Dihaem Cytochrome Research Articles

Influence of haem environment on the catalytic properties of the tetrathionate reductase TsdA from Campylobacter jejuni.

Bifunctional dihaem cytochrome c thiosulfate dehydrogenases/tetrathionate reductases (TsdA) exhibit different catalytic properties depending on the source organism. In the human food-borne intestinal pathogen Campylobacter jejuni, TsdA functions as a tetrathionate reductase enabling respiration with tetrathionate as an alternative electron acceptor. In the present study, evidence is provided that Cys138 and Met255 serve as the sixth ligands of Haem 1 and Haem 2 respectively, in the oxidized CjTsdA wt protein. Replacement of Cys138 resulted in a virtually inactive enzyme, confirming Haem 1 as the active site haem. Significantly, TsdA variants carrying amino acid exchanges in the vicinity of the electron-transferring Haem 2 (Met255, Asn254 and Lys252) exhibited markedly altered catalytic properties of the enzyme, showing these residues play a key role in the physiological function of TsdA. The growth phenotypes and tetrathionate reductase activities of a series of ΔtsdA/*tsdA complementation strains constructed in the original host C. jejuni 81116, showed that invivo, the TsdA variants exhibited the same catalytic properties as the pure, recombinantly produced enzymes. However, variants that catalysed tetrathionate reduction more effectively than the wild-type enzyme did not allow better growth.

Tetrathionate stimulated growth of Campylobacter jejuni identifies a new type of bi‐functional tetrathionate reductase (TsdA) that is widely distributed in bacteria

Tetrathionate (S4 O6 (2-) ) is used by some bacteria as an electron acceptor and can be produced in the vertebrate intestinal mucosa from the oxidation of thiosulphate (S2 O3 (2-) ) by reactive oxygen species during inflammation. Surprisingly, growth of the microaerophilic mucosal pathogen Campylobacter jejuni under oxygen-limited conditions was stimulated by tetrathionate, although it does not possess any known type of tetrathionate reductase. Here, we identify a dihaem cytochrome c (C8j_0815; TsdA) as the enzyme responsible. Kinetic studies with purified recombinant C. jejuni TsdA showed it to be a bifunctional tetrathionate reductase/thiosulphate dehydrogenase with a high affinity for tetrathionate. A tsdA null mutant still slowly reduced, but could not grow on, tetrathionate under oxygen limitation, lacked thiosulphate-dependent respiration and failed to convert thiosulphate to tetrathionate microaerobically. A TsdA paralogue (C8j_0040), lacking the unusual His-Cys haem ligation of TsdA, had low thiosulphate dehydrogenase and tetrathionate reductase activities. Our data highlight a hitherto unrecognized capacity of C. jejuni to use tetrathionate and thiosulphate in its energy metabolism, which may promote growth in the host. Moreover, as TsdA represents a new class of tetrathionate reductase that is widely distributed among bacteria, we predict that energy conserving tetrathionate respiration is far more common than currently appreciated.

Thiosulfate dehydrogenase: a widespread unusual acidophilic c‐type cytochrome

In this work we identified the gene for the tetrathionate-forming thiosulfate dehydrogenase (TsdA) from the purple sulfur bacterium Allochromatium vinosum by sequence analysis and reverse genetics. The recombinant protein produced in Escherichia coli is a periplasmic, monomeric 25.8 kDa dihaem cytochrome c with an enzyme activity optimum at pH 4. UV-visible and electron paramagnetic resonance spectroscopy indicate methionine (strictly conserved M(222) or M(236)) and cysteine (C(123) ) as probable sixth distal axial ligands of the two haem irons in TsdA. These results place TsdA in the group of c-type cytochromes with an unusual axial histidine-cysteine coordination of the haem iron. These proteins appear to play a pivotal role in sulfur-based energy metabolism. Exchange of C(123) to glycine rendered thiosulfate dehydrogenase inactive, proving the importance of this residue for catalysis. TsdA homologues are present in α-, β-, δ-, γ- and ε-Proteobacteria. Three of these were produced in E. coli and exhibited the expected enzymatic activity. The widespread occurrence of tsdA agrees with reports of tetrathionate formation not only by specialized sulfur oxidizers but also by many chemoorganoheterotrophs that use thiosulfate as a supplemental but not as the sole energy source.

