Electrochemically driven catalysis of Rhizobium sp. NT-26 arsenite oxidase with its native electron acceptor cytochrome c552

We describe the catalytic voltammograms of the periplasmic arsenite oxidase (Aio) from the chemolithoautotrophic bacterium Rhizobium sp. str. NT-26 that oxidizes arsenite to arsenate. Electrochemistry of the enzyme was accomplished using its native electron transfer partner, cytochrome c₅₅₂ (cyt c₅₅₂), as a mediator. The protein cyt c₅₅₂ adsorbed on a mercaptoundecanoic acid (MUA) modified Au electrode exhibited a stable, reversible one-electron voltammetric response at + 275 mV vs NHE (pH 6). In the presence of arsenite and Aio the voltammetry of cyt c₅₅₂ is transformed from a transient response to an amplified sigmoidal (steady state) wave consistent with an electro-catalytic system. Digital simulation was performed using a single set of parameters for all catalytic voltammetries obtained at different sweep rates and various substrate concentrations. The obtained kinetic constants from digital simulation provide new insight into the kinetics of the NT-26 Aio catalytic mechanism.     

Localization and concentration of hydroxylamine oxidoreductase and cytochromes c-552, c-554, cm-553, cm-552 and a in Nitrosomonas europaea

Two membrane-associated cytochromes, cytochrome c_m-553 and cytochrome c_m-552, were derived from Nitrosomonas europaea. The major c-type cytochrome, cytochrome c_m-553, accounted for 92% of the c heme found in the membrane. It had absorption maxima at 410 nm in the oxidized form and at 417, 523 and 553 nm in the dithionite reduced form. Cytochrome c_m-552 possessed absorption maxima at 409 nm in the oxidized form, at 421, 522 and 552 in the dithionite reduced form, and at 418 in the dithionite reduced plus CO form. The concentration and cellular distribution of the two c-type membrane cytochromes, hydroxylamine oxidoreductase and cytochromes c-552, c-554, and a were determined. Over 95% of the soluble cytochromes (hydroxylamine oxidoreductase cytochromes and c-552 and c-554) were periplasmic, whereas cytochrome c_m-553, cytochrome c_m-552 and cytochrome a were associated with the cell membrane. The outer membrane and cytoplasm were devoid of cytochromes. The extracytoplasmic location of the proton-yielding hydroxylamine oxidizing system (NH₂OH ™ HNO + 2H⁺ + 2e⁻) may contribute to an energy-linked proton gradient. The heme concentrations of hydroxylamine oxidoreductase and cytochromes c-552, c-554, c_m-553, c_m-552 and a were approx. 2.4, 1.2, 0.3, 1.3, 0.1 and 1.1 nmol/mg cell protein, respectively. The corresponding molar ratios of heme were 22:11:2.9:12:1.0:10. The enzyme or cytochrome concentrations for hydroxylamine oxidoreductase and cytochromes c-552, c-554, c_m-553, c_m-552 and a were approx. 0.13, 1.05, 0.09, 0.63, 0.055 and 0.56 nmol/mg cell protein, respectively. The corresponding molar ratios were 0.24:2.2:0.16:1.2:0.1:1.0.     

Structure and Sequence Conservation of hao Cluster Genes of Autotrophic Ammonia-Oxidizing Bacteria: Evidence for Their Evolutionary History

Comparison of the organization and sequence of the hao (hydroxylamine oxidoreductase) gene clusters from the gammaproteobacterial autotrophic ammonia-oxidizing bacterium (aAOB) Nitrosococcus oceani and the betaproteobacterial aAOB Nitrosospira multiformis and Nitrosomonas europaea revealed a highly conserved gene cluster encoding the following proteins: hao, hydroxylamine oxidoreductase; orf2, a putative protein; cycA, cytochrome c₅₅₄; and cycB, cytochrome c_m552. The deduced protein sequences of HAO, c₅₅₄, and c_m552 were highly similar in all aAOB despite their differences in species evolution and codon usage. Phylogenetic inference revealed a broad family of multi-c-heme proteins, including HAO, the pentaheme nitrite reductase, and tetrathionate reductase. The c-hemes of this group also have a nearly identical geometry of heme orientation, which has remained conserved during divergent evolution of function. High sequence similarity is also seen within a protein family, including cytochromes c_m552, NrfH/B, and NapC/NirT. It is proposed that the hydroxylamine oxidation pathway evolved from a nitrite reduction pathway involved in anaerobic respiration (denitrification) during the radiation of the Proteobacteria. Conservation of the hydroxylamine oxidation module was maintained by functional pressure, and the module expanded into two separate narrow taxa after a lateral gene transfer event between gamma- and betaproteobacterial ancestors of extant aAOB. HAO-encoding genes were also found in six non-aAOB, either singly or tandemly arranged with an orf2 gene, whereas a c₅₅₄ gene was lacking. The conservation of the hao gene cluster in general and the uniqueness of the c₅₅₄ gene in particular make it a suitable target for the design of primers and probes useful for molecular ecology approaches to detect aAOB.     

