Domain-Swapped Dimer of Pseudomonas aeruginosa Cytochrome c 551: Structural Insights into Domain Swapping of Cytochrome c Family Proteins

Cytochrome c (cyt c) family proteins, such as horse cyt c, Pseudomonas aeruginosa cytochrome c ₅₅₁ (PA cyt c ₅₅₁), and Hydrogenobacter thermophilus cytochrome c ₅₅₂ (HT cyt c ₅₅₂), have been used as model proteins to study the relationship between the protein structure and folding process. We have shown in the past that horse cyt c forms oligomers by domain swapping its C-terminal helix, perturbing the Met–heme coordination significantly compared to the monomer. HT cyt c ₅₅₂ forms dimers by domain swapping the region containing the N-terminal α-helix and heme, where the heme axial His and Met ligands belong to different protomers. Herein, we show that PA cyt c ₅₅₁ also forms domain-swapped dimers by swapping the region containing the N-terminal α-helix and heme. The secondary structures of the M61A mutant of PA cyt c ₅₅₁ were perturbed slightly and its oligomer formation ability decreased compared to that of the wild-type protein, showing that the stability of the protein secondary structures is important for domain swapping. The hinge loop of domain swapping for cyt c family proteins corresponded to the unstable region specified by hydrogen exchange NMR measurements for the monomer, although the swapping region differed among proteins. These results show that the unstable loop region has a tendency to become a hinge loop in domain-swapped proteins.     

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.     

Kinetics of the electron transfer reaction of Cytochrome <Emphasis Type="Italic">c</Emphasis><Subscript>552</Subscript> adsorbed on biomimetic electrode studied by time-resolved surface-enhanced resonance Raman spectroscopy and electrochemistry

Cytochrome c ₅₅₂ (Cyt-c ₅₅₂) and its redox partner ba ₃ -oxidase from Thermus thermophilus possess structural differences compared with Horse heart cytochrome c (cyt-c)/cytochrome c oxidase (CcO) system, where the recognition between partners and the electron transfer (ET) process is initiated via electrostatic interactions. We demonstrated in a previous study by surface-enhanced resonance Raman (SERR) spectroscopy that roughened silver electrodes coated with uncharged mixed self-assembled monolayers HS–(CH₂) _n –CH₃/HS–(CH₂) _{n + 1}–OH 50/50, n = 5, 10 or 15, was a good model to mimic the Cyt-c ₅₅₂ redox partner. All the adsorbed molecules are well oriented on such biomimetic electrodes and transfer one electron during the redox process. The present work focuses on the kinetic part of the heterogeneous ET process of Cyt-c ₅₅₂ adsorbed onto electrodes coated with such mixed SAMs of different alkyl chain length. For that purpose, two complementary methods were combined. Firstly cyclic voltammetry shows that the ET between the adsorbed Cyt-c ₅₅₂ and the biomimetic electrode is direct and reversible. Furthermore, it allows the estimation of both the density surface coverage of adsorbed Cyt-c ₅₅₂ and the kinetic constants values. Secondly, time-resolved SERR (TR-SERR) spectroscopy showed that the ET process occurs without conformational change of the Cyt-c ₅₅₂ heme group and allows the determination of kinetic constants. Results show that the kinetic constant values obtained by TR-SERR spectroscopy could be compared to those obtained from cyclic voltammetry. They are estimated at 200, 150 and 40 s⁻¹ for the ET of Cyt-c ₅₅₂ adsorbed onto electrodes coated with mixed SAMs HS–(CH₂) _n –CH₃/HS–(CH₂) _{n + 1}–OH 50/50, n = 5, 10 or 15, respectively. Presented at the joint biannual meeting of the SFB-GEIMM-GRIP, Anglet France, 14–19 October, 2006.     