Identification of a bacterial di-haem cytochrome c peroxidase from Methylomicrobium album BG8

The nucleotide sequence of an open reading frame (corB) downstream of the copper-repressible CorA-encoding gene of the methanotrophic bacterium Methylomicrobium album BG8 was obtained by restriction enzyme digestion and inverse PCR. The amino acid sequence deduced from this gene showed significant sequence similarity to the surface-associated di-haem cytochrome c peroxidase (SACCP) previously isolated from Methylococcus capsulatus (Bath), including both c-type haem-binding motifs. Homology analysis placed this protein, phylogenetically, within the subfamily containing the M. capsulatus SACCP of the bacterial di-haem cytochrome c peroxidase (BCCP) family of proteins. Immunospecific recognition confirmed synthesis of the M. album CorB as a protein non-covalently associated with the outer membrane and exposed to the periplasm. corB expression is regulated by the availability of copper ions during growth and the protein is most abundant in M. album when grown at a low copper-to-biomass ratio, indicating an important physiological role of CorB under these growth conditions. corB was co-transcribed with the gene encoding CorA, constituting a copper-responding operon, which appears to be under the control of a sigma(54)-dependent promoter. M. album CorB is the second isolated member of the recently described subfamily of the BCCP family of proteins. So far, these proteins have only been described in methanotrophic bacteria.

The periplasmic nitrate reductase in Shewanella: the resolution, distribution and functional implications of two NAP isoforms, NapEDABC and NapDAGHB

In the bacterial periplasm, the reduction of nitrate to nitrite is catalysed by a periplasmic nitrate reductase (NAP) system, which is a species-dependent assembly of protein subunits encoded by the nap operon. The reduction of nitrate catalysed by NAP takes place in the 90 kDa NapA subunit, which contains a Mo-bis-molybdopterin guanine dinucleotide cofactor and one [4Fe-4S] iron-sulfur cluster. A review of the nap operons in the genomes of 19 strains of Shewanella shows that most genomes contain two nap operons. This is an unusual feature of this genus. The two NAP isoforms each comprise three isoform-specific subunits - NapA, a di-haem cytochrome NapB, and a maturation chaperone NapD - but have different membrane-intrinsic subunits, and have been named NAP-alpha (NapEDABC) and NAP-beta (NapDAGHB). Sixteen Shewanella genomes encode both NAP-alpha and NAP-beta. The genome of the vigorous denitrifier Shewanella denitrificans OS217 encodes only NAP-alpha and the genome of the respiratory nitrate ammonifier Shewanella oneidensis MR-1 encodes only NAP-beta. This raises the possibility that NAP-alpha and NAP-beta are associated with physiologically distinct processes in the environmentally adaptable genus Shewanella.

The haem–copper oxygen reductase of Desulfovibrio vulgaris contains a dihaem cytochrome c in subunit II

The genome of the sulphate reducing bacterium Desulfovibrio vulgaris Hildenborough, still considered a strict anaerobe, encodes two oxygen reductases of the bd and haem–copper types. The haem–copper oxygen reductase deduced amino acid sequence reveals that it is a Type A2 enzyme, which in its subunit II contains two c-type haem binding motifs. We have characterized the cytochrome c domain of subunit II and confirmed the binding of two haem groups, both with Met-His iron coordination. Hence, this enzyme constitutes the first example of a ccaa 3 haem–copper oxygen reductase. The expression of D. vulgaris haem–copper oxygen reductase was found to be independent of the electron donor and acceptor source and is not altered by stress factors such as oxygen exposure, nitrite, nitrate, and iron; therefore the haem–copper oxygen reductase seems to be constitutive. The KCN sensitive oxygen reduction by D. vulgaris membranes demonstrated in this work indicates the presence of an active haem–copper oxygen reductase. D. vulgaris membranes perform oxygen reduction when accepting electrons from the monohaem cytochrome c 553, thus revealing the first possible electron donor to the terminal oxygen reductase of D. vulgaris. The physiological implication of the presence of the oxygen reductase in this organism is discussed.