Cytochrome components of denitrifyingPseudomonas stutzeri

Cytochromesc-551,c-552,c-554,cd, ac type with low α/β peaks, and an acidicc-type cytochrome were detected in extracts ofPseudomonas stutzeri. The first four were purified and physically characterized. Light absorption spectra indicate a probably histidine-methionine liganding of heme iron inc-551 andc-554, but an absence of methionine in the ligand ofc-552 heme iron. In displaying two separately reduciblec-hemes, thec-552 appears homologous with that fromP. perfectomarinus.     

The use of a water-soluble carbodiimide to study the interaction between Chromatium vinosum flavocytochrome c-552 and cytochrome c

The interaction between horse heart cytochrome c and Chromatium vinosum flavocytochrome c-552 was studied using the water-soluble reagent 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC). Treatment of flavocytochrome c-552 with EDC was found to inhibit the sulfide: cytochrome c reductase activity of the enzyme. SDS gel electrophoresis studies revealed that EDC treatment led to modification of carboxyl groups in both the M_r 21000 heme peptide and the M_r 46000 flavin peptide, and also to the formation of a cross-linked heme peptide dimer with an M_r value of 42000. Both the inhibition of sulfide: cytochrome c reductase activity and the formation of the heme peptide dimer were decreased when the EDC modification was carried out in the presence of cytochrome c. In addition, two new cross-linked species with M_r values of 34000 and 59000 were formed. These were identified as cross-linked cytochrome c-heme peptide and cytochrome c-flavin peptide species, respectively. Neither of these species were formed in the presence of a cytochrome c derivative in which all of the lysine amino groups had been dimethylated, demonstrating that EDC had cross-linked lysine amino groups on native cytochrome c to carboxyl groups on the heme and flavin peptides. A complex between cytochrome c and flavocytochrome c-552 was required for cross-linking to occur, since ionic strengths above 100 mM inhibited cross-linking.     

Preliminary X-ray studies on Chromatium vinosum flavocytochrome c552

Preliminary crystallographic data are given for Chromatium vinosum flavocytochrome c₅₅₂. This protein is a 72,000 M_r complex incorporating one flavin and two c-type cytochrome subunits. Interest attaches to the complex structure owing to observed rapid rates of electron transfer between the flavin and heme prosthetic groups. These results suggest that the structure determination of flavocytochrome c₅₅₂ will allow direct examination of a productive interprotein electron transfer complex.     

The reaction of Euglena gracilis cytochrome c-552 with nonphysio-logical oxidants and reductants.

The reaction of Euglena gracilis cytochrome c-552 (cytochrome f) with the nonphysiological reactants potassium ferrocyanide, potassium ferricyanide, sodium ascorbate, sodium dithionite, and Chromatium vinosum high potential nonheme iron protein was studied by stopped-flow and temperature-jump kinetic methods. The reaction of the purified, water-soluble protein with the reactants was investigated as a function of ionic strength, pH, and temperature. The results demonstrated that reduction and oxidation takes place at a negatively charged site on the cytochrome c-552 surface. Participation of specific amino acid residues in electron transfer is implicated from the pH results. The results obtained for the nonphysiological reactions of cytochrome c-552 are compared with available data for horse heart cytochrome c and Rhodospirillum rubrum cytochrome c₂. The results strongly suggest that Euglena gracilis cytochrome c-552 undergoes nonphysiological oxidation and reduction by a mechanism different from that found for cytochrome c or cytochrome c₂.     