Lack of Cytochrome c in Mouse Fibroblasts Disrupts Assembly/Stability of Respiratory Complexes I and IV

Cytochrome c (cyt c) is a heme-containing protein that participates in electron transport in the respiratory chain and as a signaling molecule in the apoptotic cascade. Here we addressed the effect of removing mammalian cyt c on the integrity of the respiratory complexes in mammalian cells. Mitochondria from cyt c knockout mouse cells lacked fully assembled complexes I and IV and had reduced levels of complex III. A redox-deficient mutant of cyt c was unable to rescue the levels of complexes I and IV. We found that cyt c is associated with both complex IV and respiratory supercomplexes, providing a potential mechanism for the requirement for cyt c in the assembly/stability of complex IV.The mitochondrial electron transport chain consists of four multisubunit complexes, namely, NADH-ubiquinone oxidoreductase (complex I),² succinate-ubiquinone oxidoreductase (complex II), ubiquinone-cytochrome c oxidoreductase (complex III), and cytochrome c oxidase (complex IV, COX). Cytochrome c (cyt c) shuttles electrons from oxidative phosphorylation complex III to complex IV. Electrons are transferred from reduced cyt c sequentially to the Cu_A site, heme a, heme a₃, and Cu_B binuclear center in the complex IV before being finally transferred to molecular oxygen to generate water (1). Respiratory complexes are assembled into supercomplexes (also called respirasomes). These contain complex I bound to dimeric complex III and a variable copy number of complex IV (2).In Saccharomyces cerevisiae, cyt c is encoded by two genes: CYC1 and CYC7. Mutagenesis studies in yeast have shown that cyt c is required for the assembly of COX (3, 4). In yeast lacking both the cyt c genes (CYC1 and CYC7), COX assembly was absent. It was also shown that cyt c is only structurally required for COX assembly, because a catalytic mutant of cyt c (W65S) was sufficient to bring about near normal levels of COX. However, because yeast lacks complex I, they could not analyze the role of cyt c in the assembly/stability of complex I. Mammals possess two different isoforms of cyt c encoded on different chromosomes: the somatic (cyt cS)- and testis (cyt cT)-specific isoforms. In mouse, the cDNAs bear 74% homology, whereas the proteins possess 86% identity with most dissimilarity in the C terminus.Cardiolipin (CL) is an anionic phospholipid present almost exclusively in the mitochondrial membranes and constitutes 25% of its total phospholipids (5). Work from several laboratories showed that CL is essential for the membrane anchorage of the respiratory supercomplexes. CL has two main roles in the mitochondrial structure and function, namely, stabilization of mitochondrial membranes and specific interactions with proteins. CL deficiency results in inefficient energy transformation by oxidative phosphorylation, swelling of mitochondria, decreased ATP/oxygen ratio, and reduced membrane potential (6, 7). In accordance, in S. cerevisiae lacking CL synthase, the supercomplex comprising complexes III and IV is unstable (8). Assembly mutants of COX had significantly reduced CL synthase activity, whereas assembly mutants of respiratory complex III and complex V showed less inhibition (9). Subsequently, the proton gradient across the inner mitochondrial membrane was found to be important for CL formation and that CL synthase was stimulated by alkaline pH at the matrix side (10). In this study, we investigated the role of cyt c depletion on CL levels by examining its content and composition in cyt c null cells.Here we aimed to answer the following questions: What is the role of cyt c in the assembly and maintenance of the different respiratory complexes in mammals? Are there changes in the content/composition of lipids in the cyt c-ablated cells? Analysis of mouse fibroblasts revealed that cyt c is essential for the assembly/stability of COX, and a catalytically mutant form of cyt c cannot rescue the COX defect in the cyt c null cells. CL and triacylglycerols showed significant differences in the cyt c null cells, both in content and composition.     

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.     

Defects in cytochrome cd 1-dependent nitrite respiration of transposon Tn5-induced mutants from Pseudomonas stutzeri

Mutants with defective respiratory nitrite utilization (Nir^- phenotype) were obtained by transposon Tn5 insertion into genomic DNA of the ZoBell strain of Pseudomonas stutzeri. Three representative mutants were characterized with respect to their activities of nitrite and nitric oxide reduction, cytochrome cd ₁ content, and pattern of soluble c-type cytochromes. Mutant strain MK201 over-produced cytochrome c ₅₅₂ about fourfold by comparison with the wild type, but possessed an in vitro functional cytochrome cd ₁. Mutant strain MK202 lacked cytochrome cd ₁ and, simultaneously, had low amounts of cytochrome c ₅₅₂ and the split -peak c-type cytochrome. Strain MK203 synthesized nitrite reductase defective in the heme d ₁ prosthetic group. Irrespective of these biochemically distinct Nir^- phenotypes, all mutants preserved the nitric oxidereducing capability of the wild type. The mutant characteristics demonstrate that cytochrome cd ₁ is essential for nitrite respiration of P. stutzeri and establish the presence of a nitric oxide-reducing system distinct from cytochrome cd ₁. They also indicate the functional or regulatory interdependence of c-type cytochromes.     