Rhodobacter sphaeroides haem protein: a novel cytochrome with nitric oxide dioxygenase activity

Rhodobacter sphaeroides produces a novel cytochrome, designated as SHP (sphaeroides haem protein), that is unusual in having asparagine as a redox-labile haem ligand. The gene encoding SHP is contained within an operon that also encodes a DHC (dihaem cytochrome c) and a membrane-associated cytochrome b. DHC and SHP have been shown to have high affinity for each other at low ionic strength (Kd=0.2 microM), and DHC is able to reduce SHP very rapidly. The reduced form of the protein, SHP2+ (reduced or ferrous SHP), has high affinity for both oxygen and nitric oxide (NO). It has been shown that the oxyferrous form, SHP2+-O2 (oxygen-bound form of SHP), reacts rapidly with NO to produce nitrate, whereas SHP2+-NO (the NO-bound form of SHP) will react with superoxide with the same product formed. It is therefore possible that SHP functions physiologically as a nitric oxide dioxygenase, protecting the organism against NO poisoning, and we propose a possible mechanism for this process.

Pseudo-merohedral twinning in crystals of the dihaemc-type cytochrome DHC2 fromGeobacter sulfurreducens

The dihaem cytochrome DHC2 from Geobacter sulfurreducens has been described as a model system for the study of one of the conserved haem-packing motifs typically observed in multihaem cytochromes c, in which the covalent attachment of haem to the protein allows effective spatial clustering of redox centres and a high haem:protein ratio. Heterologously expressed DHC2 has been crystallized previously and the structure has been solved by multiple-wavelength anomalous dispersion (MAD) and refined to a resolution of 1.5 A (PDB code 2czs). Crystals belonged to the monoclinic space group P2(1), with unit-cell parameters a = 39.65, b = 55.68, c = 39.64 A, beta = 105.91 degrees . Close inspection of the data indicated the presence of pseudo-merohedral twinning; while not hindering structure solution by MAD, this resulted in high refinement R factors. A re-assessment of the diffraction data for DHC2 is presented, together with a refined structure that includes the twinning present with a twinning fraction alpha of 0.32.

Cross-crystallization method used for the crystallization and preliminary diffraction analysis of a novel di-haem cytochrome c4.

The newly discovered di-haem cytochrome c4 from the purple sulfur photosynthetic bacterium Thiocapsa roseopersicina is the first cytochrome c4 to be crystallized from an anaerobic organism. It was crystallized using the addition of metal-ion salts to the standard vapour-diffusion method. Coloured well shaped three-dimensional crystals with dimensions of approximately 0.6 x 0.05 x 0.02 mm grew within 3-4 d at pH 5 and diffracted to 1.72 angstroms without radiation damage. Cytochrome c4 crystallized in space group P4(1)2(1)2 as a primitive tetragonal system with unit-cell parameters a = b = 75.29, c = 37.12 angstroms, alpha = beta = gamma = 90 degrees.

Crystallization and preliminary X-ray diffraction analysis of the di-haem cytochrome c peroxidase from Pseudomonas stutzeri.

Crystals of cytochrome c peroxidase from Pseudomonas stutzeri were obtained using sodium citrate and PEG 8000 as precipitants. A complete data set was collected to a resolution of 1.6 A under cryogenic conditions using synchrotron radiation at the ESRF. The crystals belong to space group P2(1), with unit-cell parameters a = 69.29, b = 143.31, c = 76.83 A, beta = 100.78 degrees. Four CCP molecules were found in the asymmetric unit, corresponding to a pair of dimers related by local dyads. The crystal packing in the structure shows that the functional dimers can dimerize, as suggested by previous biochemical studies.

Crystallization and preliminary X-ray diffraction analysis of two pH-dependent forms of a di-haem cytochrome c peroxidase from Pseudomonas nautica.

