Laue crystal structure of Shewanella oneidensis cytochrome c nitrite reductase from a high-yield expression system.

The high-yield expression and purification of Shewanella oneidensis cytochrome c nitrite reductase (ccNiR) and its characterization by a variety of methods, notably Laue crystallography, are reported. A key component of the expression system is an artificial ccNiR gene in which the N-terminal signal peptide from the highly expressed S. oneidensis protein "small tetraheme c" replaces the wild-type signal peptide. This gene, inserted into the plasmid pHSG298 and expressed in S. oneidensis TSP-1 strain, generated approximately 20 mg crude ccNiR per liter of culture, compared with 0.5-1 mg/L for untransformed cells. Purified ccNiR has nitrite and hydroxylamine reductase activities comparable to those previously reported for Escherichia coli ccNiR, and is stable for over 2 weeks in pH 7 solution at 4 °C. UV/vis spectropotentiometric titrations and protein film voltammetry identified five independent one-electron reduction processes. Global analysis of the spectropotentiometric data also allowed determination of the extinction coefficient spectra for the five reduced ccNiR species. The characteristics of the individual extinction coefficient spectra suggest that, within each reduced species, the electrons are distributed among the various hemes, rather than being localized on specific heme centers. The purified ccNiR yielded good-quality crystals, with which the 2.59-Å-resolution structure was solved at room temperature using the Laue diffraction method. The structure is similar to that of E. coli ccNiR, except in the region where the enzyme interacts with its physiological electron donor (CymA in the case of S. oneidensis ccNiR, NrfB in the case of the E. coli protein).

Structure and function of formate-dependent cytochrome c nitrite reductase, NrfA.

Cytochrome c nitrite reductase, NrfA, catalyzes the six-electron reduction of nitrite, NO(2)(-), to ammonium, NH(4)(+), as the final enzymatic step in the dissimilatory metabolic pathway of nitrite ammonification within the biogeochemical nitrogen cycle. NrfA is a 55-65kDa protein that binds five c-type heme groups via thioether bonds to the cysteines of conserved CXXCH heme attachment motifs. Four of these heme groups are considered to be electron transfer centers, with two histidine residues as axial ligands. The remaining heme group features an unusual CXXCK-binding motif, making lysine the proximal axial ligand and leaving the distal position for the substrate binding site located in a secluded binding pocket within the protein. The substrate nitrite is coordinated to the active site heme iron though the free electron pair at the nitrogen atom and is reduced in a consecutive series of electron and proton transfers to the final product, the ammonium ion. While no intermediates of the reaction are released, NrfA is able to reduce various other nitrogen oxides such as nitric oxide (NO), hydroxylamine (H(2)NOH), and nitrous oxide (N(2)O), but notably also sulfite, providing the only known direct link between the nitrogen and sulfur cycles. NrfA invariably forms stable homodimers, but there are at least two distinct electron transfer systems to the enzyme. In many enterobacterial species, NrfA is linked to the menaquinol pool in the cytoplasmic membrane through a soluble electron carrier, NrfB, that in turn interacts with a membrane-integral quinol dehydrogenase, NrfCD. In δ- and ε-proteobacteria, the dimeric NrfA forms a complex with a small quinol dehydrogenase of the NapC/NirT family, NrfH, allowing a more efficient electron transfer.

Escherichia coli cytochrome c nitrite reductase NrfA.

The periplasmic cytochrome c nitrite reductase (Nrf) system of Escherichia coli utilizes nitrite as a respiratory electron acceptor by reducing it to ammonium. Nitric oxide (NO) is a proposed intermediate in this six-electron reduction and NrfA can use exogenous NO as a substrate. This chapter describes the method used to assay Nrf-catalyzed NO reduction in whole cells of E. coli and the procedures for preparing highly purified NrfA suitable for use in kinetic, spectroscopic, voltammetric, and crystallization studies.

Isolation and oligomeric composition of cytochrome c nitrite reductase from the haloalkaliphilic bacterium Thioalkalivibrio nitratireducens.