SERR Spectroelectrochemical Study of Cytochrome cd 1 Nitrite Reductase Co-Immobilized with Physiological Redox Partner Cytochrome c 552 on Biocompatible Metal Electrodes

Cytochrome cd1 nitrite reductases (cd ₁NiRs) catalyze the one-electron reduction of nitrite to nitric oxide. Due to their catalytic reaction, cd ₁NiRs are regarded as promising components for biosensing, bioremediation and biotechnological applications. Motivated by earlier findings that catalytic activity of cd ₁NiR from Marinobacter hydrocarbonoclasticus (Mhcd ₁) depends on the presence of its physiological redox partner, cytochrome c ₅₅₂ (cyt c ₅₅₂), we show here a detailed surface enhanced resonance Raman characterization of Mhcd ₁ and cyt c ₅₅₂ attached to biocompatible electrodes in conditions which allow direct electron transfer between the conducting support and immobilized proteins. Mhcd ₁ and cyt c552 are co-immobilized on silver electrodes coated with self-assembled monolayers (SAMs) and the electrocatalytic activity of Ag // SAM // Mhcd ₁ // cyt c ₅₅₂ and Ag // SAM // cyt c ₅₅₂ // Mhcd ₁ constructs is tested in the presence of nitrite. Simultaneous evaluation of structural and thermodynamic properties of the immobilized proteins reveals that cyt c ₅₅₂ retains its native properties, while the redox potential of apparently intact Mhcd ₁ undergoes a ~150 mV negative shift upon adsorption. Neither of the immobilization strategies results in an active Mhcd ₁, reinforcing the idea that subtle and very specific interactions between Mhcd ₁ and cyt c ₅₅₂ govern efficient intermolecular electron transfer and catalytic activity of Mhcd ₁.     

SoxAX binding protein, a novel component of the thiosulfate-oxidizing multienzyme system in the green sulfur bacterium Chlorobium tepidum

From the photosynthetic green sulfur bacterium Chlorobium tepidum (pro synon. Chlorobaculum tepidum), we have purified three factors indispensable for the thiosulfate-dependent reduction of the small, monoheme cytochrome c₅₅₄. These are homologues of sulfur-oxidizing (Sox) system factors found in various thiosulfate-oxidizing bacteria. The first factor is SoxYZ that serves as the acceptor for the reaction intermediates. The second factor is monomeric SoxB that is proposed to catalyze the hydrolytic cleavage of sulfate from the SoxYZ-bound oxidized product of thiosulfate. The third factor is the trimeric cytochrome c₅₅₁, composed of the monoheme cytochrome SoxA, the monoheme cytochrome SoxX, and the product of the hypothetical open reading frame CT1020. The last three components were expressed separately in Escherichia coli cells and purified to homogeneity. In the presence of the other two Sox factors, the recombinant SoxA and SoxX showed a low but discernible thiosulfate-dependent cytochrome c₅₅₄ reduction activity. The further addition of the recombinant CT1020 protein greatly increased the activity, and the total activity was as high as that of the native SoxAX-CT1020 protein complex. The recombinant CT1020 protein participated in the formation of a tight complex with SoxA and SoxX and will be referred to as SAXB (SoxAX binding protein). Homologues of the SAXB gene are found in many strains, comprising roughly about one-third of the thiosulfate-oxidizing bacteria whose sox gene cluster sequences have been deposited so far and ranging over the Chlorobiaciae, Chromatiaceae, Hydrogenophilaceae, Oceanospirillaceae, etc. Each of the deduced SoxA and SoxX proteins of these bacteria constitute groups that are distinct from those found in bacteria that apparently lack SAXB gene homologues.     

Studies on well-coupled Photosystem-I-enriched subchloroplast vesicles. Electron transfer by b- and c-type cytochromes in relation to the origin of the ‘slow’ electric potential component