Two crystal forms of cytochrome c peroxidase from Pseudomonas nautica were obtained, one at pH 4.0 using sodium citrate as precipitant and another at pH 5.3 using ammonium phosphate and sodium citrate as precipitants. The two forms belong to different space groups P3(1)21 (pH 4.0) and P6(4)22 (pH 5.3), with unit-cell parameters a = b = 114.5, c = 90.7 A and a = b = 151.0, c = 155.9 A, respectively. Several complete data sets were collected using synchrotron radiation at ESRF and Cu K(alpha) X-ray radiation from a rotating-anode generator. These results will contribute to clarifying the haem transitions occurring during peroxidatic reaction and the required electron-transfer processes and to elucidating the catalytic mechanism of the enzyme and the role of calcium in the activation process.

Crystallization and preliminary X-ray analysis of the periplasmic nitrate reductase (NapA-NapB complex) from Rhodobacter sphaeroides f. sp. denitrificans.

The periplasmic nitrate reductase of Rhodobacter sphaeroides f. sp. denitrificans is a heterodimer responsible for the first step of reduction in the denitrification process by the conversion of nitrate to nitrite. It consists of a 91 kDa molybdenum-containing catalytic subunit (NapA) and a 17 kDa dihaem cytochrome c (NapB). Crystals of the NapA-NapB complex were obtained by the vapour-diffusion method using ammonium sulfate as precipitant. They belong to the P6(1)22 space group, with unit-cell parameters a = b = 151.9, c = 255.8 A, and contain a single complex in the asymmetric unit. A complete native data set was collected at a synchrotron source to 3.1 A resolution.

Succinate:quinone oxidoreductases – what can we learn from Wolinella succinogenes quinol:fumarate reductase?

The structure of Wolinella succinogenes quinol:fumarate reductase by X-ray crystallography has been determined at 2.2-Å resolution [Lancaster et al. (1999), Nature 402, 377–385]. Based on the structure of the three protein subunits A, B, and C and the arrangement of the six prosthetic groups (a covalently bound FAD, three iron–sulphur clusters, and two haem b groups) a pathway of electron transfer from the quinol-oxidising dihaem cytochrome b in the membrane to the site of fumarate reduction in the hydrophilic subunit A has been proposed. By combining the results from site-directed mutagenesis, functional and electrochemical characterisation, and X-ray crystallography, a residue was identified which is essential for menaquinol oxidation. [Lancaster et al. (2000), Proc. Natl. Acad. Sci. USA 97, 13051–13056]. The location of this residue in the structure suggests that the coupling of the oxidation of menaquinol to the reduction of fumarate in dihaem-containing succinate:quinone oxidoreductases could be associated with the generation of a transmembrane electrochemical potential. Based on crystallographic analysis of three different crystal forms of the enzyme and the results from site-directed mutagenesis, we have derived a mechanism of fumarate reduction and succinate oxidation [Lancaster et al. (2001) Eur. J. Biochem. 268, 1820–1827], which should be generally relevant throughout the superfamily of succinate:quinone oxidoreductases.

Methylobacillus flagellatus KT contains a novel cbo-type cytochrome oxidase

The o-type oxidase from the methanol-grown obligate methylotroph Methylobacillus flagellatus KT has been purified to homogeneity. The complex is composed of four subunits (57, 40, 35 and 30 kDa). It contains six haems (4C:1B:1O) and one copper atom per molecule. It is proposed that the haem O-Cu B binuclear centre and a low-spin haem B are located in subunit I (57 kDa), two haems C reside in the cytochrome c homodimer (35 kDa), two haems C belong to the dihaem cytochrome c (30 kDa). The presented data provide evidence that cytochrome cbo is a novel representative of the haem–copper oxidase superfamily.

Overproduction, purification and novel redox properties of the dihaem cytochrome c, NapB, from Haemophilus influenzae

