Nitric oxide and cytochrome oxidase: substrate,inhibitor or effector?

Endogenously produced nitric oxide (NO) controls oxygen consumption by inhibiting cytochrome c oxidase, the terminal electron acceptor of the mitochondrial electron transport chain. The oxygen-binding site of the enzyme is an iron/copper (haem a3/CuB) binuclear centre. At high substrate (ferrocytochrome c) concentrations, NO binds reversibly to the reduced iron in competition with oxygen. At low substrate concentrations, NO binds to the oxidized copper. Inhibition at the haem iron site is relieved by dissociation of the NO from the reduced iron. Inhibition at the copper site is relieved by oxidation of the bound NO and subsequent dissociation of nitrite from the enzyme. Therefore, NO can be a substrate, inhibitor or effector of cytochrome oxidase, depending on cellular conditions.     

Redox-dependent open and closed forms of the active site of the bacterial respiratory nitric-oxide reductase revealed by cyanide binding studies

The bacterial respiratory nitric-oxide reductase (NOR) catalyzes the respiratory detoxification of nitric oxide in bacteria and Archaea. It is a member of the well known super-family of heme-copper oxidases but has a [heme Fe-non-heme Fe] active site rather than the [heme Fe-Cu(B)] active site normally associated with oxygen reduction. Paracoccus denitrificans NOR is spectrally characterized by a ligand-to-metal charge transfer absorption band at 595 nm, which arises from the high spin ferric heme iron of a micro-oxo-bridged [heme Fe(III)-O-Fe(III)] active site. On reduction of the nonheme iron, the micro-oxo bridge is broken, and the ferric heme iron is hydroxylated or hydrated, depending on the pH. At present, the catalytic cycle of NOR is a matter of much debate, and it is not known to which redox state(s) of the enzyme nitric oxide can bind. This study has used cyanide to probe the nature of the active site in a number of different redox states. Our observations suggest that the micro-oxo-bridged [heme Fe(III)-O-Fe(III)] active site represents a closed or resting state of NOR that can be opened by reduction of the non-heme iron.     

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.     

Defining the proton entry point in the bacterial respiratory nitric-oxide reductase

The bacterial respiratory nitric-oxide reductase (NOR) is a member of the superfamily of O(2)-reducing, proton-pumping, heme-copper oxidases. Even although nitric oxide reduction is a highly exergonic reaction, NOR is not a proton pump and rather than taking up protons from the cytoplasmic (membrane potential-negative) side of the membrane, like the heme-copper oxidases, NOR derives its substrate protons from the periplasmic (membrane potential-positive) side of the membrane. The molecular details of this non-electrogenic proton transfer are not yet resolved, so in this study we have explored a role in a proposed proton pathway for a conserved surface glutamate (Glu-122) in the catalytic subunit (NorB). The effect of substituting Glu-122 with Ala, Gln, or Asp on a single turnover of the reduced NOR variants with O(2), an alternative and experimentally tractable substrate for NOR, was determined. Electron transfer coupled to proton uptake to the bound O(2) is severely and specifically inhibited in both the E122A and E122Q variants, establishing the importance of a protonatable side chain at this position. In the E122D mutant, proton uptake is retained but it is associated with a significant increase in the observed pK(a) of the group donating protons to the active site. This suggests that Glu-122 is important in defining this proton donor. A second nearby glutamate (Glu-125) is also required for the electron transfer coupled to proton uptake, further emphasizing the importance of this region of NorB in proton transfer. Because Glu-122 is predicted to lie near the periplasmic surface of NOR, the results provide strong experimental evidence that this residue contributes to defining the aperture of a non-electrogenic "E-pathway" that serves to deliver protons from the periplasm to the buried active site in NOR.     

Diverse NO reduction by Halomonas halodenitrificans nitric oxide reductase

Reduction of the four Fe centers is not required to initiate the reaction of the Halomonas halodenitrificans nitric oxide reductase (NOR) based on the facts that NOR in the form that ferric heme b(3) and non-heme iron (Fe(B)) are not bridged and/or the interaction between them is weakened and reversibly binds NO molecules, and that NOR in the form that only heme b(3) is oxidized reacts with NO molecules.     