Cytochrome redox changes and electric potential generation are kinetically compared during cyclic electron transfer in Photosystem-I-enriched and Photosystem-II-depleted subchloroplast vesicles (i.e., stroma lamellae membrane vesicles) supplemented with ferredoxin using a suitable electron donating system. In response to a single-turnover flash, the sequence of events is: (1) fast reduction of cytochrome b-563 (t_0.5 ≈ 0.5 ms) (2) oxidation of cytochrome c-554 (t_0.5 ≈ 2 ms), (3) slower reduction of cytochrome b-563 (t_0.5 ≈ 4 ms), (4) generation of the ‘slow’ electric potential component (t_0.5 ≈ 15–20 ms), (5) re-reduction of cytochrome c-554 (t_0.5 ≈ 30 ms) and (6) reoxidation of cytochrome b-563t_0.5 ≈ 90 ms). Per flash two cytochrome b-563 species turn over for one cytochrome c-554. These b-563 cytochromes are reduced with different kinetics via different pathways. The fast reductive pathway proceeds probably via ferredoxin, is insensitive to DNP-INT, DBMIB and HQNO and is independent on the dark redox state of the electron transfer chain. In contrast, the slow reductive pathway is sensitive to DNP-INT and DBMIB, is strongly delayed at suboptimal redox poising (i.e., low $\text{NADPH}\text{NADP}{}^{\mathrm{+}}$ ratio) and is possibly coupled to the reduction of cytochrome c-554. Each reductive pathway seems obligatory for the generation of about 50% of the slow electric potential component. Also cytochrome c-559_LP (LP, low potential) is involved in Photosystem-I-associated cyclic electron flow, but its flash-induced turnover is only observed at low preestablished electron pressure on the electron-transfer chain. Data suggest that cyclic electron flow around Photosystem I only proceeds if cytochrome b-559_LP is in the reduced state before the flash, and a tentative model is presented for electron transfer through the cyclic system.     

Reaction center complex from an aerobic photosynthetic bacterium,Erythrobacter species OCh 114

A photosynthetic reaction center complex has been purified from an aerobic photosynthetic bacterium, Erythrobacter species OCh 114. The reaction center was solubilized with 0.45% lauryldimethylamine N-oxide and purified by DEAE-Sephacel column chromatography. Absorption spectra of both reduced and oxidized forms of the reaction center were very similar to those of the reaction center from Rhodopseudomonas sphaeroides R-26 except for the contributions due to cytochrome and carotenoid. 1 mol reaction center contained 4 mol bacteriochlorophyll a, 2 mol bacteriopheophytin a, 4 mol cytochrome c-554, 2 mol ubiquinone-10, and carotenoid. The reaction center consisted of four different polypeptides of 26, 30, 32 and 42 kDa. The last one retained heme c. Absorbance at 450 nm oscillated with the period of two on consecutive flashes. The light-minus-dark difference spectrum had two peaks at 450 nm and 420 nm, indicating that odd flashes generated a stable ubisemiquinone anion and even flashes generated quinol. o-Phenanthroline accelerated the re-reduction of flash-oxidized reaction centers, indicating that o-phenanthroline inhibited the electron transfer between Q_A and Q_B. The cytochrome (cytochrome c-554) in the reaction center was oxidized on flash activation. The midpoint potential of the primary electron acceptor (Q_A) was determined by measuring the extent of oxidation of cytochrome c-554 at various ambient potentials. The mid-point potential of Q_A was −44 mV, irrespective of pH between 5.5 and 5.9.     

Protein surface charge effect on 3D domain swapping in cells for c-type cytochromes

Many c-type cytochromes (cyts) can form domain-swapped oligomers. The positively charged Hydrogenobacter thermophilus (HT) cytochrome (cyt) c₅₅₂ forms domain-swapped oligomers during expression in the Escherichia coli (E. coli) expression system, but the factors influencing the oligomerization remain unrevealed. Here, we found that the dimer of the negatively charged Shewanella violacea (SV) cyt c₅ exhibits a domain-swapped structure, in which the N-terminal helix is exchanged between protomers, similar to the structures of the HT cyt c₅₅₂ and Pseudomonas aeruginosa (PA) cyt c₅₅₁ domain-swapped dimers. Positively charged horse cyt c and HT cyt c₅₅₂ domain swapped during expression in E. coli, whereas negatively charged PA cyt c₅₅₁ and SV cyt c₅ did not. Oligomers were formed during expression in E. coli for HT cyt c₅₅₂ attached to either a co- or post-translational signal peptide for transportation through the cytoplasm membrane, but not for PA cyt c₅₅₁ attached to either signal peptide. HT cyt c₅₅₂ formed oligomers in E. coli in the presence and absence of rare codons. More oligomers were obtained from the in vitro folding of horse cyt c and HT cyt c₅₅₂ by the addition of negatively charged liposomes during folding, whereas the amount of oligomers for the in vitro folding of PA cyt c₅₅₁ and SV cyt c₅ did not change significantly by the addition. These results indicate that the protein surface charge affects the oligomerization of c-type cyts in cells; positively charged c-type cyts assemble on a negatively charged membrane, inducing formation of domain-swapped oligomers during folding.     

