form of centre Z, which may be enzymatically active, in the oxidised state of the enzyme. Centre A is structurally similar to that of CuA in bovine and bacterial cytochrome c oxidase and also contains copper ligated by cysteine. This centre may also be a binuclear copper complex.     

The substrate-bound type 2 copper site of nitrite reductase: the nitrogen hyperfine coupling of nitrite revealed by pulsed EPR

A pulsed electron paramagnetic resonance study has been performed on the type 2 copper site of nitrite reductase (NiR) from Alcaligenes faecalis. The H145A mutant, in which histidine 145 is replaced by alanine, was studied by ESEEM and HYSCORE experiments at 9 GHz on frozen solutions. This mutant contains a reduced type 1 copper site which allowed a selective investigation of the type 2 site of H145A and of its nitrite-bound form H145A (NO2(-)). The experiments yielded hyperfine and quadrupole parameters of the remote nitrogens of two of the histidines in the type 2 copper site of the protein and revealed the changes of these values induced by substrate binding (14NO2(-) and 15NO2(-)). The HYSCORE experiments displayed a signal of 15NO2(-) bound to H145A, from which hyperfine parameters of the nitrite nitrogen were estimated. The small isotropic hyperfine coupling, 0.36 MHz, of the nitrite nitrogen (14N) suggests that the substrate binds in an axial position to the copper in the type 2 site and that the molecular orbital containing the unpaired electron extends onto the substrate. This and other changes in the EPR parameters occurring after nitrite binding suggest a change in electronic structure of the site, which most likely prepares the site for the catalytic reaction. We propose that this change is essential for the reaction to occur.     

Alternate substrate binding modes to two mutant (D98N and H255N) forms of nitrite reductase from Alcaligenes faecalis S-6: structural model of a transient catalytic intermediate

High-resolution nitrite soaked oxidized and reduced crystal structures of two active site mutants, D98N and H255N, of nitrite reductase (NIR) from Alcaligenes faecalis S-6 were determined to better than 2.0 A resolution. In the oxidized D98N nitrite-soaked structures, nitrite is coordinated to the type II copper via its oxygen atoms in an asymmetric bidentate manner; however, elevated B-factors and weak electron density indicate that both nitrite and Asn98 are less ordered than in the native enzyme. This disorder likely results from the inability of the N delta 2 atom of Asn98 to form a hydrogen bond with the bound protonated nitrite, indicating that the hydrogen bond between Asp98 and nitrite in the native NIR structure is essential in anchoring nitrite in the active site for catalysis. In the oxidized nitrite soaked H255N crystal structure, nitrite does not displace the ligand water and is instead coordinated in an alternative mode via a single oxygen to the type II copper. His255 is clearly essential in defining the nitrite binding site despite the lack of direct interaction with the substrate in the native enzyme. The resulting pentacoordinate copper site in the H255N structure also serves as a model for a proposed transient intermediate in the catalytic mechanism consisting of a hydroxyl and nitric oxide molecule coordinated to the copper. The formation of an unusual dinuclear type I copper site in the reduced nitrite soaked D98N and H255N crystal structures may represent an evolutionary link between the mononuclear type I copper centers and dinuclear Cu(A) sites.     

Genomic analysis reveals widespread occurrence of new classes of copper nitrite reductases

Recently, the structure of a Cu-containing nitrite reductase (NiR) from Hyphomicrobium denitrificans (HdNiR) has been reported, establishing the existence of a new family of Cu-NiR where an additional type 1 Cu (T1Cu) containing cupredoxin domain is located at the N-terminus (Nojiri et al. in Proc. Natl. Acad. Sci. USA 104:4315-4320, 2007). HdNiR retains the well-characterised coupled T1Cu-type 2 Cu (T2Cu) core, where the T2Cu catalytic site is also built utilising ligands from neighbouring monomers. We have undertaken a genome analysis and found the wide occurrence of these NiRs, with members clustering in two groups, one showing an amino acid sequence similarity of around 80% with HdNiR, and a second group, including the NiR from the extremophile Acidothermus cellulolyticus, clustering around 50% similarity to HdNiR. This is reminiscent of the difference observed between the blue (Alcaligenes xylosoxidans) and green (Achromobacter cycloclastes and Alcaligenes faecalis) NiRs which have been extensively studied and may indicate that these also form two distinct subclasses of the new family. Genome analysis also showed the presence of Cu-NiRs with a C-terminal extension of 160-190 residues containing a class I cytochrome c domain with a characteristic beta-sheet extension. Currently no structural information exists for any member of this family. Genome analysis suggests the widespread occurrence of these novel NiRs with representatives in the alpha, beta and gamma subclasses of the Proteobacteria and in two species of the fungus Aspergillus. We selected the enzyme from Ralstonia pickettii for comparative modelling and produced a plausible structure highlighting an electron transfer mode in which the cytochrome c haem at the C-terminus can come within 16-A reach of the T1Cu centre of the T1Cu-T2Cu core.     

Cyanide binding to cd(1) nitrite reductase from Pseudomonas aeruginosa: role of the active-site His369 in ligand stabilization

Cyanide binding to fully reduced Pseudomonas aeruginosa cd(1) nitrite reductase (Pa cd(1) NiR) has been investigated for the wild-type enzyme and a site-directed mutant in which the active-site His369 was replaced by Ala. This mutation reduces the affinity toward cyanide (by approximately 13-fold) and especially decreases the rate of binding of cyanide to the reduced d(1) heme (by approximately 100-fold). The crystal structure of wild-type reduced Pa cd(1) NiR saturated with cyanide was determined to a resolution of 2.7 A. Cyanide binds to the iron of the d(1) heme, with an Fe-C-N angle of 168 degrees for both subunits of the dimer and only His369 is within hydrogen bonding distance of the nitrogen atom of the ligand. These results suggest that in Pa cd(1) NiR the invariant distal residue His369 plays a dominant role in controlling the binding of anionic ligands and allow the discussion of the mechanism of cyanide binding to the wild-type enzyme.     