Reduction of nitric oxide in bacterial nitric oxide reductase--a theoretical model study

The mechanism of the nitric oxide reduction in a bacterial nitric oxide reductase (NOR) has been investigated in two model systems of the heme-b(3)-Fe(B) active site using density functional theory (B3LYP). A model with an octahedral coordination of the non-heme Fe(B) consisting of three histidines, one glutamate and one water molecule gave an energetically feasible reaction mechanism. A tetrahedral coordination of the non-heme iron, corresponding to the one of Cu(B) in cytochrome oxidase, gave several very high barriers which makes this type of coordination unlikely. The first nitric oxide coordinates to heme b(3) and is partly reduced to a more nitroxyl anion character, which activates it toward an attack from the second NO. The product in this reaction step is a hyponitrite dianion coordinating in between the two irons. Cleaving an NO bond in this intermediate forms an Fe(B) (IV)O and nitrous oxide, and this is the rate determining step in the reaction mechanism. In the model with an octahedral coordination of Fe(B) the intrinsic barrier of this step is 16.3 kcal/mol, which is in good agreement with the experimental value of 15.9 kcal/mol. However, the total barrier is 21.3 kcal/mol, mainly due to the endergonic reduction of heme b(3) taken from experimental reduction potentials. After nitrous oxide has left the active site the ferrylic Fe(B) will form a mu-oxo bridge to heme b(3) in a reaction step exergonic by 45.3 kcal/mol. The formation of a quite stable mu-oxo bridge between heme b(3) and Fe(B) is in agreement with this intermediate being the experimentally observed resting state in oxidized NOR. The formation of a ferrylic non-heme Fe(B) in the proposed reaction mechanism could be one reason for having an iron as the non-heme metal ion in NOR instead of a Cu as in cytochrome oxidase.     

Structure and evolution of cytochrome oxidase

The structural features of cytochrome oxidases are reviewed in light of their evolution. The substrate specificity (quinol vs. cytochromec) is reflected in the presence of a unique copper centre (Cu _A ) in cytochromec oxidases. In several lines of evolution, quinol oxidases have independently lost this copper. Also, the most primitive cytochromec oxidases do not contain this copper, and electron entry takes place viac-type haems. These enzymes, exemplified by the rhizobial FixN complex, probably remind the first oxidases. They are related to the denitrification enzyme nitric oxide reductase.     

Reaction of carbon monoxide with the reduced active site of bacterial nitric oxide reductase.

Bacterial nitric oxide reductase (NOR), a member of the superfamily of heme-copper oxidases, catalyzes the two-electron reduction of nitric oxide to nitrous oxide. The key feature that distinguishes NOR from the typical heme-copper oxidases is the elemental composition of the dinuclear center, which contains non-heme iron (FeB) rather than copper (CuB). UV-vis electronic absorption and room-temperature magnetic circular dichroism (RT-MCD) spectroscopies showed that CO binds to Fe(II) heme b3 to yield a low-spin six-coordinate species. Photolysis of the Fe(II)-CO bond is followed by CO recombination (k(on) = 1.7 x 10(8) M(-1) x s(-1)) that is approximately 3 orders of magnitude faster than CO recombination to the active site of typical heme-copper oxidases (k(on) = 7 x 10(4) M(-1)x s(-1)). This rapid rate of CO recombination suggests an unimpeded pathway to the active site that may account for the enzyme's high affinity for substrate, essential for maintaining denitrification at low concentrations of NO. In contrast, the initial binding of CO to reduced heme b3 measured by stopped-flow spectroscopy is much slower (k(on) = 1.2 x 10(5) M(-1) x s(-1)). This suggests that an existing heme distal ligand (water/OH-) may be displaced to elicit the spin-state change observed in the RT-MCD spectrum.     

Two conserved glutamates in the bacterial nitric oxide reductase are essential for activity but not assembly of the enzyme