Differential cytochrome content and reductase activity in Geospirillum barnesii strain SeS3

The protein composition, cytochrome content, and reductase activity in the dissimilatory selenate-reducing bacterium Geospirillum barnesii strain SeS3, grown with thiosulfate, nitrate, selenate, or fumarate as the terminal electron acceptor, was investigated. Comparison of seven high-molecular-mass membrane proteins (105.3, 90.3, 82.6, 70.2, 67.4, 61.1, and 57.3 kDa) by SDS-PAGE showed that their detection was dependent on the terminal electron acceptor used. Membrane fractions from cells grown on thiosulfate contained a 70.2-kDa c-type cytochrome with absorbance maxima at 552, 522, and 421 nm. A 61.1-kDa c-type cytochrome with absorption maxima at 552, 523, and 423 nm was seen in membrane fractions from cells grown on nitrate. No c-type cytochromes were detected in membrane fractions of either selenate- or fumarate-grown cells. Difference spectra, however, revealed the presence of a cytochrome b ₅₅₄ (absorption maxima at 554, 523, and 422 nm) in membrane fractions from selenate-grown cells and a cytochrome b ₅₅₆ (absorption maxima at 556, 520, and 416 nm) in membrane fractions from fumarate-grown cells. Analysis of reductase activity in the different membrane fractions showed variability in substrate specificity. However, enzyme activity was greatest for the substrate on which the cells had been grown (e.g., membranes from nitrate-grown cells exhibited the greatest activity with nitrate). These results show that protein composition, cytochrome content, and reductase activity are dependent on the terminal electron acceptor used for growth. Received: 21 August 1996 / Accepted: 24 October 1996     

Purification of two pressure-regulated c-type cytochromes from a deep-sea barophilic bacterium, Shewanella sp. strain DB-172F

From a deep-sea barophilic bacterium, Shewanella sp. strain DB-172F, a membrane-bound cytochrome c-551 and a cytoplasmic cytochrome c-552 were purified. The cytochrome c-551 contained 44.2 nmol of heme c mg protein⁻¹ and cytochrome c-552 contained 31.3 nmol of heme c mg protein⁻¹. The CO difference spectrum of cytochrome c-551 showed a peak at 413.7 nm and troughs at 423.2, 522 and 552 nm which indicated that this cytochrome combined with CO. Cytochrome c-551 was found to consist of two subunits with molecular masses of 29.1 kDa and 14.7 kDa, respectively, and each subunit contained one heme c molecule. Cytochrome c-552 also consisted of two subunits with molecular masses of 16.9 kDa and 14.7 kDa, respectively, and only one of these subunits contained heme c. Cytochrome c-551 was constitutively synthesized when the cells were grown at pressures of either 0.1 MPa or 60 MPa, whereas cytochrome c-552 was synthesized only at 0.1 MPa. These results together with the results of analysis of membrane-associated catalytic activities suggest that the respiratory system of DB-172F is regulated by pressure and may be intimately related to the baroadaptability mechanism of this deep-sea bacterium.     

Cytochrome c-556, a di-heme protein from Pseudomonas aeruginosa

A procedure is described for the purification of cytochrome c-556 from Pseudomonas aeruginosa. The isolated hemoprotein exists as a dimer with a molecular weight of approximately 77 200. The dimer can be dissociated into a monomeric species (or single polypeptide chain) of 40 500 molecular weight by means of sodium dodecyl sulfate or 4 M urea. The amino acid composition demonstrates the presence of four half-cystine residues per 43 000 molecular weight. Heme and iron analyses indicate that two c-type hemes are covalently linked to each polypeptide chain. The absorption spectrum of ferrocytochrome c-556 has a double α-band with a peak at 556 nm and a shoulder at 552 nm; the β-band appears at 521 nm and the Soret band at 420 nm.The electron paramagnetic resonance spectrum of ferricytochrome c-556 contains the elements of two ferric iron species, one a low spin and the other a high spin form.The function of cytochrome c-556 is obscure. The purified cytochrome does not react with Pseudomonas cytochrome oxidase nor with the Pseudomonas cytochrome c-551 or copper protein.The properties of cytochrome c-556 indicate that it is probably not the same species as the cytochrome c-554 previously isolated from the same organism.     

