Conserved active site residues limit inhibition of a copper-containing nitrite reductase by small molecules

The interaction of copper-containing dissimilatory nitrite reductase from Alcaligenes faecalis S-6 ( AfNiR) with each of five small molecules was studied using crystallography and steady-state kinetics. Structural studies revealed that each small molecule interacted with the oxidized catalytic type 2 copper of AfNiR. Three small molecules (formate, acetate and nitrate) mimic the substrate by having at least two oxygen atoms for bidentate coordination to the type 2 copper atom. These three anions bound to the copper ion in the same asymmetric, bidentate manner as nitrite. Consistent with their weak inhibition of the enzyme ( K i >50 mM), the Cu-O distances in these AfNiR-inhibitor complexes were approximately 0.15 A longer than that observed in the AfNiR-nitrite complex. The binding mode of each inhibitor is determined in part by steric interactions with the side chain of active site residue Ile257. Moreover, the side chain of Asp98, a conserved residue that hydrogen bonds to type 2 copper-bound nitrite and nitric oxide, was either disordered or pointed away from the inhibitors. Acetate and formate inhibited AfNiR in a mixed fashion, consistent with the occurrence of second acetate binding site in the AfNiR-acetate complex that occludes access to the type 2 copper. A fourth small molecule, nitrous oxide, bound to the oxidized metal in a side-on fashion reminiscent of nitric oxide to the reduced copper. Nevertheless, nitrous oxide bound at a farther distance from the metal. The fifth small molecule, azide, inhibited the reduction of nitrite by AfNiR most strongly ( K ic = 2.0 +/- 0.1 mM). This ligand bound to the type 2 copper center end-on with a Cu-N c distance of approximately 2 A, and was the only inhibitor to form a hydrogen bond with Asp98. Overall, the data substantiate the roles of Asp98 and Ile257 in discriminating substrate from other small anions.     

Electron paramagnetic resonance studies of heme c and its nitrosyl derivative in Vibrio (Achromobacter) fischeri nitrite reductase

Interactions of Vibrio (formerly Achromobacter) fischeri nitrite reductase were studied by electron paramagnetic resonance spectroscopy. The spectrum of the oxidized enzyme showed a number of features which were attributed to two low-spin ferric hemes. These comprised an unusual derivative peak at g = 3.7 and a spectrum at g = 2.88, 2.26, and 1.51. Neither heme was reactive in the oxidized state with the substrate nitrite and with cyanide and azide. When frozen under turnover conditions (i.e., reduction in the presence of excess nitrite), the enzyme showed the spectrum of a nitrosyl heme derivative. The g = 2.88, 2.26, and 1.51 signals reappeared partially on reoxidation by nitrite, indicating that the nitrosyl species which remained arose from the g = 3.7 heme. The nitrosyl derivative showed a 14N nuclear hyperfine splitting, Az = 1.65 mT. The nitrosyl derivative was produced by treatment of the oxidized nitrite reductase with nitric oxide or hydroxylamine. Exchange of nitric oxide between the nitrosyl derivative and NO gas in solution was observed by using the [15N]nitrosyl compound. A possible reaction cycle for the enzyme is discussed, which involves reduction of the enzyme followed by binding of nitrite to one heme and formation of the nitrosyl intermediate.     

Mechanism of spinach chloroplast ferredoxin-dependent nitrite reductase: spectroscopic evidence for intermediate states

Nitrite reductases found in plants, algae, and cyanobacteria catalyze the six-electron reduction of nitrite to ammonia with reduced ferredoxin serving as the electron donor. They contain one siroheme and one [4Fe-4S] cluster, acting as separate one-electron carriers. Nitrite is thought to bind to the siroheme and to remain bound until its complete reduction to ammonia. In the present work the enzyme catalytic cycle, with ferredoxin reduced by photosystem 1 as an electron donor, has been studied by EPR and laser flash absorption spectroscopy. Substrate depletion during enzyme turnover, driven by a series of laser flashes, has been demonstrated. A complex of ferrous siroheme with NO, formed by two-electron reduction of the enzyme complex with nitrite, has been shown to be an intermediate in the enzyme catalytic cycle. The same complex can be formed by incubation of free oxidized nitrite reductase with an excess of nitrite and ascorbate. Hydroxylamine, another putative intermediate in the reduction of nitrite catalyzed by nitrite reductase, was found to react with oxidized nitrite reductase to produce the same ferrous siroheme-NO complex, with a characteristic formation time of about 13 min. The rate-limiting step for this reaction is probably hydroxylamine binding to the enzyme, with the conversion of hydroxylamine to NO at the enzyme active site likely being much faster.     