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.     

Cytochrome cd1 Nitrite Reductase NirS Is Involved in Anaerobic Magnetite Biomineralization in Magnetospirillum gryphiswaldense and Requires NirN for Proper d1 Heme Assembly

The alphaproteobacterium Magnetospirillum gryphiswaldense synthesizes magnetosomes, which are membrane-enveloped crystals of magnetite. Here we show that nitrite reduction is involved in redox control during anaerobic biomineralization of the mixed-valence iron oxide magnetite. The cytochrome cd₁-type nitrite reductase NirS shares conspicuous sequence similarity with NirN, which is also encoded within a larger nir cluster. Deletion of any one of these two nir genes resulted in impaired growth and smaller, fewer, and aberrantly shaped magnetite crystals during nitrate reduction. However, whereas nitrite reduction was completely abolished in the ΔnirS mutant, attenuated but significant nitrite reduction occurred in the ΔnirN mutant, indicating that only NirS is a nitrite reductase in M. gryphiswaldense. However, the ΔnirN mutant produced a different form of periplasmic d₁ heme that was not noncovalently bound to NirS, indicating that NirN is required for full reductase activity by maintaining a proper form of d₁ heme for holo-cytochrome cd₁ assembly. In conclusion, we assign for the first time a physiological function to NirN and demonstrate that effective nitrite reduction is required for biomineralization of wild-type crystals, probably by contributing to oxidation of ferrous iron under oxygen-limited conditions.     

Crystal Structure of the Electron Carrier Domain of the Reaction Center Cytochrome cz Subunit from Green Photosynthetic Bacterium Chlorobium tepidum

In green sulfur photosynthetic bacteria, the cytochrome c_z (cyt c_z) subunit in the reaction center complex mediates electron transfer mainly from menaquinol/cytochrome c oxidoreductase to the special pair (P840) of the reaction center. The cyt c_z subunit consists of an N-terminal transmembrane domain and a C-terminal soluble domain that binds a single heme group. The periplasmic soluble domain has been proposed to be highly mobile and to fluctuate between oxidoreductase and P840 during photosynthetic electron transfer. We have determined the crystal structure of the oxidized form of the C-terminal functional domain of the cyt c_z subunit (C-cyt c_z) from thermophilic green sulfur bacterium Chlorobium tepidum at 1.3-Å resolution. The overall fold of C-cyt c_z consists of four α-helices and is similar to that of class I cytochrome c proteins despite the low similarity in their amino acid sequences. The N-terminal structure of C-cyt c_z supports the swinging mechanism previously proposed in relation with electron transfer, and the surface properties provide useful information on possible interaction sites with its electron transfer partners. Several characteristic features are observed for the heme environment: These include orientation of the axial ligands with respect to the heme plane, surface-exposed area of the heme, positions of water molecules, and hydrogen-bond network involving heme propionate groups. These structural features are essential for elucidating the mechanism for regulating the redox state of cyt c_z.     

Intramolecular Electron Transfer in Pseudomonas aeruginosa cd1 Nitrite Reductase: Thermodynamics and Kinetics

The cd₁ nitrite reductases, which catalyze the reduction of nitrite to nitric oxide, are homodimers of 60 kDa subunits, each containing one heme-c and one heme-d₁. Heme-c is the electron entry site, whereas heme-d₁ constitutes the catalytic center. The 3D structure of Pseudomonas aeruginosa nitrite reductase has been determined in both fully oxidized and reduced states. Intramolecular electron transfer (ET), between c and d₁ hemes is an essential step in the catalytic cycle. In earlier studies of the Pseudomonas stutzeri enzyme, we observed that a marked negative cooperativity is controlling this internal ET step. In this study we have investigated the internal ET in the wild-type and His369Ala mutant of P. aeruginosa nitrite reductases and have observed similar cooperativity to that of the Pseudomonas stutzeri enzyme. Heme-c was initially reduced, in an essentially diffusion-controlled bimolecular process, followed by unimolecular electron equilibration between the c and d₁ hemes (k_ET = 4.3 s⁻¹ and K = 1.4 at 298K, pH 7.0). In the case of the mutant, the latter ET rate was faster by almost one order of magnitude. Moreover, the internal ET rate dropped (by ∼30-fold) as the level of reduction increased in both the WT and the His mutant. Equilibrium standard enthalpy and entropy changes and activation parameters of this ET process were determined. We concluded that negative cooperativity is a common feature among the cd₁ nitrite reductases, and we discuss this control based on the available 3D structure of the wild-type and the H369A mutant, in the reduced and oxidized states.     