The NT-26 cytochrome c552 and its role in arsenite oxidation

Arsenite oxidation by the facultative chemolithoautotroph NT-26 involves a periplasmic arsenite oxidase. This enzyme is the first component of an electron transport chain which leads to reduction of oxygen to water and the generation of ATP. Involved in this pathway is a periplasmic c-type cytochrome that can act as an electron acceptor to the arsenite oxidase. We identified the gene that encodes this protein downstream of the arsenite oxidase genes (aroBA). This protein, a cytochrome c₅₅₂, is similar to a number of c-type cytochromes from the α-Proteobacteria and mitochondria. It was therefore not surprising that horse heart cytochrome c could also serve, in vitro, as an alternative electron acceptor for the arsenite oxidase. Purification and characterisation of the c₅₅₂ revealed the presence of a single heme per protein and that the heme redox potential is similar to that of mitochondrial c-type cytochromes. Expression studies revealed that synthesis of the cytochrome c gene was not dependent on arsenite as was found to be the case for expression of aroBA.     

Events Surrounding the Early Development of Euglena Chloroplasts: 14. Biosynthesis of Cytochrome c-552 in Wild Type and Mutant Cells

Lack of a suitable assay has thwarted attempts to measure cytochrome c-552 in dark-grown wild type cells of Euglena gracilis var. bacillaris in mutants and in other situations where the concentrations are low. Purification methods are described based on electrofocusing which provide a cytochrome c-552 preparation homogeneous enough to elicit a single reactive antibody in rabbits; this antibody is then used as a specific and sensitive assay for cytochrome c-552. Dark-grown cells of wild type and of mutants O₁BS, O₂BX, G₁BU and P₁BXL (which make normal sized chloroplasts with abnormal internal structure in the light) have 0.02 to 0.1 × 10⁻¹¹ micromoles of cytochrome c-552 per cell, 10 to 150 times less than light-grown cells. Light-grown cells of these mutants and of wild type show a ratio of chlorophyll to cytochrome of about 300 (mole to mole). Cytochrome c-552 is undetectable in dark-grown Y₁BXD, Y₃BUD, and W₃₄ZUD which cannot carry plastid development beyond the proplastid in light; the light-grown cells of these mutants have levels of cytochrome similar to or lower than dark-grown wild type cells. Cytochrome c-552 is undetectable in light- and dark-grown mutants in which plastid DNA is undetectable (such as Y₂BUL, W₃BUL, W₈BHL, and W₁₀BSmL) consistent with the view, but not proving, that this molecule may be coded, at least in part, in plastid DNA. During light-induced chloroplast development in resting cells, cytochrome c-552 formation behaves in all respects like chlorophyll except that the dark-grown cells contain low amounts of the cytochrome c-552 but lack chlorophyll. Thus, both cytochrome c-552 and chlorophyll show the same lag period even when the length is changed by nutritional manipulation; preillumination largely eliminates the lag in the formation of both molecules, cycloheximide and streptomycin both inhibit the biosynthesis of chlorophyll and cytochrome c-552 in the same manner, and the formation of both during chloroplast development is strictly light-dependent. It is shown that chloroplasts isolated from Euglena by methods thought to give intact organelles, lack 95% of the cytochrome c-552; this and the loss of similar molecules may explain why these isolated chloroplasts are not photosynthetically active.     

Electron transfer kinetics between soluble modules of Paracoccus denitrificans cytochrome c1 and its physiological redox partners