A new procedure for isolation of cytochrome c nitrite reductase from the haloalkaliphilic bacterium Thioalkalivibrio nitratireducens increasing significantly the yield of the purified enzyme is presented. The enzyme is isolated from the soluble fraction of the cell extract as a hexamer, as shown by gel filtration chromatography and small angle X-ray scattering analysis. Thermostability of the hexameric form of the nitrite reductase is characterized in terms of thermoinactivation and thermodenaturation.

A needle in a haystack: the active site of the membrane-bound complex cytochrome c nitrite reductase.

Cytochrome c nitrite reductase is a multicenter enzyme that uses a five-coordinated heme to perform the six-electron reduction of nitrite to ammonium. In the sulfate reducing bacterium Desulfovibrio desulfuricans ATCC 27774, the enzyme is purified as a NrfA2NrfH complex that houses 14 hemes. The number of closely-spaced hemes in this enzyme and the magnetic interactions between them make it very difficult to study the active site by using traditional spectroscopic approaches such as EPR or UV-Vis. Here, we use both catalytic and non-catalytic protein film voltammetry to simply and unambiguously determine the reduction potential of the catalytic heme over a wide range of pH and we demonstrate that proton transfer is coupled to electron transfer at the active site.

Resolving complexity in the interactions of redox enzymes and their inhibitors: contrasting mechanisms for the inhibition of a cytochrome c nitrite reductase revealed by protein film voltammetry.

Cytochrome c nitrite reductase is a dimeric decaheme-containing enzyme that catalyzes the reduction of nitrite to ammonium. The contrasting effects of two inhibitors on the activity of this enzyme have been revealed, and defined, by protein film voltammetry (PFV). Azide inhibition is rapid and reversible. Variation of the catalytic current magnitude describes mixed inhibition in which azide binds to the Michaelis complex (approximately 40 mM) with a lower affinity than to the enzyme alone (approximately 15 mM) and leads to complete inhibition of enzyme activity. The position of the catalytic wave reports tighter binding of azide when the active site is oxidized (approximately 39 microM) than when it is reduced. By contrast, binding and release of cyanide are sluggish. The higher affinity of cyanide for reduced versus oxidized forms of nitrite reductase is immediately revealed, as is the presence of two sites for cyanide binding and inhibition of the enzyme. Formation of the monocyano complex by reduction of the enzyme followed by a "rapid" scan to high potentials captures the activity-potential profile of this enzyme form and shows it to be distinct from that of the uninhibited enzyme. The biscyano complex is inactive. These studies demonstrate the complexity that can be associated with inhibitor binding to redox enzymes and illustrate how PFV readily captures and deconvolves this complexity through its impact on the catalytic properties of the enzyme.

Preparation and characterization of the water-soluble heme-binding domain of cytochrome c1 from the Rhodobacter sphaeroides bc1 complex.

The ubiquinol:cytochrome c2 oxidoreductase (bc1 complex) of Rhodobacter sphaeroides consists of four subunits. One of these subunits, cytochrome c1, is the site of interaction with cytochrome c2, a periplasmic protein. In addition, the sequences of the fbcC gene and of the cytochrome c1 subunit that it encodes suggest that the protein should be located on the periplasmic side of the cytoplasmic membrane and that it is anchored to the membrane by a single membrane-spanning alpha-helix located at the carboxyl-terminal end of the polypeptide. Site-directed mutagenesis of the fbcC gene was used to alter the codon for Gln228 to a stop codon. This results in the production of a truncated version of the cytochrome c1 subunit that lacks the membrane anchor at the carboxyl terminus. The bc1 complex fails to assemble properly as a result of this mutation, but the Rb. sphaeroides cells expressing the altered gene contain a water-soluble form of cytochrome c1 in the periplasm. The water-soluble cytochrome c1 was purified and characterized. The amino-terminal sequence is identical with that of the membrane-bound subunit, indicating the signal sequence is properly processed. High pressure liquid chromatography gel filtration chromatography indicates it is monomeric (28 kDa). The heme content and electrochemical properties are similar to those of the intact subunit within the complex. Flash-induced electron transfer kinetics measured using whole cells demonstrated that the water-soluble cytochrome c1 is competent as a reductant for cytochrome c2 within the periplasmic space. These data show that the isolated water-soluble cytochrome c1 retains many of the properties of the membrane-bound subunit of the bc1 complex and, therefore, will be useful for further structural and functional characterization.