Kinetic and Structural Characterization of the Interaction between the FMN Binding Domain of Cytochrome P450 Reductase and Cytochrome c

Cytochrome P450 reductase (CPR) is a diflavin enzyme that transfers electrons to many protein partners. Electron transfer from CPR to cyt c has been extensively used as a model reaction to assess the redox activity of CPR. CPR is composed of multiple domains, among which the FMN binding domain (FBD) is the direct electron donor to cyt c. Here, electron transfer and complex formation between FBD and cyt c are investigated. Electron transfer from FBD to cyt c occurs at distinct rates that are dependent on the redox states of FBD. When compared with full-length CPR, FBD reduces cyt c at a higher rate in both the semiquinone and hydroquinone states. The NMR titration experiments reveal the formation of dynamic complexes between FBD and cyt c on a fast exchange time scale. Chemical shift mapping identified residues of FBD involved in the binding interface with cyt c, most of which are located in proximity to the solvent-exposed edge of the FMN cofactor along with other residues distributed around the surface of FBD. The structural model of the FBD-cyt c complex indicates two possible orientations of complex formation. The major complex structure shows a salt bridge formation between Glu-213/Glu-214 of FBD and Lys-87 of cyt c, which may be essential for the formation of the complex, and a predicted electron transfer pathway mediated by Lys-13 of cyt c. The findings provide insights into the function of CPR and CPR-cyt c interaction on a structural basis.     

Mutagenesis of nitrite reductase from Pseudomonas aeruginosa: tyrosine-10 in the c heme domain is not involved in catalysis

In Pseudomonas aeruginosa, conversion of nitrite to NO in dissimilatory denitrification is catalyzed by the enzyme nitrite reductase (NiR), a homodimer containing a covalently bound c heme and a d₁ heme per subunit. We report the purification and characterization of the first single mutant of P. aeruginosa cd₁ NiR in which Tyr¹⁰ has been replaced by Phe; this amino acid was chosen as a possibly important residue in the catalytic mechanism of this enzyme based on the proposal (Fülöp, V., Moir, J.W.B., Ferguson, S.J. and Hajdu, J. (1995) Cell 81, 369–377) that the topologically homologous Tyr²⁵ plays a crucial role in controlling the activity of the cd₁ NiR from Thiosphaera pantotropha. Our results show that in P. aeruginosa NiR substitution of Tyr¹⁰ with Phe has no effect on the activity, optical spectroscopy and electron transfer kinetics of the enzyme, indicating that distal coordination of the Fe³⁺ of the d₁ heme is provided by different side-chains in different species.     

A Critical Role for the cccA Gene Product,Cytochrome c2, in Diverting Electrons from Aerobic Respiration to Denitrification in Neisseria gonorrhoeae

Neisseria gonorrhoeae is a microaerophile that, when oxygen availability is limited, supplements aerobic respiration with a truncated denitrification pathway, nitrite reduction to nitrous oxide. We demonstrate that the cccA gene of Neisseria gonorrhoeae strain F62 (accession number NG0292) is expressed, but the product, cytochrome c₂, accumulates to only low levels. Nevertheless, a cccA mutant reduced nitrite at about half the rate of the parent strain. We previously reported that cytochromes c₄ and c₅ transfer electrons to cytochrome oxidase cbb₃ by two independent pathways and that the CcoP subunit of cytochrome oxidase cbb₃ transfers electrons to nitrite. We show that mutants defective in either cytochrome c₄ or c₅ also reduce nitrite more slowly than the parent. By combining mutations in cccA (Δc₂), cycA (Δc₄), cycB (Δc₅), and ccoP (ccoP-C368A), we demonstrate that cytochrome c₂ is required for electron transfer from cytochrome c₄ via the third heme group of CcoP to the nitrite reductase, AniA, and that cytochrome c₅ transfers electrons to nitrite reductase by an independent pathway. We propose that cytochrome c₂ forms a complex with cytochrome oxidase. If so, the redox state of cytochrome c₂ might regulate electron transfer to nitrite or oxygen. However, our data are more consistent with a mechanism in which cytochrome c₂ and the CcoQ subunit of cytochrome oxidase form alternative complexes that preferentially catalyze nitrite and oxygen reduction, respectively. Comparison with the much simpler electron transfer pathway for nitrite reduction in the meningococcus provides fascinating insights into niche adaptation within the pathogenic neisseriae.     