The transient electron transfer (ET) interactions between cytochrome c₁ of the bc₁-complex from Paracoccus denitrificans and its physiological redox partners cytochrome c₅₅₂ and cytochrome c₅₅₀ have been characterized functionally by stopped-flow spectroscopy. Two different soluble fragments of cytochrome c₁ were generated and used together with a soluble cytochrome c₅₅₂ module as a model system for interprotein ET reactions. Both c₁ fragments lack the membrane anchor; the c₁ core fragment (c_1CF) consists of only the hydrophilic heme-carrying domain, whereas the c₁ acidic fragment (c_1AF) additionally contains the acidic domain unique to P. denitrificans. In order to determine the ionic strength dependencies of the ET rate constants, an optimized stopped-flow protocol was developed to overcome problems of spectral overlap, heme autoxidation and the prevalent non-pseudo first order conditions. Cytochrome c₁ reveals fast bimolecular rate constants (10⁷ to 10⁸ M^− 1 s^− 1) for the ET reaction with its physiological substrates c₅₅₂ and c₅₅₀, thus approaching the limit of a diffusion-controlled process, with 2 to 3 effective charges of opposite sign contributing to these interactions. No direct involvement of the N-terminal acidic c₁-domain in electrostatically attracting its substrates could be detected. However, a slight preference for cytochrome c₅₅₀ over c₅₅₂ reacting with cyochrome c₁ was found and attributed to the different functions of both cytochromes in the respiratory chain of P. denitrificans.     

Isolation of Paracoccus denitrificans cytochrome cd1: comparative kinetics with other nitrite reductases

The dissimilatory nitrite reductase of the cytochrome cd₁ type was purified from Paracoccus denitrificans (ATCC 13543) by a novel procedure that avoided conventional ion-exchange techniques. The characterization of this enzyme was extended to include amino acid composition, extinction coefficients, and kinetic properties not previously reported. Cytochromes cd₁ from Alicaligenes faecalis and Pseudomonas aeruginosa were also isolated and assayed with electron donor proteins. The enzymes from all three sources were shown to obey the same integrated rate law. Cross-reactivities were measured in which a reduced donor protein from one strain was assayed with cytochrome cd₁ from another strain using nitrite as ultimate acceptor. Donors included c-type cytochromes and azurins. In general, the enzymes showed specificity for a donor from the same strain; interspecies cross-reactions were typically slower on the order of 10-fold than corresponding native rates. Notable exceptions were Paracoccus cytochrome cd₁, which alone reacted with eukaryotic horse cytochrome c at appreciable rates, and the Pseudomonas cd₁-Alcaligenesc554 reaction, which was 4-fold faster than the native Alcaligenes cd₁-Alcaligenesc554 reaction. For all three enzymes, competitive kinetics were measured in which the alternative substrates, nitrite and oxygen, competed for enzyme in the same assay. It was found that the competitive kinetics were dominated by nonenzymatic reactions involving an enzyme product, nitric oxide.     

Spectroscopic and Kinetic Investigation of the Fully Reduced and Mixed Valence States of ba3-Cytochrome c Oxidase from Thermus thermophilus: A FOURIER TRANSFORM INFRARED (FTIR) AND TIME-RESOLVED STEP-SCAN FTIR STUDY*

The complete understanding of a molecular mechanism of action requires the thermodynamic and kinetic characterization of different states and intermediates. Cytochrome c oxidase reduces O₂ to H₂O, a reaction coupled to proton translocation across the membrane. Therefore, it is necessary to undertake a thorough characterization of the reduced form of the enzyme and the determination of the electron transfer processes and pathways between the redox-active centers. In this study Fourier transform infrared (FTIR) and time-resolved step-scan FTIR spectroscopy have been applied to study the fully reduced and mixed valence states of cytochrome ba₃ from Thermus thermophilus. We used as probe carbon monoxide (CO) to characterize both thermodynamically and kinetically the cytochrome ba₃-CO complex in the 5.25–10.10 pH/pD range and to study the reverse intramolecular electron transfer initiated by the photolysis of CO in the two-electron reduced form. The time-resolved step-scan FTIR data revealed no pH/pD dependence in both the decay of the transient Cu_B¹⁺-CO complex and rebinding to heme a₃ rates, suggesting that no structural change takes place in the vicinity of the binuclear center. Surprisingly, photodissociation of CO from the mixed valence form of the enzyme does not lead to reverse electron transfer from the reduced heme a₃ to the oxidized low-spin heme b, as observed in all the other aa₃ and bo₃ oxidases previously examined. The heme b-heme a₃ electron transfer is guaranteed, and therefore, there is no need for structural rearrangements and complex synchronized cooperativities. Comparison among the available structures of ba₃- and aa₃-cytochrome c oxidases identifies possible active pathways involved in the electron transfer processes and key structural elements that contribute to the different behavior observed in cytochrome ba₃.