Some recent advances relating to prokaryotic cytochrome c reductases and cytochrome c oxidases.

Prokaryotic systems provide excellent experimental opportunities for exploring structure/function relationships for the complex, membrane-bound, multisubunit enzymes responsible for the reduction and subsequent oxidation of c-type cytochromes in respiratory or photosynthetic electron transport chains. Two points are made in this mini-review: (1) The eukaryotic and prokaryotic aa3-type cytochrome c oxidases are members of an apparently large superfamily of structurally related respiratory oxidases. This superfamily displays considerable variation in terms of the heme prosthetic groups (a or b) as well as the substrate oxidized (quinol or cytochrome c). The relationships among these enzymes help to facilitate explorations of how they work. (2) Molecular biology techniques can be used to generate intact, redox-active, water-soluble domains of membrane-bound subunits. These soluble domains can be used for detailed examination, including obtaining high resolution structure by NMR techniques or by X-ray crystallography. This approach is being used to study the soluble heme-binding domain of cytochrome c1 from the bc1 complex of Rhodobacter sphaeroides.

An atypical heme-binding structure of cytochrome c1 of Euglena gracilis mitochondrial complex III.

Complex III was purified from submitochondrial particles prepared from Euglena gracilis. The purified complex consisted of 10 subunits and lost antimycin sensitivity. The Euglena complex III showed an atypical difference absorption spectrum for cytochrome c1 with its alpha-band maximum at 561 nm. The pyridine ferrohemochrome prepared from covalently bound heme in the Euglena complex III had an alpha-peak at 553 nm. This wavelength is the same as that of pyridine ferrohemochrome prepared from Euglena mitochondrial cytochrome c (c-558), the heme of which is linked to only a single cysteine residue through a thioether bond. Cytochrome c1 which was a heme-stained subunit with a molecular mass of 32.5 kDa was isolated from the purified complex III and its N-terminal sequence of 46 amino acids was determined. On the basis of apparent homologies to cytochromes c1 from other sources, this sequence included the heme-binding region. However, the amino acid at position 36, corresponding to the first cysteine involved in heme linkage in other cytochromes c1, was phenylalanine. Position 39, corresponding to the second cysteine, was not identified despite the treatment for removal of the heme and carboxymethylation of the expected cysteine. The unidentified amino acid is assumed to be a derivative of cysteine to which the heme is linked through a single thioether bond. The histidine-40 corresponding to the probable fifth ligand for heme iron was conserved in Euglena cytochrome c1.

Resolution of the circular dichroism spectra of the mitochondrial cytochrome bc1 complex.

The circular dichroic spectrum of the mitochondrial cytochrome bc1 complex isolated from bovine heart has been resolved into the contributions from the prosthetic groups: cytochrome c1, the 'Rieske' iron-sulphur centre and the two b cytochromes. It is apparent that firstly, the circular dichroism (CD) properties of cytochrome c1 within the bc1 complex differ from those found in the isolated cytochrome c1 and secondly, both the oxidized and reduced b cytochromes exhibit an intense spectrum of bilobic shape, with the wavelengths of the cross-over points closely corresponding to those of the maxima in the optical absorbance spectra. These latter CD features are discussed in relation to the proposed structure of cytochrome b.

Preparation and properties of cardiac cytochrome c1.