Reduced ferredoxin: CO2 oxidoreductase from Clostridium pasteurianum. Effect of ligands to transition metals on the activity and the stability of the enzyme.

Reduced ferredoxin: CO2 oxidoreductase (CO2-reductase) from Clostridium pasteurianum catalyzes the reduction of CO2 to formate at the expense of reduced ferredoxin, an isotopic exchange between CO2 and formate in the absence of ferredoxin, and the oxidation of formate to CO2 with oxidized ferredoxin. The three activities were found to be equally affected by monovalent anions known to be ligands to transition metals: The enzyme was reversibly inhibited by azide (Ki = 0.004mM), cyanate (Ki = 0.3 mM), thiocyanate (Ki = 1mM), nitrite (Ki = 0.4mM), nitrate (Ki = 6mM), chlorate (Ki = 3mM), fluoride (Ki = 5mM), and by chloride, bromide, iodide (Ki greater than 5mM). There was no observable effect of pH on the inhibition constants. The enzyme was not inhibited by carbon monoxide. The enzyme was irreversibly inactivated by low concentrations (10muM) of cyanide. The rate of inactivation increased with increasing pH with an inflection point near pH 9.5. Reduced ferredoxin and formate rather than oxidized ferredoxin or CO2 protected the enzyme from inactivation by cyanide. The enzyme was protected by azide and cyanate from inactivation. In the presence of high concentrations of the monovalent anions the rate of inactivation by heat (55 degrees C), by molecular oxygen, and by cyanide was decreased by a factor of more than 100. Half maximal protection was observed at the Ki concentrations of the two reversible inhibitors. The data are interpreted to indicate that a transition metal of weak "a class" character and a disulfide are catalytically significant groups of CO2-reductase from C. pasteurianum.     

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...     

The ferredoxin-binding site of ferredoxin: Nitrite oxidoreductase. Differential chemical modification of the free enzyme and its complex with ferredoxin.

Spinach (Spinacea oleracea) leaf ferredoxin (Fd)-dependent nitrite reductase was treated with either the arginine-modifying reagent phenyl-glyoxal or the lysine-modifying reagent pyridoxal-5'-phosphate under conditions where only the Fd-binding affinity of the enzyme was affected and where complex formation between Fd and the enzyme prevented the inhibition by either reagent. Modification with [14C]phenylglyoxal allowed the identification of two nitrite reductase arginines, R375 and R556, that are protected by Fd against labeling. Modification of nitrite reductase with pyridoxal-5'-phosphate, followed by reduction with NaBH4, allowed the identification of a lysine, K436, that is protected by Fd against labeling. Positive charges are present at these positions in all of the Fd-dependent nitrite reductase for which sequences are available, suggesting that these amino acids are directly involved in electrostatic binding of Fd to the enzyme.     

Studies on the differential inhibition by azide on the nitrite/nitrous oxide level of denitrification.

A gas chromatographic method was used to demonstrate that nitrite can counteract the inhibition by azide of nitrous oxide reductase activity in denitrifiers. This effect explains why azide (and cyanide) can inhibit nitrogen production from nitrous oxide in these organisms but have little effect on nitrogen production from nitrite. Although the physiological basis by which nitrite opposes the action of azide remains unknown, extensive destruction of azide by nitrite can be ruled out as an explanation.     

Studies on the differential inhibition by azide on the nitrite/nitrous oxide level of denitrification.