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.     

Real-Time Dynamic Adsorption Processes of Cytochrome c on an Electrode Observed through Electrochemical High-Speed Atomic Force Microscopy

An understanding of dynamic processes of proteins on the electrode surface could enhance the efficiency of bioelectronics development and therefore it is crucial to gain information regarding both physical adsorption of proteins onto the electrode and its electrochemical property in real-time. We combined high-speed atomic force microscopy (HS-AFM) with electrochemical device for simultaneous observation of the surface topography and electron transfer of redox proteins on an electrode. Direct electron transfer of cytochrome c (cyt c) adsorbed on a self-assembled monolayers (SAMs) formed electrode is very attractive subject in bioelectrochemistry. This paper reports a real-time visualization of cyt c adsorption processes on an 11-mercaptoundecanoic acid-modified Au electrode together with simultaneous electrochemical measurements. Adsorbing cyt c molecules were observed on a subsecond time resolution simultaneously with increasing redox currents from cyt c using EC-HS-AFM. The root mean square roughness (R_RMS) from the AFM images and the number of the electrochemically active cyt c molecules adsorbed onto the electrode (Γ) simultaneously increased in positive cooperativity. Cyt c molecules were fully adsorbed on the electrode in the AFM images when the peak currents were steady. This use of electrochemical HS-AFM significantly facilitates understanding of dynamic behavior of biomolecules on the electrode interface and contributes to the further development of bioelectronics.     

Formation of engineered intersubunit disulfide bond in cytochrome bc1 complex disrupts electron transfer activity in the complex

Protein domain movement of the Rieske iron-sulfur protein has been speculated to play an essential role in the bifurcated oxidation of ubiquinol catalyzed by the cytochrome bc₁ complex. To better understand the electron transfer mechanism of the bifurcated ubiquinol oxidation at Qp site, we fixed the head domain of ISP at the cyt c₁ position by creating an intersubunit disulfide bond between two genetically engineered cysteine residues: one at position 141 of ISP and the other at position 180 of the cyt c₁ [S141C(ISP)/G180C(cyt c₁)]. The formation of a disulfide bond between ISP and cyt c₁ in this mutant complex is confirmed by SDS-PAGE and Western blot. In this mutant complex, the disulfide bond formation is concurrent with the loss of the electron transfer activity of the complex. When the disulfide bond is released by treatment with β-mercaptoethanol, the activity is restored. These results further support the hypothesis that the mobility of the head domain of ISP is functionally important in the cytochrome bc₁ complex. Formation of the disulfide bond between ISP and cyt c₁ shortens the distance between the [2Fe-2S] cluster and heme c₁, hence the rate of intersubunit electron transfer between these two redox prosthetic groups induced by pH change is increased. The intersubunit disulfide bond formation also decreases the rate of stigmatellin induced reduction of ISP in the fully oxidized complex, suggesting that an endogenous electron donor comes from the vicinity of the b position in the cytochrome b.     

Assembly of redox active metallo-enzymes and metallo-peptides on electrodes: Abiological constructs to probe natural processes

Redox active metallo-proteins and metallo-peptides attached to self-assembled monolayers (SAM) of thiols on Au electrodes or constituting the SAM on Au electrodes can provide unique opportunities to investigate a range of complicated biological phenomena in controlled abiological constructs. In addition to conventional biochemical tools like site-directed mutagenesis, these constructs allow control over electron transfer (ET) processes, micro solvation (SAM design), folding/misfolding and orientation of these biological entities. This article presents a review of the work done by this group in creating abiological bio-inspired SAM on Au electrodes to probe several important biological processes where redox plays or might play a major role. These include stabilisation of different morphologies of Aβ peptides and which allow investigation of the reactivity of their Cu/Zn/heme-bound forms, determination of both outer-sphere and inner-sphere reorganisation energies of cytochrome c along with deciphering the role of the fluxional methionine and finally creation of bio-chemical constructs of cytochrome c oxidase which not only reduce O₂ selectively to H₂O efficiently but also provide key insights in O₂ reduction mechanism which has aided the development of efficient artificial catalysts.     