The napB gene of the pathogenic bacterium Haemophilus influenzae encodes a dihaem cytochrome c, the small subunit of a heterodimeric periplasmic nitrate reductase similar to those found in other bacteria. In order to obtain sufficient protein for biophysical studies, we aimed to overproduce the recombinant dihaem protein in Escherichia coli. Initial expression experiments indicated that the NapB signal peptide was not cleaved by the leader peptidase of the host organism. Apocytochrome was formed under aerobic, semi-aerobic and anaerobic growth conditions in either Luria–Bertani or minimal salts medium. The highest amounts of apo-NapB were produced in the latter medium, and the bulk was inserted into the cytoplasmic membrane. The two haem groups were covalently attached to the pre-apocytochrome only under anaerobic growth conditions, and with 2.5mM nitrite or at least 10mM nitrate supplemented to the minimal salts growth medium. In order to obtain holocytochrome, the gene sequence encoding mature NapB was cloned in-frame with the E. coli ompA (outer membrane protein A) signal sequence. Under anaerobic conditions, NapB was secreted into the periplasmic space, with the OmpA signal peptide being correctly processed and with both haem c groups attached covalently. Unless expressed in the DegP-protease-deficient strain HM125, some of the recombinant NapB polypeptides were N-terminally truncated as a result of proteolytic activity. Under aerobic growth conditions, co-expression with the E. coli ccm (cytochrome c maturation) genes resulted in a higher yield of holocytochrome c. The pure recombinant NapB protein showed absorption maxima at 419, 522 and 550nm in the reduced form. The midpoint reduction potentials of the two haem groups were determined to be −25mV and −175mV. These results support our hypothesis that the Nap system fulfils a nitrate-scavenging role in H. influenzae.

Overproduction, purification and novel redox properties of the dihaem cytochrome c, NapB, from Haemophilus influenzae.

The napB gene of the pathogenic bacterium Haemophilus influenzae encodes a dihaem cytochrome c, the small subunit of a heterodimeric periplasmic nitrate reductase similar to those found in other bacteria. In order to obtain sufficient protein for biophysical studies, we aimed to overproduce the recombinant dihaem protein in Escherichia coli. Initial expression experiments indicated that the NapB signal peptide was not cleaved by the leader peptidase of the host organism. Apocytochrome was formed under aerobic, semi-aerobic and anaerobic growth conditions in either Luria--Bertani or minimal salts medium. The highest amounts of apo-NapB were produced in the latter medium, and the bulk was inserted into the cytoplasmic membrane. The two haem groups were covalently attached to the pre-apocytochrome only under anaerobic growth conditions, and with 2.5 mM nitrite or at least 10 mM nitrate supplemented to the minimal salts growth medium. In order to obtain holocytochrome, the gene sequence encoding mature NapB was cloned in-frame with the E. coli ompA (outer membrane protein A) signal sequence. Under anaerobic conditions, NapB was secreted into the periplasmic space, with the OmpA signal peptide being correctly processed and with both haem c groups attached covalently. Unless expressed in the DegP-protease-deficient strain HM125, some of the recombinant NapB polypeptides were N-terminally truncated as a result of proteolytic activity. Under aerobic growth conditions, co-expression with the E. coli ccm (cytochrome c maturation) genes resulted in a higher yield of holocytochrome c. The pure recombinant NapB protein showed absorption maxima at 419, 522 and 550 nm in the reduced form. The midpoint reduction potentials of the two haem groups were determined to be -25 mV and -175 mV. These results support our hypothesis that the Nap system fulfils a nitrate-scavenging role in H. influenzae.

Crystallization and preliminary X-ray analysis of the recombinant dihaem cytochrome c (NapB) from Haemophilus influenzae.

The napB gene of the pathogenic bacterium Haemophilus influenzae encodes a dihaem cytochrome c, the small subunit of a heterodimeric periplasmic nitrate reductase (Nap). Recombinant NapB was overproduced in Escherichia coli, purified to near-homogeneity and crystallized using the hanging-drop method. Thin quadrilateral plates were grown under various conditions but proved to be unsuitable for X-ray analysis. However, a single crystal was grown using 1.75 M ammonium sulfate in 0.1 M sodium acetate pH 5.5, from which a native data set could be collected to 1.8 A resolution using synchrotron radiation. Using the same conditions, further crystals were obtained by microseeding. The space group was determined to be P42(1)2, with unit-cell parameters a = 77.55, b = 77.55, c = 28.64 A and an unusually low solvent content of 16.5%, assuming there to be one molecule of NapB in the asymmetric unit. Analysis of the dissolved crystals indicated that partial proteolysis of the protein had occurred. Taking the molecular mass of the crystallized form ( approximately 8500 Da) into account, the solvent content was estimated to be 53%, with a V(M) value of 2.64 A(3) Da(-1).