Reactions of spinach nitrite reductase with its substrate, nitrite, and a putative intermediate, hydroxylamine

Plant nitrite reductase (NiR) catalyzes the reduction of nitrite (NO(2)(-)) to ammonia, using reduced ferredoxin as the electron donor. NiR contains a [4Fe-4S] cluster and an Fe-siroheme, which is the nitrite binding site. In the enzyme's as-isolated form ([4Fe-4S](2+)/Fe(3+)), resonance Raman spectroscopy indicated that the siroheme is in the high-spin ferric hexacoordinated state with a weak sixth axial ligand. Kinetic and spectroscopic experiments showed that the reaction of NiR with NO(2)(-) results in an unexpectedly EPR-silent complex formed in a single step with a rate constant of 0.45 +/- 0.01 s(-)(1). This binding rate is slow compared to that expected from the NiR turnover rates reported in the literature, suggesting that binding of NO(2)(-) to the as-isolated form of NiR is not the predominant type of substrate binding during enzyme turnover. Resonance Raman spectroscopic characterization of this complex indicated that (i) the siroheme iron is low-spin hexacoordinated ferric, (ii) the ligand coordination is unusually heterogeneous, and (iii) the ligand is not nitric oxide, most likely NO(2)(-). The reaction of oxidized NiR with hydroxylamine (NH(2)OH), a putative intermediate, results in a ferrous siroheme-NO complex that is spectroscopically identical to the one observed during NiR turnover. Resonance Raman and absorption spectroscopy data show that the reaction of oxidized NiR ([4Fe-4S](2+)/Fe(3+)) with hydroxylamine is binding-limited, while the NH(2)OH conversion to nitric oxide is much faster.     

A facilitated electron transfer of copper--zinc superoxide dismutase (SOD) based on a cysteine-bridged SOD electrode

The direct electrochemical redox reaction of bovine erythrocyte copper--zinc superoxide dismutase (Cu(2)Zn(2)SOD) was clearly observed at a gold electrode modified with a self-assembled monolayer (SAM) of cysteine in phosphate buffer solution containing SOD, although its reaction could not be observed at the bare electrode. In this case, SOD was found to be stably confined on the SAM of cysteine and the redox response could be observed even when the cysteine-SAM electrode used in the SOD solution was transferred to the pure electrolyte solution containing no SOD, suggesting the permanent binding of SOD via the SAM of cysteine on the electrode surface. The electrode reaction of the SOD confined on the cysteine-SAM electrode was found to be quasi-reversible with the formal potential of 65 +/- 3 mV vs. Ag/AgCl and its kinetic parameters were estimated: the electron transfer rate constant k(s) is 1.2 +/- 0.2 s(-1) and the anodic (alpha(a)) and cathodic (alpha(c)) transfer coefficients are 0.39 +/- 0.02 and 0.61 +/- 0.02, respectively. The assignment of the redox peak of SOD at the cysteine-SAM modified electrode could be sufficiently carried out using the native SOD (Cu(2)Zn(2)SOD), its Cu- or Zn-free derivatives (E(2)Zn(2)SOD and Cu(2)E(2)SOD, E designates an empty site) and the SOD reconstituted from E(2)Zn(2)SOD and Cu(2+). The Cu complex moiety, the active site for the enzymatic dismutation of the superoxide ion, was characterized to be also the electroactive site of SOD. In addition, we found that the SOD confined on the electrode can be expected to possess its inherent enzymatic activity for dismutation of the superoxide ion.     

Crystallographic structures of bovine copper-zinc superoxide dismutase reveal asymmetry in two subunits: functionally important three and five coordinate copper sites captured in the same crystal

A key feature of the generally accepted catalytic mechanism of CuZn superoxide dismutase (CuZnSOD) is the breakage of the imidazolate bridge between copper and zinc and the loss of a coordinated water molecule from copper on reduction from Cu(II) to Cu(I). Crystal structures exist for the enzyme from a number of sources in the oxidised, five coordinate copper form. For the reduced form two structures from different sources have been determined only recently but provide contradictory results. We present crystal structures of bovine CuZnSOD (BSOD) in two different space groups. The structure of the P212121 form (pBSOD), at 1.65 A resolution clearly shows one subunit with Cu in the five coordinate, oxidised form, and the other with Cu in the three coordinate form expected for the reduced state. This mixed state of pBSOD is confirmed by XANES data of these crystals. The pBSOD structure has thus captured each subunit in one of the two oxidation state conformations and thus provides direct crystallographic evidence for the superoxide dismutase mechanism involving the breakage of the imidazole bridge between Cu and Zn. A shift in the position of copper in subunit A poises the catalytic centre to undergo the first stage of catalysis via dissociation of Cu from His61 with a concomittant movement of the coordinated water molecule towards His61, which rotates by approximately 20 degrees, enabling it to form a hydrogen bond to the water molecule. The Cu-Zn separation in the reduced site is increased by approximately 0.5 A. In contrast the 2.3 A resolution structure in space group C2221 (cBSOD) shows both of the Cu atoms to be in the five coordinate, oxidised form but in this space group the whole of subunit A is significantly more disordered than subunit B. An examination of published structures of "oxidised" SODs, shows a trend towards longer Cu-Zn and Cu-His61 separations in subunit A, which together with the structures reported here indicate a potential functional asymmetry between the subunits of CuZnSODs. We also suggest that the increased separation between Cu and Zn is a precursor to breakage of His61.