A method for the large-scale isolation of beef heart mitochondrial cytochrome c1 in high purity was developed. This method gave higher yield of "one-band" cytochrome c1 than previously reported [Kim, C. H., & King, T. E. (1981) Biochem. Biophys. Res. Commun. 102, 607-614]. In addition, the present method was effective in the preparation of "two-band" cytochrome c1 which was used to prepare the hinge protein according to the principle of sequential resolution [Kim, C. H., & King, T. E. (1983) J. Biol. Chem. 258, 13543-13551]. The isolation of one-band and two-band cytochrome c1 by this procedure could be completed within 3 or 4 days starting with succinate-cytochrome c reductase. One-band cytochrome c1 showed a molecular weight of 44,000 by sedimentation equilibrium and 29,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The disparities in these data from the actual value of 27,924 by amino acid sequence analysis, as previously reported [Wakabayashi, S., Matsubara, H., Kim, C. H., & King, T. E. (1982) J. Biol. Chem. 257, 9335-9344], are most probably due to the formation of detergent or detergent-phosphate complex. A comparison of some properties of one-band cytochrome c1 with those of two-band cytochrome c1 clearly showed significant differences between the two preparations. These results suggest the hypothesis that one of the possible roles of the hinge protein in the mitochondrial respiratory chain is to stabilize the conformation of cytochrome c1.

Characterization of purified cytochrome c1 from Rhodobacter sphaeroides R-26.

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

The EPR spectra of the cytochrome b-c1 complex of Rhodopseudomonas sphaeroides.

The purified cytochrome b-c1 complex of Rhodopseudomonas sphaeroides has two b cytochromes distinguishable by optical, thermodynamic and electron paramagnetic resonance criteria (gz values are approximately equal to 3.75 and approximately equal to 3.4). EPR features typical of a Rieske iron sulfur cluster (g values of 2.03 1.90 and 1.81) and a c1 type cytochrome (g approximately equal to 3.4) were also observed. The b and c1 cytochromes were individually purified from the complex. The cytochrome c1 retained its native EPR spectrum. The b cytochrome lost over 90% of the intensity from the 'b566 type' heme site (g approximately equal to 3.75), while the 'b561 type' heme site (g approximately equal to 3.4) retained its native EPR spectrum.

Purification of the iron-sulfur protein, ubiquinone-binding protein, and cytochrome c1 from a single source of mitochondrial complex III.

By detergent-exchange chromatography using a phenyl-Sepharose CL-4B column, Complex III of the respiratory chain of beef heart mitochondria was efficiently resolved into five fractions that were rich in the iron-sulfur protein, ubiquinone-binding protein, core proteins, cytochrome c1, and cytochrome b, respectively. Complex III was initially bound to the phenyl-Sepharose column equilibrated with buffer containing 0.25% deoxycholate and 0.2 M NaCl. An iron-sulfur protein fraction was first eluted from the column with buffer containing 1% deoxycholate and no salt after removal of phospholipids from the complex by washing with the buffer for the column equilibration, as reported previously (Y. Shimomura, M. Nishikimi, and T. Ozawa, 1984, J. Biol. Chem. 259, 14059-14063). Subsequently, a fraction containing the ubiquinone-binding protein and another containing two core proteins were eluted with buffers containing 1.5 and 3 M guanidine, respectively. A fraction containing cytochrome c1 was then eluted with buffer containing 1% dodecyl octaethylene glycol monoether. Finally, a cytochrome b-rich fraction was eluted with buffer containing 2% sodium dodecyl sulfate. The fractions of the iron-sulfur protein and ubiquinone-binding protein were further purified by gel chromatography on a Sephacryl S-200 superfine column, and the cytochrome c1 fraction was further purified by ion-exchange chromatography on a DEAE-Sepharose CL-6B column; each of the three purified proteins was homogeneous as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

Further studies on the binding of DCCD to cytochrome B and subunit VIII of complex III isolated from beef heart mitochondria.