A gas chromatographic method was used to demonstrate that nitrite can counteract the inhibition by azide of nitrous oxide reductase activity in denitrifiers. This effect explains why azide (and cyanide) can inhibit nitrogen production from nitrous oxide in these organisms but have little effect on nitrogen production from nitrite. Although the physiological basis by which nitrite opposes the action of azide remains unknown, extensive destruction of azide by nitrite can be ruled out as an explanation.     

Formate dehydrogenase. Subunit and mechanism of inhibition by cyanide and azide.

Formate dehydrogenase (EC 1.2.1.2) prepared from peas (Pisum sativum) was a two-subunit enzyme. The enzyme accelerated the formation of an NAD+-cyanide compound having an adsorption band at 330 nm. The enzyme was able to bind one NAD+ molecule per each subunit but only 1 mole of NAD+-cyanide compound was formed per two subunits. The complex of NAD+, cyanide, and the enzyme was very stable and had no catalytic activity. Azide inhibited the formate dehydrogenase reaction in two different ways. By incubation of the enzyme with azide in the presence of NAD+, half of its catalytic activity was lost. The remaining activity was also inhibited by azide but this inhibition was removed competively by formate. Contrary to the case of cyanide the inhibition by azide could be removed by dialysis and no spectral species due to the addition compound of NAD+ and azide could be observed. The data from double recipricol plots of the initial velocity and the formate concentration led to a conclusion that formate dehydrogenase has two sites with about equal catalytic activity. The Km for formate was different for the two catalytic sites (1.67 and 6.25 mM) but the difference was not noticeable in the case of the Km for NAD+.     

Protonation and inhibition of Nitrosomonas europaea cytochrome c peroxidase observed with protein film voltammetry

The impact of protonation and inhibitor binding of the diheme cytochrome c peroxidase (CCP) from Nitrosomonas europaea has been examined by the technique of catalytic protein film voltammetry (PFV). Previous efforts have shown that the low-potential heme active site (L) binds substrate and yields electrocatalysis at an pyrolytic graphite edge electrode, with properties evocative of a high-potential intermediate, with E(m)>540mV (vs. normal hydrogen electrode) [A.L. Bradley, S.E. Chobot, D.M. Arciero, A.B. Hooper, S. J. Elliott, J. Biol. Chem. 279 (2004) 13297-13300]. Here we demonstrate through similar experiments that catalytic PFV generates limiting currents which allow for electrochemically-detected enzymology of the Ne CCP: such as the demonstration that pH-dependent Michaelis-Menten constants (K(m) values) reveal a pK(a) value of 6.5 associated with the "ES" complex. Further, the direct electrocatalysis is shown in the presence of known inhibitors (cyanide and azide), indicating that inhibitor binding occurs at L, and shifts the resulting catalytic midpoint potential in a negative direction. Michaelis-Menten treatment of the limiting currents generated in the presence of variable concentrations of inhibitors showed that cyanide behaved as a competitive inhibitor with a K(i) value of 0.15muM; azide revealed a mixed-mode of inhibition. The observed data were found to support a previous model of electrocatalysis, and the role of proton transfer chemistry in the active site is discussed in terms of a structural model.     

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.     

Prosthetic group content and ligand-binding properties of spinach nitrite reductase

Chemical analysis of the ferredoxin-dependent native form (Mr = 85,000) of spinach nitrite reductase has demonstrated a siroheme content that approaches 2 mol of siroheme/mol of enzyme. A widely studied modified (Mr = 61,000) form of nitrite reductase, that has lost much of the native enzyme's ability to use ferredoxin as an electron donor, contains approximately 1 mol of siroheme/mol of enzyme. Quantitation of the high spin ferri-siroheme EPR signals and of nitrite-binding sites of the two preparations confirmed that the native enzyme's siroheme content is approximately twice that of the modified enzyme. Plots of nitrite and cyanide binding to the native enzyme versus ligand concentration are sigmoidal, with Hill coefficients of 1.6-1.8 and 2.3-2.8, respectively. Plots of enzyme activity versus nitrite concentration for the native enzyme are sigmoidal with a Hill coefficient of 2.4. Cyanide inhibition of enzymatic activity was shown to be not competitive. Addition of cyanide to the native enzyme resulted in a diminution of the high spin ferri-siroheme EPR signal and produced EPR signals with g values of 2.71, 2.33, and 1.49 due to low spin ferri-siroheme.     