The bacterial nitric oxide reductase (NOR) is a divergent member of the family of respiratory heme-copper oxidases. It differs from other family members in that it contains an Fe(B)-heme-Fe dinuclear catalytic center rather than a Cu(B)-heme-Fe center and in that it does not pump protons. Several glutamate residues are conserved in NORs but are absent in other heme-copper oxidases. To facilitate mutagenesis-based studies of these residues in Paracoccus denitrificans NOR, we developed two expression systems that enable inactive or poorly active NOR to be expressed, characterized in vivo, and purified. These are (i) a homologous system utilizing the cycA promoter to drive aerobic expression of NOR in P. denitrificans and (ii) a heterologous system which provides the first example of the expression of an integral-membrane cytochrome bc complex in Escherichia coli. Alanine substitutions for three of the conserved glutamate residues (E125, E198, and E202) were introduced into NOR, and the proteins were expressed in P. denitrificans and E. coli. Characterization in intact cells and membranes has demonstrated that two of the glutamates are essential for normal levels of NOR activity: E125, which is predicted to be on the periplasmic surface close to helix IV, and E198, which is predicted to lie in the middle of transmembrane helix VI. The subsequent purification and spectroscopic characterization of these enzymes established that they are stable and have a wild-type cofactor composition. Possible roles for these glutamates in proton uptake and the chemistry of NO reduction at the active site are discussed.     

A pathway for protons in nitric oxide reductase from Paracoccus denitrificans

Nitric oxide reductase (NOR) from P. denitrificans is a membrane-bound protein complex that catalyses the reduction of NO to N(2)O (2NO+2e(-)+2H(+)-->N(2)O+H(2)O) as part of the denitrification process. Even though NO reduction is a highly exergonic reaction, and NOR belongs to the superfamily of O(2)-reducing, proton-pumping heme-copper oxidases (HCuOs), previous measurements have indicated that the reaction catalyzed by NOR is non-electrogenic, i.e. not contributing to the proton electrochemical gradient. Since electrons are provided by donors in the periplasm, this non-electrogenicity implies that the substrate protons are also taken up from the periplasm. Here, using direct measurements in liposome-reconstituted NOR during reduction of both NO and the alternative substrate O(2), we demonstrate that protons are indeed consumed from the 'outside'. First, multiple turnover reduction of O(2) resulted in an increase in pH on the outside of the NOR-vesicles. Second, comparison of electrical potential generation in NOR-liposomes during oxidation of the reduced enzyme by either NO or O(2) shows that the proton transfer signals are very similar for the two substrates proving the usefulness of O(2) as a model substrate for these studies. Last, optical measurements during single-turnover oxidation by O(2) show electron transfer coupled to proton uptake from outside the NOR-liposomes with a tau=15 ms, similar to results obtained for net proton uptake in solubilised NOR [U. Flock, N.J. Watmough, P. Adelroth, Electron/proton coupling in bacterial nitric oxide reductase during reduction of oxygen, Biochemistry 44 (2005) 10711-10719]. NOR must thus contain a proton transfer pathway leading from the periplasmic surface into the active site. Using homology modeling with the structures of HCuOs as templates, we constructed a 3D model of the NorB catalytic subunit from P. denitrificans in order to search for such a pathway. A plausible pathway, consisting of conserved protonatable residues, is suggested.     

Ultrafast ligand binding dynamics in the active site of native bacterial nitric oxide reductase

The active site of nitric oxide reductase from Paracoccus denitrificans contains heme and non-heme iron and is evolutionarily related to heme-copper oxidases. The CO and NO dynamics in the active site were investigated using ultrafast transient absorption spectroscopy. We find that, upon photodissociation from the active site heme, 20% of the CO rebinds in 170 ps, suggesting that not all the CO transiently binds to the non-heme iron. The remaining 80% does not rebind within 4 ns and likely migrates out of the active site without transient binding to the non-heme iron. Rebinding of NO to ferrous heme takes place in approximately 13 ps. Our results reveal that heme-ligand recombination in this enzyme is considerably faster than in heme-copper oxidases and are consistent with a more confined configuration of the active site.     

Structural basis for nitrous oxide generation by bacterial nitric oxide reductases

The crystal structure of the bacterial nitric oxide reductase (cNOR) from Pseudomonas aeruginosa is reported. Its overall structure is similar to those of the main subunit of aerobic and micro-aerobic cytochrome oxidases (COXs), in agreement with the hypothesis that all these enzymes are members of the haem-copper oxidase superfamily. However, substantial structural differences between cNOR and COX are observed in the catalytic centre and the delivery pathway of the catalytic protons, which should be reflected in functional differences between these respiratory enzymes. On the basis of the cNOR structure, we propose a possible reaction mechanism of nitric oxide reduction to nitrous oxide as a working hypothesis.     