Nitrate reduction in the periplasm of gram-negative bacteria

In contrast to the bacterial assimilatory and membrane-associated, respiratory nitrate reductases that have been studied for many years, it is only recently that periplasmic nitrate reductases have attracted growing interest. Recent research has shown that these soluble proteins are widely distributed, but vary greatly between species. All of those so far studied include four essential components: the periplasmic molybdoprotein, NapA, which is associated with a small, di-haem cytochrome, NapB; a putative quinol oxidase, NapC; and a possible pathway-specific chaperone, NapD. At least five other components have been found in different species. Other variations between species include the location of the nap genes on chromosomal or extrachromosomal DNA, and the environmental factors that regulate their expression. Despite the relatively small number of bacteria so far screened, striking correlations are beginning to emerge between the organization of the nap genes, the physiology of the host, the conditions under which the nap genes are expressed, and even the fate of nitrite, the product of Nap activity. Evidence is emerging that Nap fulfills a novel role in nitrate scavenging by some pathogenic bacteria.

Succinate: quinone oxidoreductases: new insights from X-ray crystal structures

Membrane-bound succinate dehydrogenases (succinate:quinone reductases, SQR) and fumarate reductases (quinol:fumarate reductases, QFR) couple the oxidation of succinate to fumarate to the reduction of quinone to quinol and also catalyse the reverse reaction. SQR (respiratory complex II) is involved in aerobic metabolism as part of the citric acid cycle and of the aerobic respiratory chain. QFR is involved in anaerobic respiration with fumarate as the terminal electron acceptor, and is part of an electron transport chain catalysing the oxidation of various donor substrates by fumarate. QFR and SQR complexes are collectively referred to as succinate:quinone oxidoreductases (EC 1.3.5.1), have very similar compositions and are predicted to share similar structures. The complexes consist of two hydrophilic and one or two hydrophobic, membrane-integrated subunits. The larger hydrophilic subunit A carries covalently bound flavin adenine dinucleotide and subunit B contains three iron-sulphur centres. QFR of Wolinella succinogenes and SQR of Bacillus subtilis contain only one hydrophobic subunit (C) with two haem b groups. In contrast, SQR and QFR of Escherichia coli contain two hydrophobic subunits (C and D) which bind either one (SQR) or no haem b group (QFR). The structure of W. succinogenes QFR has been determined at 2.2 Å resolution by X-ray crystallography (C.R.D. Lancaster, A. Kröger, M. Auer, H. Michel, Nature 402 (1999) 377–385). Based on this structure of the three protein subunits and the arrangement of the six prosthetic groups, a pathway of electron transfer from the quinol-oxidising dihaem cytochrome b to the site of fumarate reduction and a mechanism of fumarate reduction was proposed. The W. succinogenes QFR structure is different from that of the haem-less QFR of E. coli, described at 3.3 Å resolution (T.M. Iverson, C. Luna-Chavez, G. Cecchini, D.C. Rees, Science 284 (1999) 1961–1966), mainly with respect to the structure of the membrane-embedded subunits and the relative orientations of soluble and membrane-embedded subunits. Also, similarities and differences between QFR transmembrane helix IV and transmembrane helix F of bacteriorhodopsin and their implications are discussed.

Structure of fumarate reductase from Wolinella succinogenes at 2.2 A resolution.

Fumarate reductase couples the reduction of fumarate to succinate to the oxidation of quinol to quinone, in a reaction opposite to that catalysed by the related complex II of the respiratory chain (succinate dehydrogenase). Here we describe the crystal structure at 2.2 A resolution of the three protein subunits containing fumarate reductase from the anaerobic bacterium Wolinella succinogenes. Subunit A contains the site of fumarate reduction and a covalently bound flavin adenine dinucleotide prosthetic group. Subunit B contains three iron-sulphur centres. The menaquinol-oxidizing subunit C consists of five membrane-spanning, primarily helical segments and binds two haem b molecules. On the basis of the structure, we propose a pathway of electron transfer from the dihaem cytochrome b to the site of fumarate reduction and a mechanism of fumarate reduction. The relative orientations of the soluble and membrane-embedded subunits of succinate:quinone oxidoreductases appear to be unique.