Lytic and Non-Lytic Permeabilization of Cardiolipin-Containing Lipid Bilayers Induced by Cytochrome c

The release of cytochrome c (cyt c) from mitochondria is an important early step during cellular apoptosis, however the precise mechanism by which the outer mitochondrial membrane becomes permeable to these proteins is as yet unclear. Inspired by our previous observation of cyt c crossing the membrane barrier of giant unilamellar vesicle model systems, we investigate the interaction of cyt c with cardiolipin (CL)-containing membranes using the innovative droplet bilayer system that permits electrochemical measurements with simultaneous microscopy observation. We find that cyt c can permeabilize CL-containing membranes by induction of lipid pores in a dose-dependent manner, with membrane lysis eventually observed at relatively high (µM) cyt c concentrations due to widespread pore formation in the membrane destabilizing its bilayer structure. Surprisingly, as cyt c concentration is further increased, we find a regime with exceptionally high permeability where a stable membrane barrier is still maintained between droplet compartments. This unusual non-lytic state has a long lifetime (>20 h) and can be reversibly formed by mechanically separating the droplets before reforming the contact area between them. The transitions between behavioural regimes are electrostatically driven, demonstrated by their suppression with increasing ionic concentrations and their dependence on CL composition. While membrane permeability could also be induced by cationic PAMAM dendrimers, the non-lytic, highly permeable membrane state could not be reproduced using these synthetic polymers, indicating that details in the structure of cyt c beyond simply possessing a cationic net charge are important for the emergence of this unconventional membrane state. These unexpected findings may hold significance for the mechanism by which cyt c escapes into the cytosol of cells during apoptosis.     

Isolation and Characterization of Rhodobacter capsulatus Mutants Affected in Cytochrome cbb3 Oxidase Activity