Biosynthesis and functional role of haem O and haem A

Haem O and/or haem A are specifically synthesized for the haem-copper respiratory oxidases. A 17-carbon hydroxyethylfarnesyl chain at the pyrrole ring A of the haems seems essential for catalytic functions at the oxygen-reduction site. The discovery of haem O in the cytochrome bo complex from Escherichia coli was a breakthrough in the studies on haem A biosynthesis. Molecular biological and biochemical studies in the past three years demonstrated that the cyoE/ctaB/COX10 genes are indispensable for functional expression of the terminal oxidases and encode a novel enzyme haem O synthase (protohaem IX farnesyltransferase). It has recently been suggested that the ctaA gene adjacent to the ctaB-ctaCDEF gene cluster in Bacillus subtilis encodes haem A synthase (haem O monooxygenase). In this article, we review current knowledge of the genes for haem O and haem A biosyntheses, the location and regulation of haem O synthase, the possible enzymatic mechanism of farnesyl transfer to haem B and the possible roles of the farnesylated haems.     

Towards the mechanism of proton pumping by the haem-copper oxidases

The haem-copper oxidases comprise a large family of enzymes that is widespread among aerobic organisms. These remarkable membrane-bound proteins catalyse the respiratory reduction of dioxygen to water, and conserve free energy from this reaction by operating as proton pumps. The mechanism of redox-dependent proton translocation has been elusive despite the availability of high resolution crystal structures from several oxidases. Here, we discuss some recent as well as some older results that may shed light on this mechanism. We conclude that proton-pumping is initiated by vectorial proton transfer from a conserved glutamic acid (Glu242 in the bovine enzyme) to a proton acceptor above the haem groups, and that this primary event is mechanistically coupled to electron transfer from haem a to the binuclear haem a3/CuB centre. Subsequently, Glu242 is reprotonated from the negatively charged side of the membrane. Next this proton is transferred to the binuclear site to complete the chemistry, Glu242 is reprotonated once more, and the "prepumped" proton is ejected on the opposite side of the membrane. The different kinetics of electron-coupled proton transfer in different steps of the catalytic cycle may be related to differences in the driving force due to different Em values of the electron acceptor in the binuclear site.     

Structure-based redesign of cofactor binding in putrescine oxidase

Putrescine oxidase (PuO) from Rhodococcus erythropolis is a soluble homodimeric flavoprotein, which oxidizes small aliphatic diamines. In this study, we report the crystal structures and cofactor binding properties of wild-type and mutant enzymes. From a structural viewpoint, PuO closely resembles the sequence-related human monoamine oxidases A and B. This similarity is striking in the flavin-binding site even if PuO does not covalently bind the cofactor as do the monoamine oxidases. A remarkable conserved feature is the cis peptide conformation of the Tyr residue whose conformation is important for substrate recognition in the active site cavity. The structure of PuO in complex with the reaction product reveals that Glu324 is crucial in recognizing the terminal amino group of the diamine substrate and explains the narrow substrate specificity of the enzyme. The structural analysis also provides clues for identification of residues that are responsible for the competitive binding of ADP versus FAD (~50% of wild-type PuO monomers isolated are occupied by ADP instead of FAD). By replacing Pro15, which is part of the dinucleotide-binding domain, enzyme preparations were obtained that are almost 100% in the FAD-bound form. Furthermore, mutants have been designed and prepared that form a covalent 8α-S-cysteinyl-FAD linkage. These data provide new insights into the molecular basis for substrate recognition in amine oxidases and demonstrate that engineering of flavoenzymes to introduce covalent linkage with the cofactor is a possible route to develop more stable protein molecules, better suited for biocatalytic purposes.     

Histidine ligand variants of a flavo-diiron protein: effects on structure and activities