Complex III (the cytochrome b-c1 complex) from beef heart mitochondria was incubated with [14C]DCCD for various periods of time. The polypeptide profile of the complex was compared in both stained gels and their autoradiograms when three different methods were used to terminate the reaction. Precipitation with ammonium sulfate resulted in the formation of a new band with an apparent molecular weight of 39,000 in both incubated samples and the zero time controls. Reisolation of the complex by centrifugation through 10% sucrose or by precipitation with trichloroacetic acid did not result in any changes in the appearance of the subunit peptides of the complex. Subunit III (cytochrome b) and subunit VIII were the only bands labeled after termination of the reaction by centrifugation through sucrose, while both ammonium sulfate and trichloroacetic precipitation resulted in nonspecific labeling of several other subunits of the complex and increased labeling of subunit VIII relative to subunit III. Preincubation of the complex with antimycin prior to treatment with [14C]DCCD resulted in a 50% decrease in the binding of DCCD to both cytochrome b and subunit VIII. Furthermore, treatment of the complex III with DCCD resulted in a change in the red shift observed after antimycin or myxothiazol addition to the dithionite-reduced complex resulting in a broad peak with no sharp maximum. These results provide further confirmation that DCCD binds preferentially to cytochrome b and subunit VIII of complex III from beef heart mitochondria and suggest that cytochrome b may play a role in proton translocation.

Isolation and characterization of cytochrome C1 from photosynthetic bacterium Rhodopseudomonas sphaeroides R-26.

Cytochrome c1 of photosynthetic bacterium R. sphaeroides R-26 has been purified from isolated cytochrome b-c1 complex to a single polypeptide, using a procedure involving Triton X-100 and urea solubilization, calcium phosphate column chromatography and ammonium sulfate fractionation. The purified protein contains 30 nmoles heme per mg protein and has an apparent molecular weight of 30,000, as determined by sodium dodecylsulfate polyacrylamide gel electrophoresis. Bacterial cytochrome c1 is soluble in aqueous solution in the absence of detergent and has spectral characteristics similar to mammalian cytochrome c1. The amino acid compositions of these two proteins, however, are not comparable.

Microcalorimetric studies of the interactions between cytochromes c and c1 and of their interactions with phospholipids.

Thermotropic properties of purified cytochrome c1 and cytochrome c have been studied by differential scanning calorimetry under various conditions. Both cytochromes exhibit a single endothermodenaturation peak in the differential scanning calorimetric thermogram. Thermodenaturation temperatures are ionic strength, pH, and redox state dependent. The ferrocytochromes are more stable toward thermodenaturation than the ferricytochromes. The enthalpy changes of thermodenaturation of ferro- and ferricytochrome c1 are markedly dependent on the ionic strength of the solution. The effect of the ionic strength of solution on the enthalpy change of thermodenaturation of cytochrome c is rather insignificant. The formation of a complex between cytochromes c and c1 at lower ionic strength causes a significant destabilization of the former and a slight stabilization of the latter. The destabilization of cytochrome c upon mixing with cytochrome c1 was also observed at high ionic strength, under which conditions no stable complex was detected by physical separation. This suggests formation of a transient complex between these two cytochromes. When cytochrome c was complexed with phospholipids, no change in the thermodenaturation temperature was observed, but a great increase in the enthalpy change of thermodenaturation resulted.

Cytochrome c1 from Paracoccus denitrificans.

Cytochrome c1 was purified from the bacterium Paracoccus denitrificans. It is an acidic, hydrophobic polypeptide with an apparent molecular weight of around 65000 and a single, covalently attached heme; it cross-reacts immunologically with cytochrome c1 from yeast mitochondria. The amino acid sequence of the tryptic heme peptide of the bacterial cytochrome c1 shows extensive homology to the corresponding region of beef heart cytochrome c1 [Wakabayashi, S. et al. (1982) J. Biol. Chem. 257, 9335-9344]. Positive evidence for a stable association of the Paracoccus cytochrome c1 with other polypeptides and b-type heme components ('bc1-complex') has not yet been obtained.