The relation of ligand binding to redox state in the hexa-heme nitrite reductase of Wolinella succinogenes.

Ligand binding reactions and the relation between redox state and ligand binding in the hexa-heme nitrite reductase of Wolinella succinogenes have been studied using laser flash photolysis. On a picosecond time scale, a rapid excursion was observed corresponding to the breaking and reforming of an iron histidine bond. With the CO derivative, a geminate reaction was observed with a rate of 3 ns-1. On a nanosecond time scale, no slower geminate reactions were observed. For the cyanide derivative, no geminate reactions were observed at either time scale. The second order reaction of CO with the enzyme had a time course consisting of two distinct components. This time course changed in form as the enzyme came to equilibrium with CO, and the slower rebinding component was replaced by a faster rebinding component. It is suggested that CO binding enhances reduction of a heme with an unusually low redox potential and opens the structure of the active site to allow a faster second order reaction of CO. The proportion of the geminate CO reaction was unchanged, consistent with changes relatively remote from the ligand binding site. The second order reactions of cyanide also showed that redox effects influence its rebinding reaction. Adding cyanide to the CO complex of nitrite reductase showed that the two ligands have distinct heme binding sites.     

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.     

Purification and properties of a dissimilatory nitrate reductase from Haloferax denitrificans.

A membrane-bound nitrate reductase (nitrite:(acceptor) oxidoreductase, EC 1.7.99.4) from the extremely halophilic bacterium Haloferax denitrificans was solubilized by incubating membranes in buffer lacking NaCl and purified by DEAE, hydroxylapatite, and Sepharose 6B gel filtration chromatography. The purified nitrate reductase reduced chlorate and was inhibited by azide and cyanide. Preincubating the enzyme with cyanide increased the extent of inhibition which in turn was intensified when dithionite was present. Although cyanide was a noncompetitive inhibitor with respect to nitrate, nitrate protected against inhibition. The enzyme, as isolated, was composed of two subunits (Mr 116,000 and 60,000) and behaved as a dimer during gel filtration (Mr 380,000). Unlike other halobacterial enzymes, this nitrate reductase was most active, as well as stable, in the absence of salt.     

Yeast glutathione reductase. Studies of the kinetics and stability of the enzyme as a function of pH and salt concentration.

1. The pH dependencies of the apparent Michaelis constant for oxidized glutathione and the apparent turnover number of yeast glutathione reductase (EC 1.6.4.2) have been determined at a fixed concentration of 0.1 mM NADPH in the range pH 4.5--8.0. Between pH 5.5 and 7.6, both of these parameters are relatively constant. The principal effect of low pH on the kinetics of the enzyme-catalyzed reaction is the observation of a pH-dependent substrate inhibition by oxidized glutathione at pH less than or equal 7, which is shown to correlate with the binding of oxidized glutathione to the oxidized form of the enzyme. 2. The catalytic activity of yeast glutathione reductase at pH 5.5 is affected by the sodium acetate buffer concentration. The stability of the oxidized and reduced forms of the enzyme at pH 5.5 and 25 degrees C in the absence of bovine serum albumin was studied as a function of sodium acetate concentration. The results show that activation of the catalytic activity of the enzyme at low sodium acetate concentration correlates with an effect of sodium acetate on a reduced form of the enzyme. In contrast, inhibition of the catalytic activity of the enzyme at high sodium acetate concentration correlates with an effect of sodium acetate on the oxidized form of the enzyme.     