Flavo-diiron proteins (FDPs) contain non-heme diiron and proximal flavin mononucleotide (FMN) active sites and function as terminal components of a nitric oxide reductase (NOR) and/or a four-electron dioxygen reductase (O₂R). While most FDPs show similar structural, spectroscopic, and redox properties, O₂R and NOR activities vary significantly among FDPs. A potential source of this variability is the iron ligation status of a conserved His residue that provides an iron ligand in all known FDP structures but one, where this His residue is rotated away from iron and replaced by a solvent ligand. In order to test the effect of this His ligation status, we changed this ligating His residue (H90) in Thermotoga maritima (Tm) FDP to either Asn or Ala. The wild-type Tm FDP shows significantly higher O₂R than NOR activity. Single crystal X-ray crystallography revealed a remarkably conserved diiron site structure in the H90N and ?A variants, differing mainly by either Asn or solvent coordination, respectively, in place of H90. The steady-state activities were minimally affected by the H90 substitutions, remaining significantly higher for O₂R versus NOR. The pre-steady-state kinetics of the fully reduced FDP with O₂ were also minimally affected by the H90 substitutions. The results indicate that the coordination status of this His ligand does not significantly modulate the O₂R or NOR activities, and that FDPs can retain these activities when the individual iron centers are differentiated by His ligand substitution. This differentiation may have implications for the O₂R and NOR mechanisms of FDPs.     

Substrate binding and the catalytic reactions in cbb3-type oxidases: The lipid membrane modulates ligand binding

Heme–copper oxidases (HCuOs) are the terminal components of the respiratory chain in the mitochondrial membrane or the cell membrane in many bacteria. These enzymes reduce oxygen to water and use the free energy from this reaction to maintain a proton-motive force across the membrane in which they are embedded. The heme–copper oxidases of the cbb₃-type are only found in bacteria, often pathogenic ones since they have a low K_m for O₂, enabling the bacteria to colonize semi-anoxic environments. Cbb₃-type (C) oxidases are highly divergent from the mitochondrial-like aa₃-type (A) oxidases, and within the heme–copper oxidase family, cbb₃ is the closest relative to the most divergent member, the bacterial nitric oxide reductase (NOR). Nitric oxide reductases reduce NO to N₂O without coupling the reaction to the generation of any electrochemical proton gradient. The significant structural differences between A- and C-type heme–copper oxidases are manifested in the lack in cbb₃ of most of the amino acids found to be important for proton pumping in the A-type, as well as in the different binding characteristics of ligands such as CO, O₂ and NO. Investigations of the reasons for these differences at a molecular level have provided insights into the mechanism of O₂ and NO reduction as well as the proton-pumping mechanism in all heme–copper oxidases. In this paper, we discuss results from these studies with the focus on the relationship between proton transfer and ligand binding and reduction. In addition, we present new data, which show that CO binding to one of the c-type hemes of CcoP is modulated by protein–lipid interactions in the membrane. These results show that the heme c-CO binding can be used as a probe of protein–membrane interactions in cbb₃ oxidases, and possible physiological consequences for this behavior are discussed.     

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.     

From NO to OO: Nitric Oxide and Dioxygen in Bacterial Respiration

Nitric oxide reductase (NOR) is a key enzyme in denitrification, reforming the N–N bond (making N₂O from two NO molecules) in the nitrogen cycle. It is a cytochrome bc complex which has apparently only two subunits, NorB and NorC. It contains two low-spin cytochromes (c and b), and a high-spin cytochrome b which forms a binuclear center with a non-heme iron. NorC contains the c-type heme and NorB can be predicted to bind the other metal centers. NorB is homologous to the major subunit of the heme/copper cytochrome oxidases, and NOR thus belongs to the superfamily, although it has an Fe/Fe active site rather than an Fe/Cu binuclear center and a different catalytic activity. Current evidence suggests that NOR is not a proton pump, and that the protons consumed in NO reduction are not taken from the cytoplasmic side of the membrane. Therefore, the comparison between structural and functional properties of NOR and cytochrome c- and quinol-oxidizing enzymes which function as proton pumps may help us to understand the mechanism of the latter. This review is a brief summary of the current knowledge on molecular biology, structure, and bioenergetics of NOR as a member of the oxidase superfamily.     

Cytochrome c oxidase rapidly metabolises nitric oxide to nitrite

Previous studies have shown that the addition of nitric oxide to cytochrome c oxidase rapidly generates spectral changes compatible with the formation of nitrite at the binuclear haem:copper centre. Here we directly demonstrate nitrite release following nitric oxide addition to the enzyme. The nitrite complex is kinetically inactive and the off rate for nitrite was found to be slow (0.024 min(-1)). However, the presence of reductants enhances the off rate and enables cytochrome oxidase to catalyse the rapid oxidation of nitric oxide to nitrite free in solution. This may play a major role in the mitochondrial metabolism of nitric oxide.