The facultative phototrophic bacterium Rhodobacter capsulatus contains only one form of cytochrome (cyt) c oxidase, which has recently been identified as a cbb₃-type cyt c oxidase. This is unlike other related species, such as Rhodobacter sphaeroides and Paracoccus denitrificans, which contain an additional mitochondrial-like aa₃-type cyt c oxidase. An extensive search for mutants affected in cyt c oxidase activity in R. capsulatus led to the isolation of at least five classes of mutants. Plasmids complementing them to a wild-type phenotype were obtained for all but one of these classes from a chromosomal DNA library. The first class of mutants contained mutations within the structural genes (ccoNOQP) of the cyt cbb₃ oxidase. Sequence analysis of these mutants and of the plasmids complementing them revealed that ccoNOQP in R. capsulatus is not flanked by the oxygen response regulator fnr, which is located upstream of these genes in other species. Genetic and biochemical characterizations of mutants belonging to this group indicated that the subunits CcoN, CcoO, and CcoP are required for the presence of an active cyt cbb₃ oxidase, and unlike in Bradyrhizobium japonicum, no active CcoN-CcoO subcomplex was found in R. capsulatus. In addition, mutagenesis experiments indicated that the highly conserved open reading frame 277 located adjacent to ccoNOQP is required neither for cyt cbb₃ oxidase activity or assembly nor for respiratory or photosynthetic energy transduction in R. capsulatus. The remaining cyt c oxidase-minus mutants mapped outside of ccoNOQP and formed four additional groups. In one of these groups, a fully assembled but inactive cyt cbb₃ oxidase was found, while another group had only extremely small amounts of it. The next group was characterized by a pleiotropic effect on all membrane-bound c-type cytochromes, and the remaining mutants not complemented by the plasmids complementing the first four groups formed at least one additional group affecting the biogenesis of the cyt cbb₃ oxidase of R. capsulatus.The gram-negative facultative photosynthetic bacterium Rhodobacter capsulatus has a highly branched electron transport chain, resulting in its ability to grow under a wide variety of conditions (52). Its light-driven photosynthetic electron transfer pathway is a cyclic process between the photochemical reaction center and the ubihydroquinone cytochrome (cyt) c oxidoreductase (cyt bc₁ complex) (30). On the other hand, the respiratory electron transfer pathways of R. capsulatus are branched after the quinone pool and contain two different terminal oxidases, previously called cyt b₄₁₀ (cyt c oxidase) and cyt b₂₆₀ (quinol oxidase) (3, 27, 29, 53). The branch involving cyt c oxidase is similar to the mitochondrial electron transfer chain in that it depends on the cyt bc₁ complex and a c-type cyt acting as an electron carrier. The quinol oxidase branch circumvents the cyt bc₁ complex and the cyt c oxidase by taking electrons directly from the quinone pool to reduce O₂ to H₂O. The pronounced metabolic versatility, including the ability to grow under dark, anaerobic conditions (50, 52), makes these purple non-sulfur bacteria excellent model organisms for studying microbial energy transduction.Marrs and Gest (29) have reported the first R. capsulatus mutants which were defective in the respiratory electron transport chain. Of these mutants, M5 was incapable of catalyzing the α-naphthol plus N′,N′-dimethyl-p-phenylenediamine (DMPD) plus O₂→indophenol blue plus H₂O reaction (NADI reaction) and unable to grow by respiration (Res⁻), and hence was deficient in both terminal oxidases. Another mutant, M4, was also NADI⁻ but Res⁺ due to the presence of an active quinol oxidase. Marrs and Gest have also described two different spontaneous revertants of M5, called M6 and M7, which regained the ability to grow by respiration (29). M6 regained cyt c oxidase activity and became concurrently NADI⁺ and sensitive to low concentrations of cyanide and the cyt bc₁ inhibitor myxothiazol, but remained quinol oxidase⁻. On the other hand, M7 regained the quinol oxidase activity but remained cyt c oxidase⁻ (thus, NADI⁻ and resistant to myxothiazol, a phenotype identical to that of M4). All of these mutants remained proficient for phototrophic (Ps) growth.The cyt c oxidase of R. capsulatus has been purified previously and characterized as being a novel cbb₃-type cyt c oxidase without a Cu_A center (15). It is composed of at least a membrane-integral b-type cyt (subunit I [CcoN]) with a low-spin heme b and a high-spin heme b₃-Cu_B binuclear center, and two membrane-anchored c-type cyts (CcoO and CcoP). It has a unique active site that possibly confers a very high affinity for its substrate oxygen (49). The structural genes of this enzyme (ccoNOQP) have been sequenced recently from R. capsulatus 37b4 (45) and aligned to the partial amino acid sequence of the purified enzyme from R. capsulatus MT1131 (15). Although a ccoN mutant of strain 37b4 was reported to lack cyt c oxidase activity (45), the observed discrepancies between the amino acid sequence and the nucleotide sequence do not entirely exclude the possible presence of two similar cb-type cyt c oxidases in this species. The presence of a similar cyt c oxidase has also been demonstrated in several other bacteria, including P. denitrificans (9), R. sphaeroides (13), and Rhizobium spp. In the latter species, the homologs of ccoNOQP have been named fixNOQP (23, 34) and are required to support respiration under oxygen-limited growth during symbiotic nitrogen fixation (36).The biogenesis of a multisubunit protein complex containing several prosthetic groups, such as cyt cbb₃ oxidase, is likely to require many accessory proteins involved in various posttranslational events, including protein translocation, assembly, cofactor insertion, and maturation (46). Thus, insights into this important biological process, about which currently little is known, may be gained by searching for mutants defective in cyt c oxidase activity. In this work, we describe the isolation of such mutants and their molecular genetic characterization, including those already available, such as M4, M5, and M7G. These studies indicate that in R. capsulatus, gene products of at least five different loci are involved in the formation of an active cyt cbb₃ oxidase.     

Kinetic studies on redox reactions of hemoproteins. I. Reduction of thermoresistant cytochrome c-552 and horse heart cytochrome c by ferrocyanide

The oxidation-reduction reaction of horse heart cytochrome c and cytochrome c (552, Thermus thermophilus), which is highly thermoresistant, was studied by temperature-jump method. Ferrohexacyanide was used as reductant.

Thermodynamic and activation parameters of the reaction obtained for both cytochromes were compared with each other. The results of this showed that (1) the redox potential of cytochrome c-552,+0.19 V, is markedly less than that of horse heart cytochrome c. (2) ?H_ox³ of cytochrome c-552 is considerably lower than that of horse heart cytochrome c. (3) ?H_ox³ and ?S_red³ of cytoochrome c-552 are more negative than those of horse heart cytochrome c. (4) k_red of cytochrome c-552 is much lower than that of horse heart cytochrome c at room temperature.