Anion inhibition studies of an α-carbonic anhydrase from the thermophilic bacterium Sulfurihydrogenibium yellowstonense YO3AOP1

The newly discovered thermophilic bacterium Sulfurihydrogenibium yellowstonense YO3AOP1 encodes an α-carbonic anhydrases (CAs, EC 4.2.1.1) which is highly catalytically active and thermostable. Here we report the inhibition of this enzyme, denominated SspCA, with inorganic and complex anions and other molecules interacting with zinc proteins. SspCA was inhibited in the micromolar range by diethyldithiocarbamate, sulfamide, sulfamic acid, phenylboronic and phenylarsonic acid, trithiocarbonate and selenocyanide (K(I)s of 4-70μM) and in the submillimolar one by iodide, cyanide, (thio)cyanate, hydrogen sulfide, azide, nitrate, nitrite, many complex anions incorporating heavy metal ions and iminodisulfonate (K(I)s of 0.48-0.86mM). SspCA was not substantially inhibited by bicarbonate and carbonate, hydrogensulfite and peroxidisulfate (K(I)s in the range of 21.1-84.6mM). The exceptional thermostability and lack of strong affinity for hydrogensulfide, bicarbonate, and carbonate make this enzyme an interesting candidate for biotechnological applications of enzymatic CO(2) fixation.     

Biochemical and biophysical studies on cytochrome c oxidase. XX. Reaction with sulphide.

1.Upon addition of sulphide to oxidized cytochrome c oxidase, a low-spin heme sulphide compound is formed with an EPR signal at gx = 2.54, gy = 2.23 and gz = 1.87. Concomitantly with the formation of this signal the EPR-detectable low-spin heme signal at g = 3 and the copper signal near g = 2 decrease in intensity, pointing to a partial reduction of the enzyme by sulphide. 2. The addition of sulphide to cytochrome c oxidase, previously reduced in the presence of azide or cyanide, brings about a disappearance of the azido-cytochrome c oxidase signal at gx = 2.9, gy = 2.2, and gz = 1.67 and a decrease of the signal at g = 3.6 of cyano-cytochrome c oxidase. Concomitantly the sulphide-induced EPR signal is formed. 3. These observations demonstrate that azide, cyanide and sulphide are competitive for an oxidized binding site on cytochrome c oxidase. Moreover, it is shown that the affinity of cyanide and sulphide for this site is greater than that of azide.     

NO production by Pseudomonas aeruginosa cd1 nitrite reductase

The structural and catalytic properties of Pseudomonas aeruginosa cd1 nitrite reductase, a key enzyme in bacterial denitrification, are reviewed in this paper. The mechanism of reduction of nitrite to NO is discussed in detail with special attention to the structural interpretation of function. The ability to stabilize negatively charged molecules, such as the substrate (nitrite) and other ligands (hydroxide and cyanide), is a key feature of catalysis in cd1NIRs. The positive potential in the active site is largely due to the presence of the two conserved distal histidines, which are involved in both substrate binding and product release.     

The steady-state kinetics of the NADH-dependent nitrite reductase from Escherichia coli K 12. Nitrite and hydroxylamine reduction.

The reduction of both NO2- and hydroxylamine by the NADH-dependent nitrite reductase of Escherichia coli K 12 (EC 1.6.6.4) appears to follow Michaelis-Menten kinetics over a wide range of NADH concentrations. Substrate inhibition can, however, be detected at low concentrations of the product NAD+. In addition, NAD+ displays mixed product inhibition with respect to NADH and mixed or uncompetitive inhibition with respect to hydroxylamine. These inhibition characteristics are consistent with a mechanism in which hydroxylamine binds during catalysis to a different enzyme form from that generated when NAD+ is released. The apparent maximum velocity with NADH as varied substrate increases as the NAD+ concentration increases from 0.05 to 0.7 mM with 1 mM-NO2- or 100 mM-hydroxylamine as oxidized substrate. This increase is more marked for hydroxylamine reduction than for NO2- reduction. Models incorporating only one binding site for NAD can account for the variation in the Michaelis-Menten parameters for both NADH and hydroxylamine with [NAD+] for hydroxylamine reduction. According to these models, activation of the reaction occurs by reversal of an over-reduction of the enzyme by NADH. If the observed activation of the enzyme by NAD+ derives both from activation of the generation of the enzyme-hydroxylamine complex from the enzyme-NO2- complex during NO2- reduction and from activation of the reduction of the enzyme-hydroxylamine complex to form NH4+, then the variation of Vapp. for NO2- or hydroxylamine with [NAD+] is consistent with the occurrence of the same enzyme-hydroxylamine complex as an intermediate in both reactions.